PIC16LF1824T39A
20-Pin Flash Microcontrollers with XLP Technology
High-Performance RISC CPU
• Only 49 Instructions to Learn:
- All single-cycle instructions except branches
• Operating Speed:
- DC – 32 MHz oscillator/clock input
- DC – 125 ns instruction cycle
• Up to 8 Kbytes Linear Program Memory
Addressing
• Up to 256 bytes Linear Data Memory Addressing
• Interrupt Capability with Automatic Context
Saving
• 16-Level Deep Hardware Stack with Optional
Overflow/Underflow Reset
• Direct, Indirect and Relative Addressing modes:
- Two full 16-bit File Select Registers (FSRs)
- FSRs can read program and data memory
Flexible Oscillator Structure
• Precision 32 MHz Internal Oscillator Block:
- Factory calibrated to ± 1%, typical
- Software selectable frequencies range of
31 kHz to 32 MHz
• 31 kHz Low-Power Internal Oscillator
• Four Crystal modes up to 32 MHz
• Three External Clock modes up to 32 MHz
• 4X Phase Lock Loop (PLL)
• Fail-Safe Clock Monitor:
- Allows for safe shutdown if peripheral clock
stops
• Two-Speed Oscillator Start-up
• Reference Clock module:
- Programmable clock output frequency and
duty-cycle
Special Microcontroller Features
• 1.8V-3.6V operation
• Self-Programmable under Software Control
• Power-on Reset (POR), Power-up Timer (PWRT)
and Oscillator Start-up Timer (OST)
• Programmable Brown-out Reset (BOR)
• Extended Watchdog Timer (WDT)
• In-Circuit Serial Programming™ (ICSP™) via
Two Pins
• In-Circuit Debug (ICD) via Two Pins
• Enhanced Low-Voltage Programming (LVP)
• Programmable Code Protection
• Power-Saving Sleep mode
2012-2017 Microchip Technology Inc.
Extreme Low-Power Management with
XLP
•
•
•
•
Sleep mode: 175 nA @ 1.8V, typical, RF Sleep
Watchdog Timer: 200 nA @ 1.8V, typical
Timer1 Oscillator: 650 nA @ 32 kHz, 1.8V, typical
Operating Current: 48 µA/MHz @ 1.8V RF Sleep,
typical
- 9 mA @ 1 MHz, 1.8V, RF on at 0 dBm, typical
- 16.5 mA @ 1 MHz, 1.8V, RF on at +10 dBm,
typical
Analog Features
• Analog-to-Digital Converter (ADC) module:
- 10-bit resolution, up to 12 channels
- Auto acquisition capability
- Conversion available during Sleep
• Analog Comparator module:
- Two rail-to-rail analog comparators
- Power mode control
- Software controllable hysteresis
• Voltage Reference module:
- Fixed Voltage Reference (FVR) with 1.024V,
2.048V and 4.096V output levels
- 5-bit rail-to-rail resistive DAC with positive
and negative reference selection
RF Transmitter
•
•
•
•
Fully-Integrated Transmitter
FSK Operation up to 100 kbps
OOK Operation up to 10 kbps
Frequency-Agile Operation in 310, 433, 868 and
915 MHz Bands
• +10 dBm or 0 dBm Configurable Output Power
Peripheral Highlights
• 11 I/O Pins and 1 Input-only Pin:
- High current sink/source 25 mA/25 mA
- Programmable weak pull-ups
- Programmable interrupt-on-change pins
• Timer0: 8-bit Timer/Counter with 8-bit Prescaler
• Enhanced Timer1:
- 16-bit timer/counter with prescaler
- External Gate Input mode
- Dedicated, low-power 32 kHz oscillator driver
• Three Timer2-types: 8-bit Timer/Counter with 8-bit
Period Register, Prescaler and Postscaler
• Two Capture, Compare, PWM (CCP) modules
• Two Enhanced CCP (ECCP) modules:
- Software selectable time bases
- Auto-shutdown and auto-restart
- PWM steering
DS40001657C-page 1
PIC16LF1824T39A
• Master Synchronous Serial Port (MSSP) with SPI
and I2CTM with:
- 7-bit address masking
- SMBus/PMBusTM compatibility
• Enhanced Universal Synchronous Asynchronous
Receiver Transmitter (EUSART) module
• mTouch™ Sensing Oscillator module:
- 8 input channels
• Data Signal Modulator module:
- Selectable modulator and carrier sources
• SR Latch:
- Multiple Set/Reset input options
- Emulates 555 Timer applications
Note:
Data SRAM
(bytes)
I/O’s(2)
10-bit ADC (ch)
CapSense (ch)
Comparators
Timers
(8/16-bit)
EUSART
MSSP (I2C™/SPI)
ECCP (Full-Bridge)
ECCP (Half-Bridge)
CCP
SR Latch
Debug(1)
XLP
RF
PIC16LF1824T39A
4K
Note 1: One pin is input-only.
Data EEPROM
(bytes)
Device
Program Memory
Flash (words)
PIC16LF1824T39A Family Types
256
256
12
8
8
2
4/1
1
1
1/1/2
Y
I/H
Y
Y
For
other
small
form-factor
package
availability
and
www.microchip.com/packaging or contact your local sales office.
DS40001657C-page 2
marking
information,
visit
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 1:
20-PIN DIAGRAM FOR
PIC16LF1824T39A
TSSOP
VDD
20
VSS
2
19
RA0/ICSPDAT
RA4
3
18
RA1/ICSPCLK
17
RA2
16
RC0
15
RC1
14
RC2
13
XTAL
RA3/MCLR/VPP
4
RC5
5
RC4
6
PIC16LF1824T39A
1
RA5
RC3
7
VDDRF
8
CTRL
9
12
DATA
10
11
VSSRF
RFOUT
2012-2017 Microchip Technology Inc.
DS40001657C-page 3
PIC16LF1824T39A
A/D
Reference
Cap Sense
Comparator
SR Latch
Timers
ECCP
EUSART
MSSP
Interrupt
Modulator
Pull-up
Basic
RA0
19
AN0
VREFDACOUT
CPS0
C1IN+
—
—
—
TX(1)
CK(1)
—
IOC
—
Y
ICSPDAT
ICDDAT
—
RA1
18
AN1
VREF+
CPS1
C12IN0-
SRI
—
—
RX(1)
DT(1)
—
IOC
—
Y
ICSPCLK
ICDCLK
—
RA2
17
AN2
—
CPS2
C1OUT
SRQ
T0CKI
CCP3
FLT0
—
—
INT/
IOC
—
Y
—
—
RA3
4
—
—
—
—
—
T1G(1)
—
—
SS(1)
IOC
—
Y
MCLR
VPP
—
RA4
3
AN3
—
CPS3
—
—
T1G(1)
T1OSO
P2B(1)
—
SDO(1)
IOC
—
Y
OSC2
CLKOUT
CLKR
—
RA5
2
—
—
—
—
—
T1CKI
T1OSI
CCP2
P2A(1)
—
—
IOC
—
Y
OSC1
CLKIN
—
RC0
16
AN4
—
CPS4
C2IN+
—
—
P1D(1)
—
SCL
SCK
—
—
Y
—
—
RC1
15
AN5
—
CPS5
C12IN1-
—
—
CCP4
P1C(1)
—
SDA
SDI
—
—
Y
—
—
RC2
14
AN6
—
CPS6
C12IN2-
—
—
P1D(1)
P2B(1)
—
SDO(1)
—
MDCIN1
Y
—
—
RC3
7
AN7
—
CPS7
C12IN3-
—
—
CCP2(1)
P1C(1)
P2A(1)
—
SS(1)
—
MDMIN
Y
—
—
RC4
6
—
—
—
C2OUT
SRNQ
—
P1B
TX(1)
CK(1)
—
—
MDOUT
Y
—
—
RC5
5
—
—
—
—
—
—
CCP1
P1A
RX(1)
DT(1)
—
—
MDCIN2
Y
—
—
—
RF
20-Pin TSSOP
20-PIN ALLOCATION TABLE (PIC16LF1824T39A)
I/O
TABLE 1:
VDD
1
—
—
—
—
—
—
—
—
—
—
—
—
VDD
Vss
20
—
—
—
—
—
—
—
—
—
—
—
—
VSS
—
CTRL
9
—
—
—
—
—
—
—
—
—
—
—
—
—
CTRL
RFOUT
10
—
—
—
—
—
—
—
—
—
—
—
—
—
RFOUT
DATA
12
—
—
—
—
—
—
—
—
—
—
—
—
—
DATA
XTAL
13
—
—
—
—
—
—
—
—
—
—
—
—
—
XTAL
VDDRF
8
—
—
—
—
—
—
—
—
—
—
—
—
—
VDDRF
—
—
—
—
—
—
—
—
—
—
—
—
—
VSSRF
VSSRF
Note
11
1:
Pin function is selectable via the APFCON0 or APFCON1 registers.
DS40001657C-page 4
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
Table of Contents
1.0 Device Overview .......................................................................................................................................................................... 7
2.0 Enhanced Mid-Range CPU ........................................................................................................................................................ 12
3.0 Memory Organization ................................................................................................................................................................. 14
4.0 Device Configuration .................................................................................................................................................................. 42
5.0 Oscillator Module (With Fail-Safe Clock Monitor)....................................................................................................................... 48
6.0 Reference Clock Module ............................................................................................................................................................ 66
7.0 Resets ........................................................................................................................................................................................ 69
8.0 Interrupts .................................................................................................................................................................................... 78
9.0 Power-Down Mode (Sleep) ........................................................................................................................................................ 92
10.0 Watchdog Timer (WDT) ............................................................................................................................................................. 94
11.0 Data EEPROM and Flash Program Memory Control ................................................................................................................. 97
12.0 I/O Ports ................................................................................................................................................................................... 112
13.0 Interrupt-on-Change ................................................................................................................................................................. 126
14.0 Fixed Voltage Reference (FVR) ............................................................................................................................................... 129
15.0 Temperature Indicator Module ................................................................................................................................................. 131
16.0 Analog-to-Digital Converter (ADC) Module .............................................................................................................................. 132
17.0 Digital-to-Analog Converter (DAC) Module .............................................................................................................................. 145
18.0 SR Latch................................................................................................................................................................................... 150
19.0 Comparator Module.................................................................................................................................................................. 155
20.0 Timer0 Module ......................................................................................................................................................................... 163
21.0 Timer1 Module ......................................................................................................................................................................... 167
22.0 Timer2/4/6 Modules.................................................................................................................................................................. 179
23.0 Data Signal Modulator (DSM) .................................................................................................................................................. 183
24.0 Capture/Compare/PWM Module .............................................................................................................................................. 192
25.0 Master Synchronous Serial Port (MSSP) Module .................................................................................................................... 220
26.0 Enhanced Universal Synchronous Asynchronous Receiver Transmitter (EUSART) ............................................................... 275
27.0 Capacitive Sensing Module...................................................................................................................................................... 303
28.0 RF Transmitter.......................................................................................................................................................................... 311
29.0 In-Circuit Serial Programming™ (ICSP™) ................................................................................................................................ 323
30.0 Instruction Set Summary .......................................................................................................................................................... 326
31.0 Electrical Specifications............................................................................................................................................................ 340
32.0 DC and AC Characteristics Graphs and Tables....................................................................................................................... 368
33.0 Development Support............................................................................................................................................................... 388
34.0 Packaging Information.............................................................................................................................................................. 392
Appendix A: Revision History............................................................................................................................................................. 396
The Microchip Web Site ..................................................................................................................................................................... 397
Customer Change Notification Service .............................................................................................................................................. 397
Customer Support .............................................................................................................................................................................. 397
Product Identification System ............................................................................................................................................................ 398
2012-2017 Microchip Technology Inc.
DS40001657C-page 5
PIC16LF1824T39A
TO OUR VALUED CUSTOMERS
It is our intention to provide our valued customers with the best documentation possible to ensure successful use of your Microchip
products. To this end, we will continue to improve our publications to better suit your needs. Our publications will be refined and
enhanced as new volumes and updates are introduced.
If you have any questions or comments regarding this publication, please contact the Marketing Communications Department via
E-mail at docerrors@microchip.com or fax the Reader Response Form in the back of this data sheet to (480) 792-4150. We
welcome your feedback.
Most Current Data Sheet
To obtain the most up-to-date version of this data sheet, please register at our Worldwide Web site at:
http://www.microchip.com
You can determine the version of a data sheet by examining its literature number found on the bottom outside corner of any page.
The last character of the literature number is the version number, (e.g., DS30000A is version A of document DS30000).
Errata
An errata sheet, describing minor operational differences from the data sheet and recommended workarounds, may exist for current
devices. As device/documentation issues become known to us, we will publish an errata sheet. The errata will specify the revision
of silicon and revision of document to which it applies.
To determine if an errata sheet exists for a particular device, please check with one of the following:
• Microchip’s Worldwide Web site; http://www.microchip.com
• Your local Microchip sales office (see last page)
When contacting a sales office, please specify which device, revision of silicon and data sheet (include literature number) you are
using.
Customer Notification System
Register on our web site at www.microchip.com to receive the most current information on all of our products.
DS40001657C-page 6
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
1.0
DEVICE OVERVIEW
The PIC16LF1824T39A is described within this data
sheet. It is available in 20-pin packages. Figure 1-1 shows
a block diagram of the PIC16LF1824T39A device.
Table 1-2 shows the pinout descriptions.
Reference Table 1-1 for peripherals available per
device.
DEVICE PERIPHERAL
SUMMARY
Peripheral
PIC16LF1824T39A
TABLE 1-1:
ADC
●
Capacitive Sensing Module (CSM)
●
Data EEPROM
●
Digital-to-Analog Converter (DAC)
●
Digital Signal Modulator (DSM)
●
EUSART
●
Fixed Voltage Reference (FVR)
●
SR Latch
●
Capture/Compare/PWM Modules
ECCP1
●
ECCP2
●
CCP3
●
CCP4
●
C1
●
C2
●
MSSP
●
Timer0
●
Timer1
●
Timer2
●
Timer4
●
Timer6
●
Comparators
Master Synchronous Serial Ports
Timers
2012-2017 Microchip Technology Inc.
DS40001657C-page 7
PIC16LF1824T39A
FIGURE 1-1:
PIC16LF1824T39A BLOCK DIAGRAM
Program
Flash Memory
CLKR
RAM
EEPROM
Clock
Reference
OSC2/CLKOUT
Timing
Generation
OSC1/CLKIN
INTRC
Oscillator
PORTA
CPU
(Figure 2-1)
MCLR
PORTC
ADC
10-Bit
Timer0
Timer1
Timer2
Timer4
Timer6
Comparators
SR
Latch
ECCP1
ECCP2
CCP3
CCP4
MSSP
EUSART
TRANSMITTER
Note
1:
2:
DS40001657C-page 8
See applicable chapters for more information on peripherals.
See Table 1-1 for peripherals available on specific devices.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 1-2:
PIC16LF1824T39A PINOUT DESCRIPTION
Name
Function
Input Type
Output Type
RA0
TTL
CMOS
General purpose I/O.
AN0
AN
—
A/D Channel 0 input.
RA0/AN0/CPS0/C1IN+/VREF-/
DACOUT/TX(1)/CK(1)/
ICSPDAT/ICDDAT
Description
CPS0
AN
—
Capacitive sensing input 0.
C1IN+
AN
—
Comparator C1 positive input.
VREF-
AN
—
A/D and DAC Negative Voltage Reference input.
DACOUT
—
AN
Digital-to-Analog Converter output.
TX
—
CMOS
USART asynchronous transmit.
CK
ST
CMOS
USART synchronous clock.
ICSPDAT
ST
CMOS
ICSP™ Data I/O.
ICDDAT
ST
CMOS
In-Circuit Data I/O.
RA1
TTL
CMOS
General purpose I/O.
AN1
AN
—
A/D Channel 1 input.
RA1/AN1/CPS1/C12IN0-/VREF+/
SRI/RX(1)/DT(1)/ICSPCLK/
ICDCLK
CPS1
AN
—
Capacitive sensing input 1.
C12IN0-
AN
—
Comparator C1 or C2 negative input.
VREF+
AN
—
A/D and DAC Positive Voltage Reference input.
SRI
ST
—
SR latch input.
RX
ST
—
DT
ST
CMOS
USART synchronous data.
ICSPCLK
ST
—
Serial Programming Clock.
ICDCLK
ST
—
In-Circuit Debug Clock.
RA2
TTL
CMOS
General purpose I/O.
AN2
AN
—
A/D Channel 2 input.
RA2/AN2/CPS2/T0CKI/INT/
C1OUT/SRQ/CCP3/FLT0
USART asynchronous input.
CPS2
AN
—
Capacitive sensing input 2.
T0CKI
ST
—
Timer0 clock input.
INT
ST
—
C1OUT
—
CMOS
External interrupt.
Comparator C1 output.
SRQ
—
CMOS
SR latch non-inverting output.
CCP3
ST
CMOS
Capture/Compare/PWM3.
FLT0
ST
—
RA3
TTL
—
General purpose input.
SS
ST
—
Slave Select input.
T1G
ST
—
Timer1 Gate input.
VPP
HV
—
Programming voltage.
MCLR
ST
—
Master Clear with internal pull-up.
RA3/SS(1)/T1G(1)/VPP/MCLR
ECCP Auto-Shutdown Fault input.
Legend: AN = Analog input or output CMOS= CMOS compatible input or output
OD = Open Drain
TTL = TTL compatible input ST
= Schmitt Trigger input with CMOS levels I2C = Schmitt Trigger input with I2C
HV = High Voltage
XTAL = Crystal
levels
Note 1: Pin functions can be moved using the APFCONO and APFCON1 registers (Register 12-1 and Register 12-2).
2: Default function location.
2012-2017 Microchip Technology Inc.
DS40001657C-page 9
PIC16LF1824T39A
TABLE 1-2:
PIC16LF1824T39A PINOUT DESCRIPTION (CONTINUED)
Name
RA4/AN3/CPS3/OSC2/
CLKOUT/T1OSO/CLKR/
SDO(1)/P2B(1)/T1G(1,2)
RA5/CLKIN/OSC1/T1OSI/
T1CKI/P2A(1)/CCP2(1)
RC0/AN4/CPS4/C2IN+/SCL/
SCK/P1D(1)
RC1/AN5/CPS5/C12IN1-/SDA/
SDI/P1C(1)/CCP4
RC2/AN6/CPS6/C12IN2-/
P1D(1,2)/P2B(1,2)/SDO(1,2)/
MDCIN1
Function
Input Type
Output Type
Description
RA4
TTL
CMOS
General purpose I/O.
AN3
AN
—
A/D Channel 3 input.
CPS3
AN
—
Capacitive sensing input 3.
OSC2
—
CMOS
Crystal/Resonator (LP, XT, HS modes).
CLKOUT
—
CMOS
FOSC/4 output.
T1OSO
XTAL
XTAL
Timer1 oscillator connection.
CLKR
—
CMOS
Clock Reference output.
SDO
—
CMOS
SPI data output.
P2B
—
CMOS
PWM output.
T1G
ST
—
RA5
TTL
CMOS
Timer1 Gate input.
General purpose I/O.
CLKIN
ST
—
External clock input (EC mode).
OSC1
XTAL
—
Crystal/Resonator (LP, XT, HS modes).
T1OSI
XTAL
XTAL
T1CKI
ST
—
Timer1 oscillator connection.
Timer1 clock input.
P2A
—
CMOS
PWM output.
CCP2
ST
CMOS
Capture/Compare/PWM2.
RC0
TTL
CMOS
General purpose I/O.
AN4
AN
—
A/D Channel 4 input.
Capacitive sensing input 4.
CPS4
AN
—
C2IN+
AN
—
Comparator C2 positive input.
SCL
I2C
OD
I2C clock.
SCK
ST
CMOS
SPI clock.
P1D
—
CMOS
PWM output.
RC1
TTL
CMOS
General purpose I/O.
AN5
AN
—
A/D Channel 5 input.
CPS5
AN
—
Capacitive sensing input 5.
C12IN1-
AN
—
Comparator C1 or C2 negative input.
SDA
I2C
OD
I2C data input/output.
SDI
CMOS
—
SPI data input.
P1C
—
CMOS
CCP4
ST
CMOS
Capture/Compare/PWM4.
RC2
TTL
CMOS
General purpose I/O.
PWM output.
AN6
AN
—
A/D Channel 6 input.
CPS6
AN
—
Capacitive sensing input 6.
C12IN2-
AN
—
Comparator C1 or C2 negative input.
P1D
—
CMOS
P2B
—
CMOS
PWM output.
SDO
—
CMOS
SPI data output.
MDCIN1
ST
—
PWM output.
Modulator Carrier Input 1.
Legend: AN = Analog input or output CMOS= CMOS compatible input or output
OD = Open Drain
TTL = TTL compatible input ST
= Schmitt Trigger input with CMOS levels I2C = Schmitt Trigger input with I2C
HV = High Voltage
XTAL = Crystal
levels
Note 1: Pin functions can be moved using the APFCONO and APFCON1 registers (Register 12-1 and Register 12-2).
2: Default function location.
DS40001657C-page 10
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 1-2:
PIC16LF1824T39A PINOUT DESCRIPTION (CONTINUED)
Name
Function
Input Type
Output Type
RC3
TTL
CMOS
AN7
AN
—
A/D Channel 7 input.
CPS7
AN
—
Capacitive sensing input 7.
C12IN3-
AN
—
Comparator C1 or C2 negative input.
P2A
—
CMOS
PWM output.
CCP2
ST
CMOS
Capture/Compare/PWM2.
P1C
—
CMOS
PWM output.
RC3/AN7/CPS7/C12IN3-/
P2A(1,2)/CCP2(1,2)/P1C(1,2)/
SS(1,2)/MDMIN
RC4/C2OUT/SRNQ/P1B/TX(1,2)/
CK(1,2)/MDOUT
Description
General purpose I/O.
SS
ST
—
Slave Select input.
MDMIN
ST
—
Modulator source input.
RC4
TTL
CMOS
General purpose I/O.
C2OUT
—
CMOS
Comparator C2 output.
SRNQ
—
CMOS
SR latch inverting output.
P1B
—
CMOS
PWM output.
TX
—
CMOS
USART asynchronous transmit.
CK
ST
CMOS
USART synchronous clock.
MDOUT
—
CMOS
Modulator output.
RC5
TTL
CMOS
General purpose I/O.
RC5/P1A/CCP1/RX(1,2)/DT(1,2)/
MDCIN2
P1A
—
CMOS
PWM output.
CCP1
ST
CMOS
Capture/Compare/PWM1.
RX
ST
—
DT
ST
CMOS
USART synchronous data.
MDCIN2
ST
—
Modulator Carrier Input 2.
VDD
Power
—
Positive supply.
Ground reference.
VDD
USART asynchronous input.
VSS
Power
—
VDDRF
VDDRF
Power
—
Positive supply.
VSSRF
VSSRF
Power
—
Ground reference.
CTRL
CTRL
CMOS
—
Configuration Selection and Configuration Clock
VSS
RFOUT
RFOUT
—
RF
DATA
DATA
CMOS
CMOS
XTAL
XTAL
XTAL
—
Transmitter RF output
Configuration Data and Transmit Data
Crystal Oscillator
Legend: AN = Analog input or output CMOS= CMOS compatible input or output
OD = Open Drain
TTL = TTL compatible input ST
= Schmitt Trigger input with CMOS levels I2C = Schmitt Trigger input with I2C
HV = High Voltage
XTAL = Crystal
levels
Note 1: Pin functions can be moved using the APFCONO and APFCON1 registers (Register 12-1 and Register 12-2).
2: Default function location.
2012-2017 Microchip Technology Inc.
DS40001657C-page 11
PIC16LF1824T39A
2.0
ENHANCED MID-RANGE CPU
This family of devices contain an enhanced mid-range
8-bit CPU core. The CPU has 49 instructions. Interrupt
capability includes automatic context saving. The
hardware stack is 16 levels deep and has Overflow and
Underflow Reset capability. Direct, Indirect, and
Relative Addressing modes are available. Two File
Select Registers (FSRs) provide the ability to read
program and data memory.
•
•
•
•
Automatic Interrupt Context Saving
16-level Stack with Overflow and Underflow
File Select Registers
Instruction Set
2.1
Automatic Interrupt Context
Saving
During interrupts, certain registers are automatically
saved in Shadow registers and restored when returning
from the interrupt. This saves stack space and user
code. See Section 8.5 “Automatic Context Saving”,
for more information.
2.2
16-level Stack with Overflow and
Underflow
These devices have an external stack memory 15 bits
wide and 16 words deep. A Stack Overflow or Underflow will set the appropriate bit (STKOVF or STKUNF)
in the PCON register and, if enabled, will cause a
software Reset. See section Section 3.4 “Stack” for
more details.
2.3
File Select Registers
There are two 16-bit File Select Registers (FSR). FSRs
can access all file registers and program memory,
which allows one data pointer for all memory. When an
FSR points to program memory, there is one additional
instruction cycle in instructions using INDF to allow the
data to be fetched. General purpose memory can now
also be addressed linearly, providing the ability to
access contiguous data larger than 80 bytes. There are
also new instructions to support the FSRs. See
Section 3.5 “Indirect Addressing” for more details.
2.4
Instruction Set
There are 49 instructions for the enhanced mid-range
CPU to support the features of the CPU. See
Section 30.0 “Instruction Set Summary” for more
details.
DS40001657C-page 12
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 2-1:
CORE BLOCK DIAGRAM
15
Configuration
15
MUX
Flash
Program
Memory
Program
Bus
16-Level
8 Level Stack
Stack
(13-bit)
(15-bit)
14
Instruction
Instruction Reg
reg
8
Data Bus
Program Counter
RAM
Program Memory
Read (PMR)
12
RAM Addr
Addr MUX
Direct Addr 7
5
Indirect
Addr
12
12
BSR
FSR Reg
reg
15
FSR0reg
Reg
FSR
FSR1
Reg
FSR reg
15
STATUS Reg
reg
STATUS
8
3
Power-up
Timer
OSC1/CLKIN
OSC2/CLKOUT
Instruction
Decodeand
&
Decode
Control
Timing
Generation
Oscillator
Start-up Timer
Power-on
Reset
Watchdog
Timer
Brown-out
Reset
MUX
ALU
8
W reg
Internal
Oscillator
Block
VDD
2012-2017 Microchip Technology Inc.
VSS
DS40001657C-page 13
PIC16LF1824T39A
3.0
MEMORY ORGANIZATION
The following features are associated with access and
control of program memory and data memory:
This device contains the following types of memory:
• PCL and PCLATH
• Stack
• Indirect Addressing
• Program Memory
- Configuration Words
- Device ID
- User ID
- Flash Program Memory
• Data Memory
- Core Registers
- Special Function Registers
- General Purpose RAM
- Common RAM
• Data EEPROM memory(1)
3.1
Program Memory Organization
The enhanced mid-range core has a 15-bit program
counter capable of addressing a 32K x 14 program
memory space. Table 3-1 shows the memory sizes
implemented for the PIC16LF1824T39A device.
Accessing a location above these boundaries will cause
a wrap-around within the implemented memory space.
The Reset vector is at 0000h and the interrupt vector is
at 0004h (see Figure 3-1).
Note 1: The data EEPROM memory and the
method to access Flash memory through
the EECON registers is described in
Section 11.0 “Data EEPROM and Flash
Program Memory Control”.
TABLE 3-1:
DEVICE SIZES AND ADDRESSES
Device
PIC16LF1824T39A
DS40001657C-page 14
Program Memory Space (Words)
Last Program Memory Address
4,096
0FFFh
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 3-1:
PROGRAM MEMORY MAP
AND STACK FOR
PIC16LF1824T39A
PC
CALL, CALLW
RETURN, RETLW
Interrupt, RETFIE
On-chip
Program
Memory
15
3.1.1
READING PROGRAM MEMORY AS
DATA
There are two methods of accessing constants in
program memory. The first method is to use tables of
RETLW instructions. The second method is to set an
FSR to point to the program memory.
3.1.1.1
RETLW Instruction
Stack Level 0
Stack Level 1
The RETLW instruction can be used to provide access
to tables of constants. The recommended way to create
such a table is shown in Example 3-1.
Stack Level 15
EXAMPLE 3-1:
Reset Vector
0000h
Interrupt Vector
0004h
0005h
Page 0
07FFh
0800h
Page 1
Rollover to Page 0
Wraps to Page 0
0FFFh
1000h
2012-2017 Microchip Technology Inc.
RETLW
RETLW
RETLW
RETLW
DATA0
DATA1
DATA2
DATA3
RETLW INSTRUCTION
;Add Index in W to
;program counter to
;select data
;Index0 data
;Index1 data
my_function
;… LOTS OF CODE…
MOVLW
DATA_INDEX
call constants
;… THE CONSTANT IS IN W
The BRW instruction makes this type of table very
simple to implement. If your code must remain portable
with previous generations of microcontrollers, then the
BRW instruction is not available so the older table read
method must be used.
Wraps to Page 0
Rollover to Page 1
constants
BRW
7FFFh
DS40001657C-page 15
PIC16LF1824T39A
3.1.1.2
Indirect Read with FSR
The program memory can be accessed as data by
setting bit 7 of the FSRxH register and reading the
matching INDFx register. The MOVIW instruction will
place the lower eight bits of the addressed word in the
W register. Writes to the program memory cannot be
performed via the INDF registers. Instructions that
access the program memory via the FSR require one
extra instruction cycle to complete. Example 3-2
demonstrates accessing the program memory via an
FSR.
The High directive will set bit if a label points to a
location in program memory.
EXAMPLE 3-2:
ACCESSING PROGRAM
MEMORY VIA FSR
constants
RETLW DATA0
;Index0 data
RETLW DATA1
;Index1 data
RETLW DATA2
RETLW DATA3
my_function
;… LOTS OF CODE…
MOVLW
LOW constants
MOVWF
FSR1L
MOVLW
HIGH constants
MOVWF
FSR1H
MOVIW
0[FSR1]
;THE PROGRAM MEMORY IS IN W
3.2
3.2.1
CORE REGISTERS
The core registers contain the registers that directly
affect the basic operation. The core registers occupy
the first 12 addresses of every data memory bank
(addresses x00h/x08h through x0Bh/x8Bh). These
registers are listed in Table 3-2 below. For detailed
information, see Table 3-3.
TABLE 3-2:
CORE REGISTERS
Addresses
BANKx
x00h or x80h
x01h or x81h
x02h or x82h
x03h or x83h
x04h or x84h
x05h or x85h
x06h or x86h
x07h or x87h
x08h or x88h
x09h or x89h
x0Ah or x8Ah
x0Bh or x8Bh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
Data Memory Organization
The data memory is partitioned in 32 memory banks
with 128 bytes in a bank. Each bank consists of
(Figure 3-2):
•
•
•
•
12 core registers
20 Special Function Registers (SFR)
Up to 80 bytes of General Purpose RAM (GPR)
16 bytes of common RAM
The active bank is selected by writing the bank number
into the Bank Select Register (BSR). Unimplemented
memory will read as ‘0’. All data memory can be
accessed either directly (via instructions that use the
file registers) or indirectly via the two File Select
Registers (FSR). See Section 3.5 “Indirect
Addressing” for more information.
DS40001657C-page 16
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
3.2.1.1
STATUS Register
The STATUS register, shown in Register 3-1, contains:
• the arithmetic status of the ALU
• the Reset status
The STATUS register can be the destination for any
instruction, like any other register. If the STATUS
register is the destination for an instruction that affects
the Z, DC or C bits, then the write to these three bits is
disabled. These bits are set or cleared according to the
device logic. Furthermore, the TO and PD bits are not
writable. Therefore, the result of an instruction with the
STATUS register as destination may be different than
intended.
REGISTER 3-1:
U-0
It is recommended, therefore, that only BCF, BSF,
SWAPF and MOVWF instructions are used to alter the
STATUS register, because these instructions do not
affect any Status bits. For other instructions not
affecting any Status bits (Refer to Section 30.0
“Instruction Set Summary”).
Note 1: The C and DC bits operate as Borrow
and Digit Borrow out bits, respectively, in
subtraction.
STATUS: STATUS REGISTER
U-0
—
For example, CLRF STATUS will clear the upper three
bits and set the Z bit. This leaves the STATUS register
as ‘000u u1uu’ (where u = unchanged).
—
U-0
R-1/q
R-1/q
R/W-0/u
R/W-0/u
R/W-0/u
—
TO
PD
Z
DC(1)
C(1)
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
q = Value depends on condition
bit 7-5
Unimplemented: Read as ‘0’
bit 4
TO: Time-out bit
1 = After power-up, CLRWDT instruction or SLEEP instruction
0 = A WDT time-out occurred
bit 3
PD: Power-down bit
1 = After power-up or by the CLRWDT instruction
0 = By execution of the SLEEP instruction
bit 2
Z: Zero bit
1 = The result of an arithmetic or logic operation is zero
0 = The result of an arithmetic or logic operation is not zero
bit 1
DC: Digit Carry/Digit Borrow bit (ADDWF, ADDLW, SUBLW, SUBWF instructions)(1)
1 = A carry-out from the 4th low-order bit of the result occurred
0 = No carry-out from the 4th low-order bit of the result
bit 0
C: Carry/Borrow bit (ADDWF, ADDLW, SUBLW, SUBWF instructions)(1)
1 = A carry-out from the Most Significant bit of the result occurred
0 = No carry-out from the Most Significant bit of the result occurred
Note 1:
For Borrow, the polarity is reversed. A subtraction is executed by adding the two’s complement of the
second operand. For rotate (RRF, RLF) instructions, this bit is loaded with either the high-order or low-order
bit of the source register.
2012-2017 Microchip Technology Inc.
DS40001657C-page 17
PIC16LF1824T39A
3.2.2
SPECIAL FUNCTION REGISTER
The Special Function Registers are registers used by
the application to control the desired operation of
peripheral functions in the device. The Special Function
Registers occupy the 20 bytes after the core registers
of every data memory bank (addresses x0Ch/x8Ch
through x1Fh/x9Fh). The registers associated with the
operation of the peripherals are described in the appropriate peripheral chapter of this data sheet.
3.2.3
FIGURE 3-2:
7-bit Bank Offset
Core Registers
(12 bytes)
0Bh
0Ch
GENERAL PURPOSE RAM
Special Function Registers
(20 bytes maximum)
1Fh
20h
Linear Access to GPR
The general purpose RAM can be accessed in a
non-banked method via the FSRs. This can simplify
access to large memory structures. See Section 3.5.2
“Linear Data Memory” for more information.
3.2.4
Memory Region
00h
There are up to 80 bytes of GPR in each data memory
bank. The Special Function Registers occupy the 20
bytes after the core registers of every data memory
bank (addresses x0Ch/x8Ch through x1Fh/x9Fh).
3.2.3.1
BANKED MEMORY
PARTITIONING
General Purpose RAM
(80 bytes maximum)
COMMON RAM
There are 16 bytes of common RAM accessible from all
banks.
6Fh
70h
Common RAM
(16 bytes)
7Fh
3.2.5
DEVICE MEMORY MAPS
The memory maps for the device family are as shown
in Table 3-3.
TABLE 3-3:
MEMORY MAP TABLES
Device
PIC16LF1824T39A
DS40001657C-page 18
Banks
Table No.
0-7
Table 3-4
8-15
Table 3-5
16-23
Table 3-6
24-31
Table 3-7
31
Table 3-8
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A MEMORY MAP, BANKS 0-7
BANK 0
000h
001h
002h
003h
004h
005h
006h
007h
008h
009h
00Ah
00Bh
00Ch
00Dh
00Eh
00Fh
010h
011h
012h
013h
014h
015h
016h
017h
018h
019h
01Ah
01Bh
01Ch
01Dh
01Eh
01Fh
020h
BANK 1
BANK 4
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
TRISA
—
TRISC
—
—
PIE1
PIE2
PIE3
—
OPTION
PCON
WDTCON
OSCTUNE
OSCCON
OSCSTAT
ADRESL
ADRESH
100h
101h
102h
103h
104h
105h
106h
107h
108h
109h
10Ah
10Bh
10Ch
10Dh
10Eh
10Fh
110h
111h
112h
113h
114h
115h
116h
117h
118h
119h
11Ah
11Bh
11Ch
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
LATA
—
LATC
—
—
CM1CON0
CM1CON1
CM2CON0
CM2CON1
CMOUT
BORCON
FVRCON
DACCON0
DACCON1
SRCON0
SRCON1
—
180h
181h
182h
183h
184h
185h
186h
187h
188h
189h
18Ah
18Bh
18Ch
18Dh
18Eh
18Fh
190h
191h
192h
193h
194h
195h
196h
197h
198h
199h
19Ah
19Bh
19Ch
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
ANSELA
—
ANSELC
—
—
EEADRL
EEADRH
EEDATL
EEDATH
EECON1
EECON2
—
—
RCREG
TXREG
SPBRGL
SPBRGH
200h
201h
202h
203h
204h
205h
206h
207h
208h
209h
20Ah
20Bh
20Ch
20Dh
20Eh
20Fh
210h
211h
212h
213h
214h
215h
216h
217h
218h
219h
21Ah
21Bh
21Ch
—
CPSCON0
CPSCON1
09Dh
09Eh
09Fh
0A0h
ADCON0
ADCON1
—
11Dh
11Eh
11Fh
120h
APFCON0
APFCON1
—
19Dh
19Eh
19Fh
1A0h
RCSTA
TXSTA
BAUDCON
21Dh
21Eh
21Fh
220h
2012-2017 Microchip Technology Inc.
06Fh
070h
General
Purpose
Register
80 Bytes
0EFh
0F0h
General
Purpose
Register
80 Bytes
16Fh
170h
Accesses
70h – 7Fh
Common RAM
Legend:
BANK 3
080h
081h
082h
083h
084h
085h
086h
087h
088h
089h
08Ah
08Bh
08Ch
08Dh
08Eh
08Fh
090h
091h
092h
093h
094h
095h
096h
097h
098h
099h
09Ah
09Bh
09Ch
General
Purpose
Register
80 Bytes
07Fh
BANK 2
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
PORTA
—
PORTC
—
—
PIR1
PIR2
PIR3
—
TMR0
TMR1L
TMR1H
T1CON
T1GCON
TMR2
PR2
T2CON
0FFh
Unimplemented
Read as ‘0’
1EFh
1F0h
Accesses
70h – 7Fh
17Fh
= Unimplemented data memory locations, read as ‘0’.
BANK 5
280h
281h
282h
283h
284h
285h
286h
287h
288h
289h
28Ah
28Bh
28Ch
28Dh
28Eh
28Fh
290h
291h
292h
293h
294h
295h
296h
297h
298h
299h
29Ah
29Bh
29Ch
29Dh
29Eh
29Fh
2A0h
Unimplemented
Read as ‘0’
26Fh
270h
Accesses
70h – 7Fh
1FFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
WPUA
—
WPUC
—
—
SSP1BUF
SSP1ADD
SSP1MSK
SSP1STAT
SSP1CON
SSP1CON2
SSP1CON3
—
—
—
—
—
—
—
—
BANK 6
300h
301h
302h
303h
304h
305h
306h
307h
308h
309h
30Ah
30Bh
30Ch
30Dh
30Eh
30Fh
310h
311h
312h
313h
314h
315h
316h
317h
318h
319h
31Ah
31Bh
31Ch
31Dh
31Eh
31Fh
320h
Unimplemented
Read as ‘0’
BANK 7
380h
381h
382h
383h
384h
385h
386h
387h
388h
389h
38Ah
38Bh
38Ch
38Dh
38Eh
38Fh
390h
391h
392h
393h
394h
395h
396h
397h
398h
399h
39Ah
39Bh
39Ch
39Dh
39Eh
39Fh
3A0h
Unimplemented
Read as ‘0’
Accesses
70h – 7Fh
2FFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
CCPR3L
CCPR3H
CCP3CON
—
—
—
—
CCPR4L
CCPR4H
CCP4CON
—
—
—
—
—
—
—
—
—
—
—
CLKRCON
—
MDCON
MDSRC
MDCARL
MDCARH
Unimplemented
Read as ‘0’
Accesses
70h – 7Fh
37Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
INLVLA
—
INLVLC
—
—
IOCAP
IOCAN
IOCAF
3EFh
3F0h
36Fh
370h
2EFh
2F0h
Accesses
70h – 7Fh
27Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
CCPR1L
CCPR1H
CCP1CON
PWM1CON
CCP1AS
PSTR1CON
—
CCPR2L
CCPR2H
CCP2CON
PWM2CON
CCP2AS
PSTR2CON
CCPTMRS0
—
Accesses
70h – 7Fh
3FFh
PIC16LF1824T39A
DS40001657C-page 19
TABLE 3-4:
2012-2017 Microchip Technology Inc.
TABLE 3-5:
PIC16LF1824T39A MEMORY MAP, BANKS 8-15
BANK 8
BANK 9
480h
481h
482h
483h
484h
485h
486h
487h
488h
489h
48Ah
48Bh
48Ch
48Dh
48Eh
48Fh
490h
491h
492h
493h
494h
495h
496h
497h
498h
499h
49Ah
49Bh
49Ch
49Dh
49Eh
49Fh
4A0h
Unimplemented
Read as ‘0’
46Fh
470h
DS40001657C-page 20
47Fh
BANK 10
500h
501h
502h
503h
504h
505h
506h
507h
508h
509h
50Ah
50Bh
50Ch
50Dh
50Eh
50Fh
510h
511h
512h
513h
514h
515h
516h
517h
518h
519h
51Ah
51Bh
51Ch
51Dh
51Eh
51Fh
520h
Unimplemented
Read as ‘0’
4EFh
4F0h
Accesses
70h – 7Fh
Legend:
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 11
580h
581h
582h
583h
584h
585h
586h
587h
588h
589h
58Ah
58Bh
58Ch
58Dh
58Eh
58Fh
590h
591h
592h
593h
594h
595h
596h
597h
598h
599h
59Ah
59Bh
59Ch
59Dh
59Eh
59Fh
5A0h
Unimplemented
Read as ‘0’
56Fh
570h
Accesses
70h – 7Fh
4FFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Unimplemented
Read as ‘0’
5EFh
5F0h
Accesses
70h – 7Fh
57Fh
= Unimplemented data memory locations, read as ‘0’.
BANK 12
600h
601h
602h
603h
604h
605h
606h
607h
608h
609h
60Ah
60Bh
60Ch
60Dh
60Eh
60Fh
610h
611h
612h
613h
614h
615h
616h
617h
618h
619h
61Ah
61Bh
61Ch
61Dh
61Eh
61Fh
620h
BANK 13
680h
681h
682h
683h
684h
685h
686h
687h
688h
689h
68Ah
68Bh
68Ch
68Dh
68Eh
68Fh
690h
691h
692h
693h
694h
695h
696h
697h
698h
699h
69Ah
69Bh
69Ch
69Dh
69Eh
69Fh
6A0h
Unimplemented
Read as ‘0’
66Fh
670h
Accesses
70h – 7Fh
5FFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 14
700h
701h
702h
703h
704h
705h
706h
707h
708h
709h
70Ah
70Bh
70Ch
70Dh
70Eh
70Fh
710h
711h
712h
713h
714h
715h
716h
717h
718h
719h
71Ah
71Bh
71Ch
71Dh
71Eh
71Fh
720h
Unimplemented
Read as ‘0’
6EFh
6F0h
Accesses
70h – 7Fh
67Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 15
780h
781h
782h
783h
784h
785h
786h
787h
788h
789h
78Ah
78Bh
78Ch
78Dh
78Eh
78Fh
790h
791h
792h
793h
794h
795h
796h
797h
798h
799h
79Ah
79Bh
79Ch
79Dh
79Eh
79Fh
7A0h
Unimplemented
Read as ‘0’
76Fh
770h
Accesses
70h – 7Fh
6FFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Unimplemented
Read as ‘0’
7EFh
7F0h
Accesses
70h – 7Fh
77Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Accesses
70h – 7Fh
7FFh
PIC16LF1824T39A
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
TMR4
PR4
T4CON
—
—
—
—
TMR6
PR6
T6CON
—
400h
401h
402h
403h
404h
405h
406h
407h
408h
409h
40Ah
40Bh
40Ch
40Dh
40Eh
40Fh
410h
411h
412h
413h
414h
415h
416h
417h
418h
419h
41Ah
41Bh
41Ch
41Dh
41Eh
41Fh
420h
PIC16LF1824T39A MEMORY MAP, BANKS 16-23
BANK 16
2012-2017 Microchip Technology Inc.
800h
801h
802h
803h
804h
805h
806h
807h
808h
809h
80Ah
80Bh
80Ch
80Dh
80Eh
80Fh
810h
811h
812h
813h
814h
815h
816h
817h
818h
819h
81Ah
81Bh
81Ch
81Dh
81Eh
81Fh
820h
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 17
880h
881h
882h
883h
884h
885h
886h
887h
888h
889h
88Ah
88Bh
88Ch
88Dh
88Eh
88Fh
890h
891h
892h
893h
894h
895h
896h
897h
898h
899h
89Ah
89Bh
89Ch
89Dh
89Eh
89Fh
8A0h
Unimplemented
Read as ‘0’
86Fh
870h
Legend:
BANK 18
900h
901h
902h
903h
904h
905h
906h
907h
908h
909h
90Ah
90Bh
90Ch
90Dh
90Eh
90Fh
910h
911h
912h
913h
914h
915h
916h
917h
918h
919h
91Ah
91Bh
91Ch
91Dh
91Eh
91Fh
920h
Unimplemented
Read as ‘0’
8EFh
8F0h
Accesses
70h – 7Fh
87Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 19
980h
981h
982h
983h
984h
985h
986h
987h
988h
989h
98Ah
98Bh
98Ch
98Dh
98Eh
98Fh
990h
991h
992h
993h
994h
995h
996h
997h
998h
999h
99Ah
99Bh
99Ch
99Dh
99Eh
99Fh
9A0h
Unimplemented
Read as ‘0’
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Accesses
70h – 7Fh
97Fh
= Unimplemented data memory locations, read as ‘0’.
BANK 20
A00h
A01h
A02h
A03h
A04h
A05h
A06h
A07h
A08h
A09h
A0Ah
A0Bh
A0Ch
A0Dh
A0Eh
A0Fh
A10h
A11h
A12h
A13h
A14h
A15h
A16h
A17h
A18h
A19h
A1Ah
A1Bh
A1Ch
A1Dh
A1Eh
A1Fh
A20h
Unimplemented
Read as ‘0’
9EFh
9F0h
96Fh
970h
Accesses
70h – 7Fh
8FFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 21
A80h
A81h
A82h
A83h
A84h
A85h
A86h
A87h
A88h
A89h
A8Ah
A8Bh
A8Ch
A8Dh
A8Eh
A8Fh
A90h
A91h
A92h
A93h
A94h
A95h
A96h
A97h
A98h
A99h
A9Ah
A9Bh
A9Ch
A9Dh
A9Eh
A9Fh
AA0h
Unimplemented
Read as ‘0’
BANK 22
B00h
B01h
B02h
B03h
B04h
B05h
B06h
B07h
B08h
B09h
B0Ah
B0Bh
B0Ch
B0Dh
B0Eh
B0Fh
B10h
B11h
B12h
B13h
B14h
B15h
B16h
B17h
B18h
B19h
B1Ah
B1Bh
B1Ch
B1Dh
B1Eh
B1Fh
B20h
Unimplemented
Read as ‘0’
Accesses
70h – 7Fh
A7Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
AEFh
AF0h
A6Fh
A70h
Accesses
70h – 7Fh
9FFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 23
B80h
B81h
B82h
B83h
B84h
B85h
B86h
B87h
B88h
B89h
B8Ah
B8Bh
B8Ch
B8Dh
B8Eh
B8Fh
B90h
B91h
B92h
B93h
B94h
B95h
B96h
B97h
B98h
B99h
B9Ah
B9Bh
B9Ch
B9Dh
B9Eh
B9Fh
BA0h
Unimplemented
Read as ‘0’
Unimplemented
Read as ‘0’
Accesses
70h – 7Fh
B7Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BEFh
BF0h
B6Fh
B70h
Accesses
70h – 7Fh
AFFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Accesses
70h – 7Fh
BFFh
PIC16LF1824T39A
DS40001657C-page 21
TABLE 3-6:
2012-2017 Microchip Technology Inc.
TABLE 3-7:
PIC16LF1824T39A MEMORY MAP, BANKS 24-31
BANK 24
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 25
C80h
C81h
C82h
C83h
C84h
C85h
C86h
C87h
C88h
C89h
C8Ah
C8Bh
C8Ch
C8Dh
C8Eh
C8Fh
C90h
C91h
C92h
C93h
C94h
C95h
C96h
C97h
C98h
C99h
C9Ah
C9Bh
C9Ch
C9Dh
C9Eh
C9Fh
CA0h
Unimplemented
Read as ‘0’
DS40001657C-page 22
C6Fh
C70h
CFFh
BANK 26
D00h
D01h
D02h
D03h
D04h
D05h
D06h
D07h
D08h
D09h
D0Ah
D0Bh
D0Ch
D0Dh
D0Eh
D0Fh
D10h
D11h
D12h
D13h
D14h
D15h
D16h
D17h
D18h
D19h
D1Ah
D1Bh
D1Ch
D1Dh
D1Eh
D1Fh
D20h
Unimplemented
Read as ‘0’
CEFh
CF0h
Accesses
70h – 7Fh
Legend:
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 27
D80h
D81h
D82h
D83h
D84h
D85h
D86h
D87h
D88h
D89h
D8Ah
D8Bh
D8Ch
D8Dh
D8Eh
D8Fh
D90h
D91h
D92h
D93h
D94h
D95h
D96h
D97h
D98h
D99h
D9Ah
D9Bh
D9Ch
D9Dh
D9Eh
D9Fh
DA0h
Unimplemented
Read as ‘0’
D6Fh
D70h
Accesses
70h – 7Fh
CFFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Unimplemented
Read as ‘0’
DEFh
DF0h
Accesses
70h – 7Fh
D7Fh
= Unimplemented data memory locations, read as ‘0’.
BANK 28
E00h
E01h
E02h
E03h
E04h
E05h
E06h
E07h
E08h
E09h
E0Ah
E0Bh
E0Ch
E0Dh
E0Eh
E0Fh
E10h
E11h
E12h
E13h
E14h
E15h
E16h
E17h
E18h
E19h
E1Ah
E1Bh
E1Ch
E1Dh
E1Eh
E1Fh
E20h
BANK 29
E80h
E81h
E82h
E83h
E84h
E85h
E86h
E87h
E88h
E89h
E8Ah
E8Bh
E8Ch
E8Dh
E8Eh
E8Fh
E90h
E91h
E92h
E93h
E94h
E95h
E96h
E97h
E98h
E99h
E9Ah
E9Bh
E9Ch
E9Dh
E9Eh
E9Fh
EA0h
Unimplemented
Read as ‘0’
E6Fh
E70h
Accesses
70h – 7Fh
DFFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 30
F00h
F01h
F02h
F03h
F04h
F05h
F06h
F07h
F08h
F09h
F0Ah
F0Bh
F0Ch
F0Dh
F0Eh
F0Fh
F10h
F11h
F12h
F13h
F14h
F15h
F16h
F17h
F18h
F19h
F1Ah
F1Bh
F1Ch
F1Dh
F1Eh
F1Fh
F20h
Unimplemented
Read as ‘0’
EEFh
EF0h
Accesses
70h – 7Fh
E7Fh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BANK 31
F80h
INDF0
F81h
INDF1
F82h
PCL
F83h
STATUS
F84h
FSR0L
F85h
FSR0H
F86h
FSR1L
F87h
FSR1H
F88h
BSR
F89h
WREG
F8Ah
PCLATH
F8Bh
INTCON
F8Ch
F8Dh
F8Eh
F8Fh
F90h
F91h
F92h
F93h
F94h
F95h
F96h
F97h
See Table 3-8 for
F98h register mapping
F99h
details
F9Ah
F9Bh
F9Ch
F9Dh
F9Eh
F9Fh
FA0h
Unimplemented
Read as ‘0’
F6Fh
F70h
Accesses
70h – 7Fh
EFFh
INDF0
INDF1
PCL
STATUS
FSR0L
FSR0H
FSR1L
FSR1H
BSR
WREG
PCLATH
INTCON
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
FEFh
FF0h
Accesses
70h – 7Fh
Accesses
70h – 7Fh
F7Fh
FFFh
PIC16LF1824T39A
C00h
C01h
C02h
C03h
C04h
C05h
C06h
C07h
C08h
C09h
C0Ah
C0Bh
C0Ch
C0Dh
C0Eh
C0Fh
C10h
C11h
C12h
C13h
C14h
C15h
C16h
C17h
C18h
C19h
C1Ah
C1Bh
C1Ch
C1Dh
C1Eh
C1Fh
C20h
PIC16LF1824T39A
TABLE 3-8:
PIC16LF1824T39A MEMORY
MAP, BANK 31
Bank 31
FA0h
Unimplemented
Read as ‘0’
FE3h
FE4h
FE5h
FE6h
FE7h
FE8h
FE9h
FEAh
FEBh
FECh
FEDh
FEEh
FEFh
Legend:
STATUS_SHAD
WREG_SHAD
BSR_SHAD
PCLATH_SHAD
FSR0L_SHAD
FSR0H_SHAD
FSR1L_SHAD
FSR1H_SHAD
—
STKPTR
TOSL
TOSH
3.2.6
SPECIAL FUNCTION REGISTER
SUMMARY
The Special Function Register Summary for this device
is as follows:
Device
PIC16LF1824T39A
Bank(s)
Page No.
0
24
1
25
2
26
3
27
4
28
5
29
6
30
7
31
8
32
9-30
33
31
34
= Unimplemented data memory locations,
read as ‘0’.
2012-2017 Microchip Technology Inc.
DS40001657C-page 23
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 0
000h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
001h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
002h(1)
PCL
Program Counter (PC) Least Significant Byte
003h(1)
STATUS
004h(1)
FSR0L
005h(1)
FSR0H
006h(1)
FSR1L
007h(1)
FSR1H
008h(1)
BSR
009h(1)
WREG
00Ah(1)
PCLATH
—
00Bh(1)
INTCON
GIE
PEIE
00Ch
PORTA
—
—
RA5
RA4
RA3
RA2
00Eh
PORTC
—
—
RC5
RC4
RC3
RC2
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
---0 0000
---0 0000
0000 0000
uuuu uuuu
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
TMR0IE
INTE
IOCIE
TMR0IF
-000 0000
-000 0000
IOCIF
0000 000x
0000 000u
RA1
RA0
--xx xxxx
--xx xxxx
RC1
RC0
xxxx xxxx
xxxx xxxx
—
INTF
00Fh
—
Unimplemented
—
010h
—
Unimplemented
—
—
011h
PIR1
TMR1GIF
ADIF
012h
PIR2
OSFIF
C2IF
C1IF
013h
PIR3
—
—
CCP4IF
014h
—
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
0000 0000
0000 0000
EEIF
BCL1IF
CCP3IF
TMR6IF
—
—
CCP2IF
0000 0--0
0000 0--0
—
TMR4IF
—
--00 0-0-
--00 0-0-
Unimplemented
—
—
015h
TMR0
Timer0 Module Register
xxxx xxxx
uuuu uuuu
016h
TMR1L
Holding Register for the Least Significant Byte of the 16-bit TMR1 Register
xxxx xxxx
uuuu uuuu
017h
TMR1H
Holding Register for the Most Significant Byte of the 16-bit TMR1 Register
xxxx xxxx
uuuu uuuu
018h
T1CON
TMR1CS
1
TMR1CS
0
TMR1ON 0000 00-0
uuuu uu-u
019h
T1GCON
TMR1GE
T1GPOL
T1CKPS
T1GTM
T1GSPM
T1OSCEN
T1SYNC
—
T1GGO/
DONE
T1GVAL
T1GSS
0000 0x00
uuuu uxuu
01Ah
TMR2
Timer2 Module Register
0000 0000
0000 0000
01Bh
PR2
Timer2 Period Register
1111 1111
1111 1111
01Ch
T2CON
-000 0000
-000 0000
01Dh
—
—
T2OUTPS
TMR2ON
T2CKPS
Unimplemented
01Eh
CPSCON0
CPSON
CPSRM
—
—
01Fh
CPSCON1
—
—
—
—
CPSRNG
CPSOUT
CPSCH
T0XCS
—
—
00-- 0000
00-- 0000
---- 0000
---- 0000
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
DS40001657C-page 24
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 1
080h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
081h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
082h(1)
PCL
Program Counter (PC) Least Significant Byte
083h(1)
STATUS
084h(1)
FSR0L
085h(1)
FSR0H
086h(1)
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
FSR1L
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
087h(1)
FSR1H
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
088h(1)
BSR
---0 0000
---0 0000
089h(1)
WREG
0000 0000
uuuu uuuu
08Ah(1)
PCLATH
—
08Bh(1)
INTCON
GIE
PEIE
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
TMR0IE
INTE
IOCIE
TMR0IF
INTF
-000 0000
-000 0000
IOCIF
0000 000x
0000 000u
08Ch
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
--11 1111
--11 1111
08Eh
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
1111 1111
1111 1111
—
08Fh
—
Unimplemented
—
090h
—
Unimplemented
—
—
091h
PIE1
TMR1GIE
ADIE
092h
PIE2
OSFIE
C2IE
C1IE
093h
PIE3
—
—
CCP4IE
094h
—
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
0000 0000
0000 0000
EEIE
BCL1IE
CCP3IE
TMR6IE
—
—
CCP2IE
0000 0--0
0000 0--0
—
TMR4IE
—
--00 0-0-
--00 0-0-
Unimplemented
—
—
1111 1111
1111 1111
00-- 11qq
qq-- qquu
SWDTEN --01 0110
--01 0110
095h
OPTION_REG
WPUEN
INTEDG
TMR0CS
TMR0SE
096h
PCON
STKOVF
STKUNF
—
—
097h
WDTCON
—
—
098h
OSCTUNE
—
—
099h
OSCCON
SPLLEN
09Ah
OSCSTAT
T1OSCR
09Bh
ADRESL
A/D Result Register Low
09Ch
ADRESH
A/D Result Register High
xxxx xxxx
uuuu uuuu
09Dh
ADCON0
-000 0000
-000 0000
09Eh
ADCON1
0000 -000
0000 -000
09Fh
—
—
—
PSA
RMCLR
RI
POR
WDTPS
BOR
TUN
IRCF
PLLR
OSTS
—
ADFM
PS
HFIOFR
—
HFIOFL
MFIOFR
CHS
ADCS
SCS
LFIOFR
GO/DONE
—
ADNREF
HFIOFS
ADON
ADPREF
Unimplemented
--00 0000
--00 0000
0011 1-00
0011 1-00
10q0 0q00
qqqq qq0q
xxxx xxxx
uuuu uuuu
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
2012-2017 Microchip Technology Inc.
DS40001657C-page 25
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 2
100h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
101h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
102h(1)
PCL
Program Counter (PC) Least Significant Byte
103h(1)
STATUS
104h(1)
FSR0L
105h(1)
FSR0H
106h(1)
FSR1L
107h(1)
FSR1H
108h(1)
BSR
109h(1)
WREG
10Ah(1)
PCLATH
—
10Bh(1)
INTCON
GIE
PEIE
10Ch
LATA
—
—
LATA5
LATA4
—
LATA2
10Eh
LATC
—
—
LATC5
LATC4
LATC3
LATC2
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
---0 0000
---0 0000
0000 0000
uuuu uuuu
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
TMR0IE
INTE
IOCIE
TMR0IF
-000 0000
-000 0000
IOCIF
0000 000x
0000 000u
LATA1
LATA0
--xx -xxx
--uu -uuu
LATC1
LATC0
xxxx xxxx
uuuu uuuu
—
INTF
10Fh
—
Unimplemented
—
110h
—
Unimplemented
—
—
0000 -100
0000 -100
111h
CM1CON0
C1ON
C1OUT
112h
CM1CON1
C1INTP
C1INTN
113h
CM2CON0
C2ON
C2OUT
114h
CM2CON1
C2INTP
C2INTN
115h
CMOUT
—
—
116h
BORCON
SBOREN
—
117h
FVRCON
FVREN
118h
DACCON0
119h
DACCON1
C1HYS
—
—
C1NCH1
C1NCH0
0000 ---0
0000 ---0
—
C2SP
C2HYS
C2SYNC
0000 -100
0000 -100
C2PCH
—
—
0000 --00
0000 --00
—
—
—
—
MC2OUT
MC1OUT ---- --00
---- --00
—
—
—
—
—
BORRDY 1--- ---q
FVRRDY
TSEN
TSRNG
CDAFVR
ADFVR
DACEN
DACLPS
DACOE
—
DACPSS
—
—
—
—
SRCON0
SRLEN
11Bh
SRCON1
SRSPE
11Ch
—
APFCON0
11Eh
APFCON1
11Fh
—
C1POL
C1SP
11Ah
11Dh
C1OE
C1PCH
C2OE
C2POL
SRSC2E
C1SYNC
C2NCH
DACNSS
DACR
SRCLK
SRSCKE
—
SRSC1E
0q00 0000
u--- ---u
0q00 0000
000- 00-0
000- 00-0
---0 0000
---0 0000
SRQEN
SRNQEN
SRPS
SRPR
0000 0000
0000 0000
SRRPE
SRRCKE
SRRC2E
SRRC1E
0000 0000
0000 0000
Unimplemented
RXDTSEL
SDOSEL
SSSEL
—
T1GSEL TXCKSEL
—
—
—
—
P1DSEL
P1CSEL
—
—
000- 0000
000- 0000
P2BSEL CCP2SEL --00 0000
--00 0000
—
Unimplemented
—
—
—
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
DS40001657C-page 26
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 3
180h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
181h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
182h(1)
PCL
Program Counter (PC) Least Significant Byte
183h(1)
STATUS
184h(1)
FSR0L
185h(1)
FSR0H
186h(1)
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
FSR1L
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
187h(1)
FSR1H
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
188h(1)
BSR
---0 0000
---0 0000
189h(1)
WREG
0000 0000
uuuu uuuu
18Ah(1)
PCLATH
—
18Bh(1)
INTCON
GIE
PEIE
TMR0IE
INTE
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
IOCIE
TMR0IF
INTF
IOCIF
-000 0000
-000 0000
0000 000x
0000 000u
18Ch
ANSELA
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
---1 -111
---1 -111
18Eh
ANSELC
—
—
—
—
ANSC3
ANSC2
ANSC1
ANSC0
11-- 1111
11-- 1111
18Fh
—
Unimplemented
—
—
190h
—
Unimplemented
—
—
191h
EEADRL
0000 0000
0000 0000
192h
EEADRH
1000 0000
1000 0000
193h
EEDATL
xxxx xxxx
uuuu uuuu
194h
EEDATH
—
—
--xx xxxx
--uu uuuu
195h
EECON1
EEPGD
CFGS
0000 x000
0000 q000
196h
EECON2
0000 0000
0000 0000
197h
—
Unimplemented
—
—
198h
—
Unimplemented
—
—
USART Receive Data Register
0000 0000
0000 0000
199h
RCREG
EEPROM/Program Memory Address Register Low Byte
—(2)
EEPROM/Program Memory Address Register High Byte
EEPROM / Program Memory Read Data Register Low Byte
EEPROM / Program Memory Read Data Register High Byte
LWLO
FREE
WRERR
WREN
WR
RD
EEPROM control register 2
19Ah
TXREG
USART Transmit Data Register
0000 0000
0000 0000
19Bh
SPBRGL
Baud Rate Generator Data Register Low
0000 0000
0000 0000
19Ch
SPBRGH
Baud Rate Generator Data Register High
0000 0000
0000 0000
19Dh
RCSTA
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
0000 000x
0000 000x
19Eh
TXSTA
CSRC
TX9
TXEN
SYNC
SENDB
BRGH
TRMT
TX9D
0000 0010
0000 0010
19Fh
BAUDCON
ABDOVF
RCIDL
—
SCKP
BRG16
—
WUE
ABDEN
01-0 0-00
01-0 0-00
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
2012-2017 Microchip Technology Inc.
DS40001657C-page 27
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 4
200h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
201h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
202h(1)
PCL
Program Counter (PC) Least Significant Byte
203h(1)
STATUS
204h(1)
FSR0L
205h(1)
FSR0H
206h(1)
FSR1L
207h(1)
FSR1H
208h(1)
BSR
209h(1)
WREG
20Ah(1)
PCLATH
—
20Bh(1)
INTCON
GIE
PEIE
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
---0 0000
---0 0000
0000 0000
uuuu uuuu
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
TMR0IE
INTE
IOCIE
TMR0IF
INTF
-000 0000
-000 0000
IOCIF
0000 000x
0000 000u
20Ch
WPUA
—
—
WPUA5
WPUA4
WPUA3
WPUA2
WPUA1
WPUA0
--11 1111
--11 1111
20Eh
WPUC
—
—
WPUC5
WPUC4
WPUC3
WPUC2
WPUC1
WPUC0
1111 1111
1111 1111
—
20Fh
—
Unimplemented
—
210h
—
Unimplemented
—
—
xxxx xxxx
uuuu uuuu
211h
SSP1BUF
Synchronous Serial Port Receive Buffer/Transmit Register
212h
SSP1ADD
ADD
0000 0000
0000 0000
213h
SSP1MSK
MSK
1111 1111
1111 1111
214h
SSP1STAT
SMP
CKE
D/A
P
0000 0000
0000 0000
215h
SSP1CON1
WCOL
SSPOV
SSPEN
CKP
0000 0000
0000 0000
216h
SSP1CON2
GCEN
ACKSTAT
ACKDT
ACKEN
RCEN
PEN
RSEN
SEN
0000 0000
0000 0000
217h
SSP1CON3
ACKTIM
PCIE
SCIE
BOEN
SDAHT
SBCDE
AHEN
DHEN
0000 0000
0000 0000
S
R/W
UA
BF
SSPM
218h
—
Unimplemented
—
—
219h
—
Unimplemented
—
—
21Ah
—
Unimplemented
—
—
21Bh
—
Unimplemented
—
—
21Ch
—
Unimplemented
—
—
21Dh
—
Unimplemented
—
—
21Eh
—
Unimplemented
—
—
21Fh
—
Unimplemented
—
—
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
DS40001657C-page 28
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 5
280h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
281h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
282h(1)
PCL
Program Counter (PC) Least Significant Byte
283h(1)
STATUS
284h(1)
FSR0L
285h(1)
FSR0H
286h(1)
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
FSR1L
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
287h(1)
FSR1H
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
288h(1)
BSR
---0 0000
---0 0000
289h(1)
WREG
0000 0000
uuuu uuuu
28Ah(1)
PCLATH
—
28Bh(1)
INTCON
GIE
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
-000 0000
-000 0000
0000 000x
0000 000u
28Ch
—
Unimplemented
—
—
28Dh
—
Unimplemented
—
—
28Eh
—
Unimplemented
—
—
28Fh
—
Unimplemented
—
—
290h
—
Unimplemented
—
—
291h
CCPR1L
Capture/Compare/PWM Register 1 (LSB)
xxxx xxxx
uuuu uuuu
292h
CCPR1H
Capture/Compare/PWM Register 1 (MSB)
xxxx xxxx
uuuu uuuu
293h
CCP1CON
0000 0000
0000 0000
294h
PWM1CON
P1RSEN
295h
CCP1AS
CCP1AS
E
296h
PSTR1CON
P1M
—
DC1B
P1DC
CCP1AS
—
—
STR1SY
NC
297h
—
298h
CCPR2L
Capture/Compare/PWM Register 2 (LSB)
299h
CCPR2H
Capture/Compare/PWM Register 2 (MSB)
29Ah
CCP2CON
29Bh
PWM2CON
P2RSEN
29Ch
CCP2AS
CCP2AS
E
29Dh
PSTR2CON
29Eh
CCPTMRS0
29Fh
—
CCP1M
PSS1AC
STR1D
STR1C
PSS1BD
STR1B
STR1A
Unimplemented
P2M
—
DC2B
CCP2M
P2DC
CCP2AS
—
C4TSEL
—
STR2SY
NC
C3TSEL
PSS2AC
STR2D
STR2C
C2TSEL
PSS2BD
STR2B
STR2A
C1TSEL
Unimplemented
0000 0000
0000 0000
0000 0000
0000 0000
---0 0001
---0 0001
—
—
xxxx xxxx
uuuu uuuu
xxxx xxxx
uuuu uuuu
0000 0000
0000 0000
0000 0000
0000 0000
0000 0000
0000 0000
---0 0001
---0 0001
0000 0000
0000 0000
—
—
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
2012-2017 Microchip Technology Inc.
DS40001657C-page 29
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 6
300h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
301h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
302h(1)
PCL
Program Counter (PC) Least Significant Byte
303h(1)
STATUS
304h(1)
FSR0L
305h(1)
FSR0H
306h(1)
FSR1L
307h(1)
FSR1H
308h(1)
BSR
309h(1)
WREG
30Ah(1)
PCLATH
—
30Bh(1)
INTCON
GIE
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
---0 0000
---0 0000
0000 0000
uuuu uuuu
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
-000 0000
-000 0000
0000 000x
0000 000u
30Ch
—
Unimplemented
—
—
30Dh
—
Unimplemented
—
—
30Eh
—
Unimplemented
—
—
30Fh
—
Unimplemented
—
—
310h
—
Unimplemented
—
—
311h
CCPR3L
Capture/Compare/PWM Register 3 (LSB)
xxxx xxxx
uuuu uuuu
312h
CCPR3H
Capture/Compare/PWM Register 3 (MSB)
xxxx xxxx
uuuu uuuu
313h
CCP3CON
--00 0000
--00 0000
—
—
DC3B
CCP3M
314h
—
Unimplemented
—
—
315h
—
Unimplemented
—
—
316h
—
Unimplemented
—
—
317h
—
Unimplemented
—
—
318h
CCPR4L
Capture/Compare/PWM Register 4 (LSB)
xxxx xxxx
uuuu uuuu
319h
CCPR4H
Capture/Compare/PWM Register 4 (MSB)
xxxx xxxx
uuuu uuuu
31Ah
CCP4CON
--00 0000
--00 0000
—
—
DC4B
CCP4M
31Bh
—
Unimplemented
—
—
31Ch
—
Unimplemented
—
—
31Dh
—
Unimplemented
—
—
31Eh
—
Unimplemented
—
—
31Fh
—
Unimplemented
—
—
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
DS40001657C-page 30
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 7
380h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
381h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
382h(1)
PCL
Program Counter (PC) Least Significant Byte
383h(1)
STATUS
384h(1)
FSR0L
385h(1)
FSR0H
386h(1)
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
FSR1L
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
387h(1)
FSR1H
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
388h(1)
BSR
---0 0000
---0 0000
389h(1)
WREG
0000 0000
uuuu uuuu
38Ah(1)
PCLATH
—
38Bh(1)
INTCON
GIE
PEIE
38Ch
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
38Eh
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
TMR0IE
INTE
IOCIE
TMR0IF
-000 0000
-000 0000
IOCIF
0000 000x
0000 000u
INLVLA1
INLVLA0
--00 0100
--00 0100
INLVLC1
INLVLC0
--00 0000
--00 0000
—
INTF
38Fh
—
Unimplemented
—
390h
—
Unimplemented
—
—
391h
IOCAP
—
—
IOCAP5
IOCAP4
IOCAP3
IOCAP2
IOCAP1
IOCAP0
--00 0000
--00 0000
392h
IOCAN
—
—
IOCAN5
IOCAN4
IOCAN3
IOCAN2
IOCAN1
IOCAN0
--00 0000
--00 0000
393h
IOCAF
—
—
IOCAF5
IOCAF4
IOCAF3
IOCAF2
IOCAF1
IOCAF0
--00 0000
--00 0000
397h
—
Unimplemented
—
—
398h
—
Unimplemented
—
—
399h
—
Unimplemented
—
—
0011 0000
0011 0000
39Ah
CLKRCON
—
39Bh
CLKREN
CLKROE
CLKRSL
R
CLKRDC
CLKRDIV
Unimplemented
—
—
0010 ---0
0010 ---0
MDMS
x--- xxxx
u--- uuuu
—
MDCL
xxx- xxxx
uuu- uuuu
—
MDCH
xxx- xxxx
uuu- uuuu
39Ch
MDCON
MDEN
MDOE
MDSLR
MDOPOL
39Dh
MDSRC
MDMSODIS
—
—
—
39Eh
MDCARL
MDCLODIS
MDCLPOL
MDCLSYNC
39Fh
MDCARH
MDCHODIS
MDCHPOL
MDCHSY
NC
MDOUT
—
—
MDBIT
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
2012-2017 Microchip Technology Inc.
DS40001657C-page 31
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 8
400h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
401h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
402h(1)
PCL
Program Counter (PC) Least Significant Byte
403h(1)
STATUS
404h(1)
FSR0L
405h(1)
FSR0H
406h(1)
FSR1L
407h(1)
FSR1H
408h(1)
BSR
409h(1)
WREG
40Ah(1)
PCLATH
—
40Bh(1)
INTCON
GIE
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
---0 0000
---0 0000
0000 0000
uuuu uuuu
—
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
-000 0000
-000 0000
0000 000x
0000 000u
40Ch
—
Unimplemented
—
—
40Dh
—
Unimplemented
—
—
40Eh
—
Unimplemented
—
—
40Fh
—
Unimplemented
—
—
410h
—
Unimplemented
—
—
411h
—
Unimplemented
—
—
412h
—
Unimplemented
—
—
413h
—
Unimplemented
—
—
414h
—
Unimplemented
—
—
0000 0000
0000 0000
1111 1111
1111 1111
-000 0000
-000 0000
415h
TMR4
Timer4 Module Register
416h
PR4
Timer4 Period Register
417h
T4CON
—
T4OUTPS
TMR4ON
T4CKPS
418h
—
Unimplemented
—
—
419h
—
Unimplemented
—
—
41Ah
—
Unimplemented
—
—
41Bh
—
Unimplemented
—
—
0000 0000
0000 0000
1111 1111
1111 1111
-000 0000
-000 0000
—
—
41Ch
TMR6
Timer6 Module Register
41Dh
PR6
Timer6 Period Register
41Eh
T6CON
41Fh
—
—
T6OUTPS
TMR6ON
T6CKPS
Unimplemented
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
DS40001657C-page 32
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PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Banks 9-30
x00h/
x80h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
x00h/
x81h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
x02h/
x82h(1)
PCL
Program Counter (PC) Least Significant Byte
0000 0000
0000 0000
x03h/
x83h(1)
STATUS
---1 1000
---q quuu
x04h/
x84h(1)
FSR0L
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
x05h/
x85h(1)
FSR0H
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
x06h/
x86h(1)
FSR1L
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
x07h/
x87h(1)
FSR1H
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
x08h/
x88h(1)
BSR
---0 0000
---0 0000
x09h/
x89h(1)
WREG
0000 0000
uuuu uuuu
x0Ah/
x8Ah(1)
PCLATH
—
-000 0000
-000 0000
x0Bh/
x8Bh(1)
INTCON
GIE
0000 000x
0000 000u
—
—
—
—
x0Ch/
x8Ch
—
x1Fh/
x9Fh
—
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
Unimplemented
IOCIF
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
2012-2017 Microchip Technology Inc.
DS40001657C-page 33
PIC16LF1824T39A
TABLE 3-9:
Address
SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Value on
POR, BOR
Value on all
other
Resets
Bank 31
F80h(1)
INDF0
Addressing this location uses contents of FSR0H/FSR0L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
F81h(1)
INDF1
Addressing this location uses contents of FSR1H/FSR1L to address data memory
(not a physical register)
xxxx xxxx
xxxx xxxx
F82h(1)
PCL
Program Counter (PC) Least Significant Byte
F83h(1)
STATUS
F84h(1)
FSR0L
F85h(1)
FSR0H
F86h(1)
FSR1L
F87h(1)
FSR1H
F88h(1)
BSR
F89h(1)
WREG
F8Ah(1)
PCLATH
—
F8Bh(1)
INTCON
GIE
0000 0000
0000 0000
---1 1000
---q quuu
Indirect Data Memory Address 0 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 0 High Pointer
0000 0000
0000 0000
Indirect Data Memory Address 1 Low Pointer
0000 0000
uuuu uuuu
Indirect Data Memory Address 1 High Pointer
0000 0000
0000 0000
---0 0000
---0 0000
0000 0000
uuuu uuuu
—
—
F8Ch
—
FE3h
—
FE4h
STATUS_
—
—
—
TO
PD
—
Z
DC
C
BSR
Working Register
Write Buffer for the upper 7 bits of the Program Counter
-000 0000
-000 0000
0000 000x
0000 000u
—
—
---- -xxx
---- -uuu
0000 0000
uuuu uuuu
---x xxxx
---u uuuu
-xxx xxxx
uuuu uuuu
Indirect Data Memory Address 0 Low Pointer Shadow
xxxx xxxx
uuuu uuuu
Indirect Data Memory Address 0 High Pointer Shadow
xxxx xxxx
uuuu uuuu
Indirect Data Memory Address 1 Low Pointer Shadow
xxxx xxxx
uuuu uuuu
Indirect Data Memory Address 1 High Pointer Shadow
xxxx xxxx
uuuu uuuu
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
Unimplemented
—
—
—
—
—
Z
DC
C
SHAD
FE5h
WREG_
Working Register Shadow
SHAD
FE6h
BSR_
—
—
—
Bank Select Register Shadow
SHAD
FE7h
PCLATH_
—
Program Counter Latch High Register Shadow
SHAD
FE8h
FSR0L_
SHAD
FE9h
FSR0H_
SHAD
FEAh
FSR1L_
SHAD
FEBh
FSR1H_
SHAD
FECh
—
FEDh
STKPTR
FEEh
TOSL
FEFh
TOSH
Unimplemented
—
—
—
Current Stack Pointer
Top-of-Stack Low byte
—
Top-of-Stack High byte
—
—
---1 1111
---1 1111
xxxx xxxx
uuuu uuuu
-xxx xxxx
-uuu uuuu
Legend:
Note
x = unknown, u = unchanged, q = value depends on condition, - = unimplemented, r = reserved.
Shaded locations are unimplemented, read as ‘0’.
1: These registers can be addressed from any bank.
2: Unimplemented, read as ‘1’.
DS40001657C-page 34
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PIC16LF1824T39A
3.3
PCL and PCLATH
3.3.3
COMPUTED FUNCTION CALLS
The Program Counter (PC) is 15 bits wide. The low byte
comes from the PCL register, which is a readable and
writable register. The high byte (PC) is not directly
readable or writable and comes from PCLATH. On any
Reset, the PC is cleared. Figure 3-3 shows the five
situations for the loading of the PC.
A computed function CALL allows programs to maintain
tables of functions and provide another way to execute
state machines or look-up tables. When performing a
table read using a computed function CALL, care
should be exercised if the table location crosses a PCL
memory boundary (each 256-byte block).
FIGURE 3-3:
If using the CALL instruction, the PCH and PCL
registers are loaded with the operand of the CALL
instruction. PCH is loaded with PCLATH.
PC
PCLATH
PC
PCH
6
7
14
PCH
PCL
0
0
Instruction with
PCL as
Destination
8
ALU Result
PCL
0
GOTO, CALL
4
0
11
OPCODE
PC
14
6
PCLATH
PC
14
6
PCLATH
LOADING OF PC IN
DIFFERENT SITUATIONS
14
PCH
7
PCL
0
PCH
0
CALLW
8
W
PCL
0
BRW
14
PCH
3.3.4
BRANCHING
The branching instructions add an offset to the PC.
This allows relocatable code and code that crosses
page boundaries. There are two forms of branching,
BRW and BRA. The PC will have incremented to fetch
the next instruction in both cases. When using either
branching instruction, a PCL memory boundary may be
crossed.
If using BRW, load the W register with the desired
unsigned address and execute BRW. The entire PC will
be loaded with the address PC + 1 + W.
If using BRA, the entire PC will be loaded with PC + 1 +,
the signed value of the operand of the BRA instruction.
15
PC + W
PC
The CALLW instruction enables computed calls by combining PCLATH and W to form the destination address.
A computed CALLW is accomplished by loading the W
register with the desired address and executing CALLW.
The PCL register is loaded with the value of W and
PCH is loaded with PCLATH.
PCL
0
BRA
15
PC + OPCODE
3.3.1
MODIFYING PCL
Executing any instruction with the PCL register as the
destination simultaneously causes the Program
Counter PC bits (PCH) to be replaced by the
contents of the PCLATH register. This allows the entire
contents of the program counter to be changed by
writing the desired upper seven bits to the PCLATH
register. When the lower eight bits are written to the
PCL register, all 15 bits of the program counter will
change to the values contained in the PCLATH register
and those being written to the PCL register.
3.3.2
COMPUTED GOTO
A computed GOTO is accomplished by adding an offset to
the program counter (ADDWF PCL). When performing a
table read using a computed GOTO method, care should
be exercised if the table location crosses a PCL memory
boundary (each 256-byte block). Refer to Application
Note AN556, “Implementing a Table Read” (DS00556).
2012-2017 Microchip Technology Inc.
DS40001657C-page 35
PIC16LF1824T39A
3.4
Stack
3.4.1
The stack is available through the TOSH, TOSL and
STKPTR registers. STKPTR is the current value of the
Stack Pointer. TOSH:TOSL register pair points to the
TOP of the stack. Both registers are read/writable. TOS
is split into TOSH and TOSL due to the 15-bit size of the
PC. To access the stack, adjust the value of STKPTR,
which will position TOSH:TOSL, then read/write to
TOSH:TOSL. STKPTR is five bits to allow detection of
overflow and underflow.
All devices have a 16-level x 15-bit wide hardware
stack (refer to Figures 3-4 through 3-7). The stack
space is not part of either program or data space. The
PC is PUSHed onto the stack when CALL or CALLW
instructions are executed or an interrupt causes a
branch. The stack is POPed in the event of a RETURN,
RETLW or a RETFIE instruction execution. PCLATH is
not affected by a PUSH or POP operation.
The stack operates as a circular buffer if the STVREN
bit = 0 (Configuration Word 2). This means that after
the stack has been PUSHed sixteen times, the seventeenth PUSH overwrites the value that was stored from
the first PUSH. The eighteenth PUSH overwrites the
second PUSH (and so on). The STKOVF and STKUNF
flag bits will be set on an Overflow/Underflow, regardless of whether the Reset is enabled.
Note:
Care should be taken when modifying the
STKPTR while interrupts are enabled.
During normal program operation, CALL, CALLW and
Interrupts will increment STKPTR while RETLW,
RETURN, and RETFIE will decrement STKPTR. At any
time STKPTR can be inspected to see how much stack
is left. The STKPTR always points at the currently used
place on the stack. Therefore, a CALL or CALLW will
increment the STKPTR and then write the PC, and a
return will unload the PC and then decrement STKPTR.
Note 1: There are no instructions/mnemonics
called PUSH or POP. These are actions
that occur from the execution of the
CALL, CALLW, RETURN, RETLW and
RETFIE instructions or the vectoring to
an interrupt address.
FIGURE 3-4:
ACCESSING THE STACK
Reference Figure 3-4 through Figure 3-7 for examples
of accessing the stack.
ACCESSING THE STACK EXAMPLE 1
TOSH:TOSL
0x0F
STKPTR = 0x1F
Stack Reset Disabled
(STVREN = 0)
0x0E
0x0D
0x0C
0x0B
0x0A
Initial Stack Configuration:
0x09
After Reset, the stack is empty. The
empty stack is initialized so the Stack
Pointer is pointing at 0x1F. If the Stack
Overflow/Underflow Reset is enabled, the
TOSH/TOSL registers will return ‘0’. If
the Stack Overflow/Underflow Reset is
disabled, the TOSH/TOSL registers will
return the contents of stack address 0x0F.
0x08
0x07
0x06
0x05
0x04
0x03
0x02
0x01
0x00
TOSH:TOSL
DS40001657C-page 36
0x1F
0x0000
STKPTR = 0x1F
Stack Reset Enabled
(STVREN = 1)
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 3-5:
ACCESSING THE STACK EXAMPLE 2
0x0F
0x0E
0x0D
0x0C
0x0B
0x0A
0x09
This figure shows the stack configuration
after the first CALL or a single interrupt.
If a RETURN instruction is executed, the
return address will be placed in the
Program Counter and the Stack Pointer
decremented to the empty state (0x1F).
0x08
0x07
0x06
0x05
0x04
0x03
0x02
0x01
TOSH:TOSL
FIGURE 3-6:
0x00
Return Address
STKPTR = 0x00
ACCESSING THE STACK EXAMPLE 3
0x0F
0x0E
0x0D
0x0C
After seven CALLs or six CALLs and an
interrupt, the stack looks like the figure
on the left. A series of RETURN instructions
will repeatedly place the return addresses
into the Program Counter and pop the stack.
0x0B
0x0A
0x09
0x08
0x07
TOSH:TOSL
2012-2017 Microchip Technology Inc.
0x06
Return Address
0x05
Return Address
0x04
Return Address
0x03
Return Address
0x02
Return Address
0x01
Return Address
0x00
Return Address
STKPTR = 0x06
DS40001657C-page 37
PIC16LF1824T39A
FIGURE 3-7:
ACCESSING THE STACK EXAMPLE 4
TOSH:TOSL
3.4.2
0x0F
Return Address
0x0E
Return Address
0x0D
Return Address
0x0C
Return Address
0x0B
Return Address
0x0A
Return Address
0x09
Return Address
0x08
Return Address
0x07
Return Address
0x06
Return Address
0x05
Return Address
0x04
Return Address
0x03
Return Address
0x02
Return Address
0x01
Return Address
0x00
Return Address
When the stack is full, the next CALL or
an interrupt will set the Stack Pointer to
0x10. This is identical to address 0x00
so the stack will wrap and overwrite the
return address at 0x00. If the Stack
Overflow/Underflow Reset is enabled, a
Reset will occur and location 0x00 will
not be overwritten.
STKPTR = 0x10
OVERFLOW/UNDERFLOW RESET
If the STVREN bit in Configuration Word 2 is set to ‘1’,
the device will be reset if the stack is PUSHed beyond
the sixteenth level or POPed beyond the first level,
setting the appropriate bits (STKOVF or STKUNF,
respectively) in the PCON register.
3.5
Indirect Addressing
The INDFn registers are not physical registers. Any
instruction that accesses an INDFn register actually
accesses the register at the address specified by the
File Select Registers (FSR). If the FSRn address
specifies one of the two INDFn registers, the read will
return ‘0’ and the write will not occur (though Status bits
may be affected). The FSRn register value is created
by the pair FSRnH and FSRnL.
The FSR registers form a 16-bit address that allows an
addressing space with 65536 locations. These locations
are divided into three memory regions:
• Traditional Data Memory
• Linear Data Memory
• Program Flash Memory
DS40001657C-page 38
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 3-8:
INDIRECT ADDRESSING
0x0000
0x0000
Traditional
Data Memory
0x0FFF
0x1000
0x1FFF
0x0FFF
Reserved
0x2000
Linear
Data Memory
0x29AF
0x29B0
FSR
Address
Range
0x7FFF
0x8000
Reserved
0x0000
Program
Flash Memory
0xFFFF
Note:
0x7FFF
Not all memory regions are completely implemented. Consult device memory tables for memory limits.
2012-2017 Microchip Technology Inc.
DS40001657C-page 39
PIC16LF1824T39A
3.5.1
TRADITIONAL DATA MEMORY
The traditional data memory is a region from FSR
address 0x000 to FSR address 0xFFF. The addresses
correspond to the absolute addresses of all SFR, GPR
and common registers.
FIGURE 3-9:
TRADITIONAL DATA MEMORY MAP
Direct Addressing
4
BSR
0
6
Indirect Addressing
From Opcode
7
0
0
Bank Select
Location Select
0x00
0000
0001 0010
FSRxH
0
0
0
7
FSRxL
0
0
Bank Select
Location Select
1111
0x7F
Bank 0 Bank 1 Bank 2
DS40001657C-page 40
Bank 31
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
3.5.2
3.5.3
LINEAR DATA MEMORY
The linear data memory is the region from FSR
address 0x2000 to FSR address 0x29AF. This region is
a virtual region that points back to the 80-byte blocks of
GPR memory in all the banks.
Unimplemented memory reads as 0x00. Use of the
linear data memory region allows buffers to be larger
than 80 bytes because incrementing the FSR beyond
one bank will go directly to the GPR memory of the next
bank.
The 16 bytes of common memory are not included in
the linear data memory region.
FIGURE 3-10:
7
FSRnH
0 0 1
LINEAR DATA MEMORY
MAP
0
7
FSRnL
0
PROGRAM FLASH MEMORY
To make constant data access easier, the entire
program Flash memory is mapped to the upper half of
the FSR address space. When the MSB of FSRnH is
set, the lower 15 bits are the address in program
memory which will be accessed through INDF. Only the
lower eight bits of each memory location is accessible
via INDF. Writing to the program Flash memory cannot
be accomplished via the FSR/INDF interface. All
instructions that access program Flash memory via the
FSR/INDF interface will require one additional
instruction cycle to complete.
FIGURE 3-11:
7
1
FSRnH
PROGRAM FLASH
MEMORY MAP
0
Location Select
Location Select
0x2000
7
FSRnL
0x8000
0
0x0000
0x020
Bank 0
0x06F
0x0A0
Bank 1
0x0EF
0x120
Program
Flash
Memory
(low 8
bits)
Bank 2
0x16F
0xF20
Bank 30
0x29AF
2012-2017 Microchip Technology Inc.
0xF6F
0xFFFF
0x7FFF
DS40001657C-page 41
PIC16LF1824T39A
4.0
DEVICE CONFIGURATION
Device Configuration consists of Configuration Word 1
and Configuration Word 2, Code Protection and Device
ID.
4.1
Configuration Words
There are several Configuration Word bits that allow
different oscillator and memory protection options.
These are implemented as Configuration Word 1 at
8007h and Configuration Word 2 at 8008h.
Note:
The DEBUG bit in Configuration Word is
managed
automatically
by
device
development tools including debuggers
and programmers. For normal device
operation, this bit should be maintained as
a ‘1’.
DS40001657C-page 42
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
REGISTER 4-1:
CONFIGURATION WORD 1
R/P-1/1
R/P-1/1
R/P-1/1
FCMEN
IESO
CLKOUTEN
R/P-1/1
R/P-1/1
BOREN
CPD
bit 13
R/P-1/1
R/P-1/1
R/P-1/1
CP
MCLRE
PWRTE
R/P-1/1
bit 8
R/P-1/1
R/P-1/1
WDTE
R/P-1/1
R/P-1/1
R/P-1/1
FOSC
bit 7
bit 0
Legend:
R = Readable bit
P = Programmable bit
U = Unimplemented bit, read as ‘1’
‘0’ = Bit is cleared
‘1’ = Bit is set
-n = Value when blank or after Bulk Erase
bit 13
FCMEN: Fail-Safe Clock Monitor Enable bit
1 = Fail-Safe Clock Monitor is enabled
0 = Fail-Safe Clock Monitor is disabled
bit 12
IESO: Internal External Switchover bit
1 = Internal/External Switchover mode is enabled
0 = Internal/External Switchover mode is disabled
bit 11
CLKOUTEN: Clock Out Enable bit
If FOSC Configuration bits are set to LP, XT, HS modes:
This bit is ignored, CLKOUT function is disabled. Oscillator function on the CLKOUT pin.
All other FOSC modes:
1 = CLKOUT function is disabled. I/O function on the CLKOUT pin.
0 = CLKOUT function is enabled on the CLKOUT pin
bit 10-9
BOREN: Brown-out Reset Enable bits(1)
11 = BOR enabled
10 = BOR enabled during operation and disabled in Sleep
01 = BOR controlled by SBOREN bit of the BORCON register
00 = BOR disabled
bit 8
CPD: Data Code Protection bit(2)
1 = Data memory code protection is disabled
0 = Data memory code protection is enabled
bit 7
CP: Code Protection bit(3)
1 = Program memory code protection is disabled
0 = Program memory code protection is enabled
bit 6
MCLRE: RA3/MCLR/VPP Pin Function Select bit
If LVP bit = 1:
This bit is ignored.
If LVP bit = 0:
1 = MCLR/VPP pin function is MCLR; Weak pull-up enabled.
0 = MCLR/VPP pin function is digital input; MCLR internally disabled; Weak pull-up under control of WPUA register.
bit 5
PWRTE: Power-up Timer Enable bit(1)
1 = PWRT disabled
0 = PWRT enabled
bit 4-3
WDTE: Watchdog Timer Enable bit
11 = WDT enabled
10 = WDT enabled while running and disabled in Sleep
01 = WDT controlled by the SWDTEN bit in the WDTCON register
00 = WDT disabled
Note 1:
2:
3:
Enabling Brown-out Reset does not automatically enable Power-up Timer.
The entire data EEPROM will be erased when the code protection is turned off during an erase.
The entire program memory will be erased when the code protection is turned off.
2012-2017 Microchip Technology Inc.
DS40001657C-page 43
PIC16LF1824T39A
REGISTER 4-1:
bit 2-0
Note 1:
2:
3:
CONFIGURATION WORD 1 (CONTINUED)
FOSC: Oscillator Selection bits
111 = ECH: External Clock, High-Power mode (4-32 MHz): device clock supplied to CLKIN pin
110 = ECM: External Clock, Medium-Power mode (0.5-4 MHz): device clock supplied to CLKIN
pin
101 = ECL: External Clock, Low-Power mode (0-0.5 MHz): device clock supplied to CLKIN pin
100 = INTOSC oscillator: I/O function on CLKIN pin
011 = EXTRC oscillator: External RC circuit connected to CLKIN pin
010 = HS oscillator: High-speed crystal/resonator connected between OSC1 and OSC2 pins
001 = XT oscillator: Crystal/resonator connected between OSC1 and OSC2 pins
000 = LP oscillator: Low-power crystal connected between OSC1 and OSC2 pins
Enabling Brown-out Reset does not automatically enable Power-up Timer.
The entire data EEPROM will be erased when the code protection is turned off during an erase.
The entire program memory will be erased when the code protection is turned off.
DS40001657C-page 44
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
REGISTER 4-2:
CONFIGURATION WORD 2
R/P-1/1
R/P-1/1
U-1
R/P-1/1
R/P-1/1
R/P-1/1
LVP(1)
DEBUG(2)
—
BORV
STVREN
PLLEN
bit 13
bit 8
U-1
U-1
U-1
R-1
U-1
U-1
—
—
—
Reserved
—
—
R/P-1/1
R/P-1/1
WRT
bit 7
bit 0
Legend:
R = Readable bit
P = Programmable bit
U = Unimplemented bit, read as ‘1’
‘0’ = Bit is cleared
‘1’ = Bit is set
-n = Value when blank or after Bulk Erase
bit 13
LVP: Low-Voltage Programming Enable bit(1)
1 = Low-voltage programming enabled
0 = High-voltage on MCLR must be used for programming
bit 12
DEBUG: In-Circuit Debugger Mode bit(2)
1 = In-Circuit Debugger disabled, ICSPCLK and ICSPDAT are general purpose I/O pins
0 = In-Circuit Debugger enabled, ICSPCLK and ICSPDAT are dedicated to the debugger
bit 11
Unimplemented: Read as ‘1’
bit 10
BORV: Brown-out Reset Voltage Selection bit(3)
1 = Brown-out Reset voltage (Vbor), low trip point selected
0 = Brown-out Reset voltage (Vbor), high trip point selected
bit 9
STVREN: Stack Overflow/Underflow Reset Enable bit
1 = Stack Overflow or Underflow will cause a Reset
0 = Stack Overflow or Underflow will not cause a Reset
bit 8
PLLEN: PLL Enable bit
1 = 4xPLL enabled
0 = 4xPLL disabled
bit 7-5
Unimplemented: Read as ‘1’
bit 4
Reserved: This location should be programmed to a ‘1’
bit 3-2
Unimplemented: Read as ‘1’
bit 1-0
WRT: Flash Memory Self-Write Protection bits
11 = Write protection off
10 = 000h to 1FFh write-protected, 200h to FFFh may be modified by EECON control
01 = 000h to 7FFh write-protected, 800h to FFFh may be modified by EECON control
00 = 000h to FFFh write-protected, no addresses may be modified by EECON control
Note 1:
2:
3:
The LVP bit cannot be programmed to ‘0’ when Programming mode is entered via LVP.
The DEBUG bit in Configuration Word is managed automatically by device development tools including debuggers and
programmers. For normal device operation, this bit should be maintained as a ‘1’.
See Vbor parameter for specific trip point voltages.
2012-2017 Microchip Technology Inc.
DS40001657C-page 45
PIC16LF1824T39A
4.2
Code Protection
Code protection allows the device to be protected from
unauthorized access. Program memory protection and
data EEPROM protection are controlled independently.
Internal access to the program memory and data
EEPROM are unaffected by any code protection
setting.
4.2.1
PROGRAM MEMORY PROTECTION
The entire program memory space is protected from
external reads and writes by the CP bit in Configuration
Word 1. When CP = 0, external reads and writes of
program memory are inhibited and a read will return all
‘0’s. The CPU can continue to read program memory,
regardless of the protection bit settings. Writing the
program memory is dependent upon the write
protection
setting.
See
Section 4.3
“Write
Protection” for more information.
4.2.2
DATA EEPROM PROTECTION
The entire data EEPROM is protected from external
reads and writes by the CPD bit. When CPD = 0,
external reads and writes of data EEPROM are
inhibited. The CPU can continue to read and write data
EEPROM regardless of the protection bit settings.
4.3
Write Protection
Write protection allows the device to be protected from
unintended self-writes. Applications, such as
bootloader software, can be protected while allowing
other regions of the program memory to be modified.
The WRT bits in Configuration Word 2 define the
size of the program memory block that is protected.
4.4
User ID
Four memory locations (8000h-8003h) are designated as
ID locations where the user can store checksum or other
code identification numbers. These locations are
readable and writable during normal execution. See
Section 11.5 “User ID, Device ID and Configuration
Word Access” for more information on accessing these
memory locations. For more information on checksum
calculation, see the “PIC16F/LF182X/PIC12F/LF1822
Memory Programming Specification” (DS41390).
DS40001657C-page 46
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
4.5
Device ID and Revision ID
The memory location 8006h is where the Device ID and
Revision ID are stored. The upper nine bits hold the
Device ID. The lower five bits hold the Revision ID. See
Section 11.5 “User ID, Device ID and Configuration
Word Access” for more information on accessing
these memory locations.
Development tools, such as device programmers and
debuggers, may be used to read the Device ID and
Revision ID.
REGISTER 4-3:
DEVICEID: DEVICE ID REGISTER(1)
R
R
R
R
R
R
DEV
bit 13
R
R
bit 8
R
R
R
DEV
R
R
R
REV
bit 7
bit 0
Legend:
R = Readable bit
‘0’ = Bit is cleared
bit 13-5
DEV: Device ID bits
101000010 = PIC16LF1824T39A
bit 4-0
REV: Revision ID bits
‘1’ = Bit is set
These bits are used to identify the revision.
Note 1:
This location cannot be written.
2012-2017 Microchip Technology Inc.
DS40001657C-page 47
PIC16LF1824T39A
5.0
5.1
OSCILLATOR MODULE (WITH
FAIL-SAFE CLOCK MONITOR)
Overview
The oscillator module has a wide variety of clock
sources and selection features that allow it to be used
in a wide range of applications while maximizing performance and minimizing power consumption. Figure 5-1
illustrates a block diagram of the oscillator module.
Clock sources can be supplied from external oscillators,
quartz crystal resonators, ceramic resonators and
Resistor-Capacitor (RC) circuits. In addition, the system
clock source can be supplied from one of two internal
oscillators and PLL circuits, with a choice of speeds
selectable via software. Additional clock features
include:
• Selectable system clock source between external
or internal sources via software.
• Two-Speed Start-up mode, which minimizes
latency between external oscillator start-up and
code execution.
• Fail-Safe Clock Monitor (FSCM) designed to
detect a failure of the external clock source (LP,
XT, HS, EC or RC modes) and switch
automatically to the internal oscillator.
• Oscillator Start-up Timer (OST) ensures stability
of crystal oscillator sources
DS40001657C-page 48
The oscillator module can be configured in one of eight
clock modes.
1.
2.
3.
4.
5.
6.
7.
8.
ECL – External Clock Low-Power mode
(0 MHz to 0.5 MHz)
ECM – External Clock Medium-Power mode
(0.5 MHz to 4 MHz)
ECH – External Clock High-Power mode
(4 MHz to 32 MHz)
LP – 32 kHz Low-Power Crystal mode.
XT – Medium Gain Crystal or Ceramic Resonator
Oscillator mode (up to 4 MHz)
HS – High Gain Crystal or Ceramic Resonator
mode (4 MHz to 20 MHz)
RC – External Resistor-Capacitor (RC)
INTOSC – Internal oscillator (31 kHz to 32 MHz)
Clock Source modes are selected by the FOSC
bits in the Configuration Word 1. The FOSC bits
determine the type of oscillator that will be used when
the device is first powered.
The EC clock mode relies on an external logic level
signal as the device clock source. The LP, XT, and HS
clock modes require an external crystal or resonator to
be connected to the device. Each mode is optimized for
a different frequency range. The RC clock mode
requires an external resistor and capacitor to set the
oscillator frequency.
The INTOSC internal oscillator block produces low,
medium, and high-frequency clock sources,
designated LFINTOSC, MFINTOSC, and HFINTOSC.
(see Internal Oscillator Block, Figure 5-1). A wide
selection of device clock frequencies may be derived
from these three clock sources.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 5-1:
SIMPLIFIED PIC® MCU CLOCK SOURCE BLOCK DIAGRAM
External
Oscillator
LP, XT, HS, RC, EC
OSC2
Sleep
4 x PLL
Oscillator Timer1
FOSC = 100
T1OSO
IRCF
HFPLL
500 kHz
Source
16 MHz
(HFINTOSC)
Postscaler
Internal
Oscillator
Block
500 kHz
(MFINTOSC)
31 kHz
Source
16 MHz
8 MHz
4 MHz
2 MHz
1 MHz
500 kHz
250 kHz
125 kHz
62.5 kHz
31.25 kHz
31 kHz
31 kHz (LFINTOSC)
2012-2017 Microchip Technology Inc.
MUX
T1OSI
T1OSCEN
Enable
Oscillator
Sleep
T1OSC
CPU and
Peripherals
MUX
OSC1
Internal Oscillator
Clock
Control
FOSC SCS
Clock Source Option
for other modules
WDT, PWRT, Fail-Safe Clock Monitor
Two-Speed Start-up and other modules
DS40001657C-page 49
PIC16LF1824T39A
5.2
Clock Source Types
Clock sources can be classified as external or internal.
External clock sources rely on external circuitry for the
clock source to function. Examples are: oscillator
modules (EC mode), quartz crystal resonators or
ceramic resonators (LP, XT and HS modes) and
Resistor-Capacitor (RC) mode circuits.
Internal clock sources are contained internally within
the oscillator module. The internal oscillator block has
two internal oscillators and a dedicated Phase-Locked
Loop (HFPLL) that are used to generate three internal
system clock sources: the 16 MHz High-Frequency
Internal Oscillator (HFINTOSC), 500 kHz (MFINTOSC)
and the 31 kHz Low-Frequency Internal Oscillator
(LFINTOSC).
The system clock can be selected between external or
internal clock sources via the System Clock Select
(SCS) bits in the OSCCON register. See Section 5.3
“Clock Switching” for additional information.
5.2.1
FIGURE 5-2:
EXTERNAL CLOCK (EC)
MODE OPERATION
OSC1/CLKIN
Clock from
Ext. System
PIC® MCU
FOSC/4 or I/O(1)
Note 1:
OSC2/CLKOUT
Output depends upon CLKOUTEN bit of the
Configuration Word 1.
EXTERNAL CLOCK SOURCES
An external clock source can be used as the device
system clock by performing one of the following
actions:
• Program the FOSC bits in the Configuration
Word 1 to select an external clock source that will
be used as the default system clock upon a
device Reset.
• Write the SCS bits in the OSCCON register
to switch the system clock source to:
- Timer1 Oscillator during run-time, or
- An external clock source determined by the
value of the FOSC bits.
See Section 5.3 “Clock Switching”for more information.
5.2.1.1
The Oscillator Start-up Timer (OST) is disabled when
EC mode is selected. Therefore, there is no delay in
operation after a Power-on Reset (POR) or wake-up
from Sleep. Because the PIC® MCU design is fully
static, stopping the external clock input will have the
effect of halting the device while leaving all data intact.
Upon restarting the external clock, the device will
resume operation as if no time had elapsed.
EC Mode
The External Clock (EC) mode allows an externally
generated logic level signal to be the system clock
source. When operating in this mode, an external clock
source is connected to the OSC1 input.
OSC2/CLKOUT is available for general purpose I/O or
CLKOUT. Figure 5-2 shows the pin connections for EC
mode.
EC mode has three power modes to select from through
Configuration Word 1:
5.2.1.2
LP, XT, HS Modes
The LP, XT and HS modes support the use of quartz
crystal resonators or ceramic resonators connected to
OSC1 and OSC2 (Figure 5-3). The three modes select
a low, medium or high gain setting of the internal
inverter-amplifier to support various resonator types
and speed.
LP Oscillator mode selects the lowest gain setting of
the internal inverter-amplifier. LP mode current
consumption is the least of the three modes. This mode
is designed to drive only 32.768 kHz tuning-fork type
crystals (watch crystals).
XT Oscillator mode selects the intermediate gain
setting of the internal inverter-amplifier. XT mode
current consumption is the medium of the three modes.
This mode is best suited to drive resonators with a
medium drive level specification.
HS Oscillator mode selects the highest gain setting of
the internal inverter-amplifier. HS mode current
consumption is the highest of the three modes. This
mode is best suited for resonators that require a high
drive setting.
Figure 5-3 and Figure 5-4 show typical circuits for
quartz crystal and ceramic resonators, respectively.
• High power, 4-32 MHz (FOSC = 111)
• Medium power, 0.5-4 MHz (FOSC = 110)
• Low power, 0-0.5 MHz (FOSC = 101)
DS40001657C-page 50
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 5-3:
QUARTZ CRYSTAL
OPERATION (LP, XT OR
HS MODE)
FIGURE 5-4:
CERAMIC RESONATOR
OPERATION
(XT OR HS MODE)
PIC® MCU
PIC® MCU
OSC1/CLKIN
C1
To Internal
Logic
Quartz
Crystal
C2
OSC1/CLKIN
RS(1)
RF(2)
C1
Sleep
OSC2/CLKOUT
Note 1: A series resistor (RS) may be required for
quartz crystals with low drive level.
RP(3)
C2 Ceramic RS(1)
Resonator
Note 1:
2: The value of RF varies with the Oscillator mode
selected (typically between 2 M to 10 M.
Note 1: Quartz
crystal
characteristics
vary
according to type, package and
manufacturer. The user should consult the
manufacturer data sheets for specifications
and recommended application.
2: Always verify oscillator performance over
the VDD and temperature range that is
expected for the application.
3: For oscillator design assistance, reference
the following Microchip Applications Notes:
• AN826, “Crystal Oscillator Basics and
Crystal Selection for rfPIC® and PIC®
Devices” (DS00826)
• AN849, “Basic PIC® Oscillator Design”
(DS00849)
• AN943, “Practical PIC® Oscillator
Analysis and Design” (DS00943)
• AN949, “Making Your Oscillator Work”
(DS00949)
2012-2017 Microchip Technology Inc.
To Internal
Logic
RF(2)
Sleep
OSC2/CLKOUT
A series resistor (RS) may be required for
ceramic resonators with low drive level.
2: The value of RF varies with the Oscillator mode
selected (typically between 2 M to 10 M.
3: An additional parallel feedback resistor (RP)
may be required for proper ceramic resonator
operation.
5.2.1.3
Oscillator Start-up Timer (OST)
If the oscillator module is configured for LP, XT or HS
modes, the Oscillator Start-up Timer (OST) counts
1024 oscillations from OSC1. This occurs following a
Power-on Reset (POR) and when the Power-up Timer
(PWRT) has expired (if configured), or a wake-up from
Sleep. During this time, the program counter does not
increment and program execution is suspended unless
either FSCM or Two-Speed Start-up are enabled. In
this case, the code will continue to execute at the
selected INTOSC frequency while the OST is counting.
The OST ensures that the oscillator circuit, using a
quartz crystal resonator or ceramic resonator, has
started and is providing a stable system clock to the
oscillator module.
In order to minimize latency between external oscillator
start-up and code execution, the Two-Speed Clock
Start-up mode can be selected (see Section 5.4
“Two-Speed Clock Start-up Mode”).
DS40001657C-page 51
PIC16LF1824T39A
5.2.1.4
4xPLL
The oscillator module contains a 4xPLL that can be
used with both external and internal clock sources to
provide a system clock source. The input frequency for
the 4xPLL must fall within specifications. See the PLL
Clock Timing Specifications in Section 31.0
“Electrical Specifications”.
The 4xPLL may be enabled for use by one of two
methods:
1.
2.
Program the PLLEN bit in Configuration Word 2
to a ‘1’.
Write the SPLLEN bit in the OSCCON register to
a ‘1’. If the PLLEN bit in Configuration Word 2 is
programmed to a ‘1’, then the value of SPLLEN
is ignored.
5.2.1.5
TIMER1 Oscillator
The Timer1 Oscillator is a separate crystal oscillator
that is associated with the Timer1 peripheral. It is optimized for timekeeping operations with a 32.768 kHz
crystal connected between the T1OSO and T1OSI
device pins.
The Timer1 Oscillator can be used as an alternate
system clock source and can be selected during
run-time using clock switching. Refer to Section 5.3
“Clock Switching” for more information.
FIGURE 5-5:
Note 1: Quartz
crystal
characteristics
vary
according to type, package and
manufacturer. The user should consult the
manufacturer data sheets for specifications
and recommended application.
2: Always verify oscillator performance over
the VDD and temperature range that is
expected for the application.
3: For oscillator design assistance, reference
the following Microchip Applications Notes:
• AN826, “Crystal Oscillator Basics and
Crystal Selection for rfPIC® and PIC®
Devices” (DS00826)
• AN849, “Basic PIC® Oscillator Design”
(DS00849)
• AN943, “Practical PIC® Oscillator
Analysis and Design” (DS00943)
• AN949, “Making Your Oscillator Work”
(DS00949)
• TB097, “Interfacing a Micro Crystal
MS1V-T1K 32.768 kHz Tuning Fork
Crystal to a PIC16F690/SS” (DS91097)
• AN1288, “Design Practices for
Low-Power External Oscillators”
(DS01288)
QUARTZ CRYSTAL
OPERATION (TIMER1
OSCILLATOR)
PIC® MCU
T1OSI
C1
To Internal
Logic
32.768 kHz
Quartz
Crystal
C2
DS40001657C-page 52
T1OSO
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
5.2.1.6
External RC Mode
5.2.2
The external Resistor-Capacitor (RC) modes support
the use of an external RC circuit. This allows the
designer maximum flexibility in frequency choice while
keeping costs to a minimum when clock accuracy is not
required.
The RC circuit connects to OSC1. OSC2/CLKOUT is
available for general purpose I/O or CLKOUT. The
function of the OSC2/CLKOUT pin is determined by the
state of the CLKOUTEN bit in Configuration Word 1.
Figure 5-6 shows the external RC mode connections.
FIGURE 5-6:
VDD
EXTERNAL RC MODES
PIC® MCU
REXT
OSC1/CLKIN
Internal
Clock
CEXT
VSS
FOSC/4 or I/O(1)
OSC2/CLKOUT
The device may be configured to use the internal
oscillator block as the system clock by performing one
of the following actions:
• Program the FOSC bits in Configuration
Word 1 to select the INTOSC clock source, which
will be used as the default system clock upon a
device Reset.
• Write the SCS bits in the OSCCON register
to switch the system clock source to the internal
oscillator during run-time. See Section 5.3
“Clock Switching”for more information.
In INTOSC mode, OSC1/CLKIN is available for general
purpose I/O. OSC2/CLKOUT is available for general
purpose I/O or CLKOUT.
The function of the OSC2/CLKOUT pin is determined
by the state of the CLKOUTEN bit in Configuration
Word 1.
The internal oscillator block has two independent
oscillators and a dedicated Phase-Locked Loop,
HFPLL that can produce one of three internal system
clock sources.
1.
Recommended values: 10 k REXT 100 k, 20 pF, 2-5V
Note 1:
Output depends upon CLKOUTEN bit of the
Configuration Word 1.
2.
The RC oscillator frequency is a function of the supply
voltage, the resistor (REXT) and capacitor (CEXT) values
and the operating temperature. Other factors affecting
the oscillator frequency are:
• threshold voltage variation
• component tolerances
• packaging variations in capacitance
INTERNAL CLOCK SOURCES
3.
The HFINTOSC (High-Frequency Internal
Oscillator) is factory calibrated and operates at
16 MHz. The HFINTOSC source is generated
from the 500 kHz MFINTOSC source and the
dedicated Phase-Locked Loop, HFPLL. The
frequency of the HFINTOSC can be
user-adjusted via software using the OSCTUNE
register (Register 5-3).
The MFINTOSC (Medium-Frequency Internal
Oscillator) is factory calibrated and operates at
500 kHz. The frequency of the MFINTOSC can
be user-adjusted via software using the
OSCTUNE register (Register 5-3).
The LFINTOSC (Low-Frequency Internal
Oscillator) is uncalibrated and operates at
31 kHz.
The user also needs to take into account variation due
to tolerance of external RC components used.
2012-2017 Microchip Technology Inc.
DS40001657C-page 53
PIC16LF1824T39A
5.2.2.1
HFINTOSC
The High-Frequency Internal Oscillator (HFINTOSC) is
a factory calibrated 16 MHz internal clock source. The
frequency of the HFINTOSC can be altered via
software using the OSCTUNE register (Register 5-3).
The output of the HFINTOSC connects to a postscaler
and multiplexer (see Figure 5-1). One of nine
frequencies derived from the HFINTOSC can be
selected via software using the IRCF bits of the
OSCCON register. See Section 5.2.2.7 “Internal
Oscillator Clock Switch Timing” for more information.
The HFINTOSC is enabled by:
• Configure the IRCF bits of the OSCCON
register for the desired HF frequency, and
• FOSC = 100, or
• Set the System Clock Source (SCS) bits of the
OSCCON register to ‘1x’.
The High-Frequency Internal Oscillator Ready bit
(HFIOFR) of the OSCSTAT register indicates when the
HFINTOSC is running and can be utilized.
The High-Frequency Internal Oscillator Status Locked
bit (HFIOFL) of the OSCSTAT register indicates when
the HFINTOSC is running within 2% of its final value.
The High-Frequency Internal Oscillator Status Stable
bit (HFIOFS) of the OSCSTAT register indicates when
the HFINTOSC is running within 0.5% of its final value.
5.2.2.2
MFINTOSC
The
Medium-Frequency
Internal
Oscillator
(MFINTOSC) is a factory calibrated 500 kHz internal
clock source. The frequency of the MFINTOSC can be
altered via software using the OSCTUNE register
(Register 5-3).
The output of the MFINTOSC connects to a postscaler
and multiplexer (see Figure 5-1). One of nine
frequencies derived from the MFINTOSC can be
selected via software using the IRCF bits of the
OSCCON register. See Section 5.2.2.7 “Internal
Oscillator Clock Switch Timing” for more information.
The MFINTOSC is enabled by:
• Configure the IRCF bits of the OSCCON
register for the desired HF frequency, and
• FOSC = 100, or
• Set the System Clock Source (SCS) bits of the
OSCCON register to ‘1x’
The Medium-Frequency Internal Oscillator Ready bit
(MFIOFR) of the OSCSTAT register indicates when the
MFINTOSC is running and can be utilized.
5.2.2.3
Internal Oscillator Frequency
Adjustment
The 500 kHz internal oscillator is factory calibrated.
This internal oscillator can be adjusted in software by
writing to the OSCTUNE register (Register 5-3). Since
the HFINTOSC and MFINTOSC clock sources are
derived from the 500 kHz internal oscillator, a change
in the OSCTUNE register value will apply to both.
The default value of the OSCTUNE register is ‘0’. The
value is a 6-bit two’s complement number. A value of
1Fh will provide an adjustment to the maximum
frequency. A value of 20h will provide an adjustment to
the minimum frequency.
When the OSCTUNE register is modified, the oscillator
frequency will begin shifting to the new frequency. Code
execution continues during this shift. There is no
indication that the shift has occurred.
OSCTUNE does not affect the LFINTOSC frequency.
Operation of features that depend on the LFINTOSC
clock source frequency, such as the Power-up Timer
(PWRT), Watchdog Timer (WDT), Fail-Safe Clock
Monitor (FSCM) and peripherals, are not affected by the
change in frequency.
5.2.2.4
LFINTOSC
The Low-Frequency Internal Oscillator (LFINTOSC) is
an uncalibrated 31 kHz internal clock source.
The output of the LFINTOSC connects to a multiplexer
(see Figure 5-1). Select 31 kHz, via software, using the
IRCF bits of the OSCCON register. See
Section 5.2.2.7 “Internal Oscillator Clock Switch
Timing” for more information. The LFINTOSC is also
the frequency for the Power-up Timer (PWRT),
Watchdog Timer (WDT) and Fail-Safe Clock Monitor
(FSCM).
The LFINTOSC is enabled by selecting 31 kHz
(IRCF bits of the OSCCON register = 000) as the
system clock source (SCS bits of the OSCCON
register = 1x), or when any of the following are
enabled:
• Configure the IRCF bits of the OSCCON
register for the desired LF frequency, and
• FOSC = 100, or
• Set the System Clock Source (SCS) bits of the
OSCCON register to ‘1x’
Peripherals that use the LFINTOSC are:
• Power-up Timer (PWRT)
• Watchdog Timer (WDT)
• Fail-Safe Clock Monitor (FSCM)
The Low-Frequency Internal Oscillator Ready bit
(LFIOFR) of the OSCSTAT register indicates when the
LFINTOSC is running and can be utilized.
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5.2.2.5
Internal Oscillator Frequency
Selection
The system clock speed can be selected via software
using the Internal Oscillator Frequency Select bits
IRCF of the OSCCON register.
The outputs of the 16 MHz HFINTOSC postscaler and
the LFINTOSC connect to a multiplexer (see
Figure 5-1). The Internal Oscillator Frequency Select
bits IRCF of the OSCCON register select the
frequency output of the internal oscillators. One of the
following frequencies can be selected via software:
•
•
•
•
•
•
•
•
•
•
•
•
32 MHz (requires 4xPLL)
16 MHz
8 MHz
4 MHz
2 MHz
1 MHz
500 kHz (default after Reset)
250 kHz
125 kHz
62.5 kHz
31.25 kHz
31 kHz (LFINTOSC)
Note:
Following any Reset, the IRCF bits
of the OSCCON register are set to ‘0111’
and the frequency selection is set to
500 kHz. The user can modify the IRCF
bits to select a different frequency.
The IRCF bits of the OSCCON register allow
duplicate selections for some frequencies. These
duplicate choices can offer system design trade-offs.
Lower power consumption can be obtained when
changing oscillator sources for a given frequency.
Faster transition times can be obtained between
frequency changes that use the same oscillator source.
2012-2017 Microchip Technology Inc.
5.2.2.6
32 MHz Internal Oscillator
Frequency Selection
The Internal Oscillator Block can
4xPLL associated with the External
produce a 32 MHz internal system
following settings are required to
internal clock source:
be used with the
Oscillator Block to
clock source. The
use the 32 MHz
• The FOSC bits in Configuration Word 1 must be
set to use the INTOSC source as the device
system clock (FOSC = 100).
• The SCS bits in the OSCCON register must be
cleared to use the clock determined by
FOSC in Configuration Word 1
(SCS = 00).
• The IRCF bits in the OSCCON register must be
set to the 8 MHz HFINTOSC set to use
(IRCF = 1110).
• The SPLLEN bit in the OSCCON register must be
set to enable the 4xPLL, or the PLLEN bit of the
Configuration Word 2 must be programmed to a
‘1’.
Note:
When using the PLLEN bit of the
Configuration Word 2, the 4xPLL cannot
be disabled by software and the 8 MHz
HFINTOSC option will no longer be
available.
The 4xPLL is not available for use with the internal
oscillator when the SCS bits of the OSCCON register
are set to ‘1x’. The SCS bits must be set to ‘00’ to use
the 4xPLL with the internal oscillator.
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PIC16LF1824T39A
5.2.2.7
Internal Oscillator Clock Switch
Timing
When switching between the HFINTOSC, MFINTOSC
and the LFINTOSC, the new oscillator may already be
shut down to save power (see Figure 5-7). If this is the
case, there is a delay after the IRCF bits of the
OSCCON register are modified before the frequency
selection takes place. The OSCSTAT register will
reflect the current active status of the HFINTOSC,
MFINTOSC and LFINTOSC oscillators. The sequence
of a frequency selection is as follows:
1.
2.
3.
4.
5.
6.
7.
IRCF bits of the OSCCON register are
modified.
If the new clock is shut down, a clock start-up
delay is started.
Clock switch circuitry waits for a falling edge of
the current clock.
The current clock is held low and the clock
switch circuitry waits for a rising edge in the new
clock.
The new clock is now active.
The OSCSTAT register is updated as required.
Clock switch is complete.
See Figure 5-7 for more details.
If the internal oscillator speed is switched between two
clocks of the same source, there is no start-up delay
before the new frequency is selected. Clock switching
time delays are shown in Table 5-1.
Start-up delay specifications are located in the
oscillator tables of Section 31.0 “Electrical
Specifications”.
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PIC16LF1824T39A
FIGURE 5-7:
HFINTOSC/
MFINTOSC
INTERNAL OSCILLATOR SWITCH TIMING
LFINTOSC (FSCM and WDT disabled)
HFINTOSC/
MFINTOSC
Start-up Time
2-cycle Sync
Running
LFINTOSC
IRCF
0
0
System Clock
HFINTOSC/
MFINTOSC
LFINTOSC (Either FSCM or WDT enabled)
HFINTOSC/
MFINTOSC
2-cycle Sync
Running
LFINTOSC
0
IRCF
0
System Clock
LFINTOSC
HFINTOSC/MFINTOSC
LFINTOSC turns off unless WDT or FSCM is enabled
LFINTOSC
Start-up Time
2-cycle Sync
Running
HFINTOSC/
MFINTOSC
IRCF
=0
0
System Clock
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5.3
Clock Switching
5.3.3
TIMER1 OSCILLATOR
The system clock source can be switched between
external and internal clock sources via software using
the System Clock Select (SCS) bits of the OSCCON
register. The following clock sources can be selected
using the SCS bits:
The Timer1 oscillator is a separate crystal oscillator
associated with the Timer1 peripheral. It is optimized
for timekeeping operations with a 32.768 kHz crystal
connected between the T1OSO and T1OSI device
pins.
• Default system oscillator determined by FOSC
bits in Configuration Word 1
• Timer1 32 kHz crystal oscillator
• Internal Oscillator Block (INTOSC)
The Timer1 oscillator is enabled using the T1OSCEN
control bit in the T1CON register. See Section 21.0
“Timer1 Module with Gate Control” for more
information about the Timer1 peripheral.
5.3.1
SYSTEM CLOCK SELECT (SCS)
BITS
The System Clock Select (SCS) bits of the OSCCON
register selects the system clock source that is used for
the CPU and peripherals.
• When the SCS bits of the OSCCON register = 00,
the system clock source is determined by value of
the FOSC bits in the Configuration Word 1.
• When the SCS bits of the OSCCON register = 01,
the system clock source is the Timer1 oscillator.
• When the SCS bits of the OSCCON register = 1x,
the system clock source is chosen by the internal
oscillator frequency selected by the IRCF
bits of the OSCCON register. After a Reset, the
SCS bits of the OSCCON register are always
cleared.
Note:
5.3.4
TIMER1 OSCILLATOR READY
(T1OSCR) BIT
The user must ensure that the Timer1 oscillator is
ready to be used before it is selected as a system clock
source. The Timer1 Oscillator Ready (T1OSCR) bit of
the OSCSTAT register indicates whether the Timer1
oscillator is ready to be used. After the T1OSCR bit is
set, the SCS bits can be configured to select the Timer1
oscillator.
Any automatic clock switch, which may
occur from Two-Speed Start-up or
Fail-Safe Clock Monitor, does not update
the SCS bits of the OSCCON register. The
user can monitor the OSTS bit of the
OSCSTAT register to determine the current
system clock source.
When switching between clock sources, a delay is
required to allow the new clock to stabilize. These
oscillator delays are shown in Table 5-1.
5.3.2
OSCILLATOR START-UP TIMER
STATUS (OSTS) BIT
The Oscillator Start-up Timer Status (OSTS) bit of the
OSCSTAT register indicates whether the system clock
is running from the external clock source, as defined by
the FOSC bits in the Configuration Word 1, or
from the internal clock source. In particular, OSTS
indicates that the Oscillator Start-up Timer (OST) has
timed out for LP, XT or HS modes. The OST does not
reflect the status of the Timer1 oscillator.
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5.4
Two-Speed Clock Start-up Mode
Two-Speed Start-up mode provides additional power
savings by minimizing the latency between external
oscillator start-up and code execution. In applications
that make heavy use of the Sleep mode, Two-Speed
Start-up will remove the external oscillator start-up
time from the time spent awake and can reduce the
overall power consumption of the device. This mode
allows the application to wake-up from Sleep, perform
a few instructions using the INTOSC internal oscillator
block as the clock source and go back to Sleep without
waiting for the external oscillator to become stable.
Two-Speed Start-up provides benefits when the
oscillator module is configured for LP, XT, or HS
modes. The Oscillator Start-up Timer (OST) is enabled
for these modes and must count 1024 oscillations
before the oscillator can be used as the system clock
source.
5.4.1
TWO-SPEED START-UP MODE
CONFIGURATION
Two-Speed Start-up mode is configured by the
following settings:
• IESO (of the Configuration Word 1) = 1;
Internal/External Switchover bit (Two-Speed
Start-up mode enabled).
• SCS (of the OSCCON register) = 00.
• FOSC bits in the Configuration Word 1
configured for LP, XT or HS mode.
Two-Speed Start-up mode is entered after:
• Power-on Reset (POR) and, if enabled, after
Power-up Timer (PWRT) has expired, or
• Wake-up from Sleep.
Note:
If the oscillator module is configured for any mode
other than LP, XT or HS mode, then Two-Speed
Start-up is disabled. This is because the external clock
oscillator does not require any stabilization time after
POR or an exit from Sleep.
When FSCM is enabled, Two-Speed
Start-up will automatically be enabled.
If the OST count reaches 1024 before the device
enters Sleep mode, the OSTS bit of the OSCSTAT
register is set and program execution switches to the
external oscillator. However, the system may never
operate from the external oscillator if the time spent
awake is very short.
Note:
Executing a SLEEP instruction will abort
the oscillator start-up time and will cause
the OSTS bit of the OSCSTAT register to
remain clear.
TABLE 5-1:
OSCILLATOR SWITCHING DELAYS
Switch From
Switch To
Frequency
Oscillator Delay
LFINTOSC(1)
Sleep/POR
MFINTOSC(1)
HFINTOSC(1)
31 kHz
31.25 kHz-500 kHz
31.25 kHz-16 MHz
Oscillator Warm-up Delay (TWARM)
Sleep/POR
EC, RC(1)
DC – 32 MHz
2 cycles
LFINTOSC
EC, RC(1)
DC – 32 MHz
1 cycle of each
Sleep/POR
Timer1 Oscillator
LP, XT, HS(1)
32 kHz-20 MHz
1024 Clock Cycles (OST)
Any clock source
MFINTOSC(1)
HFINTOSC(1)
31.25 kHz-500 kHz
31.25 kHz-16 MHz
2 s (approx.)
Any clock source
LFINTOSC(1)
31 kHz
1 cycle of each
Any clock source
Timer1 Oscillator
32 kHz
1024 Clock Cycles (OST)
PLL inactive
PLL active
16-32 MHz
2 ms (approx.)
Note 1:
PLL inactive.
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DS40001657C-page 59
PIC16LF1824T39A
5.4.2
1.
2.
3.
4.
5.
6.
7.
TWO-SPEED START-UP
SEQUENCE
5.4.3
Wake-up from Power-on Reset or Sleep.
Instructions begin execution by the internal
oscillator at the frequency set in the IRCF
bits of the OSCCON register.
OST enabled to count 1024 clock cycles.
OST timed out, wait for falling edge of the
internal oscillator.
OSTS is set.
System clock held low until the next falling edge
of new clock (LP, XT or HS mode).
System clock is switched to external clock
source.
FIGURE 5-8:
CHECKING TWO-SPEED CLOCK
STATUS
Checking the state of the OSTS bit of the OSCSTAT
register will confirm if the microcontroller is running
from the external clock source, as defined by the
FOSC bits in the Configuration Word 1, or the
internal oscillator.
TWO-SPEED START-UP
INTOSC
TOST
OSC1
0
1
1022 1023
OSC2
Program Counter
PC - N
PC
PC + 1
System Clock
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5.5
Fail-Safe Clock Monitor
5.5.3
The Fail-Safe Clock Monitor (FSCM) allows the device
to continue operating should the external oscillator fail.
The FSCM can detect oscillator failure any time after
the Oscillator Start-up Timer (OST) has expired. The
FSCM is enabled by setting the FCMEN bit in the
Configuration Word 1. The FSCM is applicable to all
external Oscillator modes (LP, XT, HS, EC, Timer1
Oscillator and RC).
FIGURE 5-9:
FSCM BLOCK DIAGRAM
Clock Monitor
Latch
External
Clock
LFINTOSC
Oscillator
÷ 64
31 kHz
(~32 s)
488 Hz
(~2 ms)
S
Q
R
Q
Sample Clock
5.5.1
FAIL-SAFE DETECTION
The FSCM module detects a failed oscillator by
comparing the external oscillator to the FSCM sample
clock. The sample clock is generated by dividing the
LFINTOSC by 64. See Figure 5-9. Inside the fail
detector block is a latch. The external clock sets the
latch on each falling edge of the external clock. The
sample clock clears the latch on each rising edge of the
sample clock. A failure is detected when an entire
half-cycle of the sample clock elapses before the
external clock goes low.
5.5.2
The Fail-Safe condition is cleared after a Reset,
executing a SLEEP instruction or changing the SCS bits
of the OSCCON register. When the SCS bits are
changed, the OST is restarted. While the OST is
running, the device continues to operate from the
INTOSC selected in OSCCON. When the OST times
out, the Fail-Safe condition is cleared after successfully
switching to the external clock source. The OSFIF bit
should be cleared prior to switching to the external
clock source. If the Fail-Safe condition still exists, the
OSFIF flag will again become set by hardware.
5.5.4
Clock
Failure
Detected
FAIL-SAFE CONDITION CLEARING
RESET OR WAKE-UP FROM SLEEP
The FSCM is designed to detect an oscillator failure
after the Oscillator Start-up Timer (OST) has expired.
The OST is used after waking up from Sleep and after
any type of Reset. The OST is not used with the EC or
RC Clock modes so that the FSCM will be active as
soon as the Reset or wake-up has completed. When
the FSCM is enabled, the Two-Speed Start-up is also
enabled. Therefore, the device will always be executing
code while the OST is operating.
Note:
Due to the wide range of oscillator start-up
times, the Fail-Safe circuit is not active
during oscillator start-up (i.e., after exiting
Reset or Sleep). After an appropriate
amount of time, the user should check the
Status bits in the OSCSTAT register to
verify the oscillator start-up and that the
system clock switchover has successfully
completed.
FAIL-SAFE OPERATION
When the external clock fails, the FSCM switches the
device clock to an internal clock source and sets the bit
flag OSFIF of the PIR2 register. Setting this flag will
generate an interrupt if the OSFIE bit of the PIE2
register is also set. The device firmware can then take
steps to mitigate the problems that may arise from a
failed clock. The system clock will continue to be
sourced from the internal clock source until the device
firmware successfully restarts the external oscillator
and switches back to external operation.
The internal clock source chosen by the FSCM is
determined by the IRCF bits of the OSCCON
register. This allows the internal oscillator to be
configured before a failure occurs.
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PIC16LF1824T39A
FIGURE 5-10:
FSCM TIMING DIAGRAM
Sample Clock
Oscillator
Failure
System
Clock
Output
Clock Monitor Output
(Q)
Failure
Detected
OSCFIF
Test
Note:
Test
Test
The system clock is normally at a much higher frequency than the sample clock. The relative frequencies in
this example have been chosen for clarity.
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PIC16LF1824T39A
5.6
Oscillator Control Registers
REGISTER 5-1:
R/W-0/0
OSCCON: OSCILLATOR CONTROL REGISTER
R/W-0/0
R/W-1/1
SPLLEN
R/W-1/1
IRCF
R/W-1/1
U-0
R/W-0/0
—
R/W-0/0
SCS
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
SPLLEN: Software PLL Enable bit
If PLLEN in Configuration Word 1 = 1:
SPLLEN bit is ignored. 4xPLL is always enabled (subject to oscillator requirements)
If PLLEN in Configuration Word 1 = 0:
1 = 4xPLL Is enabled
0 = 4xPLL is disabled
bit 6-3
IRCF: Internal Oscillator Frequency Select bits
000x = 31 kHz LF
0010 = 31.25 kHz MF
0011 = 31.25 kHz HF(1)
0100 = 62.5 kHz MF
0101 = 125 kHz MF
0110 = 250 kHz MF
0111 = 500 kHz MF (default upon Reset)
1000 = 125 kHz HF(1)
1001 = 250 kHz HF(1)
1010 = 500 kHz HF(1)
1011 = 1 MHz HF
1100 = 2 MHz HF
1101 = 4 MHz HF
1110 = 8 MHz or 32 MHz HF(see Section 5.2.2.1 “HFINTOSC”)
1111 = 16 MHz HF
bit 2
Unimplemented: Read as ‘0’
bit 1-0
SCS: System Clock Select bits
1x = Internal oscillator block
01 = Timer1 oscillator
00 = Clock determined by FOSC in Configuration Word 1.
Note 1:
Duplicate frequency derived from HFINTOSC.
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REGISTER 5-2:
OSCSTAT: OSCILLATOR STATUS REGISTER
R-1/q
R-0/q
R-q/q
R-0/q
R-0/q
R-q/q
R-0/0
R-0/q
T1OSCR
PLLR
OSTS
HFIOFR
HFIOFL
MFIOFR
LFIOFR
HFIOFS
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
q = Conditional
bit 7
T1OSCR: Timer1 Oscillator Ready bit
If T1OSCEN = 1:
1 = Timer1 oscillator is ready
0 = Timer1 oscillator is not ready
If T1OSCEN = 0:
1 = Timer1 clock source is always ready
bit 6
PLLR 4xPLL Ready bit
1 = 4xPLL is ready
0 = 4xPLL is not ready
bit 5
OSTS: Oscillator Start-up Timer Status bit
1 = Running from the clock defined by the FOSC bits of the Configuration Word 1
0 = Running from an internal oscillator (FOSC = 100)
bit 4
HFIOFR: High-Frequency Internal Oscillator Ready bit
1 = HFINTOSC is ready
0 = HFINTOSC is not ready
bit 3
HFIOFL: High-Frequency Internal Oscillator Locked bit
1 = HFINTOSC is at least 2% accurate
0 = HFINTOSC is not 2% accurate
bit 2
MFIOFR: Medium-Frequency Internal Oscillator Ready bit
1 = MFINTOSC is ready
0 = MFINTOSC is not ready
bit 1
LFIOFR: Low-Frequency Internal Oscillator Ready bit
1 = LFINTOSC is ready
0 = LFINTOSC is not ready
bit 0
HFIOFS: High-Frequency Internal Oscillator Stable bit
1 = HFINTOSC is at least 0.5% accurate
0 = HFINTOSC is not 0.5% accurate
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PIC16LF1824T39A
REGISTER 5-3:
OSCTUNE: OSCILLATOR TUNING REGISTER
U-0
U-0
—
—
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
TUN
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
TUN: Frequency Tuning bits
011111 = Maximum frequency
011110 =
•
•
•
000001 =
000000 = Oscillator module is running at the factory-calibrated frequency.
111111 =
•
•
•
100000 = Minimum frequency
TABLE 5-2:
SUMMARY OF REGISTERS ASSOCIATED WITH CLOCK SOURCES
Name
Bit 7
OSCCON
SPLLEN
OSCSTAT
T1OSCR
Bit 6
Bit 5
PLLR
OSTS
Bit 4
Bit 3
Bit 2
HFIOFR
HFIOFL
MFIOFR
BCL1IE
IRCF
—
—
—
PIE2
OSFIE
C2IE
C1IE
EEIE
PIR2
OSFIF
C2IF
C1IF
EEIF
OSCTUNE
Legend:
CONFIG1
Legend:
SCS
T1CKPS
Register
on Page
63
LFIOFR
HFIOFS
64
—
—
CCP2IE
86
BCL1IF
—
—
CCP2IF
89
T1OSCEN
T1SYNC
—
TMR1ON
175
65
— = unimplemented location, read as ‘0’. Shaded cells are not used by clock sources.
TABLE 5-3:
Name
Bit 0
TUN
TMR1CS
T1CON
Bit 1
Bits
SUMMARY OF CONFIGURATION WORD WITH CLOCK SOURCES
Bit -/7
Bit -/6
Bit 13/5
Bit 12/4
Bit 11/3
IESO
CLKOUTEN
13:8
—
—
FCMEN
7:0
CP
MCLRE
PWRTE
Bit 10/2
Bit 9/1
BOREN
WDTE
FOSC
Bit 8/0
CPD
Register
on Page
43
— = unimplemented location, read as ‘0’. Shaded cells are not used by clock sources.
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PIC16LF1824T39A
6.0
REFERENCE CLOCK MODULE
6.3
Conflicts with the CLKR pin
The reference clock module provides the ability to send
a divided clock to the clock output pin of the device
(CLKR) and provide a secondary internal clock source
to the modulator module. This module is available in all
oscillator configurations and allows the user to select a
greater range of clock submultiples to drive external
devices in the application. The reference clock module
includes the following features:
There are two cases when the reference clock output
signal cannot be output to the CLKR pin, if:
•
•
•
•
•
•
6.3.1
System clock is the source
Available in all oscillator configurations
Programmable clock divider
Output enable to a port pin
Selectable duty cycle
Slew rate control
The reference clock module is controlled by the
CLKRCON register (Register 6-1) and is enabled when
setting the CLKREN bit. To output the divided clock
signal to the CLKR port pin, the CLKROE bit must be
set. The CLKRDIV bits enable the selection of
eight
different
clock
divider
options. The
CLKRDC bits can be used to modify the duty
cycle of the output clock(1). The CLKRSLR bit controls
slew rate limiting.
Note 1: If the base clock rate is selected without
a divider, the output clock will always
have a duty cycle equal to that of the
source clock, unless a 0% duty cycle is
selected. If the clock divider is set to base
clock/2, then 25% and 75% duty cycle
accuracy will be dependent upon the
source clock.
• LP, XT, or HS oscillator mode is selected.
• CLKOUT function is enabled.
Even if either of these cases are true, the module can
still be enabled and the reference clock signal may be
used in conjunction with the modulator module.
OSCILLATOR MODES
If LP, XT, or HS oscillator modes are selected, the
OSC2/CLKR pin must be used as an oscillator input pin
and the CLKR output cannot be enabled. See
Section 5.2 “Clock Source Types” for more information on different oscillator modes.
6.3.2
CLKOUT FUNCTION
The CLKOUT function has a higher priority than the
reference clock module. Therefore, if the CLKOUT
function is enabled by the CLKOUTEN bit in Configuration Word 1, FOSC/4 will always be output on the port
pin. Reference Section 4.0 “Device Configuration”
for more information.
6.4
Operation During Sleep
As the reference clock module relies on the system
clock as its source, and the system clock is disabled in
Sleep, the module does not function in Sleep, even if
an external clock source or the Timer1 clock source is
configured as the system clock. The module outputs
will remain in their current state until the device exits
Sleep.
For information on using the reference clock output
with the modulator module, see Section 23.0 “Data
Signal Modulator”.
6.1
Slew Rate
The slew rate limitation on the output port pin can be
disabled. The slew rate limitation can be removed by
clearing the CLKRSLR bit in the CLKRCON register.
6.2
Effects of a Reset
Upon any device Reset, the reference clock module is
disabled. The user’s firmware is responsible for
initializing the module before enabling the output. The
registers are reset to their default values.
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REGISTER 6-1:
CLKRCON: REFERENCE CLOCK CONTROL REGISTER
R/W-0/0
R/W-0/0
R/W-1/1
CLKREN
CLKROE
CLKRSLR
R/W-1/1
R/W-0/0
R/W-0/0
CLKRDC
R/W-0/0
R/W-0/0
CLKRDIV
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
CLKREN: Reference Clock Module Enable bit
1 = Reference Clock module is enabled
0 = Reference Clock module is disabled
bit 6
CLKROE: Reference Clock Output Enable bit(3)
1 = Reference Clock output is enabled on CLKR pin
0 = Reference Clock output disabled on CLKR pin
bit 5
CLKRSLR: Reference Clock Slew Rate Control Limiting Enable bit
1 = Slew Rate limiting is enabled
0 = Slew Rate limiting is disabled
bit 4-3
CLKRDC: Reference Clock Duty Cycle bits
11 = Clock outputs duty cycle of 75%
10 = Clock outputs duty cycle of 50%
01 = Clock outputs duty cycle of 25%
00 = Clock outputs duty cycle of 0%
bit 2-0
CLKRDIV Reference Clock Divider bits
111 = Base clock value divided by 128
110 = Base clock value divided by 64
101 = Base clock value divided by 32
100 = Base clock value divided by 16
011 = Base clock value divided by 8
010 = Base clock value divided by 4
001 = Base clock value divided by 2(1)
000 = Base clock value(2)
Note 1: In this mode, the 25% and 75% duty cycle accuracy will be dependent on the source clock duty cycle.
2: In this mode, the duty cycle will always be equal to the source clock duty cycle, unless a duty cycle of 0%
is selected.
3: To route CLKR to pin, CLKOUTEN of Configuration Word 1 = 1 is required. CLKOUTEN of Configuration
Word 1 = 0 will result in FOSC/4. See Section 6.3 “Conflicts with the CLKR pin” for details.
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TABLE 6-1:
SUMMARY OF REGISTERS ASSOCIATED WITH REFERENCE CLOCK SOURCES
Name
CLKRCON
Legend:
Bit 7
Bit 6
Bit 5
CLKREN
CLKROE
CLKRSLR
CONFIG1
Legend:
Bit 3
CLKRDC
Bit 2
Bit 1
Bit 0
CLKRDIV
Register
on Page
67
— = unimplemented locations, read as ‘0’. Shaded cells are not used by reference clock sources.
TABLE 6-2:
Name
Bit 4
Bits
SUMMARY OF CONFIGURATION WORD WITH REFERENCE CLOCK SOURCES
Bit -/7
Bit -/6
Bit 13/5
Bit 12/4
Bit 11/3
IESO
CLKOUTEN
13:8
—
—
FCMEN
7:0
CP
MCLRE
PWRTE
WDTE
Bit 10/2
Bit 9/1
BOREN
FOSC
Bit 8/0
CPD
Register
on Page
43
— = unimplemented locations, read as ‘0’. Shaded cells are not used by reference clock sources.
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7.0
RESETS
There are multiple ways to reset this device:
•
•
•
•
•
•
•
•
Power-on Reset (POR)
Brown-out Reset (BOR)
MCLR Reset
WDT Reset
RESET instruction
Stack Overflow
Stack Underflow
Programming mode exit
To allow VDD to stabilize, an optional Power-up Timer
can be enabled to extend the Reset time after a BOR
or POR event.
A simplified block diagram of the On-Chip Reset Circuit
is shown in Figure 7-1.
FIGURE 7-1:
SIMPLIFIED BLOCK DIAGRAM OF ON-CHIP RESET CIRCUIT
Programming Mode Exit
RESET Instruction
Stack Stack Overflow/Underflow Reset
Pointer
External Reset
MCLRE
MCLR
Sleep
WDT
Time-out
Device
Reset
Power-on
Reset
VDD
Brown-out
Reset
BOR
Enable
PWRT
Zero
LFINTOSC
64 ms
PWRTEN
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7.1
Power-on Reset (POR)
7.2
Brown-Out Reset (BOR)
The POR circuit holds the device in Reset until VDD has
reached an acceptable level for minimum operation.
Slow rising VDD, fast operating speeds or analog
performance may require greater than minimum VDD.
The PWRT, BOR or MCLR features can be used to
extend the start-up period until all device operation
conditions have been met.
The BOR circuit holds the device in Reset when VDD
reaches a selectable minimum level. Between the
POR and BOR, complete voltage range coverage for
execution protection can be implemented.
7.1.1
•
•
•
•
POWER-UP TIMER (PWRT)
The Power-up Timer provides a nominal 64 ms timeout on POR or Brown-out Reset.
The device is held in Reset as long as PWRT is active.
The PWRT delay allows additional time for the VDD to
rise to an acceptable level. The Power-up Timer is
enabled by clearing the PWRTE bit in Configuration
Word 1.
The Power-up Timer starts after the release of the POR
and BOR.
For additional information, refer to Application Note
AN607, “Power-up Trouble Shooting” (DS00607).
TABLE 7-1:
The Brown-out Reset module has four operating
modes controlled by the BOREN bits in Configuration Word 1. The four operating modes are:
BOR is always on
BOR is off when in Sleep
BOR is controlled by software
BOR is always off
Refer to Table 7-3 for more information.
The Brown-out Reset voltage level is selectable by
configuring the BORV bit in Configuration Word 2.
A VDD noise rejection filter prevents the BOR from
triggering on small events. If VDD falls below VBOR for
a duration greater than parameter TBORDC, the device
will reset. See Figure 7-3 for more information.
BOR OPERATING MODES
SBOREN
Device Mode
BOR Mode
Device
Device
Operation upon
Operation upon
wake-up from
release of POR
Sleep
BOR_ON (11)
X
X
Active
Waits for BOR ready(1)
BOR_NSLEEP (10)
X
Awake
Active
BOR_NSLEEP (10)
X
Sleep
Disabled
BOR_SBOREN (01)
1
X
Active
Begins immediately
BOR_SBOREN (01)
0
X
Disabled
Begins immediately
BOR_OFF (00)
X
X
Disabled
Begins immediately
BOREN
Config bits
Waits for BOR ready
Note 1: In these specific cases, “Release of POR” and the “Wake-up from Sleep”, there is no delay in start-up. The
BOR Ready flag (BORRDY = 1) will be set before the CPU is ready to execute instructions because the
BOR circuit is forced on by the BOREN bits.
7.2.1
BOR IS ALWAYS ON
When the BOREN bits of Configuration Word 1 are set
to ‘11’, the BOR is always on. The device start-up will
be delayed until the BOR is ready and VDD is higher
than the BOR threshold.
BOR protection is active during Sleep. The BOR does
not delay wake-up from Sleep.
7.2.2
BOR IS OFF IN SLEEP
When the BOREN bits of Configuration Word 1 are set
to ‘10’, the BOR is on, except in Sleep. The device
start-up will be delayed until the BOR is ready and VDD
is higher than the BOR threshold.
DS40001657C-page 70
BOR protection is not active during Sleep. The device
wake-up will be delayed until the BOR is ready.
7.2.3
BOR CONTROLLED BY SOFTWARE
When the BOREN bits of Configuration Word 1 are set
to ‘01’, the BOR is controlled by the SBOREN bit of the
BORCON register. The device start-up is not delayed
by the BOR ready condition or the VDD level.
BOR protection begins as soon as the BOR circuit is
ready. The status of the BOR circuit is reflected in the
BORRDY bit of the BORCON register.
BOR protection is unchanged by Sleep.
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FIGURE 7-2:
BROWN-OUT READY
SBOREN
TBORRDY
BORRDY
FIGURE 7-3:
BOR Protection Active
BROWN-OUT SITUATIONS
VDD
Internal
Reset
VBOR
TPWRT(1)
VDD
Internal
Reset
VBOR
< TPWRT
TPWRT(1)
VDD
Internal
Reset
Note 1:
VBOR
TPWRT(1)
TPWRT delay only if PWRTE bit is programmed to ‘0’.
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REGISTER 7-1:
BORCON: BROWN-OUT RESET CONTROL REGISTER
R/W-1/u
U-0
U-0
U-0
U-0
U-0
U-0
R-q/u
SBOREN
—
—
—
—
—
—
BORRDY
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
q = Value depends on condition
bit 7
SBOREN: Software Brown-out Reset Enable bit
If BOREN in Configuration Word 1 01:
SBOREN is read/write, but has no effect on the BOR.
If BOREN in Configuration Word 1 = 01:
1 = BOR Enabled
0 = BOR Disabled
bit 6-1
Unimplemented: Read as ‘0’
bit 0
BORRDY: Brown-out Reset Circuit Ready Status bit
1 = The Brown-out Reset circuit is active
0 = The Brown-out Reset circuit is inactive
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7.3
MCLR
7.7
The MCLR is an optional external input that can reset
the device. The MCLR function is controlled by the
MCLRE bit of Configuration Word 1 and the LVP bit of
Configuration Word 2 (Table 7-2).
TABLE 7-2:
MCLR CONFIGURATION
MCLRE
LVP
MCLR
0
0
Disabled
1
0
Enabled
x
1
Enabled
7.3.1
MCLR ENABLED
When MCLR is enabled and the pin is held low, the
device is held in Reset. The MCLR pin is connected to
VDD through an internal weak pull-up.
The device has a noise filter in the MCLR Reset path.
The filter will detect and ignore small pulses.
Note:
7.3.2
A Reset does not drive the MCLR pin low.
MCLR DISABLED
When MCLR is disabled, the pin functions as a general
purpose input and the internal weak pull-up is under
software control. See Section 12.2 “PORTA Registers”
for more information.
7.4
Watchdog Timer (WDT) Reset
The Watchdog Timer generates a Reset if the firmware
does not issue a CLRWDT instruction within the time-out
period. The TO and PD bits in the STATUS register are
changed to indicate the WDT Reset. See Section 10.0
“Watchdog Timer” for more information.
7.5
Programming Mode Exit
Upon exit of Programming mode, the device will
behave as if a POR had just occurred.
7.8
Power-up Timer
The Power-up Timer optionally delays device execution
after a BOR or POR event. This timer is typically used to
allow VDD to stabilize before allowing the device to start
running.
The Power-up Timer is controlled by the PWRTE bit of
Configuration Word 1.
7.9
Start-up Sequence
Upon the release of a POR or BOR, the following must
occur before the device will begin executing:
1.
2.
3.
Power-up Timer runs to completion (if enabled).
Oscillator start-up timer runs to completion (if
required for oscillator source).
MCLR must be released (if enabled).
The total time-out will vary based on oscillator configuration and Power-up Timer configuration. See
Section 5.0 “Oscillator Module (With Fail-Safe
Clock Monitor)” for more information.
The Power-up Timer and oscillator start-up timer run
independently of MCLR Reset. If MCLR is kept low long
enough, the Power-up Timer and oscillator start-up
timer will expire. Upon bringing MCLR high, the device
will begin execution immediately (see Figure 7-4). This
is useful for testing purposes or to synchronize more
than one device operating in parallel.
RESET Instruction
A RESET instruction will cause a device Reset. The RI
bit in the PCON register will be set to ‘0’. See Table 7-4
for default conditions after a RESET instruction has
occurred.
7.6
Stack Overflow/Underflow Reset
The device can reset when the Stack Overflows or
Underflows. The STKOVF or STKUNF bits of the PCON
register indicate the Reset condition. These Resets are
enabled by setting the STVREN bit in Configuration
Word 2. See Section 3.4.2 “Overflow/Underflow
Reset” for more information.
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FIGURE 7-4:
RESET START-UP SEQUENCE
VDD
Internal POR
TPWRT
Power-Up Timer
MCLR
TMCLR
Internal RESET
Oscillator Modes
External Crystal
TOST
Oscillator Start-Up Timer
Oscillator
FOSC
Internal Oscillator
Oscillator
FOSC
External Clock (EC)
CLKIN
FOSC
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7.10
Determining the Cause of a Reset
Upon any Reset, multiple bits in the STATUS and
PCON register are updated to indicate the cause of the
Reset. Table 7-3 and Table 7-4 show the Reset
conditions of these registers.
TABLE 7-3:
RESET STATUS BITS AND THEIR SIGNIFICANCE
STKOVF STKUNF
RMCLR
RI
POR
BOR
TO
PD
Condition
0
0
1
1
0
x
1
1
Power-on Reset
0
0
1
1
0
x
0
x
Illegal, TO is set on POR
0
0
1
1
0
x
x
0
Illegal, PD is set on POR
0
0
1
1
u
0
1
1
Brown-out Reset
u
u
u
u
u
u
0
u
WDT Reset
u
u
u
u
u
u
0
0
WDT Wake-up from Sleep
u
u
u
u
u
u
1
0
Interrupt Wake-up from Sleep
u
u
0
u
u
u
u
u
MCLR Reset during normal operation
u
u
0
u
u
u
1
0
MCLR Reset during Sleep
u
u
u
0
u
u
u
u
RESET Instruction Executed
1
u
u
u
u
u
u
u
Stack Overflow Reset (STVREN = 1)
u
1
u
u
u
u
u
u
Stack Underflow Reset (STVREN = 1)
TABLE 7-4:
RESET CONDITION FOR SPECIAL REGISTERS(2)
Program
Counter
STATUS
Register
PCON
Register
Power-on Reset
0000h
---1 1000
00-- 110x
MCLR Reset during normal operation
0000h
---u uuuu
uu-- 0uuu
MCLR Reset during Sleep
0000h
---1 0uuu
uu-- 0uuu
WDT Reset
0000h
---0 uuuu
uu-- uuuu
WDT Wake-up from Sleep
PC + 1
---0 0uuu
uu-- uuuu
Brown-out Reset
0000h
---1 1uuu
00-- 11u0
---1 0uuu
uu-- uuuu
Condition
Interrupt Wake-up from Sleep
PC + 1
(1)
RESET Instruction Executed
0000h
---u uuuu
uu-- u0uu
Stack Overflow Reset (STVREN = 1)
0000h
---u uuuu
1u-- uuuu
Stack Underflow Reset (STVREN = 1)
0000h
---u uuuu
u1-- uuuu
Legend: u = unchanged, x = unknown, - = unimplemented bit, reads as ‘0’.
Note 1: When the wake-up is due to an interrupt and Global Interrupt Enable bit (GIE) is set, the return address is
pushed on the stack and PC is loaded with the interrupt vector (0004h) after execution of PC + 1.
2: If a Status bit is not implemented, that bit will be read as ‘0’.
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7.11
Power Control (PCON) Register
The Power Control (PCON) register contains flag bits
to differentiate between a:
•
•
•
•
•
•
Power-on Reset (POR)
Brown-out Reset (BOR)
Reset Instruction Reset (RI)
Stack Overflow Reset (STKOVF)
Stack Underflow Reset (STKUNF)
MCLR Reset (RMCLR)
The PCON register bits are shown in Register 7-2.
REGISTER 7-2:
PCON: POWER CONTROL REGISTER
R/W/HS-0/q
R/W/HS-0/q
U-0
U-0
R/W/HC-1/q
R/W/HC-1/q
R/W/HC-q/u
R/W/HC-q/u
STKOVF
STKUNF
—
—
RMCLR
RI
POR
BOR
bit 7
bit 0
Legend:
HC = Bit is cleared by hardware
HS = Bit is set by hardware
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-m/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
q = Value depends on condition
bit 7
STKOVF: Stack Overflow Flag bit
1 = A Stack Overflow occurred
0 = A Stack Overflow has not occurred or set to ‘0’ by firmware
bit 6
STKUNF: Stack Underflow Flag bit
1 = A Stack Underflow occurred
0 = A Stack Underflow has not occurred or set to ‘0’ by firmware
bit 5-4
Unimplemented: Read as ‘0’
bit 3
RMCLR: MCLR Reset Flag bit
1 = A MCLR Reset has not occurred or set to ‘1’ by firmware
0 = A MCLR Reset has occurred (set to ‘0’ in hardware when a MCLR Reset occurs)
bit 2
RI: RESET Instruction Flag bit
1 = A RESET instruction has not been executed or set to ‘1’ by firmware
0 = A RESET instruction has been executed (set to ‘0’ in hardware upon executing a RESET instruction)
bit 1
POR: Power-on Reset Status bit
1 = No Power-on Reset occurred
0 = A Power-on Reset occurred (must be set in software after a Power-on Reset occurs)
bit 0
BOR: Brown-out Reset Status bit
1 = No Brown-out Reset occurred
0 = A Brown-out Reset occurred (must be set in software after a Power-on Reset or Brown-out Reset
occurs)
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TABLE 7-5:
SUMMARY OF REGISTERS ASSOCIATED WITH RESETS
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
BORCON
SBOREN
—
—
—
—
—
—
BORRDY
72
PCON
STKOVF
STKUNF
—
—
RMCLR
RI
POR
BOR
76
STATUS
—
—
—
TO
PD
Z
DC
C
17
WDTCON
—
—
SWDTEN
96
WDTPS
Legend: — = unimplemented bit, reads as ‘0’. Shaded cells are not used by Resets.
Note 1: Other (non Power-up) Resets include MCLR Reset and Watchdog Timer Reset during normal operation.
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8.0
INTERRUPTS
The interrupt feature allows certain events to preempt
normal program flow. Firmware is used to determine
the source of the interrupt and act accordingly. Some
interrupts can be configured to wake the MCU from
Sleep mode.
This chapter contains the following information for
Interrupts:
•
•
•
•
•
Operation
Interrupt Latency
Interrupts during Sleep
INT Pin
Automatic Context Saving
Many peripherals produce interrupts. Refer to the
corresponding chapters for details.
A block diagram of the interrupt logic is shown in
Figure 8-1 and Figure 8-2.
FIGURE 8-1:
INTERRUPT LOGIC
Wake-up (If in Sleep mode)
TMR0IF
TMR0IE
INTF
Interrupt to CPU
INTE
IOCIF
IOCIE
From Peripheral Interrupt
Logic (Figure 8-2)
PEIE
GIE
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FIGURE 8-2:
PERIPHERAL INTERRUPT LOGIC
TMR1GIF
TMR1GIE
ADIF
ADIE
RCIF
RCIE
TXIF
TXIE
SSPIF
SSPIE
CCP1IF
CCP1IE
TMR1IF
TMR1IE
To Interrupt Logic
(Figure 8-1)
TMR6IF
TMR6IE
EEIF
EEIE
OSFIF
OSFIE
C1IF
C1IE
C2IF
C2IE
BCL1IF
BCL1IE
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8.1
Operation
Interrupts are disabled upon any device Reset. They
are enabled by setting the following bits:
• GIE bit of the INTCON register
• Interrupt Enable bit(s) for the specific interrupt
event(s)
• PEIE bit of the INTCON register (if the Interrupt
Enable bit of the interrupt event is contained in the
PIEx register)
8.2
Interrupt Latency
Interrupt latency is defined as the time from when the
interrupt event occurs to the time code execution at the
interrupt vector begins. The latency for synchronous
interrupts is three or four instruction cycles. For
asynchronous interrupts, the latency is three to five
instruction cycles, depending on when the interrupt
occurs. See Figure 8-3 and Figure 8-4 for more details.
The INTCON, PIR1, PIR2 and PIR3 registers record
individual interrupts via interrupt flag bits. Interrupt flag
bits will be set, regardless of the status of the GIE, PEIE
and individual interrupt enable bits.
The following events happen when an interrupt event
occurs while the GIE bit is set:
• Current prefetched instruction is flushed
• GIE bit is cleared
• Current Program Counter (PC) is pushed onto the
stack
• Critical registers are automatically saved to the
Shadow registers (See Section 8.5 “Automatic
Context Saving”)
• PC is loaded with the interrupt vector 0004h
The firmware within the Interrupt Service Routine (ISR)
should determine the source of the interrupt by polling
the interrupt flag bits. The interrupt flag bits must be
cleared before exiting the ISR to avoid repeated
interrupts. Because the GIE bit is cleared, any interrupt
that occurs while executing the ISR will be recorded
through its interrupt flag, but will not cause the
processor to redirect to the interrupt vector.
The RETFIE instruction exits the ISR by popping the
previous address from the stack, restoring the saved
context from the Shadow registers and setting the GIE
bit.
For additional information on a specific interrupt’s
operation, refer to its peripheral chapter.
Note 1: Individual interrupt flag bits are set,
regardless of the state of any other
enable bits.
2: All interrupts will be ignored while the GIE
bit is cleared. Any interrupt occurring
while the GIE bit is clear will be serviced
when the GIE bit is set again.
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FIGURE 8-3:
INTERRUPT LATENCY
OSC1
Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4
CLKOUT
Interrupt Sampled
during Q1
Interrupt
GIE
PC
Execute
PC-1
PC
1 Cycle Instruction at PC
PC+1
0004h
0005h
NOP
NOP
Inst(0004h)
PC+1/FSR
ADDR
New PC/
PC+1
0004h
0005h
Inst(PC)
NOP
NOP
Inst(0004h)
FSR ADDR
PC+1
PC+2
0004h
0005h
INST(PC)
NOP
NOP
NOP
Inst(0004h)
Inst(0005h)
FSR ADDR
PC+1
0004h
0005h
INST(PC)
NOP
NOP
Inst(0004h)
Inst(PC)
Interrupt
GIE
PC
Execute
PC-1
PC
2 Cycle Instruction at PC
Interrupt
GIE
PC
Execute
PC-1
PC
3 Cycle Instruction at PC
Interrupt
GIE
PC
Execute
PC-1
PC
3 Cycle Instruction at PC
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PC+2
NOP
NOP
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FIGURE 8-4:
INT PIN INTERRUPT TIMING
Q1
Q2
Q3
Q4
Q1
Q2
Q3
Q4
Q1
Q2
Q3
Q4
Q1
Q2
Q3
Q4
Q1
Q2
Q3
Q4
OSC1
CLKOUT (3)
(4)
INT pin
(1)
(1)
INTF
(5)
Interrupt Latency
(2)
GIE
INSTRUCTION FLOW
PC
Instruction
Fetched
Instruction
Executed
Note 1:
PC
Inst (PC)
Inst (PC – 1)
PC + 1
Inst (PC + 1)
Inst (PC)
PC + 1
—
Dummy Cycle
0004h
0005h
Inst (0004h)
Inst (0005h)
Dummy Cycle
Inst (0004h)
INTF flag is sampled here (every Q1).
2:
Asynchronous interrupt latency = 3-5 TCY. Synchronous latency = 3-4 TCY, where TCY = instruction cycle time.
Latency is the same whether Inst (PC) is a single cycle or a 2-cycle instruction.
3:
CLKOUT is not available in all oscillator modes.
4:
For minimum width of INT pulse, refer to the AC specifications in Section 31.0 “Electrical Specifications”.
5:
INTF is enabled to be set any time during the Q4-Q1 cycles.
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8.3
Interrupts During Sleep
Some interrupts can be used to wake from Sleep. To
wake from Sleep, the peripheral must be able to
operate without the system clock. The interrupt source
must have the appropriate Interrupt Enable bit(s) set
prior to entering Sleep.
On waking from Sleep, if the GIE bit is also set, the
processor will branch to the interrupt vector. Otherwise,
the processor will continue executing instructions after
the SLEEP instruction. The instruction directly after the
SLEEP instruction will always be executed before
branching to the ISR. Refer to the Section 9.0 “PowerDown Mode (Sleep)” for more details.
8.4
INT Pin
The INT pin can be used to generate an asynchronous
edge-triggered interrupt. This interrupt is enabled by
setting the INTE bit of the INTCON register. The
INTEDG bit of the OPTION_REG register determines on
which edge the interrupt will occur. When the INTEDG
bit is set, the rising edge will cause the interrupt. When
the INTEDG bit is clear, the falling edge will cause the
interrupt. The INTF bit of the INTCON register will be set
when a valid edge appears on the INT pin. If the GIE and
INTE bits are also set, the processor will redirect
program execution to the interrupt vector.
8.5
Automatic Context Saving
Upon entering an interrupt, the return PC address is
saved on the stack. Additionally, the following registers
are automatically saved in the Shadow registers:
•
•
•
•
•
W register
STATUS register (except for TO and PD)
BSR register
FSR registers
PCLATH register
Upon exiting the Interrupt Service Routine, these registers are automatically restored. Any modifications to
these registers during the ISR will be lost. If modifications to any of these registers are desired, the corresponding Shadow register should be modified and the
value will be restored when exiting the ISR. The
Shadow registers are available in Bank 31 and are
readable and writable. Depending on the user’s application, other registers may also need to be saved.
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PIC16LF1824T39A
8.5.1
INTCON REGISTER
Note:
The INTCON register is a readable and writable
register, which contains the various enable and flag bits
for TMR0 register overflow, interrupt-on-change and
external INT pin interrupts.
REGISTER 8-1:
Interrupt flag bits are set when an interrupt
condition occurs, regardless of the state of
its corresponding enable bit or the Global
Interrupt Enable bit, GIE, of the INTCON
register. User software should ensure the
appropriate interrupt flag bits are clear
prior to enabling an interrupt.
INTCON: INTERRUPT CONTROL REGISTER
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R-0/0
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF(1)
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
GIE: Global Interrupt Enable bit
1 = Enables all active interrupts
0 = Disables all interrupts
bit 6
PEIE: Peripheral Interrupt Enable bit
1 = Enables all active peripheral interrupts
0 = Disables all peripheral interrupts
bit 5
TMR0IE: Timer0 Overflow Interrupt Enable bit
1 = Enables the Timer0 interrupt
0 = Disables the Timer0 interrupt
bit 4
INTE: INT External Interrupt Enable bit
1 = Enables the INT external interrupt
0 = Disables the INT external interrupt
bit 3
IOCIE: Interrupt-on-Change Enable bit
1 = Enables the interrupt-on-change
0 = Disables the interrupt-on-change
bit 2
TMR0IF: Timer0 Overflow Interrupt Flag bit
1 = TMR0 register has overflowed
0 = TMR0 register did not overflow
bit 1
INTF: INT External Interrupt Flag bit
1 = The INT external interrupt occurred
0 = The INT external interrupt did not occur
bit 0
IOCIF: Interrupt-on-Change Interrupt Flag bit(1)
1 = When at least one of the interrupt-on-change pins changed state
0 = None of the interrupt-on-change pins have changed state
Note 1:
The IOCIF Flag bit is read-only and cleared when all the interrupt-on-change flags in the IOCxF register
have been cleared by software.
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PIC16LF1824T39A
8.5.2
PIE1 REGISTER
The PIE1 register contains the interrupt enable bits, as
shown in Register 8-2.
REGISTER 8-2:
Note:
Bit PEIE of the INTCON register must be
set to enable any peripheral interrupt.
PIE1: PERIPHERAL INTERRUPT ENABLE REGISTER 1
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
TMR1GIE: Timer1 Gate Interrupt Enable bit
1 = Enables the Timer1 Gate Acquisition interrupt
0 = Disables the Timer1 Gate Acquisition interrupt
bit 6
ADIE: A/D Converter (ADC) Interrupt Enable bit
1 = Enables the ADC interrupt
0 = Disables the ADC interrupt
bit 5
RCIE: USART Receive Interrupt Enable bit
1 = Enables the USART receive interrupt
0 = Disables the USART receive interrupt
bit 4
TXIE: USART Transmit Interrupt Enable bit
1 = Enables the USART transmit interrupt
0 = Disables the USART transmit interrupt
bit 3
SSP1IE: Synchronous Serial Port (MSSP) Interrupt Enable bit
1 = Enables the MSSP interrupt
0 = Disables the MSSP interrupt
bit 2
CCP1IE: CCP1 Interrupt Enable bit
1 = Enables the CCP1 interrupt
0 = Disables the CCP1 interrupt
bit 1
TMR2IE: TMR2 to PR2 Match Interrupt Enable bit
1 = Enables the Timer2 to PR2 match interrupt
0 = Disables the Timer2 to PR2 match interrupt
bit 0
TMR1IE: Timer1 Overflow Interrupt Enable bit
1 = Enables the Timer1 overflow interrupt
0 = Disables the Timer1 overflow interrupt
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PIC16LF1824T39A
8.5.3
PIE2 REGISTER
The PIE2 register contains the interrupt enable bits, as
shown in Register 8-3.
REGISTER 8-3:
Note:
Bit PEIE of the INTCON register must be
set to enable any peripheral interrupt.
PIE2: PERIPHERAL INTERRUPT ENABLE REGISTER 2
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
U-0
U-0
R/W-0/0
OSFIE
C2IE
C1IE
EEIE
BCL1IE
—
—
CCP2IE
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
OSFIE: Oscillator Fail Interrupt Enable bit
1 = Enables the Oscillator Fail interrupt
0 = Disables the Oscillator Fail interrupt
bit 6
C2IE: Comparator C2 Interrupt Enable bit
1 = Enables the Comparator C2 interrupt
0 = Disables the Comparator C2 interrupt
bit 5
C1IE: Comparator C1 Interrupt Enable bit
1 = Enables the Comparator C1 interrupt
0 = Disables the Comparator C1 interrupt
bit 4
EEIE: EEPROM Write Completion Interrupt Enable bit
1 = Enables the EEPROM Write Completion interrupt
0 = Disables the EEPROM Write Completion interrupt
bit 3
BCL1IE: MSSP Bus Collision Interrupt Enable bit
1 = Enables the MSSP Bus Collision Interrupt
0 = Disables the MSSP Bus Collision Interrupt
bit 2-1
Unimplemented: Read as ‘0’
bit 0
CCP2IE: CCP2 Interrupt Enable bit
1 = Enables the CCP2 Interrupt
0 = Disables the CCP2 Interrupt
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PIC16LF1824T39A
8.5.4
PIE3 REGISTER
The PIE3 register contains the interrupt enable bits, as
shown in Register 8-4.
REGISTER 8-4:
Note 1: Bit PEIE of the INTCON register must be
set to enable any peripheral interrupt.
PIE3: PERIPHERAL INTERRUPT ENABLE REGISTER 3
U-0
U-0
R/W-0/0
R/W-0/0
R/W-0/0
U-0
R/W-0/0
U-0
—
—
CCP4IE
CCP3IE
TMR6IE
—
TMR4IE
—
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5
CCP4IE: CCP4 Interrupt Enable bit
1 = Enables the CCP4 interrupt
0 = Disables the CCP4 interrupt
bit 4
CCP3IE: CCP3 Interrupt Enable bit
1 = Enables the CCP3 interrupt
0 = Disables the CCP3 interrupt
bit 3
TMR6IE: TMR6 to PR6 Match Interrupt Enable bit
1 = Enables the TMR6 to PR6 Match interrupt
0 = Disables the TMR6 to PR6 Match interrupt
bit 2
Unimplemented: Read as ‘0’
bit 1
TMR4IE: TMR4 to PR4 Match Interrupt Enable bit
1 = Enables the TMR4 to PR4 Match interrupt
0 = Disables the TMR4 to PR4 Match interrupt
bit 0
Unimplemented: Read as ‘0’
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8.5.5
PIR1 REGISTER
The PIR1 register contains the interrupt flag bits, as
shown in Register 8-5.
REGISTER 8-5:
Note:
Interrupt flag bits are set when an interrupt
condition occurs, regardless of the state of
its corresponding enable bit or the Global
Interrupt Enable bit, GIE, of the INTCON
register. User software should ensure the
appropriate interrupt flag bits are clear prior
to enabling an interrupt.
PIR1: PERIPHERAL INTERRUPT REQUEST REGISTER 1
R/W-0/0
R/W-0/0
R-0/0
R-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
TMR1GIF: Timer1 Gate Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 6
ADIF: A/D Converter Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 5
RCIF: USART Receive Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 4
TXIF: USART Transmit Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 3
SSP1IF: Synchronous Serial Port (MSSP) Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 2
CCP1IF: CCP1 Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 1
TMR2IF: Timer2 to PR2 Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 0
TMR1IF: Timer1 Overflow Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
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PIC16LF1824T39A
8.5.6
PIR2 REGISTER
The PIR2 register contains the interrupt flag bits, as
shown in Register 8-6.
REGISTER 8-6:
Note:
Interrupt flag bits are set when an interrupt
condition occurs, regardless of the state of
its corresponding enable bit or the Global
Interrupt Enable bit, GIE, of the INTCON
register. User software should ensure the
appropriate interrupt flag bits are clear prior
to enabling an interrupt.
PIR2: PERIPHERAL INTERRUPT REQUEST REGISTER 2
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
U-0
U-0
R/W-0/0
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
OSFIF: Oscillator Fail Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 6
C2IF: Comparator C2 Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 5
C1IF: Comparator C1 Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 4
EEIF: EEPROM Write Completion Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 3
BCL1IF: MSSP Bus Collision Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 2-1
Unimplemented: Read as ‘0’
bit 0
CCP2IF: CCP2 Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
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8.5.7
PIR3 REGISTER
The PIR3 register contains the interrupt flag bits, as
shown in Register 8-7.
REGISTER 8-7:
Note 1: Interrupt flag bits are set when an interrupt condition occurs, regardless of the
state of its corresponding enable bit or
the Global Interrupt Enable bit, GIE, of
the INTCON register. User software
should ensure the appropriate interrupt
flag bits are clear prior to enabling an
interrupt.
PIR3: PERIPHERAL INTERRUPT REQUEST REGISTER 3
U-0
U-0
R/W-0/0
R/W-0/0
R/W-0/0
U-0
R/W-0/0
U-0
—
—
CCP4IF
CCP3IF
TMR6IF
—
TMR4IF
—
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5
CCP4IF: CCP4 Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 4
CCP3IF: CCP3 Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 3
TMR6IF: TMR6 to PR6 Match Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 2
Unimplemented: Read as ‘0’
bit 1
TMR4IF: TMR4 to PR4 Match Interrupt Flag bit
1 = Interrupt is pending
0 = Interrupt is not pending
bit 0
Unimplemented: Read as ‘0’
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PIC16LF1824T39A
TABLE 8-1:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH INTERRUPTS
Bit 7
INTCON
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
WPUEN
INTEDG
TMR0CS
TMR0SE
PSA
PS2
PS1
PS0
165
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIE2
OSFIE
C2IE
C1IE
EEIE
BCL1IE
—
—
CCP2IE
86
OPTION_REG
PIE3
—
—
CCP4IE
CCP3IE
TMR6IE
—
TMR4IE
—
87
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
89
PIR3
—
—
CCP4IF
CCP3IF
TMR6IF
—
TMR4IF
—
90
Legend:
— = unimplemented locations, read as ‘0’. Shaded cells are not used by interrupts.
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PIC16LF1824T39A
9.0
POWER-DOWN MODE (SLEEP)
9.1
Wake-up from Sleep
The Power-Down mode is entered by executing a
SLEEP instruction.
The device can wake-up from Sleep through one of the
following events:
Upon entering Sleep mode, the following conditions
exist:
1.
2.
3.
4.
5.
6.
1.
WDT will be cleared but keeps running, if
enabled for operation during Sleep.
2. PD bit of the STATUS register is cleared.
3. TO bit of the STATUS register is set.
4. CPU clock is disabled.
5. 31 kHz LFINTOSC is unaffected and peripherals
that operate from it may continue operation in
Sleep.
6. Timer1 oscillator is unaffected and peripherals
that operate from it may continue operation in
Sleep.
7. ADC is unaffected, if the dedicated FRC clock is
selected.
8. Capacitive Sensing oscillator is unaffected.
9. I/O ports maintain the status they had before
SLEEP was executed (driving high, low or highimpedance).
10. Resets other than WDT are not affected by
Sleep mode.
Refer to individual chapters for more details on
peripheral operation during Sleep.
To minimize current consumption, the following conditions should be considered:
•
•
•
•
•
•
I/O pins should not be floating
External circuitry sinking current from I/O pins
Internal circuitry sourcing current from I/O pins
Current draw from pins with internal weak pull-ups
Modules using 31 kHz LFINTOSC
Modules using Timer1 oscillator
I/O pins that are high-impedance inputs should be
pulled to VDD or VSS externally to avoid switching
currents caused by floating inputs.
Examples of internal circuitry that might be sourcing
current include modules such as the DAC and FVR
modules. See Section 17.0 “Digital-to-Analog
Converter (DAC) Module” and Section 14.0 “Fixed
Voltage Reference (FVR)” for more information on
these modules.
DS40001657C-page 92
External Reset input on MCLR pin, if enabled
BOR Reset, if enabled
POR Reset
Watchdog Timer, if enabled
Any external interrupt
Interrupts by peripherals capable of running
during Sleep (see individual peripheral for more
information)
The first three events will cause a device Reset. The
last three events are considered a continuation of
program execution. To determine whether a device
Reset or wake-up event occurred, refer to
Section 7.10 “Determining the Cause of a Reset”.
When the SLEEP instruction is being executed, the next
instruction (PC + 1) is prefetched. For the device to
wake-up through an interrupt event, the corresponding
interrupt enable bit must be enabled. Wake-up will
occur regardless of the state of the GIE bit. If the GIE
bit is disabled, the device continues execution at the
instruction after the SLEEP instruction. If the GIE bit is
enabled, the device executes the instruction after the
SLEEP instruction, the device will call the Interrupt Service Routine. In cases where the execution of the
instruction following SLEEP is not desirable, the user
should have a NOP after the SLEEP instruction.
The WDT is cleared when the device wakes up from
Sleep, regardless of the source of wake-up.
9.1.1
WAKE-UP USING INTERRUPTS
When global interrupts are disabled (GIE cleared) and
any interrupt source has both its interrupt enable bit
and interrupt flag bit set, one of the following will occur:
• If the interrupt occurs before the execution of a
SLEEP instruction
- SLEEP instruction will execute as a NOP
- WDT and WDT prescaler will not be cleared
- TO bit of the STATUS register will not be set
- PD bit of the STATUS register will not be
cleared
• If the interrupt occurs during or after the
execution of a SLEEP instruction
- SLEEP instruction will be completely executed
- Device will immediately wake-up from Sleep
- WDT and WDT prescaler will be cleared
- TO bit of the STATUS register will be set
- PD bit of the STATUS register will be cleared
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PIC16LF1824T39A
Even if the flag bits were checked before executing a
SLEEP instruction, it may be possible for flag bits to
become set before the SLEEP instruction completes. To
determine whether a SLEEP instruction executed, test
the PD bit. If the PD bit is set, the SLEEP instruction
was executed as a NOP.
FIGURE 9-1:
WAKE-UP FROM SLEEP THROUGH INTERRUPT
Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1
Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4
OSC1(1)
TOST(3)
CLKOUT(2)
Interrupt Latency (4)
Interrupt flag
GIE bit
(INTCON reg.)
Processor in
Sleep
Instruction Flow
PC
PC
Instruction
Fetched
Instruction
Executed
Note
1:
2:
3:
4:
PC + 1
Inst(PC) = Sleep
Inst(PC - 1)
PC + 2
PC + 2
PC + 2
Inst(PC + 1)
Inst(PC + 2)
Sleep
Inst(PC + 1)
Dummy Cycle
0004h
0005h
Inst(0004h)
Inst(0005h)
Dummy Cycle
Inst(0004h)
XT, HS or LP Oscillator mode assumed.
CLKOUT is not available in XT, HS, or LP Oscillator modes, but shown here for timing reference.
TOST = 1024 TOSC (drawing not to scale). This delay applies only to XT, HS or LP Oscillator modes.
GIE = 1 assumed. In this case after wake-up, the processor calls the ISR at 0004h. If GIE = 0, execution will continue in-line.
TABLE 9-1:
SUMMARY OF REGISTERS ASSOCIATED WITH POWER-DOWN MODE
Name
Bit 7
Bit 6
Bit 5
INTCON
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register on
Page
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
IOCAF
—
—
IOCAF5
IOCAF4
IOCAF3
IOCAF2
IOCAF1
IOCAF0
128
IOCAN
—
—
IOCAN5
IOCAN4
IOCAN3
IOCAN2
IOCAN1
IOCAN0
128
—
—
IOCAP5
IOCAP4
IOCAP3
IOCAP2
IOCAP1
IOCAP0
127
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
IOCAP
PIE1
PIE2
OSFIE
C2IE
C1IE
EEIE
BCL1IE
—
—
CCP2IE
86
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
89
—
—
—
TO
PD
Z
DC
C
17
—
—
WDTPS4
WDTPS3
WDTPS2
WDTPS1
WDTPS0
SWDTEN
96
STATUS
WDTCON
Legend:
— = unimplemented, read as ‘0’. Shaded cells are not used in Power-Down mode.
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PIC16LF1824T39A
10.0
WATCHDOG TIMER
The Watchdog Timer is a system timer that generates
a Reset if the firmware does not issue a CLRWDT
instruction within the time-out period. The Watchdog
Timer is typically used to recover the system from
unexpected events.
The WDT has the following features:
• Independent clock source
• Multiple operating modes
- WDT is always on
- WDT is off when in Sleep
- WDT is controlled by software
- WDT is always off
• Configurable time-out period is from 1ms to 256
seconds (typical)
• Multiple Reset conditions
• Operation during Sleep
FIGURE 10-1:
WATCHDOG TIMER BLOCK DIAGRAM
WDTE = 01
SWDTEN
WDTE = 11
LFINTOSC
23-bit Programmable
Prescaler WDT
WDT Time-out
WDTE = 10
Sleep
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WDTPS
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10.1
Independent Clock Source
10.3
The WDT derives its time base from the 31 kHz
LFINTOSC internal oscillator.
10.2
WDT Operating Modes
The Watchdog Timer module has four operating modes
controlled by the WDTE bits in Configuration
Word 1. See Table 10-1.
10.2.1
WDT IS ALWAYS ON
When the WDTE bits of Configuration Word 1 are set to
‘11’, the WDT is always on.
WDT protection is active during Sleep.
10.2.2
WDT IS OFF IN SLEEP
When the WDTE bits of Configuration Word 1 are set to
‘10’, the WDT is on, except in Sleep.
WDT protection is not active during Sleep.
10.2.3
When the WDTE bits of Configuration Word 1 are set to
‘01’, the WDT is controlled by the SWDTEN bit of the
WDTCON register.
WDT protection is unchanged
Table 10-1 for more details.
TABLE 10-1:
by
Sleep. See
WDT OPERATING MODES
WDTE
Config bits
SWDTEN
Device
Mode
WDT
Mode
WDT_ON (11)
X
X
Active
WDT_NSLEEP (10)
X
Awake
Active
WDT_NSLEEP (10)
X
Sleep
Disabled
WDT_SWDTEN (01)
1
X
Active
WDT_SWDTEN (01)
0
X
Disabled
WDT_OFF (00)
X
X
Disabled
TABLE 10-2:
The WDTPS bits of the WDTCON register set the
time-out period from 1ms to 256 seconds. After a
Reset, the default time-out period is two seconds.
10.4
Clearing the WDT
The WDT is cleared when any of the following
conditions occur:
•
•
•
•
•
•
•
Any Reset
CLRWDT instruction is executed
Device enters Sleep
Device wakes up from Sleep
Oscillator fail event
WDT is disabled
OST is running
See Table 10-2 for more information.
10.5
WDT CONTROLLED BY SOFTWARE
Time-Out Period
Operation During Sleep
When the device enters Sleep, the WDT is cleared. If
the WDT is enabled during Sleep, the WDT resumes
counting.
When the device exits Sleep, the WDT is cleared
again. The WDT remains clear until the OST, if
enabled, completes. See Section 5.0 “Oscillator
Module (With Fail-Safe Clock Monitor)” for more
information on the OST.
When a WDT time-out occurs while the device is in
Sleep, no Reset is generated. Instead, the device
wakes up and resumes operation. The TO and PD bits
in the STATUS register are changed to indicate the
event. See Section 3.0 “Memory Organization” and
The STATUS register (Register 3-1) for more
information.
WDT CLEARING CONDITIONS
Conditions
WDT
WDTE = 00
WDTE = 01 and SWDTEN = 0
WDTE = 10 and enter Sleep
CLRWDT Command
Cleared
Oscillator Fail Detected
Exit Sleep + System Clock = T1OSC, EXTRC, INTOSC, EXTCLK
Exit Sleep + System Clock = XT, HS, LP
Change INTOSC divider (IRCF bits)
2012-2017 Microchip Technology Inc.
Cleared until the end of OST
Unaffected
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REGISTER 10-1:
WDTCON: WATCHDOG TIMER CONTROL REGISTER
U-0
U-0
R/W-0/0
R/W-1/1
R/W-0/0
R/W-1/1
R/W-1/1
R/W-0/0
—
—
WDTPS4
WDTPS3
WDTPS2
WDTPS1
WDTPS0
SWDTEN
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-m/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-1
WDTPS: Watchdog Timer Period Select bits
Bit Value = Prescale Rate
00000 = 1:32 (Interval 1 ms typ)
00001 = 1:64 (Interval 2 ms typ)
00010 = 1:128 (Interval 4 ms typ)
00011 = 1:256 (Interval 8 ms typ)
00100 = 1:512 (Interval 16 ms typ)
00101 = 1:1024 (Interval 32 ms typ)
00110 = 1:2048 (Interval 64 ms typ)
00111 = 1:4096 (Interval 128 ms typ)
01000 = 1:8192 (Interval 256 ms typ)
01001 = 1:16384 (Interval 512 ms typ)
01010 = 1:32768 (Interval 1s typ)
01011 = 1:65536 (Interval 2s typ) (Reset value)
01100 = 1:131072 (217) (Interval 4s typ)
01101 = 1:262144 (218) (Interval 8s typ)
01110 = 1:524288 (219) (Interval 16s typ)
01111 = 1:1048576 (220) (Interval 32s typ)
10000 = 1:2097152 (221) (Interval 64s typ)
10001 = 1:4194304 (222) (Interval 128s typ)
10010 = 1:8388608 (223) (Interval 256s typ)
10011 = Reserved. Results in minimum interval (1:32)
•
•
•
11111 = Reserved. Results in minimum interval (1:32)
bit 0
SWDTEN: Software Enable/Disable for Watchdog Timer bit
If WDTE = 00:
This bit is ignored.
If WDTE = 01:
1 = WDT is turned on
0 = WDT is turned off
If WDTE = 1x:
This bit is ignored.
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11.0
DATA EEPROM AND FLASH
PROGRAM MEMORY
CONTROL
The data EEPROM and Flash program memory are
readable and writable during normal operation (full VDD
range). These memories are not directly mapped in the
register file space. Instead, they are indirectly
addressed through the Special Function Registers
(SFRs). There are six SFRs used to access these
memories:
•
•
•
•
•
•
EECON1
EECON2
EEDATL
EEDATH
EEADRL
EEADRH
When interfacing the data memory block, EEDATL
holds the 8-bit data for read/write, and EEADRL holds
the address of the EEDATL location being accessed.
These devices have 256 bytes of data EEPROM with
an address range from 0h to 0FFh.
When accessing the program memory block, the
EEDATH:EEDATL register pair forms a 2-byte word
that holds the 14-bit data for read/write, and the
EEADRL and EEADRH registers form a 2-byte word
that holds the 15-bit address of the program memory
location being read.
The EEPROM data memory allows byte read and write.
An EEPROM byte write automatically erases the location and writes the new data (erase before write).
The write time is controlled by an on-chip timer. The
write/erase voltages are generated by an on-chip
charge pump rated to operate over the voltage range of
the device for byte or word operations.
Depending on the setting of the Flash Program
Memory Self Write Enable bits WRT of the
Configuration Word 2, the device may or may not be
able to write certain blocks of the program memory.
However, reads from the program memory are always
allowed.
11.1
EEADRL and EEADRH Registers
The EEADRH:EEADRL register pair can address up to
a maximum of 256 bytes of data EEPROM or up to a
maximum of 32K words of program memory.
When selecting a program address value, the MSB of
the address is written to the EEADRH register and the
LSB is written to the EEADRL register. When selecting
a EEPROM address value, only the LSB of the address
is written to the EEADRL register.
11.1.1
EECON1 AND EECON2 REGISTERS
EECON1 is the control register for EE memory
accesses.
Control bit EEPGD determines if the access will be a
program or data memory access. When clear, any
subsequent operations will operate on the EEPROM
memory. When set, any subsequent operations will
operate on the program memory. On Reset, EEPROM is
selected by default.
Control bits RD and WR initiate read and write,
respectively. These bits cannot be cleared, only set, in
software. They are cleared in hardware at completion
of the read or write operation. The inability to clear the
WR bit in software prevents the accidental, premature
termination of a write operation.
The WREN bit, when set, will allow a write operation to
occur. On power-up, the WREN bit is clear. The
WRERR bit is set when a write operation is interrupted
by a Reset during normal operation. In these situations,
following Reset, the user can check the WRERR bit
and execute the appropriate error handling routine.
Interrupt flag bit EEIF of the PIR2 register is set when
the write is complete. It must be cleared in the software.
Reading EECON2 will read all ‘0’s. The EECON2
register is used exclusively in the data EEPROM write
sequence. To enable writes, a specific pattern must be
written to EECON2.
When the device is code-protected, the device
programmer can no longer access data or program
memory. When code-protected, the CPU may continue
to read and write the data EEPROM memory and Flash
program memory.
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11.2
Using the Data EEPROM
The data EEPROM is a high-endurance, byte addressable array that has been optimized for the storage of
frequently changing information (e.g., program
variables or other data that are updated often). When
variables in one section change frequently, while variables in another section do not change, it is possible to
exceed the total number of write cycles to the
EEPROM without exceeding the total number of write
cycles to a single byte. Refer to Section 31.0 “Electrical Specifications”. If this is the case, then a refresh
of the array must be performed. For this reason,
variables that change infrequently (such as constants,
IDs, calibration, etc.) should be stored in Flash program
memory.
11.2.1
READING THE DATA EEPROM
MEMORY
To read a data memory location, the user must write the
address to the EEADRL register, clear the EEPGD and
CFGS control bits of the EECON1 register, and then
set control bit RD. The data is available at the very next
cycle, in the EEDATL register; therefore, it can be read
in the next instruction. EEDATL will hold this value until
another read or until it is written to by the user (during
a write operation).
EXAMPLE 11-1:
DATA EEPROM READ
BANKSEL EEADRL
;
MOVLW
DATA_EE_ADDR ;
MOVWF
EEADRL
;Data Memory
;Address to read
BCF
EECON1, CFGS ;Deselect Config space
BCF
EECON1, EEPGD;Point to DATA memory
BSF
EECON1, RD
;EE Read
MOVF
EEDATL, W
;W = EEDATL
Note:
Data EEPROM can be read regardless of
the setting of the CPD bit.
11.2.2
WRITING TO THE DATA EEPROM
MEMORY
To write an EEPROM data location, the user must first
write the address to the EEADRL register and the data
to the EEDATL register. Then the user must follow a
specific sequence to initiate the write for each byte.
The write will not initiate if the above sequence is not
followed exactly (write 55h to EECON2, write AAh to
EECON2, then set WR bit) for each byte. Interrupts
should be disabled during this code segment.
Additionally, the WREN bit in EECON1 must be set to
enable write. This mechanism prevents accidental
writes to data EEPROM due to errant (unexpected)
code execution (i.e., lost programs). The user should
keep the WREN bit clear at all times, except when
updating EEPROM. The WREN bit is not cleared
by hardware.
After a write sequence has been initiated, clearing the
WREN bit will not affect this write cycle. The WR bit will
be inhibited from being set unless the WREN bit is set.
At the completion of the write cycle, the WR bit is
cleared in hardware and the EE Write Complete
Interrupt Flag bit (EEIF) is set. The user can either
enable this interrupt or poll this bit. EEIF must be
cleared by software.
11.2.3
PROTECTION AGAINST SPURIOUS
WRITE
There are conditions when the user may not want to
write to the data EEPROM memory. To protect against
spurious EEPROM writes, various mechanisms have
been built-in. On power-up, WREN is cleared. Also, the
Power-up Timer (64 ms duration) prevents EEPROM
write.
The write initiate sequence and the WREN bit together
help prevent an accidental write during:
• Brown-out
• Power Glitch
• Software Malfunction
11.2.4
DATA EEPROM OPERATION
DURING CODE-PROTECT
Data memory can be code-protected by programming
the CPD bit in the Configuration Word 1 (Register 5-1)
to ‘0’.
When the data memory is code-protected, only the
CPU is able to read and write data to the data
EEPROM. It is recommended to code-protect the program memory when code-protecting data memory.
This prevents anyone from replacing your program with
a program that will access the contents of the data
EEPROM.
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Required
Sequence
EXAMPLE 11-2:
DATA EEPROM WRITE
BANKSEL
MOVLW
MOVWF
MOVLW
MOVWF
BCF
BCF
BSF
EEADRL
DATA_EE_ADDR
EEADRL
DATA_EE_DATA
EEDATL
EECON1, CFGS
EECON1, EEPGD
EECON1, WREN
;
;
;Data Memory Address to write
;
;Data Memory Value to write
;Deselect Configuration space
;Point to DATA memory
;Enable writes
BCF
MOVLW
MOVWF
MOVLW
MOVWF
BSF
BSF
BCF
BTFSC
GOTO
INTCON,
55h
EECON2
0AAh
EECON2
EECON1,
INTCON,
EECON1,
EECON1,
$-2
;Disable INTs.
;
;Write 55h
;
;Write AAh
;Set WR bit to begin write
;Enable Interrupts
;Disable writes
;Wait for write to complete
;Done
FIGURE 11-1:
GIE
WR
GIE
WREN
WR
FLASH PROGRAM MEMORY READ CYCLE EXECUTION
Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4
Flash ADDR
Flash Data
PC
PC + 1
INSTR (PC)
INSTR(PC - 1)
executed here
EEADRH,EEADRL
INSTR (PC + 1)
BSF EECON1,RD
executed here
PC
+3
PC+3
EEDATH,EEDATL
INSTR(PC + 1)
executed here
PC + 4
INSTR (PC + 3)
Forced NOP
executed here
PC + 5
INSTR (PC + 4)
INSTR(PC + 3)
executed here
INSTR(PC + 4)
executed here
RD bit
EEDATH
EEDATL
Register
EERHLT
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11.3
Flash Program Memory Overview
It is important to understand the Flash program
memory structure for erase and programming
operations. Flash program memory is arranged in
rows. A row consists of a fixed number of 14-bit
program memory words. A row is the minimum block
size that can be erased by user software.
Flash program memory may only be written or erased
if the destination address is in a segment of memory
that is not write-protected, as defined in bits WRT
of Configuration Word 2.
After a row has been erased, the user can reprogram
all or a portion of this row. Data to be written into the
program memory row is written to 14-bit wide data write
latches. These write latches are not directly accessible
to the user, but may be loaded via sequential writes to
the EEDATH:EEDATL register pair.
Note:
If the user wants to modify only a portion
of a previously programmed row, then the
contents of the entire row must be read
and saved in RAM prior to the erase.
The number of data write latches is not equivalent to
the number of row locations. During programming, user
software will need to fill the set of write latches and initiate a programming operation multiple times in order to
fully reprogram an erased row. For example, a device
with a row size of 32 words and eight write latches will
need to load the write latches with data and initiate a
programming operation four times.
11.3.1
READING THE FLASH PROGRAM
MEMORY
To read a program memory location, the user must:
1.
2.
3.
4.
Write the Least and Most Significant address
bits to the EEADRH:EEADRL register pair.
Clear the CFGS bit of the EECON1 register.
Set the EEPGD control bit of the EECON1
register.
Then, set control bit RD of the EECON1 register.
Once the read control bit is set, the program memory
Flash controller will use the second instruction cycle to
read the data. This causes the second instruction
immediately following the “BSF EECON1,RD” instruction
to be ignored. The data is available in the very next cycle,
in the EEDATH:EEDATL register pair; therefore, it can
be read as two bytes in the following instructions.
EEDATH:EEDATL register pair will hold this value until
another read or until it is written to by the user.
Note 1: The two instructions following a program
memory read are required to be NOPs.
This prevents the user from executing a
two-cycle instruction on the next
instruction after the RD bit is set.
2: Flash program memory can be read
regardless of the setting of the CP bit.
The size of a program memory row and the number of
program memory write latches may vary by device.
See Table 11-1 for details.
TABLE 11-1:
FLASH MEMORY
ORGANIZATION BY DEVICE
Erase Block
(Row) Size/
Boundary
Number of Write
Latches/
Boundary
32 words,
EEADRL =
00000
32 words,
EEADRL =
00000
Device
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EXAMPLE 11-3:
FLASH PROGRAM MEMORY READ
* This code block will read 1 word of program
* memory at the memory address:
PROG_ADDR_HI : PROG_ADDR_LO
*
data will be returned in the variables;
*
PROG_DATA_HI, PROG_DATA_LO
BANKSEL
MOVLW
MOVWF
MOVLW
MOVWL
EEADRL
PROG_ADDR_LO
EEADRL
PROG_ADDR_HI
EEADRH
; Select Bank for EEPROM registers
;
; Store LSB of address
;
; Store MSB of address
BCF
BSF
BCF
BSF
NOP
NOP
BSF
EECON1,CFGS
EECON1,EEPGD
INTCON,GIE
EECON1,RD
INTCON,GIE
;
;
;
;
;
;
;
Do not select Configuration Space
Select Program Memory
Disable interrupts
Initiate read
Executed (Figure 11-1)
Ignored (Figure 11-1)
Restore interrupts
MOVF
MOVWF
MOVF
MOVWF
EEDATL,W
PROG_DATA_LO
EEDATH,W
PROG_DATA_HI
;
;
;
;
Get LSB of word
Store in user location
Get MSB of word
Store in user location
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11.3.2
ERASING FLASH PROGRAM
MEMORY
While executing code, program memory can only be
erased by rows. To erase a row:
1.
2.
3.
4.
5.
6.
Load the EEADRH:EEADRL register pair with
the address of the new row to be erased.
Clear the CFGS bit of the EECON1 register.
Set the EEPGD, FREE and WREN bits of the
EECON1 register.
Write 55h, then AAh, to EECON2 (Flash
programming unlock sequence).
Set control bit WR of the EECON1 register to
begin the erase operation.
Poll the FREE bit in the EECON1 register to
determine when the row erase has completed.
See Example 11-4.
After the “BSF EECON1,WR” instruction, the processor
requires two cycles to set up the erase operation. The
user must place two NOP instructions after the WR bit is
set. The processor will halt internal operations for the
typical 2ms erase time. This is not Sleep mode, as the
clocks and peripherals will continue to run. After the
erase cycle, the processor will resume operation with
the third instruction after the EECON1 write instruction.
11.3.3
WRITING TO FLASH PROGRAM
MEMORY
Program memory is programmed using the following
steps:
1.
2.
3.
4.
Load the starting address of the word(s) to be
programmed.
Load the write latches with data.
Initiate a programming operation.
Repeat steps 1 through 3 until all data is written.
Before writing to program memory, the word(s) to be
written must be erased or previously unwritten.
Program memory can only be erased one row at a time.
No automatic erase occurs upon the initiation of the
write.
Program memory can be written one or more words at
a time. The maximum number of words written at one
time is equal to the number of write latches. See
Figure 11-2 (block writes to program memory with 32
write latches) for more details. The write latches are
aligned to the address boundary defined by EEADRL
as shown in Table 11-1. Write operations do not cross
these boundaries. At the completion of a program
memory write operation, the write latches are reset to
contain 0x3FFF.
DS40001657C-page 102
The following steps should be completed to load the
write latches and program a block of program memory.
These steps are divided into two parts. First, all write
latches are loaded with data except for the last program
memory location. Then, the last write latch is loaded
and the programming sequence is initiated. A special
unlock sequence is required to load a write latch with
data or initiate a Flash programming operation. This
unlock sequence should not be interrupted.
1.
Set the EEPGD and WREN bits of the EECON1
register.
2. Clear the CFGS bit of the EECON1 register.
3. Set the LWLO bit of the EECON1 register. When
the LWLO bit of the EECON1 register is ‘1’, the
write sequence will only load the write latches
and will not initiate the write to Flash program
memory.
4. Load the EEADRH:EEADRL register pair with
the address of the location to be written.
5. Load the EEDATH:EEDATL register pair with
the program memory data to be written.
6. Write 55h, then AAh, to EECON2, then set the
WR bit of the EECON1 register (Flash
programming unlock sequence). The write latch
is now loaded.
7. Increment the EEADRH:EEADRL register pair
to point to the next location.
8. Repeat steps 5 through 7 until all but the last
write latch has been loaded.
9. Clear the LWLO bit of the EECON1 register.
When the LWLO bit of the EECON1 register is
‘0’, the write sequence will initiate the write to
Flash program memory.
10. Load the EEDATH:EEDATL register pair with
the program memory data to be written.
11. Write 55h, then AAh, to EECON2, then set the
WR bit of the EECON1 register (Flash
programming unlock sequence). The entire
latch block is now written to Flash program
memory.
It is not necessary to load the entire write latch block
with user program data. However, the entire write latch
block will be written to program memory.
An example of the complete write sequence for eight
words is shown in Example 11-5. The initial address is
loaded into the EEADRH:EEADRL register pair; the
eight words of data are loaded using indirect addressing.
Note:
If the number of write latches is smaller
than the erase block size, the code
sequence provided in Example 11-5 may
be repeated multiple times to fully
program an erased program memory row.
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After the “BSF EECON1,WR” instruction, the processor
requires two cycles to set up the write operation. The
user must place two NOP instructions after the WR bit is
set. The processor will halt internal operations for the
typical 2ms, only during the cycle in which the write
takes place (i.e., the last word of the block write). This
is not Sleep mode, as the clocks and peripherals will
FIGURE 11-2:
continue to run. The processor does not stall when
LWLO = 1, loading the write latches. After the write
cycle, the processor will resume operation with the third
instruction after the EECON1 write instruction.
BLOCK WRITES TO FLASH PROGRAM MEMORY WITH 32 WRITE LATCHES
7
5
0
0 7
EEDATH
EEDATA
8
6
Last word of block
to be written
First word of block
to be written
14
EEADRL = 00000
14
EEADRL = 00001
Buffer Register
14
EEADRL = 00010
Buffer Register
14
EEADRL = 11111
Buffer Register
Buffer Register
Program Memory
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EXAMPLE 11-4:
ERASING ONE ROW OF PROGRAM MEMORY
Required
Sequence
; This row erase routine assumes the following:
; 1. A valid address within the erase block is loaded in ADDRH:ADDRL
; 2. ADDRH and ADDRL are located in shared data memory 0x70 - 0x7F
BCF
BANKSEL
MOVF
MOVWF
MOVF
MOVWF
BSF
BCF
BSF
BSF
INTCON,GIE
EEADRL
ADDRL,W
EEADRL
ADDRH,W
EEADRH
EECON1,EEPGD
EECON1,CFGS
EECON1,FREE
EECON1,WREN
MOVLW
MOVWF
MOVLW
MOVWF
BSF
NOP
55h
EECON2
0AAh
EECON2
EECON1,WR
NOP
; Disable ints so required sequences will execute properly
; Load lower 8 bits of erase address boundary
; Load upper 6 bits of erase address boundary
;
;
;
;
Point to program memory
Not configuration space
Specify an erase operation
Enable writes
;
;
;
;
;
;
;
;
Start of required sequence to initiate erase
Write 55h
Write AAh
Set WR bit to begin erase
Any instructions here are ignored as processor
halts to begin erase sequence
Processor will stop here and wait for erase complete.
; after erase processor continues with 3rd instruction
BCF
BSF
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EECON1,WREN
INTCON,GIE
; Disable writes
; Enable interrupts
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EXAMPLE 11-5:
;
;
;
;
;
;
;
WRITING TO FLASH PROGRAM MEMORY
This write routine assumes the following:
1. The 16 bytes of data are loaded, starting at the address in DATA_ADDR
2. Each word of data to be written is made up of two adjacent bytes in DATA_ADDR,
stored in little endian format
3. A valid starting address (the least significant bits = 000) is loaded in ADDRH:ADDRL
4. ADDRH and ADDRL are located in shared data memory 0x70 - 0x7F
BCF
BANKSEL
MOVF
MOVWF
MOVF
MOVWF
MOVLW
MOVWF
MOVLW
MOVWF
BSF
BCF
BSF
BSF
INTCON,GIE
EEADRH
ADDRH,W
EEADRH
ADDRL,W
EEADRL
LOW DATA_ADDR
FSR0L
HIGH DATA_ADDR
FSR0H
EECON1,EEPGD
EECON1,CFGS
EECON1,WREN
EECON1,LWLO
;
;
;
;
;
;
;
;
;
;
;
;
;
;
Disable ints so required sequences will execute properly
Bank 3
Load initial address
MOVIW
MOVWF
MOVIW
MOVWF
FSR0++
EEDATL
FSR0++
EEDATH
; Load first data byte into lower
;
; Load second data byte into upper
;
MOVF
XORLW
ANDLW
BTFSC
GOTO
EEADRL,W
0x07
0x07
STATUS,Z
START_WRITE
; Check if lower bits of address are '000'
; Check if we're on the last of 8 addresses
;
; Exit if last of eight words,
;
MOVLW
MOVWF
MOVLW
MOVWF
BSF
NOP
55h
EECON2
0AAh
EECON2
EECON1,WR
;
;
;
;
;
;
;
;
Load initial data address
Load initial data address
Point to program memory
Not configuration space
Enable writes
Only Load Write Latches
Required
Sequence
LOOP
NOP
Start of required write sequence:
Write 55h
Write AAh
Set WR bit to begin write
Any instructions here are ignored as processor
halts to begin write sequence
Processor will stop here and wait for write to complete.
; After write processor continues with 3rd instruction.
INCF
GOTO
Required
Sequence
START_WRITE
BCF
MOVLW
MOVWF
MOVLW
MOVWF
BSF
NOP
EEADRL,F
LOOP
; Still loading latches Increment address
; Write next latches
EECON1,LWLO
; No more loading latches - Actually start Flash program
; memory write
55h
EECON2
0AAh
EECON2
EECON1,WR
;
;
;
;
;
;
;
;
NOP
BCF
BSF
EECON1,WREN
INTCON,GIE
2012-2017 Microchip Technology Inc.
Start of required write sequence:
Write 55h
Write AAh
Set WR bit to begin write
Any instructions here are ignored as processor
halts to begin write sequence
Processor will stop here and wait for write complete.
; after write processor continues with 3rd instruction
; Disable writes
; Enable interrupts
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11.4
Modifying Flash Program Memory
When modifying existing data in a program memory
row, and data within that row must be preserved, it must
first be read and saved in a RAM image. Program
memory is modified using the following steps:
1.
2.
3.
4.
5.
6.
7.
8.
Load the starting address of the row to be
modified.
Read the existing data from the row into a RAM
image.
Modify the RAM image to contain the new data
to be written into program memory.
Load the starting address of the row to be
rewritten.
Erase the program memory row.
Load the write latches with data from the RAM
image.
Initiate a programming operation.
Repeat steps 6 and 7 as many times as required
to reprogram the erased row.
TABLE 11-2:
11.5
User ID, Device ID and
Configuration Word Access
Instead of accessing program memory or EEPROM
data memory, the User ID’s, Device ID/Revision ID and
Configuration Words can be accessed when CFGS = 1
in the EECON1 register. This is the region that would
be pointed to by PC = 1, but not all addresses are
accessible. Different access may exist for reads and
writes. Refer to Table 11-2.
When read access is initiated on an address outside the
parameters listed in Table 11-2, the EEDATH:EEDATL
register pair is cleared.
USER ID, DEVICE ID AND CONFIGURATION WORD ACCESS (CFGS = 1)
Address
Function
Read Access
Write Access
8000h-8003h
8006h
8007h-8008h
User IDs
Device ID/Revision ID
Configuration Words 1 and 2
Yes
Yes
Yes
Yes
No
No
EXAMPLE 11-3:
CONFIGURATION WORD AND DEVICE ID ACCESS
* This code block will read 1 word of program memory at the memory address:
*
PROG_ADDR_LO (must be 00h-08h) data will be returned in the variables;
*
PROG_DATA_HI, PROG_DATA_LO
BANKSEL
MOVLW
MOVWF
CLRF
EEADRL
PROG_ADDR_LO
EEADRL
EEADRH
; Select correct Bank
;
; Store LSB of address
; Clear MSB of address
BSF
BCF
BSF
NOP
NOP
BSF
EECON1,CFGS
INTCON,GIE
EECON1,RD
INTCON,GIE
;
;
;
;
;
;
Select Configuration Space
Disable interrupts
Initiate read
Executed (See Figure 11-1)
Ignored (See Figure 11-1)
Restore interrupts
MOVF
MOVWF
MOVF
MOVWF
EEDATL,W
PROG_DATA_LO
EEDATH,W
PROG_DATA_HI
;
;
;
;
Get LSB of word
Store in user location
Get MSB of word
Store in user location
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PIC16LF1824T39A
11.6
Write Verify
Depending on the application, good programming
practice may dictate that the value written to the data
EEPROM or program memory should be verified (see
Example 11-6) to the desired value to be written.
Example 11-6 shows how to verify a write to EEPROM.
EXAMPLE 11-6:
EEPROM WRITE VERIFY
BANKSEL EEDATL
MOVF
EEDATL, W
BSF
XORWF
BTFSS
GOTO
:
;
;EEDATL not changed
;from previous write
EECON1, RD ;YES, Read the
;value written
EEDATL, W ;
STATUS, Z ;Is data the same
WRITE_ERR ;No, handle error
;Yes, continue
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REGISTER 11-1:
R/W-x/u
EEDATL: EEPROM DATA REGISTER
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
EEDAT
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-0
EEDAT: Read/write value for EEPROM data byte or Least Significant bits of program memory
REGISTER 11-2:
EEDATH: EEPROM DATA HIGH BYTE REGISTER
U-0
U-0
—
—
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
EEDAT
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
EEDAT: Read/write value for Most Significant bits of program memory
REGISTER 11-3:
R/W-0/0
EEADRL: EEPROM ADDRESS REGISTER
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
EEADR
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-0
EEADR: Specifies the Least Significant bits for program memory address or EEPROM address
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REGISTER 11-4:
U-1
EEADRH: EEPROM ADDRESS HIGH BYTE REGISTER
R/W-0/0
R/W-0/0
—
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
EEADR
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘1’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
Unimplemented: Read as ‘1’
bit 6-0
EEADR: Specifies the Most Significant bits for program memory address or EEPROM address
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REGISTER 11-5:
EECON1: EEPROM CONTROL 1 REGISTER
R/W-0/0
R/W-0/0
R/W-0/0
R/W/HC-0/0
R/W-x/q
R/W-0/0
R/S/HC-0/0
R/S/HC-0/0
EEPGD
CFGS
LWLO
FREE
WRERR
WREN
WR
RD
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
S = Bit can only be set
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
HC = Bit is cleared by hardware
bit 7
EEPGD: Flash Program/Data EEPROM Memory Select bit
1 = Accesses program space Flash memory
0 = Accesses data EEPROM memory
bit 6
CFGS: Flash Program/Data EEPROM or Configuration Select bit
1 = Accesses Configuration, User ID and Device ID Registers
0 = Accesses Flash Program or data EEPROM Memory
bit 5
LWLO: Load Write Latches Only bit
If CFGS = 1 (Configuration space) OR CFGS = 0 and EEPGD = 1 (program Flash):
1 = The next WR command does not initiate a write; only the program memory latches are
updated.
0 = The next WR command writes a value from EEDATH:EEDATL into program memory latches
and initiates a write of all the data stored in the program memory latches.
If CFGS = 0 and EEPGD = 0: (Accessing data EEPROM)
LWLO is ignored. The next WR command initiates a write to the data EEPROM.
bit 4
FREE: Program Flash Erase Enable bit
If CFGS = 1 (Configuration space) OR CFGS = 0 and EEPGD = 1 (program Flash):
1 = Performs an erase operation on the next WR command (cleared by hardware after completion of erase).
0 = Performs a write operation on the next WR command.
If EEPGD = 0 and CFGS = 0: (Accessing data EEPROM)
FREE is ignored. The next WR command will initiate both a erase cycle and a write cycle.
bit 3
WRERR: EEPROM Error Flag bit
1 = Condition indicates an improper program or erase sequence attempt or termination (bit is set
automatically on any set attempt (write ‘1’) of the WR bit).
0 = The program or erase operation completed normally
bit 2
WREN: Program/Erase Enable bit
1 = Allows program/erase cycles
0 = Inhibits programming/erasing of program Flash and data EEPROM
bit 1
WR: Write Control bit
1 = Initiates a program Flash or data EEPROM program/erase operation.
The operation is self-timed and the bit is cleared by hardware once operation is complete.
The WR bit can only be set (not cleared) in software.
0 = Program/erase operation to the Flash or data EEPROM is complete and inactive.
bit 0
RD: Read Control bit
1 = Initiates a program Flash or data EEPROM read. Read takes one cycle. RD is cleared in
hardware. The RD bit can only be set (not cleared) in software.
0 = Does not initiate a program Flash or data EEPROM data read
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REGISTER 11-6:
W-0/0
EECON2: EEPROM CONTROL 2 REGISTER
W-0/0
W-0/0
W-0/0
W-0/0
W-0/0
W-0/0
W-0/0
EEPROM Control Register 2
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
S = Bit can only be set
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-0
Data EEPROM Unlock Pattern bits
To unlock writes, a 55h must be written first, followed by an AAh, before setting the WR bit of the
EECON1 register. The value written to this register is used to unlock the writes. There are specific
timing requirements on these writes. Refer to Section 11.2.2 “Writing to the Data EEPROM
Memory” for more information.
TABLE 11-3:
SUMMARY OF REGISTERS ASSOCIATED WITH DATA EEPROM
Name
Bit 7
Bit 6
EECON1
EEPGD
CFGS
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
LWLO
FREE
WRERR
WREN
WR
RD
110
EECON2
EEPROM Control Register 2 (not a physical register)
EEADRL
EEADRL
EEADRH
—(1)
111*
108
EEADRH VIH
0 = Port pin is < VIL
Note 1:
Writes to PORTA are actually written to corresponding LATA register. Reads from PORTA register is return
of actual I/O pin values.
REGISTER 12-4:
TRISA: PORTA TRI-STATE REGISTER
U-0
U-0
R/W-1/1
R/W-1/1
R-1/1
R/W-1/1
R/W-1/1
R/W-1/1
—(1)
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-4
TRISA: PORTA Tri-State Control bit
1 = PORTA pin configured as an input (tri-stated)
0 = PORTA pin configured as an output
bit 3
TRISA3: RA3 Port Tri-State Control bit
This bit is always ‘1’ as RA3 is an input only
bit 2-0
TRISA: PORTA Tri-State Control bit
1 = PORTA pin configured as an input (tri-stated)
0 = PORTA pin configured as an output
Note 1:
Unimplemented, read as ‘1’.
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REGISTER 12-5:
LATA: PORTA DATA LATCH REGISTER
U-0
U-0
R/W-x/u
R/W-x/u
U-0
R/W-x/u
R/W-x/u
R/W-x/u
—
—
LATA5
LATA4
—
LATA2
LATA1
LATA0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0
bit 5-4
LATA: RA Output Latch Value bits(1)
bit 3
Unimplemented: Read as ‘0
bit 2-0
LATA: RA Output Latch Value bits(1)
Note 1:
Writes to PORTA are actually written to corresponding LATA register. Reads from PORTA register is return
of actual I/O pin values.
REGISTER 12-6:
ANSELA: PORTA ANALOG SELECT REGISTER
U-0
U-0
U-0
R/W-1/1
U-0
R/W-1/1
R/W-1/1
R/W-1/1
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-5
Unimplemented: Read as ‘0’
bit 4
ANSA4: Analog Select between Analog or Digital Function on pins RA4, respectively
0 = Digital I/O. Pin is assigned to port or digital special function.
1 = Analog input. Pin is assigned as analog input(1). Digital input buffer disabled.
bit 3
Unimplemented: Read as ‘0’
bit 2-0
ANSA: Analog Select between Analog or Digital Function on pins RA, respectively
0 = Digital I/O. Pin is assigned to port or digital special function.
1 = Analog input. Pin is assigned as analog input(1). Digital input buffer disabled.
Note 1:
When setting a pin to an analog input, the corresponding TRIS bit must be set to Input mode in order to
allow external control of the voltage on the pin.
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REGISTER 12-7:
WPUA: WEAK PULL-UP PORTA REGISTER
U-0
U-0
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
—
—
WPUA5
WPUA4
WPUA3
WPUA2
WPUA1
WPUA0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
WPUA: Weak Pull-up Register bits
1 = Pull-up enabled
0 = Pull-up disabled
Note 1:
2:
Global WPUEN bit of the OPTION_REG register must be cleared for individual pull-ups to be enabled.
The weak pull-up device is automatically disabled if the pin is in configured as an output.
REGISTER 12-8:
INLVLA: PORTA INPUT LEVEL CONTROL REGISTER
U-0
U-0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-1/1
R/W-0/0
R/W-0/0
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0
bit 5-0
INLVLA: PORTA Input Level Select bits
For RA pins, respectively
1 = ST input used for PORT reads and interrupt-on-change
0 = TTL input used for PORT reads and interrupt-on-change
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TABLE 12-1:
SUMMARY OF REGISTERS ASSOCIATED WITH PORTA
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
118
APFCON0
RXDTSEL
SDOSEL
SSSEL
—
T1GSEL
TXCKSEL
—
—
113
APFCON1
—
—
—
—
P1DSEL
P1CSEL
P2BSEL
CCP2SEL
114
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
LATA
—
—
LATA5
LATA4
—
LATA2
LATA1
LATA0
118
Name
ANSELA
WPUEN
INTEDG
TMR0CS
TMR0SE
PSA
PORTA
—
—
RA5
RA4
RA3
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
WPUA
—
—
WPUA5
WPUA4
WPUA3
WPUA2
OPTION_REG
Legend:
CONFIG1
Legend:
RA1
165
RA0
117
TRISA1
TRISA0
117
WPUA1
WPUA0
119
x = unknown, u = unchanged, – = unimplemented locations, read as ‘0’. Shaded cells are not used by PORTA.
TABLE 12-2:
Name
PS
RA2
SUMMARY OF CONFIGURATION WORD WITH PORTA
Bits
Bit -/7
Bit -/6
Bit 13/5
Bit 12/4
Bit 11/3
13:8
—
—
FCMEN
IESO
CLKOUTEN
7:0
CP
MCLRE
PWRTE
Bit 10/2
Bit 9/1
BOREN
WDTE
FOSC
Bit 8/0
CPD
Register
on Page
43
— = unimplemented location, read as ‘0’. Shaded cells are not used by PORTA.
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12.3
PORTC Registers
PORTC is a 6-bit wide, bidirectional port. The
corresponding data direction register is TRISC
(Register 12-10). Setting a TRISC bit (= 1) will make
the corresponding PORTC pin an input (i.e., put the
corresponding output driver in a High-Impedance
mode). Clearing a TRISC bit (= 0) will make the
corresponding PORTC pin an output (i.e., enable the
output driver and put the contents of the output latch on
the selected pin). Example 12-2 shows how to initialize
PORTC.
Reading the PORTC register (Register 12-9) reads the
status of the pins, whereas writing to it will write to the
PORT latch. All write operations are read-modify-write
operations. Therefore, a write to a port implies that the
port pins are read, this value is modified and then written
to the PORT data latch (LATC).
The TRISC register (Register 12-10) controls the
PORTC pin output drivers, even when they are being
used as analog inputs. The user should ensure the bits in
the TRISC register are maintained set when using them
as analog inputs. I/O pins configured as analog input
always read ‘0’.
The INLVLC register (Register 12-14) controls the input
voltage threshold for each of the available PORTC
input pins. A selection between the Schmitt Trigger
CMOS or the TTL Compatible thresholds is available.
The input threshold is important in determining the
value of a read of the PORTC register and also the
level at which an interrupt-on-change occurs, if that
feature is enabled. See Table 31-4 for more information
on threshold levels.
Note:
12.3.1
12.3.2
ANSELC REGISTER
The ANSELC register (Register 12-12) is used to
configure the Input mode of an I/O pin to analog.
Setting the appropriate ANSELC bit high will cause all
digital reads on the pin to be read as ‘0’ and allow
analog functions on the pin to operate correctly.
The state of the ANSELC bits has no affect on digital output functions. A pin with TRIS clear and ANSELC set will
still operate as a digital output, but the Input mode will be
analog. This can cause unexpected behavior when
executing read-modify-write instructions on the affected
port.
Note:
The ANSELC register must be initialized
to configure an analog channel as a digital
input. Pins configured as analog inputs
will read ‘0’.
EXAMPLE 12-2:
BANKSEL
CLRF
BANKSEL
CLRF
BANKSEL
CLRF
BANKSEL
MOVLW
MOVWF
INITIALIZING PORTC
PORTC
;
PORTC
;Init PORTC
LATC
;Data Latch
LATC
;
ANSELC
ANSELC
;Make RC digital
TRISB
;
B’00110000’;Set RC as inputs
;and RC as outputs
TRISC
;
Changing the input threshold selection
should be performed while all peripheral
modules are disabled. Changing the
threshold level during the time a module is
active may inadvertently generate a
transition associated with an input pin,
regardless of the actual voltage level on
that pin.
WEAK PULL-UPS
Each of the PORTC pins has an individually configurable
internal weak pull-up. Control bits WPUC enable or
disable each pull-up (see Register 12-13). Each weak
pull-up is automatically turned off when the port pin is
configured as an output. All pull-ups are disabled on a
Power-on Reset by the WPUEN bit of the OPTION_REG
register.
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12.3.3
PORTC FUNCTIONS AND OUTPUT
PRIORITIES
Each PORTC pin is multiplexed with other functions. The
pins, their combined functions and their output priorities
are briefly described here. For additional information,
refer to the appropriate section in this data sheet.
When multiple outputs are enabled, the actual pin
control goes to the peripheral with the lowest number in
the following lists.
Analog input and some digital input functions are not
included in the list below. These input functions can
remain active when the pin is configured as an output.
Certain digital input functions override other port
functions and are included in the priority list.
RC0
1.
2.
3.
SCL (MSSP)
SCK (MSSP)
P1D
RC1
1.
2.
3.
SDA (MSSP)
P1C
CCP4
RC2
1.
2.
3.
SDO (MSSP)
P1D
P2B
RC3
1.
2.
3.
4.
SS (MSSP)
CCP2
P1C
P2A
RC4
1.
2.
3.
4.
5.
MDOUT
SRNQ
C2OUT
TX/CK
P1B
RC5
1.
2.
RX/DT
CCP1/P1A
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REGISTER 12-9:
PORTC: PORTC REGISTER
U-0
U-0
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
—
—
RC5
RC4
RC3
RC2
RC1
RC0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
RC: PORTC General Purpose I/O Pin bits
1 = Port pin is > VIH
0 = Port pin is < VIL
REGISTER 12-10: TRISC: PORTC TRI-STATE REGISTER
U-0
U-0
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
TRISC: PORTC Tri-State Control bits
1 = PORTC pin configured as an input (tri-stated)
0 = PORTC pin configured as an output
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REGISTER 12-11: LATC: PORTC DATA LATCH REGISTER
U-0
U-0
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
—
—
LATC5
LATC4
LATC3
LATC2
LATC1
LATC0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
LATC: PORTC Output Latch Value bits(1)
Note 1:
Writes to PORTC are actually written to corresponding LATC register. Reads from PORTC register is
return of actual I/O pin values.
REGISTER 12-12: ANSELC: PORTC ANALOG SELECT REGISTER
U-0
U-0
U-0
U-0
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
—
—
—
—
ANSC3
ANSC2
ANSC1
ANSC0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-4
Unimplemented: Read as ‘0’
bit 3-0
ANSC: Analog Select between Analog or Digital Function on pins RC, respectively
0 = Digital I/O. Pin is assigned to port or digital special function.
1 = Analog input. Pin is assigned as analog input(1). Digital input buffer disabled.
Note 1:
When setting a pin to an analog input, the corresponding TRIS bit must be set to Input mode in order to
allow external control of the voltage on the pin.
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PIC16LF1824T39A
REGISTER 12-13: WPUC: WEAK PULL-UP PORTC REGISTER
U-0
U-0
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
—
—
WPUC5
WPUC4
WPUC3
WPUC2
WPUC1
WPUC0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
WPUC: Weak Pull-up Register bits(1)
1 = Pull-up enabled
0 = Pull-up disabled
Note 1:
2:
Global WPUEN bit of the OPTION_REG register must be cleared for individual pull-ups to be enabled.
The weak pull-up device is automatically disabled if the pin is in configured as an output.
REGISTER 12-14: INLVLC: PORTC INPUT LEVEL CONTROL REGISTER
U-0(1)
U-0(1)
R/W-0/0(1)
R/W-0/0(1)
R/W-0/0(1)
R/W-0/0(1)
R/W-0/0(1)
R/W-0/0(1)
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
INLVLC: PORTC Input Level Select bits
For RC pins, respectively
1 = ST input used for PORT reads and interrupt-on-change
0 = TTL input used for PORT reads and interrupt-on-change
Note 1:
Reset default value.
TABLE 12-3:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH PORTC
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
ANSELC
—
—
—
—
ANSC3
ANSC2
ANSC1
ANSC0
124
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
LATC
—
—
LATC5
LATC4
LATC3
LATC2
LATC1
LATC0
124
PORTC
—
—
RC5
RC4
RC3
RC2
RC1
RC0
123
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
WPUC
—
—
WPUC5
WPUC4
WPUC3
WPUC2
WPUC1
WPUC0
125
Legend:
x = unknown, u = unchanged, - = unimplemented locations, read as ‘0’. Shaded cells are not used by PORTC.
2012-2017 Microchip Technology Inc.
DS40001657C-page 125
PIC16LF1824T39A
13.0
INTERRUPT-ON-CHANGE
The PORTA pins can be configured to operate as
Interrupt-on-Change (IOC) pins. An interrupt can be
generated by detecting a signal that has either a rising
edge or a falling edge. Any individual port pin, or
combination of port pins, can be configured to generate
an interrupt. The interrupt-on-change module has the
following features:
•
•
•
•
Interrupt-on-change enable (Master Switch)
Individual pin configuration
Rising and falling edge detection
Individual pin interrupt flags
Figure 13-1 is a block diagram of the IOC module.
13.1
Enabling the Module
13.3
Interrupt Flags
The IOCAFx and IOCBFx bits located in the IOCAF and
IOCBF registers, respectively, are status flags that
correspond to the interrupt-on-change pins of the
associated port. If an expected edge is detected on an
appropriately enabled pin, then the status flag for that pin
will be set, and an interrupt will be generated if the IOCIE
bit is set. The IOCIF bit of the INTCON register reflects
the status of all IOCAFx and IOCBFx bits.
13.4
Clearing Interrupt Flags
The individual status flags, (IOCAFx and IOCBFx bits),
can be cleared by resetting them to zero. If another edge
is detected during this clearing operation, the associated
status flag will be set at the end of the sequence,
regardless of the value actually being written.
To allow individual port pins to generate an interrupt, the
IOCIE bit of the INTCON register must be set. If the
IOCIE bit is disabled, the edge detection on the pin will
still occur, but an interrupt will not be generated.
In order to ensure that no detected edge is lost while
clearing flags, only AND operations masking out known
changed bits should be performed. The following
sequence is an example of what should be performed.
13.2
Individual Pin Configuration
EXAMPLE 13-1:
For each port pin, a rising edge detector and a falling
edge detector are present. To enable a pin to detect a
rising edge, the associated bit of the IOCxP register is
set. To enable a pin to detect a falling edge, the
associated bit of the IOCxN register is set.
MOVLW
XORWF
ANDWF
A pin can be configured to detect rising and falling
edges simultaneously by setting both associated bits of
the IOCxP and IOCxN registers, respectively.
13.5
CLEARING
INTERRUPT FLAGS
(PORTA EXAMPLE)
0xff
IOCAF, W
IOCAF, F
Operation in Sleep
The interrupt-on-change interrupt sequence will wake
the device from Sleep mode, if the IOCIE bit is set.
If an edge is detected while in Sleep mode, the IOCxF
register will be updated prior to the first instruction
executed out of Sleep.
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PIC16LF1824T39A
FIGURE 13-1:
INTERRUPT-ON-CHANGE BLOCK DIAGRAM (PORTA EXAMPLE)
IOCIE
IOCANx
D
IOCAFx
Q
From all other IOCAFx
individual pin detectors
CK
R
IOC Interrupt to
CPU Core
RAx
IOCAPx
D
Q
CK
R
Q2 Clock Cycle
REGISTER 13-1:
IOCAP: INTERRUPT-ON-CHANGE PORTA POSITIVE EDGE REGISTER
U-0
U-0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
—
—
IOCAP5
IOCAP4
IOCAP3
IOCAP2
IOCAP1
IOCAP0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
IOCAP: Interrupt-on-Change PORTA Positive Edge Enable bits
1 = Interrupt-on-Change enabled on the pin for a positive going edge. Associated Status bit and interrupt
flag will be set upon detecting an edge.
0 = Interrupt-on-Change disabled for the associated pin.
2012-2017 Microchip Technology Inc.
DS40001657C-page 127
PIC16LF1824T39A
REGISTER 13-2:
IOCAN: INTERRUPT-ON-CHANGE PORTA NEGATIVE EDGE REGISTER
U-0
U-0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
—
—
IOCAN5
IOCAN4
IOCAN3
IOCAN2
IOCAN1
IOCAN0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
IOCAN: Interrupt-on-Change PORTA Negative Edge Enable bits
1 = Interrupt-on-Change enabled on the pin for a negative going edge. Associated Status bit and interrupt
flag will be set upon detecting an edge.
0 = Interrupt-on-Change disabled for the associated pin.
REGISTER 13-3:
IOCAF: INTERRUPT-ON-CHANGE PORTA FLAG REGISTER
U-0
U-0
R/W/HS-0/0
R/W/HS-0/0
R/W/HS-0/0
R/W/HS-0/0
R/W/HS-0/0
R/W/HS-0/0
—
—
IOCAF5
IOCAF4
IOCAF3
IOCAF2
IOCAF1
IOCAF0
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
HS - Bit is set in hardware
bit 7-6
Unimplemented: Read as ‘0’
bit 5-0
IOCAF: Interrupt-on-Change PORTA Flag bits
1 = An enabled change was detected on the associated pin.
Set when IOCAPx = 1 and a rising edge was detected on RAx, or when IOCANx = 1 and a falling edge
was detected on RAx.
0 = No change was detected, or the user cleared the detected change.
TABLE 13-1:
SUMMARY OF REGISTERS ASSOCIATED WITH INTERRUPT-ON-CHANGE
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
ANSELA
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
118
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
IOCAF
—
—
IOCAF5
IOCAF4
IOCAF3
IOCAF2
IOCAF1
IOCAF0
128
IOCAN
—
—
IOCAN5
IOCAN4
IOCAN3
IOCAN2
IOCAN1
IOCAN0
128
IOCAP
—
—
IOCAP5
IOCAP4
IOCAP3
IOCAP2
IOCAP1
IOCAP0
127
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
Name
Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used by interrupt-on-change.
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PIC16LF1824T39A
14.0
FIXED VOLTAGE REFERENCE
(FVR)
14.1
Independent Gain Amplifiers
The Fixed Voltage Reference (FVR), is a stable voltage
reference, independent of VDD, with 1.024V, 2.048V or
4.096V selectable output levels. The output of the FVR
can be configured to supply a reference voltage to the
following:
The output of the FVR supplied to the ADC,
Comparators, and DAC is routed through two
independent programmable gain amplifiers. Each
amplifier can be configured to amplify the reference
voltage by 1x, 2x or 4x, to produce the three possible
voltage levels.
•
•
•
•
The ADFVR bits of the FVRCON register are
used to enable and configure the gain amplifier settings
for the reference supplied to the ADC module. Reference Section 16.0 “Analog-to-Digital Converter
(ADC) Module” for additional information.
ADC input channel
ADC positive reference
Comparator positive input
Digital-to-Analog Converter (DAC)
The FVR can be enabled by setting the FVREN bit of
the FVRCON register.
The CDAFVR bits of the FVRCON register are
used to enable and configure the gain amplifier settings
for the reference supplied to the DAC and comparator
module. Reference Section 17.0 “Digital-to-Analog
Converter (DAC) Module” and Section 19.0 “Comparator Module” for additional information.
14.2
FVR Stabilization Period
When the Fixed Voltage Reference module is enabled, it
requires time for the reference and amplifier circuits to
stabilize. Once the circuits stabilize and are ready for use,
the FVRRDY bit of the FVRCON register will be set. See
Section 31.0 “Electrical Specifications” for the
minimum delay requirement.
FIGURE 14-1:
VOLTAGE REFERENCE BLOCK DIAGRAM
ADFVR
CDAFVR
FVREN
FVRRDY
2012-2017 Microchip Technology Inc.
2
X1
X2
X4
FVR BUFFER1
(To ADC Module)
X1
X2
X4
FVR BUFFER2
(To Comparators, DAC, CPS)
2
+
_
1.024V Fixed
Reference
DS40001657C-page 129
PIC16LF1824T39A
REGISTER 14-1:
FVRCON: FIXED VOLTAGE REFERENCE CONTROL REGISTER
R/W-0/0
R-q/q
R/W-0/0
R/W-0/0
FVREN
FVRRDY
TSEN
TSRNG
R/W-0/0
R/W-0/0
R/W-0/0
CDAFVR
R/W-0/0
ADFVR
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
q = Value depends on condition
bit 7
FVREN: Fixed Voltage Reference Enable bit
0 = Fixed Voltage Reference is disabled
1 = Fixed Voltage Reference is enabled
bit 6
FVRRDY: Fixed Voltage Reference Ready Flag bit
0 = Fixed Voltage Reference output is not ready or not enabled
1 = Fixed Voltage Reference output is ready for use
bit 5
TSEN: Temperature Indicator Enable bit(2)
0 = Temperature Indicator is disabled
1 = Temperature Indicator is enabled
bit 4
TSRNG: Temperature Indicator Range Selection bit(2)
0 = VOUT = VDD - 2VT (Low Range)
1 = VOUT = VDD - 4VT (High Range)
bit 3-2
CDAFVR: Comparator and DAC Fixed Voltage Reference Selection bits
00 = Comparator and DAC Fixed Voltage Reference Peripheral output is off
01 = Comparator and DAC Fixed Voltage Reference Peripheral output is 1x (1.024V)
10 = Comparator and DAC Fixed Voltage Reference Peripheral output is 2x (2.048V)(1)
11 = Comparator and DAC Fixed Voltage Reference Peripheral output is 4x (4.096V)(1)
bit 1-0
ADFVR: ADC Fixed Voltage Reference Selection bits
00 = ADC Fixed Voltage Reference Peripheral output is off
01 = ADC Fixed Voltage Reference Peripheral output is 1x (1.024V)
10 = ADC Fixed Voltage Reference Peripheral output is 2x (2.048V)(1)
11 = ADC Fixed Voltage Reference Peripheral output is 4x (4.096V)(1)
Note 1:
2:
Fixed Voltage Reference output cannot exceed VDD.
See Section 15.0 “Temperature Indicator Module” for additional information.
TABLE 14-1:
Name
FVRCON
Legend:
SUMMARY OF REGISTERS ASSOCIATED WITH THE FIXED VOLTAGE REFERENCE
Bit 7
Bit 6
Bit 5
Bit 4
FVREN
FVRRDY
TSEN
TSRNG
Bit 3
Bit 2
CDAFVR
Bit 1
Bit 0
ADFVR
Register
on page
130
Shaded cells are unused by the Fixed Voltage Reference module.
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PIC16LF1824T39A
15.0
TEMPERATURE INDICATOR
MODULE
FIGURE 15-1:
This family of devices is equipped with a temperature
circuit designed to measure the operating temperature
of the silicon die. The circuit’s range of operating
temperature falls between of -40°C and +85°C. The
output is a voltage that is proportional to the device
temperature. The output of the temperature indicator is
internally connected to the device ADC.
VDD
TSEN
TSRNG
The circuit may be used as a temperature threshold
detector or a more accurate temperature indicator,
depending on the level of calibration performed. A onepoint calibration allows the circuit to indicate a
temperature closely surrounding that point. A two-point
calibration allows the circuit to sense the entire range
of temperature more accurately. Reference Application
Note AN1333, “Use and Calibration of the Internal
Temperature Indicator” (DS01333) for more details
regarding the calibration process.
15.1
TEMPERATURE CIRCUIT
DIAGRAM
VOUT
ADC
MUX
ADC
n
CHS bits
(ADCON0 register)
Circuit Operation
Figure 15-1 shows a simplified block diagram of the
temperature circuit. The proportional voltage output is
achieved by measuring the forward voltage drop across
multiple silicon junctions.
Equation 15-1 describes the output characteristics of
the temperature indicator.
EQUATION 15-1:
VOUT RANGES
High Range: VOUT = VDD - 4VT
Low Range: VOUT = VDD - 2VT
15.2
Minimum Operating VDD vs.
Minimum Sensing Temperature
When the temperature circuit is operated in low range,
the device may be operated at any operating voltage
that is within specifications.
When the temperature circuit is operated in high range,
the device operating voltage, VDD, must be high
enough to ensure that the temperature circuit is
correctly biased.
Table 15-1 shows the recommended minimum VDD vs.
range setting.
TABLE 15-1:
The temperature sense circuit is integrated with the
Fixed Voltage Reference (FVR) module. See
Section 14.0 “Fixed Voltage Reference (FVR)” for
more information.
The circuit is enabled by setting the TSEN bit of the
FVRCON register (Register 14-1). When disabled, the
circuit draws no current.
The circuit operates in either high or low range. The high
range, selected by setting the TSRNG bit of the
FVRCON register, provides a wider output voltage. This
provides more resolution over the temperature range,
but may be less consistent from part to part. This range
requires a higher bias voltage to operate and thus, a
higher VDD is needed.
The low range is selected by clearing the TSRNG bit of
the FVRCON register. The low range generates a lower
voltage drop and thus, a lower bias voltage is needed to
operate the circuit. The low range is provided for low
voltage operation.
2012-2017 Microchip Technology Inc.
RECOMMENDED VDD VS.
RANGE
Min. VDD, TSRNG = 1
Min. VDD, TSRNG = 0
3.6V
1.8V
15.3
Temperature Output
The output of the circuit is measured using the internal
analog-to-digital converter. A channel is reserved for the
temperature circuit output. Refer to Section 16.0
“Analog-to-Digital Converter (ADC) Module” for
detailed information.
15.4
ADC Acquisition Time
To ensure accurate temperature measurements, the
user must wait at least 200 s after the ADC input
multiplexer is connected to the temperature indicator
output before the conversion is performed. In addition,
the user must wait 200 s between sequential
conversions of the temperature indicator output.
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PIC16LF1824T39A
16.0
ANALOG-TO-DIGITAL
CONVERTER (ADC) MODULE
The ADC can generate an interrupt upon completion of
a conversion. This interrupt can be used to wake-up the
device from Sleep.
The Analog-to-Digital Converter (ADC) allows
conversion of an analog input signal to a 10-bit binary
representation of that signal. This device uses analog
inputs, which are multiplexed into a single sample and
hold circuit. The output of the sample and hold is
connected to the input of the converter. The converter
generates a 10-bit binary result via successive
approximation and stores the conversion result into the
ADC result registers (ADRESH:ADRESL register pair).
Figure 16-1 shows the block diagram of the ADC.
The ADC voltage reference is software selectable to be
either internally generated or externally supplied.
FIGURE 16-1:
ADC BLOCK DIAGRAM
ADNREF = 1
VREF-
ADNREF = 0
VDD
VSS
ADPREF = 00
ADPREF = 11
VREF+
AN0
00000
AN1
00001
AN2
00010
AN3
00011
AN4
00100
AN5
00101
AN6
00110
AN7
00111
ADPREF = 10
ref+
ref-
ADC
10
GO/DONE
Temp Indicator
11101
DAC_output
11110
FVR Buffer1
11111
ADFM
0 = Left Justify
1 = Right Justify
ADON(1)
16
VSS
ADRESH
ADRESL
CHS
Note 1:
When ADON = 0, all multiplexer inputs are disconnected.
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PIC16LF1824T39A
16.1
ADC Configuration
When configuring and using the ADC the following
functions must be considered:
•
•
•
•
•
•
Port configuration
Channel selection
ADC voltage reference selection
ADC conversion clock source
Interrupt control
Result formatting
16.1.1
PORT CONFIGURATION
The ADC can be used to convert both analog and
digital signals. When converting analog signals, the I/O
pin should be configured for analog by setting the
associated TRIS and ANSEL bits. Refer to
Section 12.0 “I/O Ports” for more information.
Note:
Analog voltages on any pin that is defined
as a digital input may cause the input buffer to conduct excess current.
16.1.2
CHANNEL SELECTION
There are up to 14 channel selections available:
• AN pins
• DAC Output
• FVR (Fixed Voltage Reference) Output
16.1.4
CONVERSION CLOCK
The source of the conversion clock is software selectable via the ADCS bits of the ADCON1 register. There
are seven possible clock options:
•
•
•
•
•
•
•
FOSC/2
FOSC/4
FOSC/8
FOSC/16
FOSC/32
FOSC/64
FRC (dedicated internal oscillator)
The time to complete one bit conversion is defined as
TAD. One full 10-bit conversion requires 11.5 TAD
periods as shown in Figure 16-3.
For correct conversion, the appropriate TAD
specification must be met. Refer to the A/D conversion
requirements
in
Section 31.0
“Electrical
Specifications” for more information. Table 16-1 gives
examples of appropriate ADC clock selections.
Note:
Unless using the FRC, any changes in the
system clock frequency will change the
ADC clock frequency, which may
adversely affect the ADC result.
Refer to Section 17.0 “Digital-to-Analog Converter
(DAC) Module” and Section 14.0 “Fixed Voltage
Reference (FVR)” for more information on these
channel selections.
The CHS bits of the ADCON0 register determine which
channel is connected to the sample and hold circuit.
When changing channels, a delay is required before
starting the next conversion. Refer to Section 16.2
“ADC Operation” for more information.
16.1.3
ADC VOLTAGE REFERENCE
The ADPREF bits of the ADCON1 register provides
control of the positive voltage reference. The positive
voltage reference can be:
•
•
•
•
VREF+ pin
VDD
FVR 2.028V
FVR 4.096V (Not available on LF devices)
The ADNREF bits of the ADCON1 register provides
control of the negative voltage reference. The negative
voltage reference can be:
• VREF- pin
• VSS
See Section 14.0 “Fixed Voltage Reference (FVR)”
for more details on the fixed voltage reference.
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PIC16LF1824T39A
TABLE 16-1:
ADC CLOCK PERIOD (TAD) VS. DEVICE OPERATING FREQUENCIES
ADC Clock Period (TAD)
ADC
Clock Source
Device Frequency (FOSC)
ADCS
32 MHz
20 MHz
16 MHz
8 MHz
4 MHz
1 MHz
000
62.5ns(2)
100 ns(2)
125 ns(2)
250 ns(2)
500 ns(2)
2.0 s
Fosc/4
100
125
ns(2)
ns(2)
ns(2)
ns(2)
Fosc/8
001
0.5 s(2)
400 ns(2)
0.5 s(2)
Fosc/16
101
800 ns
800 ns
1.0 s
Fosc/2
Fosc/32
010
1.0 s
200
1.6 s
250
2.0 s
Fosc/64
110
2.0 s
3.2 s
4.0 s
FRC
x11
1.0-6.0 s(1,4)
1.0-6.0 s(1,4)
1.0-6.0 s(1,4)
Legend:
Note 1:
2:
3:
4:
1.0 s
4.0 s
1.0 s
2.0 s
8.0 s(3)
2.0 s
4.0 s
16.0 s(3)
500
4.0 s
8.0
s(3)
1.0-6.0 s(1,4)
8.0
s(3)
32.0 s(3)
16.0
s(3)
64.0 s(3)
1.0-6.0 s(1,4)
1.0-6.0 s(1,4)
Shaded cells are outside of recommended range.
The FRC source has a typical TAD time of 1.6 s for VDD.
These values violate the minimum required TAD time.
For faster conversion times, the selection of another clock source is recommended.
The ADC clock period (TAD) and total ADC conversion time can be minimized when the ADC clock is derived from the
system clock FOSC. However, the FRC clock source must be used when conversions are to be performed with the
device in Sleep mode.
ANALOG-TO-DIGITAL CONVERSION TAD CYCLES
FIGURE 16-2:
TCY - TAD TAD1 TAD2 TAD3 TAD4 TAD5 TAD6 TAD7 TAD8 TAD9 TAD10 TAD11
b4
b0
b1
b6
b2
b7
b9
b3
b8
b5
Conversion starts
Holding capacitor is disconnected from analog input (typically 100 ns)
Set GO bit
On the following cycle:
ADRESH:ADRESL is loaded, GO bit is cleared,
ADIF bit is set, holding capacitor is connected to analog input.
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PIC16LF1824T39A
16.1.5
INTERRUPTS
16.1.6
The ADC module allows for the ability to generate an
interrupt upon completion of an Analog-to-Digital
conversion. The ADC Interrupt Flag is the ADIF bit in
the PIR1 register. The ADC Interrupt Enable is the
ADIE bit in the PIE1 register. The ADIF bit must be
cleared in software.
RESULT FORMATTING
The 10-bit A/D conversion result can be supplied in two
formats, left justified or right justified. The ADFM bit of
the ADCON1 register controls the output format.
Figure 16-3 shows the two output formats.
Note 1: The ADIF bit is set at the completion of
every conversion, regardless of whether
or not the ADC interrupt is enabled.
2: The ADC operates during Sleep only
when the FRC oscillator is selected.
This interrupt can be generated while the device is
operating or while in Sleep. If the device is in Sleep, the
interrupt will wake-up the device. Upon waking from
Sleep, the next instruction following the SLEEP instruction is always executed. If the user is attempting to
wake-up from Sleep and resume in-line code execution, the GIE and PEIE bits of the INTCON register
must be disabled. If the GIE and PEIE bits of the
INTCON register are enabled, execution will switch to
the Interrupt Service Routine.
Please refer to Section 16.1.5 “Interrupts” for more
information.
FIGURE 16-3:
10-BIT A/D CONVERSION RESULT FORMAT
ADRESH
(ADFM = 0)
ADRESL
MSB
LSB
bit 7
bit 0
bit 7
10-bit A/D Result
bit 0
Unimplemented: Read as ‘0’
MSB
(ADFM = 1)
bit 7
Unimplemented: Read as ‘0’
2012-2017 Microchip Technology Inc.
LSB
bit 0
bit 7
bit 0
10-bit A/D Result
DS40001657C-page 135
PIC16LF1824T39A
16.2
16.2.1
ADC Operation
STARTING A CONVERSION
To enable the ADC module, the ADON bit of the
ADCON0 register must be set to a ‘1’. Setting the GO/
DONE bit of the ADCON0 register to a ‘1’ will start the
Analog-to-Digital conversion.
Note:
16.2.2
The GO/DONE bit should not be set in the
same instruction that turns on the ADC.
Refer to Section 16.2.6 “A/D Conversion Procedure”.
COMPLETION OF A CONVERSION
When the conversion is complete, the ADC module will:
• Clear the GO/DONE bit
• Set the ADIF Interrupt Flag bit
• Update the ADRESH and ADRESL registers with
new conversion result
16.2.3
TERMINATING A CONVERSION
If a conversion must be terminated before completion,
the GO/DONE bit can be cleared in software. The
ADRESH and ADRESL registers will be updated with
the partially complete Analog-to-Digital conversion
sample. Incomplete bits will match the last bit
converted.
Note:
A device Reset forces all registers to their
Reset state. Thus, the ADC module is
turned off and any pending conversion is
terminated.
DS40001657C-page 136
16.2.4
ADC OPERATION DURING SLEEP
The ADC module can operate during Sleep. This
requires the ADC clock source to be set to the FRC
option. When the FRC clock source is selected, the
ADC waits one additional instruction before starting the
conversion. This allows the SLEEP instruction to be
executed, which can reduce system noise during the
conversion. If the ADC interrupt is enabled, the device
will wake-up from Sleep when the conversion
completes. If the ADC interrupt is disabled, the ADC
module is turned off after the conversion completes,
although the ADON bit remains set.
When the ADC clock source is something other than
FRC, a SLEEP instruction causes the present conversion to be aborted and the ADC module is turned off,
although the ADON bit remains set.
16.2.5
SPECIAL EVENT TRIGGER
The Special Event Trigger of the CCPx/ECCPX module
allows periodic ADC measurements without software
intervention. When this trigger occurs, the GO/DONE
bit is set by hardware and the Timer1 counter resets to
zero.
TABLE 16-2:
SPECIAL EVENT TRIGGER
Device
CCPx/ECCPx
PIC16LF1824T39A
CCP4
Using the Special Event Trigger does not assure proper
ADC timing. It is the user’s responsibility to ensure that
the ADC timing requirements are met.
Refer to Section 24.0 “Capture/Compare/PWM
Modules” for more information.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
16.2.6
A/D CONVERSION PROCEDURE
This is an example procedure for using the ADC to
perform an Analog-to-Digital conversion:
1.
2.
3.
4.
5.
6.
7.
8.
Configure Port:
• Disable pin output driver (Refer to the TRIS
register)
• Configure pin as analog (Refer to the ANSEL
register)
Configure the ADC module:
• Select ADC conversion clock
• Configure voltage reference
• Select ADC input channel
• Turn on ADC module
Configure ADC interrupt (optional):
• Clear ADC interrupt flag
• Enable ADC interrupt
• Enable peripheral interrupt
• Enable global interrupt(1)
Wait the required acquisition time(2).
Start conversion by setting the GO/DONE bit.
Wait for ADC conversion to complete by one of
the following:
• Polling the GO/DONE bit
• Waiting for the ADC interrupt (interrupts
enabled)
Read ADC Result.
Clear the ADC interrupt flag (required if interrupt
is enabled).
EXAMPLE 16-1:
A/D CONVERSION
;This code block configures the ADC
;for polling, Vdd and Vss references, Frc
;clock and AN0 input.
;
;Conversion start & polling for completion
; are included.
;
BANKSEL
ADCON1
;
MOVLW
B’11110000’ ;Right justify, Frc
;clock
MOVWF
ADCON1
;Vdd and Vss Vref
BANKSEL
TRISA
;
BSF
TRISA,0
;Set RA0 to input
BANKSEL
ANSELA
;
BSF
ANSELA,0
;Set RA0 to analog
BANKSEL
ADCON0
;
MOVLW
B’00000001’ ;Select channel AN0
MOVWF
ADCON0
;Turn ADC On
CALL
SampleTime
;Acquisiton delay
BSF
ADCON0,ADGO ;Start conversion
BTFSC
ADCON0,ADGO ;Is conversion done?
GOTO
$-1
;No, test again
BANKSEL
ADRESH
;
MOVF
ADRESH,W
;Read upper 2 bits
MOVWF
RESULTHI
;store in GPR space
BANKSEL
ADRESL
;
MOVF
ADRESL,W
;Read lower 8 bits
MOVWF
RESULTLO
;Store in GPR space
Note 1: The global interrupt can be disabled if the
user is attempting to wake-up from Sleep
and resume in-line code execution.
2: Refer to Section 16.3 “A/D Acquisition
Requirements”.
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PIC16LF1824T39A
16.2.7
ADC REGISTER DEFINITIONS
The following registers are used to control the
operation of the ADC.
REGISTER 16-1:
U-0
ADCON0: A/D CONTROL REGISTER 0
R/W-0/0
R/W-0/0
—
R/W-0/0
R/W-0/0
CHS
R/W-0/0
R/W-0/0
R/W-0/0
GO/DONE
ADON
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
Unimplemented: Read as ‘0’
bit 6-2
CHS: Analog Channel Select bits
00000 = AN0
00001 = AN1
00010 = AN2
00011 = AN3
00100 = AN4
00101 = AN5
00110 = AN6
00111 = AN7
01100 = Reserved. No channel connected
•
•
•
11100 = Reserved. No channel connected
11101 = Temperature Indicator
11110 = DAC_output(1)
11111 = FVR (Fixed Voltage Reference) Buffer 1 Output(2)
bit 1
GO/DONE: A/D Conversion Status bit
1 = A/D conversion cycle in progress. Setting this bit starts an A/D conversion cycle.
This bit is automatically cleared by hardware when the A/D conversion has completed.
0 = A/D conversion completed/not in progress
bit 0
ADON: ADC Enable bit
1 = ADC is enabled
0 = ADC is disabled and consumes no operating current
Note 1:
2:
See Section 17.0 “Digital-to-Analog Converter (DAC) Module” for more information.
See Section 14.0 “Fixed Voltage Reference (FVR)” for more information.
DS40001657C-page 138
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PIC16LF1824T39A
REGISTER 16-2:
R/W-0/0
ADCON1: A/D CONTROL REGISTER 1
R/W-0/0
ADFM
R/W-0/0
R/W-0/0
ADCS
U-0
R/W-0/0
—
ADNREF
R/W-0/0
R/W-0/0
ADPREF
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
ADFM: A/D Result Format Select bit
1 = Right justified. Six Most Significant bits of ADRESH are set to ‘0’ when the conversion result is
loaded.
0 = Left justified. Six Least Significant bits of ADRESL are set to ‘0’ when the conversion result is
loaded.
bit 6-4
ADCS: A/D Conversion Clock Select bits
000 = FOSC/2
001 = FOSC/8
010 = FOSC/32
011 = FRC (clock supplied from a dedicated RC oscillator)
100 = FOSC/4
101 = FOSC/16
110 = FOSC/64
111 = FRC (clock supplied from a dedicated RC oscillator)
bit 3
Unimplemented: Read as ‘0’
bit 2
ADNREF: A/D Negative Voltage Reference Configuration bit
0 = VREF- is connected to VSS
1 = VREF- is connected to external VREF- pin(1)
bit 1-0
ADPREF: A/D Positive Voltage Reference Configuration bits
00 = VREF+ is connected to VDD
01 = Reserved
10 = VREF+ is connected to external VREF+ pin(1)
11 = VREF+ is connected to internal Fixed Voltage Reference (FVR) module
Note 1:
When selecting the FVR or the VREF+ pin as the source of the positive reference, be aware that a
minimum voltage specification exists. See Section 31.0 “Electrical Specifications” for details.
2012-2017 Microchip Technology Inc.
DS40001657C-page 139
PIC16LF1824T39A
REGISTER 16-3:
R/W-x/u
ADRESH: ADC RESULT REGISTER HIGH (ADRESH) ADFM = 0
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
ADRES
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-0
ADRES: ADC Result Register bits
Upper eight bits of 10-bit conversion result
REGISTER 16-4:
R/W-x/u
ADRESL: ADC RESULT REGISTER LOW (ADRESL) ADFM = 0
R/W-x/u
ADRES
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
—
—
—
—
—
—
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
ADRES: ADC Result Register bits
Lower two bits of 10-bit conversion result
bit 5-0
Reserved: Do not use.
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PIC16LF1824T39A
REGISTER 16-5:
ADRESH: ADC RESULT REGISTER HIGH (ADRESH) ADFM = 1
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
—
—
—
—
—
—
R/W-x/u
R/W-x/u
ADRES
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-2
Reserved: Do not use.
bit 1-0
ADRES: ADC Result Register bits
Upper two bits of 10-bit conversion result
REGISTER 16-6:
R/W-x/u
ADRESL: ADC RESULT REGISTER LOW (ADRESL) ADFM = 1
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
ADRES
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-0
ADRES: ADC Result Register bits
Lower eight bits of 10-bit conversion result
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DS40001657C-page 141
PIC16LF1824T39A
16.3
A/D Acquisition Requirements
For the ADC to meet its specified accuracy, the charge
holding capacitor (CHOLD) must be allowed to fully
charge to the input channel voltage level. The Analog
Input model is shown in Figure 16-4. The source
impedance (RS) and the internal sampling switch (RSS)
impedance directly affect the time required to charge
the capacitor CHOLD. The sampling switch (RSS)
impedance varies over the device voltage (VDD), refer
to Figure 16-4. The maximum recommended
impedance for analog sources is 10 k. As the
EQUATION 16-1:
Assumptions:
source impedance is decreased, the acquisition time
may be decreased. After the analog input channel is
selected (or changed), an A/D acquisition must be
done before the conversion can be started. To calculate
the minimum acquisition time, Equation 16-1 may be
used. This equation assumes that 1/2 LSb error is used
(1,024 steps for the ADC). The 1/2 LSb error is the
maximum error allowed for the ADC to meet its
specified resolution.
ACQUISITION TIME EXAMPLE
Temperature = 50°C and external impedance of 10k 5.0V V DD
T ACQ = Amplifier Settling Time + Hold Capacitor Charging Time + Temperature Coefficient
= T AMP + T C + T COFF
= 2µs + T C + Temperature - 25°C 0.05µs/°C
The value for TC can be approximated with the following equations:
1
= V CHOLD
V APPLIED 1 – -------------------------n+1
2
–1
;[1] VCHOLD charged to within 1/2 lsb
–T C
----------
RC
V APPLIED 1 – e = V CHOLD
;[2] VCHOLD charge response to VAPPLIED
– Tc
---------
1
RC
;combining [1] and [2]
V APPLIED 1 – e = V APPLIED 1 – -------------------------n+1
2
–1
Note: Where n = number of bits of the ADC.
Solving for TC:
T C = – C HOLD R IC + R SS + R S ln(1/2047)
= – 12.5pF 1k + 7k + 10k ln(0.0004885)
= 1.12 µs
Therefore:
T ACQ = 2 µs + 1.12 µs + 50°C- 25°C 0.05 µs/°C
= 7.37µs
Note 1: The reference voltage (VREF) has no effect on the equation, since it cancels itself out.
2: The charge holding capacitor (CHOLD) is not discharged after each conversion.
3: The maximum recommended impedance for analog sources is 10 k. This is required to meet the pin
leakage specification.
DS40001657C-page 142
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 16-4:
ANALOG INPUT MODEL
VDD
Analog
Input
pin
Rs
VT 0.6V
CPIN
5 pF
VA
RIC 1k
Sampling
Switch
SS Rss
I LEAKAGE(1)
VT 0.6V
CHOLD = 10 pF
ref-
Legend: CHOLD
CPIN
6V
5V
VDD 4V
3V
2V
= Sample/Hold Capacitance
= Input Capacitance
RSS
I LEAKAGE = Leakage current at the pin due to
various junctions
= Interconnect Resistance
RIC
RSS
= Resistance of Sampling Switch
SS
= Sampling Switch
VT
= Threshold Voltage
5 6 7 8 9 10 11
Sampling Switch
(k)
Note 1: Refer to Section 31.0 “Electrical Specifications”.
FIGURE 16-5:
ADC TRANSFER FUNCTION
Full-Scale Range
3FFh
3FEh
ADC Output Code
3FDh
3FCh
3FBh
03h
02h
01h
00h
Analog Input Voltage
0.5 LSB
ref-
2012-2017 Microchip Technology Inc.
Zero-Scale
Transition
1.5 LSB
Full-Scale
Transition
ref+
DS40001657C-page 143
PIC16LF1824T39A
TABLE 16-3:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH ADC
Bit 7
Bit 6
ADCON0
—
CHS4
ADCON1
ADFM
Bit 5
Bit 4
Bit 3
CHS3
CHS2
ADCS
ADRESH
A/D Result Register High
ADRESL
A/D Result Register Low
Bit 2
Bit 1
Bit 0
CHS1
CHS0
GO/DONE
ADON
—
ADNREF
ADPREF
Register on
Page
138
139
140, 154
140, 154
ANSELA
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
118
ANSELC
—
—
—
—
ANSC3
ANSC2
ANSC1
ANSC0
124
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
125
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISC3
TRISC2
TRISC1
TRISC0
123
TRISA
—
—
TRISA5
TRISC
—
—
TRISC5
TRISC4
FVRCON
FVREN
FVRRDY
TSEN
TSRNG
CDAFVR
DACCON0
DACEN
DACLPS
DACOE
—
DACPSS
—
—
—
DACCON1
Legend:
DACR
ADFVR
—
DACNSS
130
148
148
x = unknown, u = unchanged, — = unimplemented, read as ‘0’, q = value depends on condition. Shaded cells are not used for ADC
module.
DS40001657C-page 144
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PIC16LF1824T39A
17.0
DIGITAL-TO-ANALOG
CONVERTER (DAC) MODULE
The Digital-to-Analog Converter supplies a variable
voltage reference, ratiometric with the input source,
with 32 selectable output levels.
The input of the DAC can be connected to:
• External VREF pins
• VDD supply voltage
• FVR (Fixed Voltage Reference)
The output of the DAC can be configured to supply a
reference voltage to the following:
17.3
DAC Voltage Reference Output
The DAC can be output to the DACOUT pin by setting
the DACOE bit of the DACCON0 register to ‘1’. Selecting
the DAC reference voltage for output on the DACOUT
pin automatically overrides the digital output buffer and
digital input threshold detector functions of that pin.
Reading the DACOUT pin when it has been configured
for DAC reference voltage output will always return a ‘0’.
Due to the limited current drive capability, a buffer must
be used on the DAC voltage reference output for
external connections to DACOUT. Figure 17-2 shows
an example buffering technique.
• Comparator positive input
• ADC input channel
• DACOUT pin
The Digital-to-Analog Converter (DAC) can be enabled
by setting the DACEN bit of the DACCON0 register.
17.1
Output Voltage Selection
The DAC has 32 voltage level ranges. The 32 levels
are set with the DACR bits of the DACCON1
register.
The DAC output voltage is determined by the following
equations:
EQUATION 17-1:
DAC OUTPUT VOLTAGE
DACR
VOUT = VSOURCE+ – VSOURCE- ------------------------------- + VSRC
5
2
Note:
17.2
VSOURCE+ can equal FVR Buffer 2, VDD or
VREF+. VSOURCE- can equal VSS or VREF-.
Ratiometric Output Level
The DAC output value is derived using a resistor ladder
with each end of the ladder tied to a positive and
negative voltage reference input source. If the voltage
of either input source fluctuates, a similar fluctuation will
result in the DAC output value.
The value of the individual resistors within the ladder
can be found in Section 31.0 “Electrical
Specifications”.
2012-2017 Microchip Technology Inc.
DS40001657C-page 145
PIC16LF1824T39A
FIGURE 17-1:
DIGITAL-TO-ANALOG CONVERTER BLOCK DIAGRAM
Digital-to-Analog Converter (DAC)
FVR BUFFER2
VSRC+
VDD
VREF+
R
R
2
R
DACEN
DACLPS
R
R
32
Steps
R
32-to-1 MUX
DACPSS
DACR
5
DAC_output
R
DACOUT
R
DACNSS
(to Comparator, CSM
and ADC modules)
DACOE
1
VREF-
VSRC-
VSS
FIGURE 17-2:
VOLTAGE REFERENCE OUTPUT BUFFER EXAMPLE
PIC® MCU
DAC
Module
R
Voltage
Reference
Output
Impedance
DS40001657C-page 146
DACOUT
+
–
Buffered DAC Output
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
17.4
Low-Power Voltage State
In order for the DAC module to consume the least
amount of power, one of the two voltage reference input
sources to the resistor ladder must be disconnected.
Either the positive voltage source, (VSRC+), or the
negative voltage source, (VSRC-) can be disabled.
The negative voltage source is disabled by setting the
DACLPS bit in the DACCON0 register. Clearing the
DACLPS bit in the DACCON0 register disables the
positive voltage source.
17.4.1
OUTPUT CLAMPED TO POSITIVE
VOLTAGE SOURCE
The DAC output voltage can be set to VSRC+ with the
least amount of power consumption by performing the
following:
• Clearing the DACEN bit in the DACCON0 register.
• Setting the DACLPS bit in the DACCON0 register.
• Configuring the DACPSS bits to the proper
positive source.
• Configuring the DACR bits to ‘11111’ in the
DACCON1 register.
FIGURE 17-3:
This is also the method used to output the voltage level
from the FVR to an output pin. See Figure 17-2 for more
information.
Reference Figure 17-3 for output clamping examples.
17.4.2
OUTPUT CLAMPED TO NEGATIVE
VOLTAGE SOURCE
The DAC output voltage can be set to VSRC- with the
least amount of power consumption by performing the
following:
• Clearing the DACEN bit in the DACCON0 register.
• Clearing the DACLPS bit in the DACCON0 register.
• Configuring the DACNSS bits to the proper
negative source.
• Configuring the DACR bits to ‘00000’ in the
DACCON1 register.
This allows the comparator to detect a zero-crossing
while not consuming additional current through the DAC
module.
Reference Figure 17-3 for output clamping examples.
OUTPUT VOLTAGE CLAMPING EXAMPLES
Output Clamped to Positive Voltage Source
VSRC+
Output Clamped to Negative Voltage Source
VSRC+
R
R
DACR = 11111
R
DACEN = 0
DACLPS = 1
R
DAC Voltage Ladder
(see Figure 17-1)
DACEN = 0
DACLPS = 0
R
VSRC-
17.5
DAC Voltage Ladder
(see Figure 17-1)
R
DACR = 00000
VSRC-
Operation During Sleep
When the device wakes up from Sleep through an
interrupt or a Watchdog Timer time-out, the contents of
the DACCON0 register are not affected. To minimize
current consumption in Sleep mode, the voltage
reference should be disabled.
17.6
Effects of a Reset
A device Reset affects the following:
• DAC is disabled.
• DAC output voltage is removed from the
DACOUT pin.
• The DACR range select bits are cleared.
2012-2017 Microchip Technology Inc.
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PIC16LF1824T39A
REGISTER 17-1:
DACCON0: VOLTAGE REFERENCE CONTROL REGISTER 0
R/W-0/0
R/W-0/0
R/W-0/0
U-0
DACEN
DACLPS
DACOE
—
R/W-0/0
R/W-0/0
U-0
R/W-0/0
—
DACNSS
DACPSS
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
DACEN: DAC Enable bit
1 = DAC is enabled
0 = DAC is disabled
bit 6
DACLPS: DAC Low-Power Voltage State Select bit
1 = DAC Positive reference source selected
0 = DAC Negative reference source selected
bit 5
DACOE: DAC Voltage Output Enable bit
1 = DAC voltage level is also an output on the DACOUT pin
0 = DAC voltage level is disconnected from the DACOUT pin
bit 4
Unimplemented: Read as ‘0’
bit 3-2
DACPSS: DAC Positive Source Select bits
00 = VDD
01 = VREF+
10 = FVR Buffer2 output
11 = Reserved, do not use
bit 1
Unimplemented: Read as ‘0’
bit 0
DACNSS: DAC Negative Source Select bit
1 = VREF0 = VSS
REGISTER 17-2:
DACCON1: VOLTAGE REFERENCE CONTROL REGISTER 1
U-0
U-0
U-0
—
—
—
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
DACR
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-5
Unimplemented: Read as ‘0’
bit 4-0
DACR: DAC Voltage Output Select bits
VOUT = ((VSRC+) - (VSRC-))*(DACR/(25)) + VSRC-
Note 1:
The output select bits are always right justified to ensure that any number of bits can be used without
affecting the register layout.
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PIC16LF1824T39A
TABLE 17-1:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH THE DAC MODULE
Bit 7
Bit 6
Bit 5
Bit 4
FVRCON
FVREN
FVRRDY
TSEN
TSRNG
CDAFVR
DACCON0
DACEN
DACLPS
DACOE
—
DACPSS
DACCON1
—
—
—
Legend:
Bit 3
Bit 2
DACR
Bit 1
Bit 0
ADFVR
—
DACNSS
Register
on page
130
148
148
— = unimplemented, read as ‘0’. Shaded cells are unused by the DAC module.
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PIC16LF1824T39A
18.0
SR LATCH
The module consists of a single SR latch with multiple
Set and Reset inputs as well as separate latch outputs.
The SR latch module includes the following features:
•
•
•
•
Programmable input selection
SR latch output is available externally
Separate Q and Q outputs
Firmware Set and Reset
The SR latch can be used in a variety of analog applications, including oscillator circuits, one-shot circuit,
hysteretic controllers, and analog timing applications.
18.1
Latch Operation
18.2
Latch Output
The SRQEN and SRNQEN bits of the SRCON0
register control the Q and Q latch outputs. Both of the
SR latch outputs may be directly output to an I/O pin at
the same time.
The applicable TRIS bit of the corresponding port must
be cleared to enable the port pin output driver.
18.3
Effects of a Reset
Upon any device Reset, the SR latch output is not
initialized to a known state. The user’s firmware is
responsible for initializing the latch output before
enabling the output pins.
The latch is a Set-Reset latch that does not depend on a
clock source. Each of the Set and Reset inputs are
active-high. The latch can be Set or Reset by:
•
•
•
•
•
Software control (SRPS and SRPR bits)
Comparator C1 output (SYNCC1OUT)
Comparator C2 output (SYNCC2OUT)
SRI pin
Programmable clock (SRCLK)
The SRPS and the SRPR bits of the SRCON0 register
may be used to Set or Reset the SR latch, respectively.
The latch is Reset-dominant. Therefore, if both Set and
Reset inputs are high, the latch will go to the Reset
state. Both the SRPS and SRPR bits are self resetting
which means that a single write to either of the bits is all
that is necessary to complete a latch Set or Reset
operation.
The output from Comparator C1 or C2 can be used as
the Set or Reset inputs of the SR latch. The output of
either Comparator can be synchronized to the Timer1
clock source. See Section 19.0 “Comparator
Module” and Section 21.0 “Timer1 Module with
Gate Control” for more information.
An external source on the SRI pin can be used as the
Set or Reset inputs of the SR latch.
An internal clock source is available that can periodically
set or reset the SR latch. The SRCLK bits in the
SRCON0 register are used to select the clock source
period. The SRSCKE and SRRCKE bits of the SRCON1
register enable the clock source to Set or Reset the SR
latch, respectively.
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PIC16LF1824T39A
FIGURE 18-1:
SR LATCH SIMPLIFIED BLOCK DIAGRAM
SRPS
Pulse
Gen(2)
SRLEN
SRQEN
SRI
S
SRSPE
SRCLK
Q
SRQ
SRSCKE
SYNCC2OUT(3)
SRSC2E
SYNCC1OUT(3)
SRSC1E
SRPR
SR
Latch(1)
Pulse
Gen(2)
SRI
R
SRRPE
SRCLK
Q
SRNQ
SRRCKE
SYNCC2OUT(3)
SRRC2E
SRLEN
SRNQEN
SYNCC1OUT(3)
SRRC1E
Note 1:
2:
3:
If R = 1 and S = 1 simultaneously, Q = 0, Q = 1
Pulse generator causes a 1 Q-state pulse width.
Name denotes the connection point at the comparator output.
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TABLE 18-1:
SRCLK FREQUENCY TABLE
SRCLK
Divider
FOSC = 32 MHz
111
512
62.5 kHz
39.0 kHz
31.3 kHz
7.81 kHz
1.95 kHz
110
256
125 kHz
78.1 kHz
62.5 kHz
15.6 kHz
3.90 kHz
101
128
250 kHz
156 kHz
125 kHz
31.25 kHz
7.81 kHz
100
64
500 kHz
313 kHz
250 kHz
62.5 kHz
15.6 kHz
011
32
1 MHz
625 kHz
500 kHz
125 kHz
31.3 kHz
010
16
2 MHz
1.25 MHz
1 MHz
250 kHz
62.5 kHz
001
8
4 MHz
2.5 MHz
2 MHz
500 kHz
125 kHz
000
4
8 MHz
5 MHz
4 MHz
1 MHz
250 kHz
REGISTER 18-1:
R/W-0/0
FOSC = 16 MHz
FOSC = 4 MHz
FOSC = 1 MHz
SRCON0: SR LATCH CONTROL 0 REGISTER
R/W-0/0
SRLEN
FOSC = 20 MHz
R/W-0/0
R/W-0/0
SRCLK
R/W-0/0
R/W-0/0
R/S-0/0
R/S-0/0
SRQEN
SRNQEN
SRPS
SRPR
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
S = Bit is set only
bit 7
SRLEN: SR Latch Enable bit
1 = SR latch is enabled
0 = SR latch is disabled
bit 6-4
SRCLK: SR Latch Clock Divider bits
000 = Generates a 1 FOSC wide pulse every 4th FOSC cycle clock
001 = Generates a 1 FOSC wide pulse every 8th FOSC cycle clock
010 = Generates a 1 FOSC wide pulse every 16th FOSC cycle clock
011 = Generates a 1 FOSC wide pulse every 32nd FOSC cycle clock
100 = Generates a 1 FOSC wide pulse every 64th FOSC cycle clock
101 = Generates a 1 FOSC wide pulse every 128th FOSC cycle clock
110 = Generates a 1 FOSC wide pulse every 256th FOSC cycle clock
111 = Generates a 1 FOSC wide pulse every 512th FOSC cycle clock
bit 3
SRQEN: SR Latch Q Output Enable bit
If SRLEN = 1:
1 = Q is present on the SRQ pin
0 = External Q output is disabled
If SRLEN = 0:
SR latch is disabled
bit 2
SRNQEN: SR Latch Q Output Enable bit
If SRLEN = 1:
1 = Q is present on the SRnQ pin
0 = External Q output is disabled
If SRLEN = 0:
SR latch is disabled
bit 1
SRPS: Pulse Set Input of the SR Latch bit(1)
1 = Pulse set input for 1 Q-clock period
0 = No effect on set input
bit 0
SRPR: Pulse Reset Input of the SR Latch bit(1)
1 = Pulse reset input for 1 Q-clock period
0 = No effect on Reset input
Note 1:
Set only, always reads back ‘0’.
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PIC16LF1824T39A
REGISTER 18-2:
SRCON1: SR LATCH CONTROL 1 REGISTER
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
SRSPE
SRSCKE
SRSC2E
SRSC1E
SRRPE
SRRCKE
SRRC2E
SRRC1E
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
SRSPE: SR Latch Peripheral Set Enable bit
1 = SR latch is set when the SRI pin is high
0 = SRI pin has no effect on the set input of the SR latch
bit 6
SRSCKE: SR Latch Set Clock Enable bit
1 = Set input of SR latch is pulsed with SRCLK
0 = SRCLK has no effect on the set input of the SR latch
bit 5
SRSC2E: SR Latch C2 Set Enable bit
1 = SR latch is set when the C2 Comparator output is high
0 = C2 Comparator output has no effect on the set input of the SR latch
bit 4
SRSC1E: SR Latch C1 Set Enable bit
1 = SR latch is set when the C1 Comparator output is high
0 = C1 Comparator output has no effect on the set input of the SR latch
bit 3
SRRPE: SR Latch Peripheral Reset Enable bit
1 = SR latch is reset when the SRI pin is high
0 = SRI pin has no effect on the Reset input of the SR latch
bit 2
SRRCKE: SR Latch Reset Clock Enable bit
1 = Reset input of SR latch is pulsed with SRCLK
0 = SRCLK has no effect on the Reset input of the SR latch
bit 1
SRRC2E: SR Latch C2 Reset Enable bit
1 = SR latch is reset when the C2 Comparator output is high
0 = C2 Comparator output has no effect on the Reset input of the SR latch
bit 0
SRRC1E: SR Latch C1 Reset Enable bit
1 = SR latch is reset when the C1 Comparator output is high
0 = C1 Comparator output has no effect on the Reset input of the SR latch
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TABLE 18-2:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH SR LATCH MODULE
Register
on Page
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
ANSELA
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
118
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
SRQEN
SRNQEN
SRPS
SRPR
152
152
INLVLC
SRCON0
SRLEN
SRCON1
SRSPE
SRSCKE
SRSC2E
SRSC1E
SRRPE
SRRCKE
SRRC2E
SRRC1E
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
Legend:
SRCLK
— = unimplemented, read as ‘0’. Shaded cells are unused by the SR latch module.
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PIC16LF1824T39A
19.0
COMPARATOR MODULE
FIGURE 19-1:
Comparators are used to interface analog circuits to a
digital circuit by comparing two analog voltages and
providing a digital indication of their relative magnitudes.
Comparators are very useful mixed signal building
blocks because they provide analog functionality
independent of program execution. The analog
comparator module includes the following features:
•
•
•
•
•
•
•
•
•
VIN+
+
VIN-
–
Output
VINVIN+
Independent comparator control
Programmable input selection
Comparator output is available internally/externally
Programmable output polarity
Interrupt-on-change
Wake-up from Sleep
Programmable Speed/Power optimization
PWM shutdown
Programmable and fixed voltage reference
19.1
SINGLE COMPARATOR
Output
Note:
The black areas of the output of the
comparator represents the uncertainty
due to input offsets and response time.
Comparator Overview
A single comparator is shown in Figure 19-1 along with
the relationship between the analog input levels and
the digital output. When the analog voltage at VIN+ is
less than the analog voltage at VIN-, the output of the
comparator is a digital low level. When the analog
voltage at VIN+ is greater than the analog voltage at
VIN-, the output of the comparator is a digital high level.
FIGURE 19-2:
COMPARATOR MODULE SIMPLIFIED BLOCK DIAGRAM
CxNCH
CxON(1)
2
CxINTP
Interrupt
det
C12IN0-
0
C12IN1-
1
MUX
2 (1)
C12IN2C12IN3-
3
Set CxIF
det
CXPOL
CxVN
D
Cx(2)
CxVP
DAC_output
0
MUX
1 (1)
FVR Buffer2
2
CXIN+
CXOUT
MCXOUT
Q
To Data Bus
+
EN
Q1
CxHYS
CxSP
async_CxOUT
3
To ECCP PWM Logic
CXSYNC
CxON(1)
VSS
CxINTN
Interrupt
CXPCH
CXOE
TRIS bit
CXOUT
0
2
D
(from Timer1)
T1CLK
Note
1:
2:
Q
1
sync_CxOUT
To Timer1,
SR Latch
When CxON = 0, all multiplexer inputs are disconnected and the Comparator will produce a ‘0’ at the output.
Output of comparator can be frozen during debugging.
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19.2
Comparator Control
Each comparator has two control registers: CMxCON0
and CMxCON1.
The CMxCON0 registers (see Register 19-1) contain
Control and Status bits for the following:
•
•
•
•
•
•
Enable
Output selection
Output polarity
Speed/Power selection
Hysteresis enable
Output synchronization
The CMxCON1 registers (see Register 19-2) contain
Control bits for the following:
•
•
•
•
Interrupt enable
Interrupt edge polarity
Positive input channel selection
Negative input channel selection
19.2.1
COMPARATOR ENABLE
Setting the CxON bit of the CMxCON0 register enables
the comparator for operation. Clearing the CxON bit
disables the comparator resulting in minimum current
consumption.
19.2.2
COMPARATOR OUTPUT
SELECTION
19.2.3
COMPARATOR OUTPUT POLARITY
Inverting the output of the comparator is functionally
equivalent to swapping the comparator inputs. The
polarity of the comparator output can be inverted by
setting the CxPOL bit of the CMxCON0 register.
Clearing the CxPOL bit results in a non-inverted output.
Table 19-1 shows the output state versus input
conditions, including polarity control.
TABLE 19-1:
COMPARATOR OUTPUT
STATE VS. INPUT
CONDITIONS
Input Condition
CxPOL
CxOUT
CxVN > CxVP
0
0
CxVN < CxVP
0
1
CxVN > CxVP
1
1
CxVN < CxVP
1
0
19.2.4
COMPARATOR SPEED/POWER
SELECTION
The trade-off between speed or power can be
optimized during program execution with the CxSP
control bit. The default state for this bit is ‘1’ which
selects the normal speed mode. Device power
consumption can be optimized at the cost of slower
comparator propagation delay by clearing the CxSP bit
to ‘0’.
The output of the comparator can be monitored by
reading either the CxOUT bit of the CMxCON0 register
or the MCxOUT bit of the CMOUT register. In order to
make the output available for an external connection,
the following conditions must be true:
• CxOE bit of the CMxCON0 register must be set
• Corresponding TRIS bit must be cleared
• CxON bit of the CMxCON0 register must be set
Note 1: The CxOE bit of the CMxCON0 register
overrides the PORT data latch. Setting
the CxON bit of the CMxCON0 register
has no impact on the port override.
2: The internal output of the comparator is
latched with each instruction cycle.
Unless otherwise specified, external
outputs are not latched.
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PIC16LF1824T39A
19.3
Comparator Hysteresis
A selectable amount of separation voltage can be
added to the input pins of each comparator to provide a
hysteresis function to the overall operation. Hysteresis
is enabled by setting the CxHYS bit of the CMxCON0
register.
See Section 31.0 “Electrical Specifications” for
more information.
19.4
Timer1 Gate Operation
The output resulting from a comparator operation can
be used as a source for gate control of Timer1. See
Section 21.6 “Timer1 Gate” for more information.
This feature is useful for timing the duration or interval
of an analog event.
It is recommended that the comparator output be
synchronized to Timer1. This ensures that Timer1 does
not increment while a change in the comparator is
occurring.
19.4.1
COMPARATOR OUTPUT
SYNCHRONIZATION
The output from either comparator, C1 or C2, can be
synchronized with Timer1 by setting the CxSYNC bit of
the CMxCON0 register.
Once enabled, the comparator output is latched on the
falling edge of the Timer1 source clock. If a prescaler is
used with Timer1, the comparator output is latched after
the prescaling function. To prevent a race condition, the
comparator output is latched on the falling edge of the
Timer1 clock source and Timer1 increments on the
rising edge of its clock source. See the Comparator
Block Diagrams (Figure 19-2 and Figure 19-2) and the
Timer1 Block Diagram (Figure 20-1) for more
information.
19.5
Comparator Interrupt
An interrupt can be generated upon a change in the
output value of the comparator for each comparator, a
rising edge detector and a falling edge detector are
present.
When either edge detector is triggered and its
associated enable bit is set (CxINTP and/or CxINTN
bits of the CMxCON1 register), the Corresponding
Interrupt Flag bit (CxIF bit of the PIR2 register) will be
set.
To enable the interrupt, you must set the following bits:
• CxON, CxPOL and CxSP bits of the CMxCON0
register
• CxIE bit of the PIE2 register
• CxINTP bit of the CMxCON1 register (for a rising
edge detection)
• CxINTN bit of the CMxCON1 register (for a falling
edge detection)
• PEIE and GIE bits of the INTCON register
The associated interrupt flag bit, CxIF bit of the PIR2
register, must be cleared in software. If another edge is
detected while this flag is being cleared, the flag will still
be set at the end of the sequence.
Note:
19.6
Although a comparator is disabled, an
interrupt can be generated by changing
the output polarity with the CxPOL bit of
the CMxCON0 register, or by switching
the comparator on or off with the CxON bit
of the CMxCON0 register.
Comparator Positive Input
Selection
Configuring the CxPCH bits of the CMxCON1
register directs an internal voltage reference or an
analog pin to the non-inverting input of the comparator:
•
•
•
•
CxIN+ analog pin
DAC_output
DAC FVR Buffer2
VSS (Ground)
See Section 14.0 “Fixed Voltage Reference (FVR)”
for more information on the Fixed Voltage Reference
module.
See Section 17.0 “Digital-to-Analog Converter
(DAC) Module” for more information on the DAC input
signal.
Any time the comparator is disabled (CxON = 0), all
comparator inputs are disabled.
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19.7
Comparator Negative Input
Selection
The CxNCH bits of the CMxCON0 register direct
one of four analog pins to the comparator inverting
input.
Note:
19.8
To use CxIN+ and CxINx- pins as analog
input, the appropriate bits must be set in
the ANSEL register and the corresponding TRIS bits must also be set to disable
the output drivers.
Comparator Response Time
The comparator output is indeterminate for a period of
time after the change of an input source or the selection
of a new reference voltage. This period is referred to as
the response time. The response time of the comparator
differs from the settling time of the voltage reference.
Therefore, both of these times must be considered when
determining the total response time to a comparator
input change. See the Comparator and Voltage Reference Specifications in Section 31.0 “Electrical Specifications” for more details.
19.9
Interaction with ECCP Logic
19.10 Analog Input Connection
Considerations
A simplified circuit for an analog input is shown in
Figure 19-3. Since the analog input pins share their
connection with a digital input, they have reverse
biased ESD protection diodes to VDD and VSS. The
analog input, therefore, must be between VSS and VDD.
If the input voltage deviates from this range by more
than 0.6V in either direction, one of the diodes is
forward biased and a latch-up may occur.
A maximum source impedance of 10 k is recommended
for the analog sources. Also, any external component
connected to an analog input pin, such as a capacitor or
a Zener diode, should have very little leakage current to
minimize inaccuracies introduced.
Note 1: When reading a PORT register, all pins
configured as analog inputs will read as a
‘0’. Pins configured as digital inputs will
convert as an analog input, according to
the input specification.
2: Analog levels on any pin defined as a
digital input, may cause the input buffer to
consume more current than is specified.
The C1 and C2 comparators can be used as general
purpose comparators. Their outputs can be brought
out to the C1OUT and C2OUT pins. When the ECCP
Auto-Shutdown is active it can use one or both
comparator signals. If auto-restart is also enabled, the
comparators can be configured as a closed loop
analog feedback to the ECCP, thereby, creating an
analog controlled PWM.
Note:
When the comparator module is first
initialized the output state is unknown.
Upon initialization, the user should verify
the output state of the comparator prior to
relying on the result, primarily when using
the result in connection with other
peripheral features, such as the ECCP
Auto-Shutdown mode.
DS40001657C-page 158
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PIC16LF1824T39A
FIGURE 19-3:
ANALOG INPUT MODEL
VDD
Rs < 10K
Analog
Input
pin
VT 0.6V
RIC
To Comparator
VA
CPIN
5 pF
VT 0.6V
ILEAKAGE(1)
Vss
Legend: CPIN
= Input Capacitance
ILEAKAGE = Leakage Current at the pin due to various junctions
RIC
= Interconnect Resistance
= Source Impedance
RS
VA
= Analog Voltage
= Threshold Voltage
VT
Note 1:
See Section 31.0 “Electrical Specifications”.
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REGISTER 19-1:
CMxCON0: COMPARATOR Cx CONTROL REGISTER 0
R/W-0/0
R-0/0
R/W-0/0
R/W-0/0
U-0
R/W-1/1
R/W-0/0
R/W-0/0
CxON
CxOUT
CxOE
CxPOL
—
CxSP
CxHYS
CxSYNC
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
CxON: Comparator Enable bit
1 = Comparator is enabled and consumes no active power
0 = Comparator is disabled
bit 6
CxOUT: Comparator Output bit
If CxPOL = 1 (inverted polarity):
1 = CxVP < CxVN
0 = CxVP > CxVN
If CxPOL = 0 (non-inverted polarity):
1 = CxVP > CxVN
0 = CxVP < CxVN
bit 5
CxOE: Comparator Output Enable bit
1 = CxOUT is present on the CxOUT pin. Requires that the associated TRIS bit be cleared to actually
drive the pin. Not affected by CxON.
0 = CxOUT is internal only
bit 4
CxPOL: Comparator Output Polarity Select bit
1 = Comparator output is inverted
0 = Comparator output is not inverted
bit 3
Unimplemented: Read as ‘0’
bit 2
CxSP: Comparator Speed/Power Select bit
1 = Comparator operates in normal power, higher speed mode
0 = Comparator operates in low-power, low-speed mode
bit 1
CxHYS: Comparator Hysteresis Enable bit
1 = Comparator hysteresis enabled
0 = Comparator hysteresis disabled
bit 0
CxSYNC: Comparator Output Synchronous Mode bit
1 = Comparator output to Timer1 and I/O pin is synchronous to changes on Timer1 clock source.
Output updated on the falling edge of Timer1 clock source.
0 = Comparator output to Timer1 and I/O pin is asynchronous.
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PIC16LF1824T39A
REGISTER 19-2:
CMxCON1: COMPARATOR CX CONTROL REGISTER 1
R/W-0/0
R/W-0/0
CxINTP
CxINTN
R/W-0/0
R/W-0/0
CxPCH
U-0
U-0
—
—
R/W-0/0
R/W-0/0
CxNCH
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
CxINTP: Comparator Interrupt on Positive Going Edge Enable bits
1 = The CxIF interrupt flag will be set upon a positive going edge of the CxOUT bit
0 = No interrupt flag will be set on a positive going edge of the CxOUT bit
bit 6
CxINTN: Comparator Interrupt on Negative Going Edge Enable bits
1 = The CxIF interrupt flag will be set upon a negative going edge of the CxOUT bit
0 = No interrupt flag will be set on a negative going edge of the CxOUT bit
bit 5-4
CxPCH: Comparator Positive Input Channel Select bits
00 = CxVP connects to CxIN+ pin
01 = CxVP connects to DAC Voltage Reference
10 = CxVP connects to FVR Voltage Reference
11 = CxVP connects to VSS
bit 3-2
Unimplemented: Read as ‘0’
bit 1-0
CxNCH: Comparator Negative Input Channel Select bits
00 = CxVN connects to C12IN0- pin
01 = CxVN connects to C12IN1- pin
10 = CxVN connects to C12IN2- pin
11 = CxVN connects to C12IN3- pin
REGISTER 19-3:
CMOUT: COMPARATOR OUTPUT REGISTER
U-0
U-0
U-0
U-0
U-0
U-0
R-0/0
R-0/0
—
—
—
—
—
—
MC2OUT
MC1OUT
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-2
Unimplemented: Read as ‘0’
bit 1
MC2OUT: Mirror Copy of C2OUT bit
bit 0
MC1OUT: Mirror Copy of C1OUT bit
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TABLE 19-2:
Name
CM1CON0
SUMMARY OF REGISTERS ASSOCIATED WITH COMPARATOR MODULE
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
C1ON
C1OUT
C1OE
C1POL
---
C1SP
C1HYS
C1SYNC
160
C2OE
C2POL
C2HYS
C2SYNC
—
C2SP
C1PCH
—
—
C2PCH
—
—
—
—
160
CM2CON0
C2ON
C2OUT
CM1CON1
C1INTP
C1INTN
CM2CON1
C2INTP
C2INTN
—
—
—
—
DACCON0
DACEN
DACLPS
DACOE
—
DACPSS
DACCON1
—
—
—
FVREN
FVRRDY
TSEN
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE2
OSFIE
C2IE
C1IE
EEIE
BCLIE
—
—
CCP2IE
86
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
89
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
CMOUT
FVRCON
Legend:
C1NCH
161
C2NCH
161
MC2OUT
MC1OUT
161
—
DACNSS
148
DACR
TSRNG
CDAFVR
148
ADFVR
130
— = unimplemented location, read as ‘0’. Shaded cells are unused by the comparator module.
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PIC16LF1824T39A
20.0
TIMER0 MODULE
20.1.2
In 8-Bit Counter mode, the Timer0 module will increment
on every rising or falling edge of the T0CKI pin or the
Capacitive Sensing Oscillator (CPSCLK) signal.
The Timer0 module is an 8-bit timer/counter with the
following features:
•
•
•
•
•
•
8-bit timer/counter register (TMR0)
8-bit prescaler (independent of Watchdog Timer)
Programmable internal or external clock source
Programmable external clock edge selection
Interrupt on overflow
TMR0 can be used to gate Timer1
8-Bit Counter mode using the T0CKI pin is selected by
setting the TMR0CS bit in the OPTION_REG register to
‘1’ and resetting the T0XCS bit in the CPSCON0 register
to ‘0’.
8-Bit Counter mode using the Capacitive Sensing
Oscillator (CPSCLK) signal is selected by setting the
TMR0CS bit in the OPTION_REG register to ‘1’ and
setting the T0XCS bit in the CPSCON0 register to ‘1’.
Figure 20-1 is a block diagram of the Timer0 module.
20.1
Timer0 Operation
The rising or falling transition of the incrementing edge
for either input source is determined by the TMR0SE bit
in the OPTION_REG register.
The Timer0 module can be used as either an 8-bit timer
or an 8-bit counter.
20.1.1
8-BIT COUNTER MODE
8-BIT TIMER MODE
The Timer0 module will increment every instruction
cycle, if used without a prescaler. 8-bit Timer mode is
selected by clearing the TMR0CS bit of the
OPTION_REG register.
When TMR0 is written, the increment is inhibited for
two instruction cycles immediately following the write.
Note:
The value written to the TMR0 register
can be adjusted, in order to account for
the two instruction cycle delay when
TMR0 is written.
FIGURE 20-1:
BLOCK DIAGRAM OF THE TIMER0
FOSC/4
Data Bus
0
T0CKI
1
1
8
Sync
2 TCY
TMR0
0
TMR0SE TMR0CS
8-bit
Prescaler
PSA
Set Flag bit TMR0IF
on Overflow
Overflow to Timer1
8
PS
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20.1.3
SOFTWARE PROGRAMMABLE
PRESCALER
A software programmable prescaler is available for
exclusive use with Timer0. The prescaler is enabled by
clearing the PSA bit of the OPTION_REG register.
Note:
The Watchdog Timer (WDT) uses its own
independent prescaler.
There are eight prescaler options for the Timer0
module ranging from 1:2 to 1:256. The prescale values
are selectable via the PS bits of the
OPTION_REG register. In order to have a 1:1 prescaler
value for the Timer0 module, the prescaler must be
disabled by setting the PSA bit of the OPTION_REG
register.
The prescaler is not readable or writable. All instructions
writing to the TMR0 register will clear the prescaler.
20.1.4
TIMER0 INTERRUPT
Timer0 will generate an interrupt when the TMR0
register overflows from FFh to 00h. The TMR0IF
interrupt flag bit of the INTCON register is set every
time the TMR0 register overflows, regardless of
whether or not the Timer0 interrupt is enabled. The
TMR0IF bit can only be cleared in software. The Timer0
interrupt enable is the TMR0IE bit of the INTCON
register.
Note:
20.1.5
The Timer0 interrupt cannot wake the
processor from Sleep since the timer is
frozen during Sleep.
8-BIT COUNTER MODE
SYNCHRONIZATION
When in 8-Bit Counter mode, the incrementing edge on
the T0CKI pin must be synchronized to the instruction
clock. Synchronization can be accomplished by
sampling the prescaler output on the Q2 and Q4 cycles
of the instruction clock. The high and low periods of the
external clocking source must meet the timing
requirements as shown in Section 31.0 “Electrical
Specifications”.
20.1.6
OPERATION DURING SLEEP
Timer0 cannot operate while the processor is in Sleep
mode. The contents of the TMR0 register will remain
unchanged while the processor is in Sleep mode.
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20.2
Option and Timer0 Control Registers
REGISTER 20-1:
OPTION_REG: OPTION REGISTER
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
WPUEN
INTEDG
TMR0CS
TMR0SE
PSA
R/W-1/1
R/W-1/1
R/W-1/1
PS
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
WPUEN: Weak Pull-up Enable bit
1 = All weak pull-ups are disabled (except MCLR, if it is enabled)
0 = Weak pull-ups are enabled by individual WPUx latch values
bit 6
INTEDG: Interrupt Edge Select bit
1 = Interrupt on rising edge of INT pin
0 = Interrupt on falling edge of INT pin
bit 5
TMR0CS: Timer0 Clock Source Select bit
1 = Transition on T0CKI pin
0 = Internal instruction cycle clock (FOSC/4)
bit 4
TMR0SE: Timer0 Source Edge Select bit
1 = Increment on high-to-low transition on T0CKI pin
0 = Increment on low-to-high transition on T0CKI pin
bit 3
PSA: Prescaler Assignment bit
1 = Prescaler is not assigned to the Timer0 module
0 = Prescaler is assigned to the Timer0 module
bit 2-0
PS: Prescaler Rate Select bits
Bit Value
Timer0 Rate
000
001
010
011
100
101
110
111
1:2
1:4
1:8
1 : 16
1 : 32
1 : 64
1 : 128
1 : 256
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TABLE 20-1:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH TIMER0
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
CPSCON0
CPSON
CPSRM
—
—
CPSRNG
FVRCON
FVREN
FVRRDY
TSEN
TSRNG
CDAFVR
INLVLA
—
—
INTCON
GIE
PEIE
OPTION_REG WPUEN
TMR0
TRISA
INLVLA5 INLVLA4
TMR0IE
INTE
INTEDG TMR0CS TMR0SE
INLVLA3
INLVLA2
IOCIE
TMR0IF
PSA
Bit 1
Bit 0
CPSOUT
T0XCS
—
TRISA5
309
ADFVR
130
INLVLA1 INLVLA0
119
INTF
IOCIF
PS
84
165
Timer0 Module Register
—
Register
on Page
163*
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
Legend: — = Unimplemented location, read as ‘0’. Shaded cells are not used by the Timer0 module.
* Page provides register information.
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21.0
TIMER1 MODULE WITH GATE
CONTROL
•
•
•
•
The Timer1 module is a 16-bit timer/counter with the
following features:
Figure 21-1 is a block diagram of the Timer1 module.
•
•
•
•
•
•
•
•
16-bit timer/counter register pair (TMR1H:TMR1L)
Programmable internal or external clock source
2-bit prescaler
Dedicated 32 kHz oscillator circuit
Optionally synchronized comparator out
Multiple Timer1 gate (count enable) sources
Interrupt on overflow
Wake-up on overflow (external clock,
Asynchronous mode only)
• Time base for the Capture/Compare function
• Special Event Trigger (with CCP/ECCP)
• Selectable Gate Source Polarity
FIGURE 21-1:
Gate Toggle Mode
Gate Single-pulse Mode
Gate Value Status
Gate Event Interrupt
TIMER1 BLOCK DIAGRAM
T1GSS
T1GSPM
00
T1G
From Timer0
Overflow
01
sync_C1OUT
10
sync_C2OUT
TMR1ON
T1GVAL
0
Single Pulse
D
Q
CK
R
Q
11
T1GPOL
0
T1G_IN
1
Acq. Control
1
Q1
Data Bus
D
Q
RD
T1GCON
EN
Interrupt
T1GGO/DONE
Set
TMR1GIF
det
T1GTM
TMR1GE
Set flag bit
TMR1IF on
Overflow
TMR1ON
To Comparator Module
TMR1(2)
TMR1H
EN
TMR1L
Q
D
T1CLK
Synchronized
clock input
0
1
TMR1CS
T1OSO
OUT
T1OSC
T1OSI
1
Cap. Sensing
Oscillator
T1SYNC
11
Synchronize(3)
Prescaler
1, 2, 4, 8
det
10
EN
0
T1OSCEN
(1)
FOSC
Internal
Clock
01
FOSC/4
Internal
Clock
00
2
T1CKPS
FOSC/2
Internal
Clock
Sleep input
T1CKI
To Clock Switching Modules
Note 1: ST Buffer is high speed type when using T1CKI.
2: Timer1 register increments on rising edge.
3: Synchronize does not operate while in Sleep.
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21.1
Timer1 Operation
21.2
The Timer1 module is a 16-bit incrementing counter
which is accessed through the TMR1H:TMR1L register
pair. Writes to TMR1H or TMR1L directly update the
counter.
The TMR1CS and T1OSCEN bits of the T1CON
register are used to select the clock source for Timer1.
Table 21-2 displays the clock source selections.
21.2.1
When used with an internal clock source, the module is
a timer and increments on every instruction cycle.
When used with an external clock source, the module
can be used as either a timer or counter and increments on every selected edge of the external source.
INTERNAL CLOCK SOURCE
When the internal clock source is selected the
TMR1H:TMR1L register pair will increment on multiples
of FOSC as determined by the Timer1 prescaler.
When the FOSC internal clock source is selected, the
Timer1 register value will increment by four counts every
instruction clock cycle. Due to this condition, a 2 LSB
error in resolution will occur when reading the Timer1
value. To utilize the full resolution of Timer1, an
asynchronous input signal must be used to gate the
Timer1 clock input.
Timer1 is enabled by configuring the TMR1ON and
TMR1GE bits in the T1CON and T1GCON registers,
respectively. Table 21-1 displays the Timer1 enable
selections.
TABLE 21-1:
Clock Source Selection
TIMER1 ENABLE
SELECTIONS
The following asynchronous sources may be used:
• Asynchronous event on the T1G pin to Timer1
gate
• C1 or C2 comparator input to Timer1 gate
Timer1
Operation
TMR1ON
TMR1GE
0
0
Off
0
1
Off
21.2.2
1
0
Always On
1
1
Count Enabled
When the external clock source is selected, the Timer1
module may work as a timer or a counter.
EXTERNAL CLOCK SOURCE
When enabled to count, Timer1 is incremented on the
rising edge of the external clock input T1CKI or the
capacitive sensing oscillator signal. Either of these
external clock sources can be synchronized to the
microcontroller system clock or they can run
asynchronously.
When used as a timer with a clock oscillator, an
external 32.768 kHz crystal can be used in conjunction
with the dedicated internal oscillator circuit.
Note:
In Counter mode, a falling edge must be
registered by the counter prior to the first
incrementing rising edge after any one or
more of the following conditions:
•
•
•
•
TABLE 21-2:
Timer1 enabled after POR
Write to TMR1H or TMR1L
Timer1 is disabled
Timer1 is disabled (TMR1ON = 0)
when T1CKI is high then Timer1 is
enabled (TMR1ON=1) when T1CKI is
low.
CLOCK SOURCE SELECTIONS
TMR1CS1
TMR1CS0
T1OSCEN
0
1
x
System Clock (FOSC)
0
0
x
Instruction Clock (FOSC/4)
1
1
x
Capacitive Sensing Oscillator
1
0
0
External Clocking on T1CKI Pin
1
0
1
Osc.Circuit On T1OSI/T1OSO Pins
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Clock Source
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21.3
Timer1 Prescaler
Timer1 has four prescaler options allowing 1, 2, 4 or 8
divisions of the clock input. The T1CKPS bits of the
T1CON register control the prescale counter. The
prescale counter is not directly readable or writable;
however, the prescaler counter is cleared upon a write to
TMR1H or TMR1L.
21.4
Timer1 Oscillator
A dedicated low-power 32.768 kHz oscillator circuit is
built-in between pins T1OSI (input) and T1OSO
(amplifier output). This internal circuit is to be used in
conjunction with an external 32.768 kHz crystal.
The oscillator circuit is enabled by setting the T1OSCEN bit of the T1CON register. The oscillator will continue to run during Sleep.
Note:
21.5
The oscillator requires a start-up and
stabilization time before use. Thus,
T1OSCEN should be set and a suitable
delay observed prior to enabling Timer1.
Timer1 Operation in
Asynchronous Counter Mode
If control bit T1SYNC of the T1CON register is set, the
external clock input is not synchronized. The timer
increments asynchronously to the internal phase
clocks. If the external clock source is selected, then
the timer will continue to run during Sleep and can
generate an interrupt on overflow, which will wake-up
the processor. However, special precautions in
software are needed to read/write the timer (see
Section 21.5.1 “Reading and Writing Timer1 in
Asynchronous Counter Mode”).
Note:
21.5.1
When switching from synchronous to
asynchronous operation, it is possible to
skip an increment. When switching from
asynchronous to synchronous operation,
it is possible to produce an additional
increment.
READING AND WRITING TIMER1 IN
ASYNCHRONOUS COUNTER
MODE
Reading TMR1H or TMR1L while the timer is running
from an external asynchronous clock will ensure a valid
read (taken care of in hardware). However, the user
should keep in mind that reading the 16-bit timer in two
8-bit values itself, poses certain problems, since the
timer may overflow between the reads.
21.6
Timer1 Gate
Timer1 can be configured to count freely or the count
can be enabled and disabled using Timer1 gate
circuitry. This is also referred to as Timer1 Gate Enable.
Timer1 gate can also be driven by multiple selectable
sources.
21.6.1
TIMER1 GATE ENABLE
The Timer1 Gate Enable mode is enabled by setting
the TMR1GE bit of the T1GCON register. The polarity
of the Timer1 Gate Enable mode is configured using
the T1GPOL bit of the T1GCON register.
When Timer1 Gate Enable mode is enabled, Timer1
will increment on the rising edge of the Timer1 clock
source. When Timer1 Gate Enable mode is disabled,
no incrementing will occur and Timer1 will hold the
current count. See Figure 21-3 for timing details.
TABLE 21-3:
TIMER1 GATE ENABLE
SELECTIONS
T1CLK
T1GPOL
T1G
0
0
Counts
0
1
Holds Count
1
0
Holds Count
1
1
Counts
21.6.2
Timer1 Operation
TIMER1 GATE SOURCE
SELECTION
The Timer1 gate source selections are shown in
Table 21-4. Source selection is controlled by the
T1GSS bits of the T1GCON register. The polarity for
each available source is also selectable. Polarity
selection is controlled by the T1GPOL bit of the
T1GCON register.
TABLE 21-4:
T1GSS
TIMER1 GATE SOURCES
Timer1 Gate Source
00
Timer1 Gate Pin
01
Overflow of Timer0
(TMR0 increments from FFh to 00h)
10
Comparator 1 Output sync_C1OUT
(optionally Timer1 synchronized output)
11
Comparator 2 Output sync_C2OUT
(optionally Timer1 synchronized output)
For writes, it is recommended that the user simply stop
the timer and write the desired values. A write
contention may occur by writing to the timer registers,
while the register is incrementing. This may produce an
unpredictable value in the TMR1H:TMR1L register pair.
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21.6.2.1
T1G Pin Gate Operation
The T1G pin is one source for Timer1 gate control. It
can be used to supply an external source to the Timer1
gate circuitry.
21.6.2.2
Timer0 Overflow Gate Operation
When Timer0 increments from FFh to 00h, a
low-to-high pulse will automatically be generated and
internally supplied to the Timer1 gate circuitry.
21.6.2.3
Comparator C1 Gate Operation
The output resulting from a Comparator 1 operation can
be selected as a source for Timer1 gate control. The
Comparator 1 output (SYNCC1OUT) can be
synchronized to the Timer1 clock or left asynchronous.
For more information see Section 19.4.1 “Comparator
Output Synchronization”.
21.6.2.4
Comparator C2 Gate Operation
The output resulting from a Comparator 2 operation
can be selected as a source for Timer1 gate control.
The Comparator 2 output (SYNCC2OUT) can be
synchronized to the Timer1 clock or left asynchronous.
For more information see Section 19.4.1 “Comparator
Output Synchronization”.
21.6.3
TIMER1 GATE TOGGLE MODE
When Timer1 Gate Toggle mode is enabled, it is possible to measure the full-cycle length of a Timer1 gate
signal, as opposed to the duration of a single level
pulse.
The Timer1 gate source is routed through a flip-flop that
changes state on every incrementing edge of the
signal. See Figure 21-4 for timing details.
Timer1 Gate Toggle mode is enabled by setting the
T1GTM bit of the T1GCON register. When the T1GTM
bit is cleared, the flip-flop is cleared and held clear. This
is necessary in order to control which edge is
measured.
Note:
21.6.4
TIMER1 GATE SINGLE-PULSE
MODE
When Timer1 Gate Single-Pulse mode is enabled, it is
possible to capture a single pulse gate event. Timer1
Gate Single-Pulse mode is first enabled by setting the
T1GSPM bit in the T1GCON register. Next, the
T1GGO/DONE bit in the T1GCON register must be set.
The Timer1 will be fully enabled on the next
incrementing edge. On the next trailing edge of the
pulse, the T1GGO/DONE bit will automatically be
cleared. No other gate events will be allowed to
increment Timer1 until the T1GGO/DONE bit is once
again set in software. See Figure 21-5 for timing details.
If the Single Pulse Gate mode is disabled by clearing the
T1GSPM bit in the T1GCON register, the T1GGO/DONE
bit should also be cleared.
Enabling the Toggle mode and the Single-Pulse mode
simultaneously will permit both sections to work
together. This allows the cycle times on the Timer1
Gate source to be measured. See Figure 21-6 for
timing details.
21.6.5
TIMER1 GATE VALUE STATUS
When Timer1 Gate Value Status is utilized, it is possible
to read the most current level of the gate control value.
The value is stored in the T1GVAL bit in the T1GCON
register. The T1GVAL bit is valid even when the Timer1
Gate is not enabled (TMR1GE bit is cleared).
21.6.6
TIMER1 GATE EVENT INTERRUPT
When Timer1 Gate Event Interrupt is enabled, it is
possible to generate an interrupt upon the completion
of a gate event. When the falling edge of T1GVAL
occurs, the TMR1GIF flag bit in the PIR1 register will be
set. If the TMR1GIE bit in the PIE1 register is set, then
an interrupt will be recognized.
The TMR1GIF flag bit operates even when the Timer1
gate is not enabled (TMR1GE bit is cleared).
Enabling Toggle mode at the same time
as changing the gate polarity may result in
indeterminate operation.
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21.7
Timer1 Interrupt
The Timer1 register pair (TMR1H:TMR1L) increments
to FFFFh and rolls over to 0000h. When Timer1 rolls
over, the Timer1 interrupt flag bit of the PIR1 register is
set. To enable the interrupt on rollover, you must set
these bits:
•
•
•
•
TMR1ON bit of the T1CON register
TMR1IE bit of the PIE1 register
PEIE bit of the INTCON register
GIE bit of the INTCON register
The interrupt is cleared by clearing the TMR1IF bit in
the Interrupt Service Routine.
Note:
21.8
The TMR1H:TMR1L register pair and the
TMR1IF bit should be cleared before
enabling interrupts.
Timer1 Operation During Sleep
Timer1 can only operate during Sleep when set up in
Asynchronous Counter mode. In this mode, an external
crystal or clock source can be used to increment the
counter. To set up the timer to wake the device:
•
•
•
•
•
TMR1ON bit of the T1CON register must be set
TMR1IE bit of the PIE1 register must be set
PEIE bit of the INTCON register must be set
T1SYNC bit of the T1CON register must be set
TMR1CS bits of the T1CON register must be
configured
• T1OSCEN bit of the T1CON register must be
configured
The device will wake-up on an overflow and execute
the next instructions. If the GIE bit of the INTCON
register is set, the device will call the Interrupt Service
Routine.
21.9
ECCP/CCP Capture/Compare Time
Base
The CCP modules use the TMR1H:TMR1L register
pair as the time base when operating in Capture or
Compare mode.
In Capture mode, the value in the TMR1H:TMR1L
register pair is copied into the CCPR1H:CCPR1L
register pair on a configured event.
In Compare mode, an event is triggered when the value
CCPR1H:CCPR1L register pair matches the value in
the TMR1H:TMR1L register pair. This event can be a
Special Event Trigger.
For
more
information,
see
“Capture/Compare/PWM Modules”.
Section 24.0
21.10 ECCP/CCP Special Event Trigger
When any of the CCP’s are configured to trigger a
special event, the trigger will clear the TMR1H:TMR1L
register pair. This special event does not cause a Timer1 interrupt. The CCP module may still be configured
to generate a CCP interrupt.
In this mode of operation, the CCPR1H:CCPR1L
register pair becomes the period register for Timer1.
Timer1 should be synchronized and FOSC/4 should be
selected as the clock source in order to utilize the
Special Event Trigger. Asynchronous operation of Timer1 can cause a Special Event Trigger to be missed.
In the event that a write to TMR1H or TMR1L coincides
with a Special Event Trigger from the CCP, the write will
take precedence.
For more information, see Section 16.2.5 “Special
Event Trigger”.
Timer1 oscillator will continue to operate in Sleep
regardless of the T1SYNC bit setting.
FIGURE 21-2:
TIMER1 INCREMENTING EDGE
T1CKI = 1
when TMR1
Enabled
T1CKI = 0
when TMR1
Enabled
Note 1:
2:
Arrows indicate counter increments.
In Counter mode, a falling edge must be registered by the counter prior to the first incrementing rising edge of the clock.
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PIC16LF1824T39A
FIGURE 21-3:
TIMER1 GATE ENABLE MODE
TMR1GE
T1GPOL
T1G_IN
T1CKI
T1GVAL
Timer1
N
FIGURE 21-4:
N+1
N+2
N+3
N+4
TIMER1 GATE TOGGLE MODE
TMR1GE
T1GPOL
T1GTM
T1G_IN
T1CKI
T1GVAL
Timer1
N
DS40001657C-page 172
N+1 N+2 N+3
N+4
N+5 N+6 N+7
N+8
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 21-5:
TIMER1 GATE SINGLE-PULSE MODE
TMR1GE
T1GPOL
T1GSPM
T1GGO/
Cleared by hardware on
falling edge of T1GVAL
Set by software
DONE
Counting enabled on
rising edge of T1G
T1G_IN
T1CKI
T1GVAL
Timer1
TMR1GIF
N
Cleared by software
2012-2017 Microchip Technology Inc.
N+1
N+2
Set by hardware on
falling edge of T1GVAL
Cleared by
software
DS40001657C-page 173
PIC16LF1824T39A
FIGURE 21-6:
TIMER1 GATE SINGLE-PULSE AND TOGGLE COMBINED MODE
TMR1GE
T1GPOL
T1GSPM
T1GTM
T1GGO/
Cleared by hardware on
falling edge of T1GVAL
Set by software
DONE
Counting enabled on
rising edge of T1G
T1G_IN
T1CKI
T1GVAL
Timer1
TMR1GIF
DS40001657C-page 174
N
Cleared by software
N+1
N+2
N+3
Set by hardware on
falling edge of T1GVAL
N+4
Cleared by
software
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
21.11 Timer1 Control Registers
REGISTER 21-1:
R/W-0/u
T1CON: TIMER1 CONTROL REGISTER
R/W-0/u
R/W-0/u
TMR1CS
R/W-0/u
T1CKPS
R/W-0/u
R/W-0/u
U-0
R/W-0/u
T1OSCEN
T1SYNC
—
TMR1ON
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
TMR1CS: Timer1 Clock Source Select bits
11 = Timer1 clock source is Capacitive Sensing Oscillator (CAPOSC)
10 = Timer1 clock source is pin or oscillator:
If T1OSCEN = 0:
External clock from T1CKI pin (on the rising edge)
If T1OSCEN = 1:
Crystal oscillator on T1OSI/T1OSO pins
01 = Timer1 clock source is system clock (FOSC)
00 = Timer1 clock source is instruction clock (FOSC/4)
bit 5-4
T1CKPS: Timer1 Input Clock Prescale Select bits
11 = 1:8 Prescale value
10 = 1:4 Prescale value
01 = 1:2 Prescale value
00 = 1:1 Prescale value
bit 3
T1OSCEN: LP Oscillator Enable Control bit
1 = Dedicated Timer1 oscillator circuit enabled
0 = Dedicated Timer1 oscillator circuit disabled
bit 2
T1SYNC: Timer1 Synchronization Control bit
1 = Do not synchronize synchronous clock input
0 = Synchronize asynchronous clock input with system clock (FOSC)
bit 1
Unimplemented: Read as ‘0’
bit 0
TMR1ON: Timer1 On bit
1 = Enables Timer1
0 = Stops Timer1 and clears Timer1 gate flip-flop
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PIC16LF1824T39A
REGISTER 21-2:
T1GCON: TIMER1 GATE CONTROL REGISTER
R/W-0/u
R/W-0/u
R/W-0/u
R/W-0/u
R/W/HC-0/u
R-x/x
R/W-0/u R/W-0/u
TMR1GE
T1GPOL
T1GTM
T1GSPM
T1GGO/DONE
T1GVAL
T1GSS
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
HC = Bit is cleared by hardware
bit 7
TMR1GE: Timer1 Gate Enable bit
If TMR1ON = 0:
This bit is ignored
If TMR1ON = 1:
1 = Timer1 counting is controlled by the Timer1 gate function
0 = Timer1 counts regardless of Timer1 gate function
bit 6
T1GPOL: Timer1 Gate Polarity bit
1 = Timer1 gate is active-high (Timer1 counts when gate is high)
0 = Timer1 gate is active-low (Timer1 counts when gate is low)
bit 5
T1GTM: Timer1 Gate Toggle Mode bit
1 = Timer1 Gate Toggle mode is enabled
0 = Timer1 Gate Toggle mode is disabled and toggle flip-flop is cleared
Timer1 gate flip-flop toggles on every rising edge.
bit 4
T1GSPM: Timer1 Gate Single-Pulse Mode bit
1 = Timer1 gate Single-Pulse mode is enabled and is controlling Timer1 gate
0 = Timer1 gate Single-Pulse mode is disabled
bit 3
T1GGO/DONE: Timer1 Gate Single-Pulse Acquisition Status bit
1 = Timer1 gate single-pulse acquisition is ready, waiting for an edge
0 = Timer1 gate single-pulse acquisition has completed or has not been started
bit 2
T1GVAL: Timer1 Gate Current State bit
Indicates the current state of the Timer1 gate that could be provided to TMR1H:TMR1L.
Unaffected by Timer1 Gate Enable (TMR1GE).
bit 1-0
T1GSS: Timer1 Gate Source Select bits
11 = Comparator 2 optionally synchronized output (SYNCC2OUT)
10 = Comparator 1 optionally synchronized output (SYNCC1OUT)
01 = Timer0 overflow output
00 = Timer1 gate pin
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PIC16LF1824T39A
TABLE 21-5:
Name
ANSELA
SUMMARY OF REGISTERS ASSOCIATED WITH TIMER1
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
CCP1CON
P1M
DC1B
CCP1M
CCP2CON
P2M1
DC2B
CCP2M
INLVLA
INTCON
PIE1
PIR1
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
118
215
215
INLVLA0
119
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
TMR1H
Holding Register for the Most Significant Byte of the 16-bit TMR1 Register
TMR1L
Holding Register for the Least Significant Byte of the 16-bit TMR1 Register
TRISA
—
—
T1CON
TMR1CS1
TMR1CS0
T1GCON
TMR1GE
T1GPOL
Legend:
*
INLVLA1
Register
on Page
TRISA5
TRISA4
T1CKPS
T1GTM
T1GSPM
TRISA3
TRISA2
T1OSCEN
T1GGO/
DONE
88
171*
171*
TRISA1
TRISA0
T1SYNC
—
TMR1ON
175
T1GVAL
T1GSS1
T1GSS0
176
117
— = unimplemented location, read as ‘0’. Shaded cells are not used by the Timer1 module.
Page provides register information.
2012-2017 Microchip Technology Inc.
DS40001657C-page 177
PIC16LF1824T39A
NOTES:
DS40001657C-page 178
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PIC16LF1824T39A
22.0
TIMER2/4/6 MODULES
There are up to three identical Timer2-type modules
available. To maintain pre-existing naming conventions,
the Timers are called Timer2, Timer4 and Timer6 (also
Timer2/4/6).
Note:
The ‘x’ variable used in this section is
used to designate Timer2, Timer4, or Timer6. For example, TxCON references
T2CON, T4CON, or T6CON. PRx
references PR2, PR4, or PR6.
The Timer2/4/6 modules incorporate the following
features:
• 8-bit Timer and Period registers (TMRx and PRx,
respectively)
• Readable and writable (both registers)
• Software programmable prescaler (1:1, 1:4, 1:16,
and 1:64)
• Software programmable postscaler (1:1 to 1:16)
• Interrupt on TMRx match with PRx, respectively
• Optional use as the shift clock for the MSSPx
modules (Timer2 only)
See Figure 22-1 for a block diagram of Timer2/4/6.
FIGURE 22-1:
TIMER2/4/6 BLOCK DIAGRAM
TMRx
Output
FOSC/4
Prescaler
1:1, 1:4, 1:16, 1:64
2
TMRx
Comparator
Sets Flag
bit TMRxIF
Reset
EQ
Postscaler
1:1 to 1:16
TxCKPS
PRx
4
TxOUTPS
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22.1
Timer2/4/6 Operation
The clock input to the Timer2/4/6 modules is the
system instruction clock (FOSC/4).
TMRx increments from 00h on each clock edge.
A 4-bit counter/prescaler on the clock input allows direct
input, divide-by-4 and divide-by-16 prescale options.
These options are selected by the prescaler control bits,
TxCKPS of the TxCON register. The value of
TMRx is compared to that of the Period register, PRx, on
each clock cycle. When the two values match, the
comparator generates a match signal as the timer
output. This signal also resets the value of TMRx to 00h
on the next cycle and drives the output
counter/postscaler (see Section 22.2 “Timer2/4/6
Interrupt”).
22.3
Timer2/4/6 Output
The unscaled output of TMRx is available primarily to
the CCP modules, where it is used as a time base for
operations in PWM mode.
Timer2 can be optionally used as the shift clock source
for the MSSPx modules operating in SPI mode.
Additional information is provided in Section 25.1
“Master SSP (MSSP1) Module Overview”.
22.4
Timer2/4/6 Operation During Sleep
The Timer2/4/6 timers cannot be operated while the
processor is in Sleep mode. The contents of the TMRx
and PRx registers will remain unchanged while the
processor is in Sleep mode.
The TMRx and PRx registers are both directly readable
and writable. The TMRx register is cleared on any
device Reset, whereas the PRx register initializes to
FFh. Both the prescaler and postscaler counters are
cleared on the following events:
•
•
•
•
•
•
•
•
•
a write to the TMRx register
a write to the TxCON register
Power-on Reset (POR)
Brown-out Reset (BOR)
MCLR Reset
Watchdog Timer (WDT) Reset
Stack Overflow Reset
Stack Underflow Reset
RESET Instruction
Note:
22.2
TMRx is not cleared when TxCON is
written.
Timer2/4/6 Interrupt
Timer2/4/6 can also generate an optional device
interrupt. The Timer2/4/6 output signal (TMRx-to-PRx
match)
provides
the
input
for
the
4-bit
counter/postscaler. This counter generates the TMRx
match interrupt flag which is latched in TMRxIF of the
PIRx register. The interrupt is enabled by setting the
TMRx Match Interrupt Enable bit, TMRxIE of the PIEx
register.
A range of 16 postscale options (from 1:1 through 1:16
inclusive) can be selected with the postscaler control
bits, TxOUTPS, of the TxCON register.
DS40001657C-page 180
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PIC16LF1824T39A
22.5
Timer2 Control Register
REGISTER 22-1:
U-0
TXCON: TIMER2/TIMER4/TIMER6 CONTROL REGISTER
R/W-0/0
R/W-0/0
—
R/W-0/0
R/W-0/0
TxOUTPS
R/W-0/0
R/W-0/0
TMRxON
bit 7
R/W-0/0
TxCKPS
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
Unimplemented: Read as ‘0’
bit 6-3
TxOUTPS: Timerx Output Postscaler Select bits
1111 = 1:16 Postscaler
1110 = 1:15 Postscaler
1101 = 1:14 Postscaler
1100 = 1:13 Postscaler
1011 = 1:12 Postscaler
1010 = 1:11 Postscaler
1001 = 1:10 Postscaler
1000 = 1:9 Postscaler
0111 = 1:8 Postscaler
0110 = 1:7 Postscaler
0101 = 1:6 Postscaler
0100 = 1:5 Postscaler
0011 = 1:4 Postscaler
0010 = 1:3 Postscaler
0001 = 1:2 Postscaler
0000 = 1:1 Postscaler
bit 2
TMRxON: Timerx On bit
1 = Timerx is on
0 = Timerx is off
bit 1-0
TxCKPS: Timer2-type Clock Prescale Select bits
11 = Prescaler is 64
10 = Prescaler is 16
01 = Prescaler is 4
00 = Prescaler is 1
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TABLE 22-1:
SUMMARY OF REGISTERS ASSOCIATED WITH TIMER2/4/6
Name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIE3
—
—
CCP4IE
CCP3IE
TMR6IE
—
TMR4IE
—
87
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
PIR3
—
—
CCP4IF
CCP3IF
TMR6IF
—
TMR4IF
—
90
PR2
Timer2 Module Period Register
179*
PR4
Timer4 Module Period Register
179*
PR6
Timer6 Module Period Register
179*
T2CON
—
T2OUTPS
TMR2ON T2CKPS1 T2CKPS0
181
T4CON
—
T4OUTPS
TMR4ON T4CKPS1 T4CKPS0
181
T6CON
—
T6OUTPS
TMR6ON T6CKPS1 T6CKPS0
181
TMR2
Holding Register for the 8-bit TMR2 Register
179*
TMR4
Holding Register for the 8-bit TMR4 Register
(1)
179*
TMR6
Holding Register for the 8-bit TMR6 Register(1)
179*
Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used for Timer2 module.
* Page provides register information.
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PIC16LF1824T39A
23.0
DATA SIGNAL MODULATOR
Using this method, the DSM can generate the following
types of key modulation schemes:
The Data Signal Modulator (DSM) is a peripheral which
allows the user to mix a data stream, also known as a
modulator signal, with a carrier signal to produce a
modulated output.
• Frequency-Shift Keying (FSK)
• Phase-Shift Keying (PSK)
• On-Off Keying (OOK)
Additionally, the following features are provided within
the DSM module:
Both the carrier and the modulator signals are supplied
to the DSM module either internally, from the output of
a peripheral, or externally through an input pin.
•
•
•
•
•
•
•
The modulated output signal is generated by performing a logical “AND” operation of both the carrier and
modulator signals and then provided to the MDOUT pin.
The carrier signal is comprised of two distinct and
separate signals. A carrier high (CARH) signal and a
carrier low (CARL) signal. During the time in which the
modulator (MOD) signal is in a logic high state, the
DSM mixes the carrier high signal with the modulator
signal. When the modulator signal is in a logic low
state, the DSM mixes the carrier low signal with the
modulator signal.
FIGURE 23-1:
Carrier Synchronization
Carrier Source Polarity Select
Carrier Source Pin Disable
Programmable Modulator Data
Modulator Source Pin Disable
Modulated Output Polarity Select
Slew Rate Control
Figure 23-1 shows a Simplified Block Diagram of the
Data Signal Modulator peripheral.
SIMPLIFIED BLOCK DIAGRAM OF THE DATA SIGNAL MODULATOR
MDCH
VSS
MDCIN1
MDCIN2
CLKR
CCP1
CCP2
CCP3
CCP4
Reserved
No Channel
Selected
0000
0001
0010
0011
0100
0101 CARH
0110
0111
1000
*
*
1111
MDEN
EN
Data Signal
Modulator
MDCHPOL
D
SYNC
MDMS
MDBIT
MDMIN
CCP1
CCP2
CCP3
CCP4
Comparator C1
Comparator C2
MSSP1 SDO1
MSSP2 SDO2
EUSART
Reserved
No Channel
Selected
Q
0000
0001
0010
0011
0100
0101
0110 MOD
0111
1000
1001
1010
0011
*
*
1111
1
0
MDCHSYNC
MDOUT
MDOPOL
MDOE
D
SYNC
MDCL
VSS
MDCIN1
MDCIN2
CLKR
CCP1
CCP2
CCP3
CCP4
Reserved
No Channel
Selected
0000
0001
0010
0011
0100
0101 CARL
0110
0111
1000
*
*
1111
2012-2017 Microchip Technology Inc.
Q
1
0
MDCLSYNC
MDCLPOL
DS40001657C-page 183
PIC16LF1824T39A
23.1
DSM Operation
The DSM module can be enabled by setting the MDEN
bit in the MDCON register. Clearing the MDEN bit in the
MDCON register, disables the DSM module by
automatically switching the carrier high and carrier low
signals to the VSS signal source. The modulator signal
source is also switched to the MDBIT in the MDCON
register. This not only assures that the DSM module is
inactive, but that it is also consuming the least amount
of current.
The values used to select the carrier high, carrier low,
and modulator sources held by the modulation source,
modulation high carrier, and modulation low carrier
control registers are not affected when the MDEN bit is
cleared and the DSM module is disabled. The values
inside these registers remain unchanged while the
DSM is inactive. The sources for the carrier high,
carrier low and modulator signals will once again be
selected when the MDEN bit is set and the DSM
module is again enabled and active.
The modulated output signal can be disabled without
shutting down the DSM module. The DSM module will
remain active and continue to mix signals, but the
output value will not be sent to the MDOUT pin. During
the time that the output is disabled, the MDOUT pin will
remain low. The modulated output can be disabled by
clearing the MDOE bit in the MDCON register.
23.2
Modulator Signal Sources
The modulator signal can be supplied from the following sources:
•
•
•
•
•
•
•
•
•
•
•
CCP1 Signal
CCP2 Signal
CCP3 Signal
CCP4 Signal
MSSP1 SDO1 Signal (SPI mode only)
MSSP2 SDO2 Signal (SPI mode only)
Comparator C1 Signal
Comparator C2 Signal
EUSART TX Signal
External Signal on MDMIN1 pin
MDBIT bit in the MDCON register
23.3
Carrier Signal Sources
The carrier high signal and carrier low signal can be
supplied from the following sources:
•
•
•
•
•
•
•
•
CCP1 signal
CCP2 signal
CCP3 signal
CCP4 signal
Reference clock module signal
External signal on MDCIN1 pin
External signal on MDCIN2 pin
VSS
The carrier high signal is selected by configuring the
MDCH bits in the MDCARH register. The carrier
low signal is selected by configuring the MDCL
bits in the MDCARL register.
23.4
Carrier Synchronization
During the time when the DSM switches between
carrier high and carrier low signal sources, the carrier
data in the modulated output signal can become
truncated. To prevent this, the carrier signal can be
synchronized to the modulator signal. When synchronization is enabled, the carrier pulse that is being mixed
at the time of the transition is allowed to transition low
before the DSM switches over to the next carrier
source.
Synchronization is enabled separately for the carrier
high and carrier low signal sources. Synchronization for
the carrier high signal can be enabled by setting the
MDCHSYNC bit in the MDCARH register. Synchronization for the carrier low signal can be enabled by setting
the MDCLSYNC bit in the MDCARL register.
Figure 23-1 through Figure 23-5 show timing diagrams
of using various synchronization methods.
The modulator signal is selected by configuring the
MDMS bits in the MDSRC register.
DS40001657C-page 184
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PIC16LF1824T39A
FIGURE 23-2:
ON OFF KEYING (OOK) SYNCHRONIZATION
Carrier Low (CARL)
Carrier High (CARH)
Modulator (MOD)
MDCHSYNC = 1
MDCLSYNC = 0
MDCHSYNC = 1
MDCLSYNC = 1
MDCHSYNC = 0
MDCLSYNC = 0
MDCHSYNC = 0
MDCLSYNC = 1
EXAMPLE 23-1:
NO SYNCHRONIZATION (MDSHSYNC = 0, MDCLSYNC = 0)
Carrier High (CARH)
Carrier Low (CARL)
Modulator (MOD)
MDCHSYNC = 0
MDCLSYNC = 0
Active Carrier
State
FIGURE 23-3:
CARH
CARL
CARH
CARL
CARRIER HIGH SYNCHRONIZATION (MDSHSYNC = 1, MDCLSYNC = 0)
Carrier High (CARH)
Carrier Low (CARL)
Modulator (MOD)
MDCHSYNC = 1
MDCLSYNC = 0
Active Carrier
State
CARH
2012-2017 Microchip Technology Inc.
both
CARL
CARH
both
CARL
DS40001657C-page 185
PIC16LF1824T39A
FIGURE 23-4:
CARRIER LOW SYNCHRONIZATION (MDSHSYNC = 0, MDCLSYNC = 1)
Carrier High (CARH)
Carrier Low (CARL)
Modulator (MOD)
MDCHSYNC = 0
MDCLSYNC = 1
Active Carrier
State
FIGURE 23-5:
CARH
CARL
CARH
CARL
FULL SYNCHRONIZATION (MDSHSYNC = 1, MDCLSYNC = 1)
Carrier High (CARH)
Carrier Low (CARL)
Modulator (MOD)
Falling edges
used to sync
MDCHSYNC = 1
MDCLSYNC = 1
Active Carrier
State
DS40001657C-page 186
CARH
CARL
CARH
CARL
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
23.5
Carrier Source Polarity Select
The signal provided from any selected input source for
the carrier high and carrier low signals can be inverted.
Inverting the signal for the carrier high source is
enabled by setting the MDCHPOL bit of the MDCARH
register. Inverting the signal for the carrier low source is
enabled by setting the MDCLPOL bit of the MDCARL
register.
23.6
Carrier Source Pin Disable
Some peripherals assert control over their corresponding output pin when they are enabled. For example,
when the CCP1 module is enabled, the output of CCP1
is connected to the CCP1 pin.
This default connection to a pin can be disabled by
setting the MDCHODIS bit in the MDCARH register for
the carrier high source and the MDCLODIS bit in the
MDCARL register for the carrier low source.
23.7
23.10 Slew Rate Control
The slew rate limitation on the output port pin can be
disabled. The slew rate limitation can be removed by
clearing the MDSLR bit in the MDCON register.
23.11 Operation in Sleep Mode
The DSM module is not affected by Sleep mode. The
DSM can still operate during Sleep, if the carrier and
modulator input sources are also still operable during
Sleep.
23.12 Effects of a Reset
Upon any device Reset, the data signal modulator
module is disabled. The user’s firmware is responsible
for initializing the module before enabling the output.
The registers are reset to their default values.
Pragrammable Modulator Data
The MDBIT of the MDCON register can be selected as
the source for the modulator signal. This gives the user
the ability to program the value used for modulation.
23.8
Modulator Source Pin Disable
The modulator source default connection to a pin can
be disabled by setting the MDMSODIS bit in the
MDSRC register.
23.9
Modulated Output Polarity
The modulated output signal provided on the MDOUT
pin can also be inverted. Inverting the modulated
output signal is enabled by setting the MDOPOL bit of
the MDCON register.
2012-2017 Microchip Technology Inc.
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PIC16LF1824T39A
REGISTER 23-1:
MDCON: MODULATION CONTROL REGISTER
R/W-0/0
R/W-0/0
R/W-1/1
R/W-0/0
R-0/0
U-0
U-0
R/W-0/0
MDEN
MDOE
MDSLR
MDOPOL
MDOUT
—
—
MDBIT
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
MDEN: Modulator Module Enable bit
1 = Modulator module is enabled and mixing input signals
0 = Modulator module is disabled and has no output
bit 6
MDOE: Modulator Module Pin Output Enable bit
1 = Modulator pin output enabled
0 = Modulator pin output disabled
bit 5
MDSLR: MDOUT Pin Slew Rate Limiting bit
1 = MDOUT pin slew rate limiting enabled
0 = MDOUT pin slew rate limiting disabled
bit 4
MDOPOL: Modulator Output Polarity Select bit
1 = Modulator output signal is inverted
0 = Modulator output signal is not inverted
bit 3
MDOUT: Modulator Output bit
Displays the current output value of the modulator module.(1)
bit 2-1
Unimplemented: Read as ‘0’
bit 0
MDBIT: Allows software to manually set modulation source input to module(2)
Note 1:
2:
The modulated output frequency can be greater and asynchronous from the clock that updates this
register bit, the bit value may not be valid for higher speed modulator or carrier signals.
MDBIT must be selected as the modulation source in the MDSRC register for this operation.
DS40001657C-page 188
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
REGISTER 23-2:
MDSRC: MODULATION SOURCE CONTROL REGISTER
R/W-x/u
U-0
U-0
U-0
MDMSODIS
—
—
—
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
MDMS
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
MDMSODIS: Modulation Source Output Disable bit
1 = Output signal driving the peripheral output pin (selected by MDMS) is disabled
0 = Output signal driving the peripheral output pin (selected by MDMS) is enabled
bit 6-4
Unimplemented: Read as ‘0’
bit 3-0
MDMS Modulation Source Selection bits
1111 = Reserved. No channel connected.
1110 = Reserved. No channel connected.
1101 = Reserved. No channel connected.
1100 = Reserved. No channel connected.
1011 = Reserved. No channel connected.
1010 = EUSART TX output
1001 = MSSP2 SDOx output
1000 = MSSP1 SDOx output
0111 = Comparator2 output
0110 = Comparator1 output
0101 = CCP4 output (PWM Output mode only)
0100 = CCP3 output (PWM Output mode only)
0011 = CCP2 output (PWM Output mode only)
0010 = CCP1 output (PWM Output mode only)
0001 = MDMIN port pin
0000 = MDBIT bit of MDCON register is modulation source
Note 1:
Narrowed carrier pulse widths or spurs may occur in the signal stream if the carrier is not synchronized.
2012-2017 Microchip Technology Inc.
DS40001657C-page 189
PIC16LF1824T39A
REGISTER 23-3:
MDCARH: MODULATION HIGH CARRIER CONTROL REGISTER
R/W-x/u
R/W-x/u
R/W-x/u
U-0
MDCHODIS
MDCHPOL
MDCHSYNC
—
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
MDCH
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
MDCHODIS: Modulator High Carrier Output Disable bit
1 = Output signal driving the peripheral output pin (selected by MDCH) is disabled
0 = Output signal driving the peripheral output pin (selected by MDCH) is enabled
bit 6
MDCHPOL: Modulator High Carrier Polarity Select bit
1 = Selected high carrier signal is inverted
0 = Selected high carrier signal is not inverted
bit 5
MDCHSYNC: Modulator High Carrier Synchronization Enable bit
1 = Modulator waits for a falling edge on the high time carrier signal before allowing a switch to the
low time carrier
0 = Modulator Output is not synchronized to the high time carrier signal(1)
bit 4
Unimplemented: Read as ‘0’
bit 3-0
MDCH Modulator Data High Carrier Selection bits (1)
1111 = Reserved. No channel connected.
•
•
•
1000 = Reserved. No channel connected.
0111 = CCP4 output (PWM Output mode only)
0110 = CCP3 output (PWM Output mode only)
0101 = CCP2 output (PWM Output mode only)
0100 = CCP1 output (PWM Output mode only)
0011 = Reference clock module signal
0010 = MDCIN2 port pin
0001 = MDCIN1 port pin
0000 = VSS
Note 1:
Narrowed carrier pulse widths or spurs may occur in the signal stream if the carrier is not synchronized.
DS40001657C-page 190
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
REGISTER 23-4:
MDCARL: MODULATION LOW CARRIER CONTROL REGISTER
R/W-x/u
R/W-x/u
R/W-x/u
U-0
MDCLODIS
MDCLPOL
MDCLSYNC
—
R/W-x/u
R/W-x/u
R/W-x/u
R/W-x/u
MDCL
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
MDCLODIS: Modulator Low Carrier Output Disable bit
1 = Output signal driving the peripheral output pin (selected by MDCL of the MDCARL register)
is disabled
0 = Output signal driving the peripheral output pin (selected by MDCL of the MDCARL register)
is enabled
bit 6
MDCLPOL: Modulator Low Carrier Polarity Select bit
1 = Selected low carrier signal is inverted
0 = Selected low carrier signal is not inverted
bit 5
MDCLSYNC: Modulator Low Carrier Synchronization Enable bit
1 = Modulator waits for a falling edge on the low time carrier signal before allowing a switch to the high
time carrier
0 = Modulator output is not synchronized to the low time carrier signal(1)
bit 4
Unimplemented: Read as ‘0’
bit 3-0
MDCL Modulator Data High Carrier Selection bits (1)
1111 = Reserved. No channel connected.
•
•
•
1000 = Reserved. No channel connected.
0111 = CCP4 output (PWM Output mode only)
0110 = CCP3 output (PWM Output mode only)
0101 = CCP2 output (PWM Output mode only)
0100 = CCP1 output (PWM Output mode only)
0011 = Reference clock module signal
0010 = MDCIN2 port pin
0001 = MDCIN1 port pin
0000 = VSS
Note 1:
Narrowed carrier pulse widths or spurs may occur in the signal stream if the carrier is not synchronized.
TABLE 23-1:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH DATA SIGNAL MODULATOR MODE
Bit 6
Bit 5
Bit 4
MDCARH
MDCHODIS
MDCHPOL
MDCHSYNC
—
MDCH
190
MDCARL
MDCLODIS
MDCLPOL
MDCLSYNC
—
MDCL
191
MDCON
MDEN
MDOE
MDSLR
MDOPOL
MDSRC
MDMSODIS
Legend:
— = unimplemented, read as ‘0’. Shaded cells are not used in the Data Signal Modulator mode.
—
2012-2017 Microchip Technology Inc.
—
—
Bit 3
MDOUT
Bit 2
—
Bit 1
Bit 0
Register
on Page
Bit 7
MDBIT
—
MDMS
188
189
DS40001657C-page 191
PIC16LF1824T39A
24.0
CAPTURE/COMPARE/PWM
MODULES
Note 1: In devices with more than one CCP
module, it is very important to pay close
attention to the register names used. A
number placed after the module acronym
is used to distinguish between separate
modules. For example, the CCP1CON
and CCP2CON control the same
operational aspects of two completely
different CCP modules.
The Capture/Compare/PWM module is a peripheral
which allows the user to time and control different
events, and to generate Pulse-Width Modulation
(PWM) signals. In Capture mode, the peripheral allows
the timing of the duration of an event. The Compare
mode allows the user to trigger an external event when
a predetermined amount of time has expired. The
PWM mode can generate Pulse-Width Modulated
signals of varying frequency and duty cycle.
2: Throughout
this
section,
generic
references to a CCP module in any of its
operating modes may be interpreted as
being equally applicable to ECCP1,
ECCP2, CCP3 and CCP4. Register
names, module signals, I/O pins, and bit
names may use the generic designator ‘x’
to indicate the use of a numeral to
distinguish a particular module, when
required.
This family of devices contains two Enhanced Capture/
Compare/PWM modules (ECCP1 and ECCP2) and two
standard Capture/Compare/PWM modules (CCP3 and
CCP4).
The capture and compare functions are identical for all
four CCP modules (ECCP1, ECCP2, CCP3, and
CCP4). The only differences between CCP modules
are in the Pulse-Width Modulation (PWM) function. The
standard PWM function is identical in modules, CCP3
and CCP4. In CCP modules ECCP1 and ECCP2, the
Enhanced PWM function has slight variations from one
another. Full-Bridge ECCP modules have four
available I/O pins while Half-Bridge ECCP modules
only have two available I/O pins. See Table 24-1 for
more information.
TABLE 24-1:
PWM RESOURCES
Device Name
PIC16LF1824T39A
DS40001657C-page 192
ECCP1
ECCP2
CCP3
CCP4
Enhanced PWM
Full-Bridge
Enhanced PWM
Half-Bridge
Standard PWM
Standard PWM
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
24.1
Capture Mode
24.1.2
The Capture mode function described in this section is
available and identical for CCP modules ECCP1,
ECCP2, CCP3 and CCP4.
Capture mode makes use of the 16-bit Timer1
resource. When an event occurs on the CCPx pin, the
16-bit CCPRxH:CCPRxL register pair captures and
stores the 16-bit value of the TMR1H:TMR1L register
pair, respectively. An event is defined as one of the
following and is configured by the CCPxM bits of
the CCPxCON register:
•
•
•
•
Every falling edge
Every rising edge
Every 4th rising edge
Every 16th rising edge
When a capture is made, the Interrupt Request Flag bit
CCPxIF of the PIRx register is set. The interrupt flag
must be cleared in software. If another capture occurs
before the value in the CCPRxH, CCPRxL register pair
is read, the old captured value is overwritten by the new
captured value.
Figure 24-1 shows a simplified diagram of the Capture
operation.
24.1.1
CCP PIN CONFIGURATION
In Capture mode, the CCPx pin should be configured
as an input by setting the associated TRIS control bit.
Also, the CCPx pin function can be moved to
alternative pins using the APFCON1 register. Refer to
Section 12.1 “Alternate Pin Function” for more
details.
Note:
If the CCPx pin is configured as an output,
a write to the port can cause a capture
condition.
FIGURE 24-1:
Prescaler
1, 4, 16
CAPTURE MODE
OPERATION BLOCK
DIAGRAM
Set Flag bit CCPxIF
(PIRx register)
CCPx
pin
CCPRxH
and
Edge Detect
Capture
Enable
TMR1H
Timer1 must be running in Timer mode or Synchronized
Counter mode for the CCP module to use the capture
feature. In Asynchronous Counter mode, the capture
operation may not work.
See Section 21.0 “Timer1 Module with Gate Control”
for more information on configuring Timer1.
24.1.3
SOFTWARE INTERRUPT MODE
When the Capture mode is changed, a false capture
interrupt may be generated. The user should keep the
CCPxIE interrupt enable bit of the PIEx register clear to
avoid false interrupts. Additionally, the user should
clear the CCPxIF interrupt flag bit of the PIRx register
following any change in Operating mode.
Note:
24.1.4
Clocking Timer1 from the system clock
(FOSC) should not be used in Capture
mode. In order for Capture mode to
recognize the trigger event on the CCPx
pin, Timer1 must be clocked from the
instruction clock (FOSC/4) or from an
external clock source.
CCP PRESCALER
There are four prescaler settings specified by the
CCPxM bits of the CCPxCON register. Whenever
the CCP module is turned off, or the CCP module is not
in Capture mode, the prescaler counter is cleared. Any
Reset will clear the prescaler counter.
Switching from one capture prescaler to another does not
clear the prescaler and may generate a false interrupt. To
avoid this unexpected operation, turn the module off by
clearing the CCPxCON register before changing the
prescaler. Example 24-1 demonstrates the code to
perform this function.
EXAMPLE 24-1:
CHANGING BETWEEN
CAPTURE PRESCALERS
BANKSEL CCPxCON
CLRF
MOVLW
CCPRxL
TIMER1 MODE RESOURCE
MOVWF
;Set Bank bits to point
;to CCPxCON
CCPxCON
;Turn CCP module off
NEW_CAPT_PS ;Load the W reg with
;the new prescaler
;move value and CCP ON
CCPxCON
;Load CCPxCON with this
;value
TMR1L
CCPxM
System Clock (FOSC)
2012-2017 Microchip Technology Inc.
DS40001657C-page 193
PIC16LF1824T39A
24.1.5
CAPTURE DURING SLEEP
24.1.6
Capture mode depends upon the Timer1 module for
proper operation. There are two options for driving the
Timer1 module in Capture mode. It can be driven by the
instruction clock (FOSC/4), or by an external clock source.
ALTERNATE PIN LOCATIONS
This module incorporates I/O pins that can be moved to
other locations with the use of the alternate pin function
registers, APFCON0 and APFCON1. To determine
which pins can be moved and what their default locations are upon a Reset, see Section 12.1 “Alternate
Pin Function” for more information.
When Timer1 is clocked by FOSC/4, Timer1 will not
increment during Sleep. When the device wakes from
Sleep, Timer1 will continue from its previous state.
Capture mode will operate during Sleep when Timer1
is clocked by an external clock source.
TABLE 24-2:
Name
APFCON1
CCPxCON
SUMMARY OF REGISTERS ASSOCIATED WITH CAPTURE
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
—
—
—
—
P1DSEL
P1CSEL
P2BSEL
CCP2SEL
PxM(1)
DCxB
CCPxM
Register
on Page
114
215
CCPRxL
Capture/Compare/PWM Register x Low Byte (LSB)
193*
CCPRxH
Capture/Compare/PWM Register x High Byte (MSB)
193*
CxOE
CxPOL
—
CxSP
—
—
CxHYS
CxSYNC
CMxCON0
CxON
CxOUT
CMxCON1
CxINTP
CxINTN
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
CxPCH
CxNCH
160
161
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
INTCON
PIE2
OSFIE
C2IE
C1IE
EEIE
BCL1IE
—
—
CCP2IE
86
PIE3
—
—
CCP4IE
CCP3IE
TMR6IE
—
TMR4IE
—
87
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
89
—
—
PIR3
T1CON
T1GCON
TMR1CS1 TMR1CS0
TMR1GE
T1GPOL
CCP4IF
CCP3IF
TMR6IF
—
TMR4IF
—
90
T1CKPS1
T1CKPS0
T1OSCEN
T1SYNC
—
TMR1ON
175
T1GTM
T1GSPM
T1GGO/DONE
T1GVAL
T1GSS1
T1GSS0
TMR1L
Holding Register for the Least Significant Byte of the 16-bit TMR1 Register
TMR1H
Holding Register for the Most Significant Byte of the 16-bit TMR1 Register
176
171*
171*
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
Legend: — = unimplemented locations, read as ‘0’. Shaded cells are not used by the Capture.
* Page provides register information.
Note 1: Applies to ECCP modules only.
DS40001657C-page 194
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
24.2
Compare Mode
24.2.2
The Compare mode function described in this section
is available and identical for CCP modules ECCP1,
ECCP2, CCP3 and CCP4.
Compare mode makes use of the 16-bit Timer1
resource. The 16-bit value of the CCPRxH:CCPRxL
register pair is constantly compared against the 16-bit
value of the TMR1H:TMR1L register pair. When a
match occurs, one of the following events can occur:
•
•
•
•
•
In Compare mode, Timer1 must be running in either
Timer mode or Synchronized Counter mode. The
compare operation may not work in Asynchronous
Counter mode.
See Section 21.0 “Timer1 Module with Gate Control”
for more information on configuring Timer1.
Note:
Toggle the CCPx output
Set the CCPx output
Clear the CCPx output
Generate a Special Event Trigger
Generate a Software Interrupt
The action on the pin is based on the value of the
CCPxM control bits of the CCPxCON register. At
the same time, the interrupt flag CCPxIF bit is set.
All Compare modes can generate an interrupt.
Figure 24-2 shows a simplified diagram of the
Compare operation.
FIGURE 24-2:
COMPARE MODE
OPERATION BLOCK
DIAGRAM
CCPxM
Mode Select
Set CCPxIF Interrupt Flag
(PIRx)
4
CCPRxH CCPRxL
CCPx
Pin
Q
S
R
Output
Logic
Match
TRIS
Output Enable
Comparator
TMR1H
TMR1L
Special Event Trigger
24.2.1
CCP PIN CONFIGURATION
The user must configure the CCPx pin as an output by
clearing the associated TRIS bit.
Also, the CCPx pin function can be moved to
alternative pins using the APFCON1 register. Refer to
Section 12.1 “Alternate Pin Function” for more
details.
Note:
Clearing the CCPxCON register will force
the CCPx compare output latch to the
default low level. This is not the PORT I/O
data latch.
2012-2017 Microchip Technology Inc.
TIMER1 MODE RESOURCE
24.2.3
Clocking Timer1 from the system clock
(FOSC) should not be used in Compare
mode. In order for Compare mode to
recognize the trigger event on the CCPx
pin, TImer1 must be clocked from the
instruction clock (FOSC/4) or from an
external clock source.
SOFTWARE INTERRUPT MODE
When Generate Software Interrupt mode is chosen
(CCPxM = 1010), the CCPx module does not
assert control of the CCPx pin (see the CCPxCON
register).
24.2.4
SPECIAL EVENT TRIGGER
When Special Event Trigger mode is chosen
(CCPxM = 1011), the CCPx module does the
following:
• Resets Timer1
• Starts an ADC conversion if ADC is enabled
The CCPx module does not assert control of the CCPx
pin in this mode.
The Special Event Trigger output of the CCP occurs
immediately upon a match between the TMR1H,
TMR1L register pair and the CCPRxH, CCPRxL
register pair. The TMR1H, TMR1L register pair is not
reset until the next rising edge of the Timer1 clock. The
Special Event Trigger output starts an A/D conversion
(if the A/D module is enabled). This allows the
CCPRxH, CCPRxL register pair to effectively provide a
16-bit programmable period register for Timer1.
TABLE 24-3:
SPECIAL EVENT TRIGGER
Device
PIC16LF1824T39A
CCPx/ECCPx
CCP4
Refer to Section 16.2.5 “Special Event Trigger” for
more information.
Note 1: The Special Event Trigger from the CCP
module does not set interrupt flag bit
TMR1IF of the PIR1 register.
2: Removing the match condition by
changing the contents of the CCPRxH
and CCPRxL register pair, between the
clock edge that generates the Special
Event Trigger and the clock edge that
generates the Timer1 Reset, will
preclude the Reset from occurring.
DS40001657C-page 195
PIC16LF1824T39A
24.2.5
COMPARE DURING SLEEP
24.2.6
The Compare mode is dependent upon the system
clock (FOSC) for proper operation. Since FOSC is shut
down during Sleep mode, the Compare mode will not
function properly during Sleep.
TABLE 24-4:
Name
APFCON1
CCPxCON
ALTERNATE PIN LOCATIONS
This module incorporates I/O pins that can be moved to
other locations with the use of the alternate pin function
registers, APFCON0 and APFCON1. To determine
which pins can be moved and what their default locations are upon a Reset, see Section 12.1 “Alternate
Pin Function” for more information.
SUMMARY OF REGISTERS ASSOCIATED WITH COMPARE
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
—
—
—
—
P1DSEL
P1CSEL
P2BSEL
CCP2SEL
PxM(1)
DCxB
CCPxM
Register
on Page
114
215
CCPRxL
Capture/Compare/PWM Register x Low Byte (LSB)
193*
CCPRxH
Capture/Compare/PWM Register x High Byte (MSB)
193*
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIE2
OSFIE
C2IE
C1IE
EEIE
BCL1IE
—
—
CCP2IE
86
PIE3
—
—
CCP4IE
CCP3IE
TMR6IE
—
TMR4IE
—
87
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
89
PIR3
—
—
CCP4IF
CCP3IF
TMR6IF
—
TMR4IF
—
90
T1CON
TMR1CS
T1OSCEN
T1SYNC
—
TMR1ON
175
T1GGO/DONE
T1GVAL
T1GCON
TMR1GE
T1GPOL
T1CKPS
T1GTM
T1GSPM
TMR1L
Holding Register for the Least Significant Byte of the 16-bit TMR1 Register
TMR1H
Holding Register for the Most Significant Byte of the 16-bit TMR1 Register
TRISA
TRISC
—
—
T1GSS
176
171*
171*
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used by Compare mode.
* Page provides register information.
Note 1: Applies to ECCP modules only.
DS40001657C-page 196
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
24.3
PWM Overview
Pulse-Width Modulation (PWM) is a scheme that
provides power to a load by switching quickly between
fully on and fully off states. The PWM signal resembles
a square wave where the high portion of the signal is
considered the on state and the low portion of the signal
is considered the off state. The high portion, also known
as the pulse width, can vary in time and is defined in
steps. A larger number of steps applied, which
lengthens the pulse width, also supplies more power to
the load. Lowering the number of steps applied, which
shortens the pulse width, supplies less power. The
PWM period is defined as the duration of one complete
cycle or the total amount of on and off time combined.
PWM resolution defines the maximum number of steps
that can be present in a single PWM period. A higher
resolution allows for more precise control of the pulse
width time and in turn the power that is applied to the
load.
FIGURE 24-3:
Period
Pulse Width
24.3.1
TMRx = 0
FIGURE 24-4:
The standard PWM mode generates a Pulse-Width
Modulation (PWM) signal on the CCPx pin with up to 10
bits of resolution. The period, duty cycle, and resolution
are controlled by the following registers:
•
•
•
•
SIMPLIFIED PWM BLOCK
DIAGRAM
CCPxCON
Duty Cycle Registers
CCPRxL
CCPRxH(2) (Slave)
CCPx
R
Comparator
TMRx
(1)
Q
S
TRIS
Comparator
STANDARD PWM OPERATION
The standard PWM function described in this section is
available and identical for CCP modules ECCP1,
ECCP2, CCP3 and CCP4.
TMRx = PRx
TMRx = CCPRxH:CCPxCON
The term duty cycle describes the proportion of the on
time to the off time and is expressed in percentages,
where 0% is fully off and 100% is fully on. A lower duty
cycle corresponds to less power applied and a higher
duty cycle corresponds to more power applied.
Figure 24-3 shows a typical waveform of the PWM
signal.
CCP PWM OUTPUT SIGNAL
PRx
Note 1:
2:
Clear Timer,
toggle CCPx pin and
latch duty cycle
The 8-bit timer TMRx register is concatenated
with the 2-bit internal system clock (FOSC), or
two bits of the prescaler, to create the 10-bit
time base.
In PWM mode, CCPRxH is a read-only register.
PRx registers
TxCON registers
CCPRxL registers
CCPxCON registers
Figure 24-4 shows a simplified block diagram of PWM
operation.
Note 1: The corresponding TRIS bit must be
cleared to enable the PWM output on the
CCPx pin.
2: Clearing the CCPxCON register will
relinquish control of the CCPx pin.
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PIC16LF1824T39A
24.3.2
SETUP FOR PWM OPERATION
The following steps should be taken when configuring
the CCP module for standard PWM operation:
1.
2.
3.
4.
5.
6.
Disable the CCPx pin output driver by setting the
associated TRIS bit.
Load the PRx register with the PWM period
value.
Configure the CCP module for the PWM mode
by loading the CCPxCON register with the
appropriate values.
Load the CCPRxL register and the DCxBx bits
of the CCPxCON register, with the PWM duty
cycle value.
Configure and start Timer2/4/6:
• Select the Timer2/4/6 resource to be used
for PWM generation by setting the
CxTSEL bits in the CCPTMRSx
register.
• Clear the TMRxIF interrupt flag bit of the
PIRx register. See Note below.
• Configure the TxCKPS bits of the TxCON
register with the Timer prescale value.
• Enable the Timer by setting the TMRxON
bit of the TxCON register.
Enable PWM output pin:
• Wait until the Timer overflows and the
TMRxIF bit of the PIRx register is set. See
Note below.
• Enable the CCPx pin output driver by
clearing the associated TRIS bit.
Note:
24.3.3
In order to send a complete duty cycle and
period on the first PWM output, the above
steps must be included in the setup
sequence. If it is not critical to start with a
complete PWM signal on the first output,
then step 6 may be ignored.
TIMER2/4/6 TIMER RESOURCE
The PWM standard mode makes use of one of the 8-bit
Timer2/4/6 timer resources to specify the PWM period.
Configuring the CxTSEL bits in the CCPTMRSx
register selects which Timer2/4/6 timer is used.
24.3.4
PWM PERIOD
The PWM period is specified by the PRx register of
Timer2/4/6. The PWM period can be calculated using
the formula of Equation 24-1.
EQUATION 24-1:
PWM PERIOD
PWM Period = PRx + 1 4 T OSC
When TMRx is equal to PRx, the following three events
occur on the next increment cycle:
• TMRx is cleared
• The CCPx pin is set. (Exception: If the PWM duty
cycle = 0%, the pin will not be set.)
• The PWM duty cycle is latched from CCPRxL into
CCPRxH
Note:
24.3.5
The Timer postscaler (see Section 22.1
“Timer2/4/6 Operation”) is not used in the
determination of the PWM frequency.
PWM DUTY CYCLE
The PWM duty cycle is specified by writing a 10-bit
value to multiple registers: CCPRxL register and
DCxB bits of the CCPxCON register. The
CCPRxL contains the eight MSbs and the DCxB
bits of the CCPxCON register contain the two LSbs.
CCPRxL and DCxB bits of the CCPxCON
register can be written to at any time. The duty cycle
value is not latched into CCPRxH until after the period
completes (i.e., a match between PRx and TMRx
registers occurs). While using the PWM, the CCPRxH
register is read-only.
Equation 24-2 is used to calculate the PWM pulse
width.
Equation 24-3 is used to calculate the PWM duty cycle
ratio.
EQUATION 24-2:
PULSE WIDTH
Pulse Width = CCPRxL:CCPxCON
T OSC (TMRx Prescale Value)
EQUATION 24-3:
DUTY CYCLE RATIO
CCPRxL:CCPxCON Duty Cycle Ratio = ---------------------------------------------------------------------4 PRx + 1
The CCPRxH register and a 2-bit internal latch are
used to double buffer the PWM duty cycle. This double
buffering is essential for glitchless PWM operation.
The 8-bit timer TMRx register is concatenated with either
the 2-bit internal system clock (FOSC), or two bits of the
prescaler, to create the 10-bit time base. The system
clock is used if the Timer2/4/6 prescaler is set to 1:1.
When the 10-bit time base matches the CCPRxH and
2-bit latch, then the CCPx pin is cleared (see
Figure 24-4).
(TMRx Prescale Value)
Note 1:
TOSC = 1/FOSC
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PIC16LF1824T39A
24.3.6
PWM RESOLUTION
EQUATION 24-4:
The resolution determines the number of available duty
cycles for a given period. For example, a 10-bit resolution
will result in 1024 discrete duty cycles, whereas an 8-bit
resolution will result in 256 discrete duty cycles.
The maximum PWM resolution is 10 bits when PRx is
255. The resolution is a function of the PRx register
value as shown by Equation 24-4.
TABLE 24-5:
Note:
If the pulse width value is greater than the
period the assigned PWM pin(s) will
remain unchanged.
1.95 kHz
7.81 kHz
31.25 kHz
125 kHz
250 kHz
333.3 kHz
16
4
1
1
1
1
0xFF
0xFF
0xFF
0x3F
0x1F
0x17
10
10
10
8
7
6.6
Timer Prescale
PRx Value
Maximum Resolution (bits)
EXAMPLE PWM FREQUENCIES AND RESOLUTIONS (FOSC = 20 MHz)
PWM Frequency
1.22 kHz
Timer Prescale
PRx Value
Maximum Resolution (bits)
TABLE 24-7:
4 PRx + 1 - bits
Resolution = log
----------------------------------------log 2
EXAMPLE PWM FREQUENCIES AND RESOLUTIONS (FOSC = 32 MHz)
PWM Frequency
TABLE 24-6:
PWM RESOLUTION
4.88 kHz
19.53 kHz
78.12 kHz
156.3 kHz
208.3 kHz
16
4
1
1
1
1
0xFF
0xFF
0xFF
0x3F
0x1F
0x17
10
10
10
8
7
6.6
EXAMPLE PWM FREQUENCIES AND RESOLUTIONS (FOSC = 8 MHz)
PWM Frequency
1.22 kHz
4.90 kHz
19.61 kHz
76.92 kHz
153.85 kHz
200.0 kHz
16
4
1
1
1
1
0x65
0x65
0x65
0x19
0x0C
0x09
8
8
8
6
5
5
Timer Prescale
PRx Value
Maximum Resolution (bits)
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PIC16LF1824T39A
24.3.7
OPERATION IN SLEEP MODE
24.3.10
In Sleep mode, the TMRx register will not increment
and the state of the module will not change. If the CCPx
pin is driving a value, it will continue to drive that value.
When the device wakes up, TMRx will continue from its
previous state.
24.3.8
CHANGES IN SYSTEM CLOCK
FREQUENCY
ALTERNATE PIN LOCATIONS
This module incorporates I/O pins that can be moved to
other locations with the use of the alternate pin function
registers, APFCON0 and APFCON1. To determine
which pins can be moved and what their default locations are upon a Reset, see Section 12.1 “Alternate
Pin Function” for more information.
The PWM frequency is derived from the system clock
frequency. Any changes in the system clock frequency
will result in changes to the PWM frequency. See
Section 5.0 “Oscillator Module (With Fail-Safe
Clock Monitor)” for additional details.
24.3.9
EFFECTS OF RESET
Any Reset will force all ports to Input mode and the
CCP registers to their Reset states.
TABLE 24-8:
Name
APFCON1
SUMMARY OF REGISTERS ASSOCIATED WITH STANDARD PWM
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
—
—
—
—
P1DSEL
P1CSEL
P2BSEL
CCP2SEL
PxM(1)
DCxB
CCPTMRS0
C4TSEL
C3TSEL
INLVLA
—
CCPxCON
CCPxM
C2TSEL
Register
on Page
114
215
C1TSEL
216
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIE2
OSFIE
C2IE
C1IE
EEIE
BCLIE
—
—
CCP2IE
86
PIE3
—
—
CCP4IE
CCP3IE
TMR6IE
—
TMR4IE
—
87
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
89
PIR3
—
—
CCP4IF
CCP3IF
TMR6IF
—
TMR4IF
—
90
PRx
TxCON
TMRx
TRISA
TRISC
Timer2/4/6 Period Register
—
179*
TxOUTPS
TMRxON
TxCKPS1
Timer2/4/6 Module Register
—
—
181
179*
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used by the PWM.
* Page provides register information.
Note 1: Applies to ECCP modules only.
DS40001657C-page 200
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PIC16LF1824T39A
24.4
PWM (Enhanced Mode)
To select an Enhanced PWM Output mode, the PxM bits
of the CCPxCON register must be configured
appropriately.
The enhanced PWM function described in this section is
available for CCP modules ECCP1, ECCP2 and
ECCP3, with any differences between modules noted.
The PWM outputs are multiplexed with I/O pins and are
designated PxA, PxB, PxC and PxD. The polarity of the
PWM pins is configurable and is selected by setting the
CCPxM bits in the CCPxCON register appropriately.
The enhanced PWM mode generates a Pulse-Width
Modulation (PWM) signal on up to four different output
pins with up to 10 bits of resolution. The period, duty
cycle, and resolution are controlled by the following
registers:
•
•
•
•
Figure 24-5 shows an example of a simplified block
diagram of the Enhanced PWM module.
Table 24-9 shows the pin assignments for various
Enhanced PWM modes.
PRx registers
TxCON registers
CCPRxL registers
CCPxCON registers
Note 1: The corresponding TRIS bit must be
cleared to enable the PWM output on the
CCPx pin.
The ECCP modules have the following additional PWM
registers which control Auto-shutdown, Auto-restart,
Dead-band Delay and PWM Steering modes:
2: Clearing the CCPxCON register will
relinquish control of the CCPx pin.
3: Any pin not used in the enhanced PWM
mode is available for alternate pin
functions, if applicable.
• CCPxAS registers
• PSTRxCON registers
• PWMxCON registers
4: To prevent the generation of an
incomplete waveform when the PWM is
first enabled, the ECCP module waits
until the start of a new PWM period
before generating a PWM signal.
The enhanced PWM module can generate the following
five PWM Output modes:
•
•
•
•
•
Single PWM
Half-Bridge PWM
Full-Bridge PWM, Forward Mode
Full-Bridge PWM, Reverse Mode
Single PWM with PWM Steering Mode
FIGURE 24-5:
EXAMPLE SIMPLIFIED BLOCK DIAGRAM OF THE ENHANCED PWM MODE
Duty Cycle Registers
DCxB
CCPxM
4
PxM
2
CCPRxL
CCPx/PxA
CCPx/PxA
TRISx
CCPRxH (Slave)
PxB
R
Comparator
Q
Output
Controller
PxB
TRISx
PxC
TMRx
Comparator
PRx
Note
1:
(1)
PxC
TRISx
S
PxD
Clear Timer,
toggle PWM pin and
latch duty cycle
PxD
TRISx
PWMxCON
The 8-bit timer TMRx register is concatenated with the 2-bit internal Q clock, or two bits of the prescaler to create the 10-bit time
base.
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PIC16LF1824T39A
TABLE 24-9:
EXAMPLE PIN ASSIGNMENTS FOR VARIOUS PWM ENHANCED MODES
ECCP Mode
Single
PxM
CCPx/PxA
PxB
PxC
PxD
00
Yes(1)
Yes(1)
Yes(1)
Yes(1)
Half-Bridge
10
Yes
Yes
No
No
Full-Bridge, Forward
01
Yes
Yes
Yes
Yes
Full-Bridge, Reverse
11
Yes
Yes
Yes
Yes
Note 1:
PWM Steering enables outputs in Single mode.
FIGURE 24-6:
EXAMPLE PWM (ENHANCED MODE) OUTPUT RELATIONSHIPS (ACTIVE-HIGH
STATE)
PxM
Signal
PRX+1
Pulse
Width
0
Period
00
(Single Output)
PxA Modulated
Delay
Delay
PxA Modulated
10
(Half-Bridge)
PxB Modulated
PxA Active
01
(Full-Bridge,
Forward)
PxB Inactive
PxC Inactive
PxD Modulated
PxA Inactive
11
(Full-Bridge,
Reverse)
PxB Modulated
PxC Active
PxD Inactive
Relationships:
• Period = 4 * TOSC * (PRx + 1) * (TMRx Prescale Value)
• Pulse Width = TOSC * (CCPRxL:CCPxCON) * (TMRx Prescale Value)
• Delay = 4 * TOSC * (PWMxCON)
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PIC16LF1824T39A
FIGURE 24-7:
EXAMPLE ENHANCED PWM OUTPUT RELATIONSHIPS (ACTIVE-LOW STATE)
PxM
Signal
PRx+1
Pulse
Width
0
Period
00
(Single Output)
PxA Modulated
PxA Modulated
10
(Half-Bridge)
Delay
Delay
PxB Modulated
PxA Active
01
(Full-Bridge,
Forward)
PxB Inactive
PxC Inactive
PxD Modulated
PxA Inactive
11
(Full-Bridge,
Reverse)
PxB Modulated
PxC Active
PxD Inactive
Relationships:
• Period = 4 * TOSC * (PRx + 1) * (TMRx Prescale Value)
• Pulse Width = TOSC * (CCPRxL:CCPxCON) * (TMRx Prescale Value)
• Delay = 4 * TOSC * (PWMxCON)
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PIC16LF1824T39A
24.4.1
HALF-BRIDGE MODE
In Half-Bridge mode, two pins are used as outputs to
drive push-pull loads. The PWM output signal is output
on the CCPx/PxA pin, while the complementary PWM
output signal is output on the PxB pin (see Figure 24-9).
This mode can be used for Half-Bridge applications, as
shown in Figure 24-9, or for Full-Bridge applications,
where four power switches are being modulated with
two PWM signals.
In Half-Bridge mode, the programmable dead-band delay
can be used to prevent shoot-through current in HalfBridge power devices. The value of the PDC bits of
the PWMxCON register sets the number of instruction
cycles before the output is driven active. If the value is
greater than the duty cycle, the corresponding output
remains inactive during the entire cycle. See
Section 24.4.5 “Programmable Dead-Band Delay
Mode” for more details of the dead-band delay
operations.
Since the PxA and PxB outputs are multiplexed with the
PORT data latches, the associated TRIS bits must be
cleared to configure PxA and PxB as outputs.
FIGURE 24-8:
Period
Period
Pulse Width
PxA(2)
td
td
PxB(2)
(1)
(1)
(1)
td = Dead-Band Delay
Note 1:
2:
FIGURE 24-9:
EXAMPLE OF HALFBRIDGE PWM OUTPUT
At this time, the TMRx register is equal to the
PRx register.
Output signals are shown as active-high.
EXAMPLE OF HALF-BRIDGE APPLICATIONS
Standard Half-Bridge Circuit (“Push-Pull”)
FET
Driver
+
PxA
Load
FET
Driver
+
PxB
-
Half-Bridge Output Driving a Full-Bridge Circuit
V+
FET
Driver
FET
Driver
PxA
FET
Driver
Load
FET
Driver
PxB
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PIC16LF1824T39A
24.4.2
FULL-BRIDGE MODE
In Full-Bridge mode, all four pins are used as outputs.
An example of Full-Bridge application is shown in
Figure 24-10.
In the Forward mode, pin CCPx/PxA is driven to its active
state, pin PxD is modulated, while PxB and PxC will be
driven to their inactive state as shown in Figure 24-11.
In the Reverse mode, PxC is driven to its active state, pin
PxB is modulated, while PxA and PxD will be driven to
their inactive state as shown Figure 24-11.
PxA, PxB, PxC and PxD outputs are multiplexed with
the PORT data latches. The associated TRIS bits must
be cleared to configure the PxA, PxB, PxC and PxD
pins as outputs.
FIGURE 24-10:
EXAMPLE OF FULL-BRIDGE APPLICATION
V+
FET
Driver
QC
QA
FET
Driver
PxA
Load
PxB
FET
Driver
PxC
FET
Driver
QD
QB
VPxD
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DS40001657C-page 205
PIC16LF1824T39A
FIGURE 24-11:
EXAMPLE OF FULL-BRIDGE PWM OUTPUT
Forward Mode
Period
PxA
(2)
Pulse Width
PxB(2)
PxC(2)
PxD(2)
(1)
(1)
Reverse Mode
Period
Pulse Width
PxA(2)
PxB(2)
PxC(2)
PxD(2)
(1)
Note 1:
2:
(1)
At this time, the TMRx register is equal to the PRx register.
Output signal is shown as active-high.
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PIC16LF1824T39A
24.4.2.1
Direction Change in Full-Bridge
Mode
In the Full-Bridge mode, the PxM1 bit in the CCPxCON
register allows users to control the forward/reverse
direction. When the application firmware changes this
direction control bit, the module will change to the new
direction on the next PWM cycle.
A direction change is initiated in software by changing
the PxM1 bit of the CCPxCON register. The following
sequence occurs four Timer cycles prior to the end of
the current PWM period:
• The modulated outputs (PxB and PxD) are placed
in their inactive state.
• The associated unmodulated outputs (PxA and
PxC) are switched to drive in the opposite
direction.
• PWM modulation resumes at the beginning of the
next period.
See Figure 24-12 for an illustration of this sequence.
The Full-Bridge mode does not provide dead-band
delay. As one output is modulated at a time, dead-band
delay is generally not required. There is a situation
where dead-band delay is required. This situation
occurs when both of the following conditions are true:
1.
2.
The direction of the PWM output changes when
the duty cycle of the output is at or near 100%.
The turn off time of the power switch, including
the power device and driver circuit, is greater
than the turn on time.
Figure 24-13 shows an example of the PWM direction
changing from forward to reverse, at a near 100% duty
cycle. In this example, at time t1, the output PxA and
PxD become inactive, while output PxC becomes
active. Since the turn off time of the power devices is
longer than the turn on time, a shoot-through current
will flow through power devices QC and QD (see
Figure 24-10) for the duration of ‘t’. The same
phenomenon will occur to power devices QA and QB
for PWM direction change from reverse to forward.
If changing PWM direction at high duty cycle is required
for an application, two possible solutions for eliminating
the shoot-through current are:
1.
2.
Reduce PWM duty cycle for one PWM period
before changing directions.
Use switch drivers that can drive the switches off
faster than they can drive them on.
Other options to prevent shoot-through current may
exist.
FIGURE 24-12:
EXAMPLE OF PWM DIRECTION CHANGE
Period(1)
Signal
Period
PxA (Active-High)
PxB (Active-High)
Pulse Width
PxC (Active-High)
(2)
PxD (Active-High)
Pulse Width
Note 1: The direction bit PxM1 of the CCPxCON register is written any time during the PWM cycle.
2: When changing directions, the PxA and PxC signals switch before the end of the current PWM cycle. The
modulated PxB and PxD signals are inactive at this time. The length of this time is four Timer counts.
2012-2017 Microchip Technology Inc.
DS40001657C-page 207
PIC16LF1824T39A
FIGURE 24-13:
EXAMPLE OF PWM DIRECTION CHANGE AT NEAR 100% DUTY CYCLE
Forward Period
t1
Reverse Period
PxA
PxB
PW
PxC
PxD
PW
TON
External Switch C
TOFF
External Switch D
Potential
Shoot-Through Current
Note 1:
T = TOFF – TON
All signals are shown as active-high.
2:
TON is the turn-on delay of power switch QC and its driver.
3:
TOFF is the turn-off delay of power switch QD and its driver.
DS40001657C-page 208
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PIC16LF1824T39A
24.4.3
ENHANCED PWM AUTOSHUTDOWN MODE
The PWM mode supports an Auto-Shutdown mode that
will disable the PWM outputs when an external
shutdown event occurs. Auto-Shutdown mode places
the PWM output pins into a predetermined state. This
mode is used to help prevent the PWM from damaging
the application.
Note 1: The auto-shutdown condition is a levelbased signal, not an edge-based signal.
As long as the level is present, the autoshutdown will persist.
2: Writing to the CCPxASE bit is disabled
while an auto-shutdown condition
persists.
The auto-shutdown sources are selected using the
CCPxAS bits of the CCPxAS register. A shutdown
event may be generated by:
3: Once the auto-shutdown condition has
been removed and the PWM restarted
(either through firmware or auto-restart)
the PWM signal will always restart at the
beginning of the next PWM period.
• A logic ‘0’ on the FLT0 pin
• A logic ‘1’ on a Comparator (Cx) output
4: Prior to an auto-shutdown event caused
by a comparator output or FLT0 pin event,
a software shutdown can be triggered in
firmware by setting the CCPxASE bit of
the CCPxAS register to ‘1’. The AutoRestart feature tracks the active status of
a shutdown caused by a comparator output or FLT0 pin event only. If it is enabled
at this time, it will immediately clear this
bit and restart the ECCP module at the
beginning of the next PWM period.
A shutdown condition is indicated by the CCPxASE
(Auto-Shutdown Event Status) bit of the CCPxAS
register. If the bit is a ‘0’, the PWM pins are operating
normally. If the bit is a ‘1’, the PWM outputs are in the
shutdown state.
When a shutdown event occurs, two things happen:
The CCPxASE bit is set to ‘1’. The CCPxASE will
remain set until cleared in firmware or an auto-restart
occurs (see Section 24.4.4 “Auto-restart Mode”).
The enabled PWM pins are asynchronously placed in
their shutdown states. The PWM output pins are
grouped into pairs [PxA/PxC] and [PxB/PxD]. The state
of each pin pair is determined by the PSSxAC and
PSSxBD bits of the CCPxAS register. Each pin pair may
be placed into one of three states:
• Drive logic ‘1’
• Drive logic ‘0’
• Tri-state (high-impedance)
FIGURE 24-14:
PWM AUTO-SHUTDOWN WITH FIRMWARE RESTART (PXRSEN = 0)
Missing Pulse
(Auto-Shutdown)
Timer
Overflow
Timer
Overflow
Missing Pulse
(CCPxASE not clear)
Timer
Overflow
Timer
Overflow
Timer
Overflow
PWM Period
PWM Activity
Start of
PWM Period
Shutdown Event
CCPxASE bit
Shutdown
Event Occurs
2012-2017 Microchip Technology Inc.
Shutdown
Event Clears
PWM
Resumes
CCPxASE
Cleared by
Firmware
DS40001657C-page 209
PIC16LF1824T39A
24.4.4
AUTO-RESTART MODE
The Enhanced PWM can be configured to automatically restart the PWM signal once the auto-shutdown
condition has been removed. Auto-restart is enabled by
setting the PxRSEN bit in the PWMxCON register.
FIGURE 24-15:
If auto-restart is enabled, the CCPxASE bit will remain
set as long as the auto-shutdown condition is active.
When the auto-shutdown condition is removed, the
CCPxASE bit will be cleared via hardware and normal
operation will resume.
PWM AUTO-SHUTDOWN WITH AUTO-RESTART (PXRSEN = 1)
Missing Pulse
(Auto-Shutdown)
Timer
Overflow
Timer
Overflow
Missing Pulse
(CCPxASE not clear)
Timer
Overflow
Timer
Overflow
Timer
Overflow
PWM Period
PWM Activity
Start of
PWM Period
Shutdown Event
CCPxASE bit
PWM
Resumes
Shutdown
Event Occurs
Shutdown
Event Clears
DS40001657C-page 210
CCPxASE
Cleared by
Hardware
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
24.4.5
PROGRAMMABLE DEAD-BAND
DELAY MODE
FIGURE 24-16:
In Half-Bridge applications where all power switches
are modulated at the PWM frequency, the power
switches normally require more time to turn off than to
turn on. If both the upper and lower power switches are
switched at the same time (one turned on, and the
other turned off), both switches may be on for a short
period of time until one switch completely turns off.
During this brief interval, a very high current (shootthrough current) will flow through both power switches,
shorting the bridge supply. To avoid this potentially
destructive shoot-through current from flowing during
switching, turning on either of the power switches is
normally delayed to allow the other switch to
completely turn off.
Period
Period
Pulse Width
PxA
(2)
td
td
PxB(2)
(1)
(1)
(1)
td = Dead-Band Delay
Note 1: At this time, the TMRx register is equal to the
PRx register.
2: Output signals are shown as active-high.
In Half-Bridge mode, a digitally programmable deadband delay is available to avoid shoot-through current
from destroying the bridge power switches. The delay
occurs at the signal transition from the non-active state
to the active state. See Figure 24-16 for illustration.
The lower seven bits of the associated PWMxCON
register (Register 24-4) sets the delay period in terms
of microcontroller instruction cycles (TCY or 4 TOSC).
FIGURE 24-17:
EXAMPLE OF HALFBRIDGE PWM OUTPUT
EXAMPLE OF HALF-BRIDGE APPLICATIONS
V+
Standard Half-Bridge Circuit (“Push-Pull”)
FET
Driver
+
V
-
PxA
Load
FET
Driver
+
V
-
PxB
V-
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24.4.6
PWM STEERING MODE
In Single Output mode, PWM steering allows any of the
PWM pins to be the modulated signal. Additionally, the
same PWM signal can be simultaneously available on
multiple pins.
Once the Single Output mode is selected
(CCPxM = 11 and PxM = 00 of the
CCPxCON register), the user firmware can bring out
the same PWM signal to one, two, three or four output
pins by setting the appropriate STRx bits of the
PSTRxCON register, as shown in Table 24-9.
Note:
The associated TRIS bits must be set to
output (‘0’) to enable the pin output driver
in order to see the PWM signal on the pin.
While the PWM Steering mode is active, CCPxM
bits of the CCPxCON register select the PWM output
polarity for the Px pins.
The PWM auto-shutdown operation also applies to
PWM Steering mode as described in Section 24.4.3
“Enhanced PWM Auto-shutdown mode”. An autoshutdown event will only affect pins that have PWM
outputs enabled.
FIGURE 24-18:
SIMPLIFIED STEERING
BLOCK DIAGRAM
STRxA
PxA Signal
CCPxM1
PORT Data
0
STRxB
CCPxM0
PORT Data
PORT Data
0
PORT Data
PxB pin
TRIS
PxC pin
1
0
TRIS
STRxD
CCPxM0
TRIS
1
STRxC
CCPxM1
PxA pin
1
PxD pin
1
0
TRIS
Note 1:
Port outputs are configured as shown when
the CCPxCON register bits PxM = 00
and CCPxM = 11.
2:
Single PWM output requires setting at least
one of the STRx bits.
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PIC16LF1824T39A
24.4.6.1
Steering Synchronization
The STRxSYNC bit of the PSTRxCON register gives
the user two selections of when the steering event will
happen. When the STRxSYNC bit is ‘0’, the steering
event will happen at the end of the instruction that
writes to the PSTRxCON register. In this case, the
output signal at the Px pins may be an
incomplete PWM waveform. This operation is useful
when the user firmware needs to immediately remove
a PWM signal from the pin.
When the STRxSYNC bit is ‘1’, the effective steering
update will happen at the beginning of the next PWM
period. In this case, steering on/off the PWM output will
always produce a complete PWM waveform.
configuration while the PWM pin output drivers are
enable is not recommended since it may result in
damage to the application circuits.
The PxA, PxB, PxC and PxD output latches may not be
in the proper states when the PWM module is
initialized. Enabling the PWM pin output drivers at the
same time as the Enhanced PWM modes may cause
damage to the application circuit. The Enhanced PWM
modes must be enabled in the proper Output mode and
complete a full PWM cycle before enabling the PWM
pin output drivers. The completion of a full PWM cycle
is indicated by the TMRxIF bit of the PIRx register
being set as the second PWM period begins.
Note:
Figures 24-19 and 24-20 illustrate the timing diagrams
of the PWM steering depending on the STRxSYNC
setting.
24.4.7
START-UP CONSIDERATIONS
When any PWM mode is used, the application
hardware must use the proper external pull-up and/or
pull-down resistors on the PWM output pins.
The CCPxM bits of the CCPxCON register allow
the user to choose whether the PWM output signals are
active-high or active-low for each pair of PWM output
pins (PxA/PxC and PxB/PxD). The PWM output
polarities must be selected before the PWM pin output
drivers are enabled. Changing the polarity
FIGURE 24-19:
24.4.8
When the microcontroller is released from
Reset, all of the I/O pins are in the highimpedance state. The external circuits
must keep the power switch devices in the
Off state until the microcontroller drives
the I/O pins with the proper signal levels or
activates the PWM output(s).
ALTERNATE PIN LOCATIONS
This module incorporates I/O pins that can be moved to
other locations with the use of the alternate pin function
registers, APFCON0 and APFCON1. To determine
which pins can be moved and what their default locations are upon a Reset, see Section 12.1 “Alternate
Pin Function” for more information.
EXAMPLE OF STEERING EVENT AT END OF INSTRUCTION (STRxSYNC = 0)
PWM Period
PWM
STRx
P1
PORT Data
PORT Data
P1n = PWM
FIGURE 24-20:
EXAMPLE OF STEERING EVENT AT BEGINNING OF INSTRUCTION
(STRxSYNC = 1)
PWM
STRx
P1
PORT Data
PORT Data
P1n = PWM
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TABLE 24-10: SUMMARY OF REGISTERS ASSOCIATED WITH ENHANCED PWM
Name
APFCON1
CCPxCON
CCPxAS
Bit 7
—
PxM
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
—
—
—
P1DSEL
P1CSEL
P2BSEL
CCP2SEL
114
(1)
CCPxASE
DCxB
CCPxAS
CCPTMRS0
C4TSEL
INLVLA
—
CCPxM
PSSxAC
C3TSEL
C2TSEL
215
PSSxBD
217
C1TSEL
216
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIE2
OSFIE
C2IE
C1IE
EEIE
BCLIE
—
—
CCP2IE
86
PIE3
—
—
CCP4IE
CCP3IE
TMR6IE
—
TMR4IE
—
87
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
89
PIR3
—
—
CCP4IF
CCP3IF
TMR6IF
—
TMR4IF
—
90
—
STRxSYNC
STRxD
STRxC
STRxB
STRxA
PRx
Timer2/4/6 Period Register
PSTRxCON
—
PWMxCON
PxRSEN
—
179*
PxDC
TxOUTPS
219
218
TxCON
—
TMRxON
TxCKPS1
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
181
Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used by the PWM.
* Page provides register information.
Note 1: Applies to ECCP modules only.
DS40001657C-page 214
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PIC16LF1824T39A
REGISTER 24-1:
R/W-00
CCPxCON: CCPx CONTROL REGISTER
R/W-0/0
R/W-0/0
PxM(1)
R/W-0/0
R/W-0/0
DCxB
R/W-0/0
R/W-0/0
R/W-0/0
CCPxM
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Reset
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
PxM: Enhanced PWM Output Configuration bits(1)
Capture mode:
Unused
Compare mode:
Unused
If CCPxM = 00, 01, 10:
xx = PxA assigned as Capture/Compare input; PxB, PxC, PxD assigned as port pins
If CCPxM = 11:
00 = Single output; PxA modulated; PxB, PxC, PxD assigned as port pins
01 = Full-Bridge output forward; PxD modulated; PxA active; PxB, PxC inactive
10 = Half-Bridge output; PxA, PxB modulated with dead-band control; PxC, PxD assigned as port pins
11 = Full-Bridge output reverse; PxB modulated; PxC active; PxA, PxD inactive
bit 5-4
DCxB: PWM Duty Cycle Least Significant bits
Capture mode:
Unused
Compare mode:
Unused
PWM mode:
These bits are the two LSbs of the PWM duty cycle. The eight MSbs are found in CCPRxL.
bit 3-0
CCPxM: ECCPx Mode Select bits
0000 =
0001 =
0010 =
0011 =
Capture/Compare/PWM off (resets ECCPx module)
Reserved
Compare mode: toggle output on match
Reserved
0100 =
0101 =
0110 =
0111 =
Capture mode: every falling edge
Capture mode: every rising edge
Capture mode: every 4th rising edge
Capture mode: every 16th rising edge
1000 =
1001 =
1010 =
1011 =
Compare mode: initialize ECCPx pin low; set output on compare match (set CCPxIF)
Compare mode: initialize ECCPx pin high; clear output on compare match (set CCPxIF)
Compare mode: generate software interrupt only; ECCPx pin reverts to I/O state
Compare mode: Special Event Trigger (ECCPx resets Timer, sets CCPxIF bit, starts A/D conversion if A/
D module is enabled)(1)
CCP Modules only:
11xx = PWM mode
ECCP modules only:
1100 = PWM mode: PxA, PxC active-high; PxB, PxD active-high
1101 = PWM mode: PxA, PxC active-high; PxB, PxD active-low
1110 = PWM mode: PxA, PxC active-low; PxB, PxD active-high
1111 = PWM mode: PxA, PxC active-low; PxB, PxD active-low
Note 1:
These bits are not implemented on CCP3 or CCP4.
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PIC16LF1824T39A
REGISTER 24-2:
R/W-0/0
CCPTMRS0: PWM TIMER SELECTION CONTROL REGISTER
R/W-0/0
C4TSEL
R/W-0/0
R/W-0/0
R/W-0/0
C3TSEL
R/W-0/0
R/W-0/0
C2TSEL
R/W-0/0
C1TSEL
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-6
C4TSEL: CCP4 Timer Selection bits
00 = CCP4 is based off Timer2 in PWM mode
01 = CCP4 is based off Timer4 in PWM mode
10 = CCP4 is based off Timer6 in PWM mode
11 = Reserved
bit 5-4
C3TSEL: CCP3 Timer Selection bits
00 = CCP3 is based off Timer2 in PWM mode
01 = CCP3 is based off Timer4 in PWM mode
10 = CCP3 is based off Timer6 in PWM mode
11 = Reserved
bit 3-2
C2TSEL: CCP2 Timer Selection bits
00 = CCP2 is based off Timer2 in PWM mode
01 = CCP2 is based off Timer4 in PWM mode
10 = CCP2 is based off Timer6 in PWM mode
11 = Reserved
bit 1-0
C1TSEL: CCP1 Timer Selection bits
00 = CCP1 is based off Timer2 in PWM mode
01 = CCP1 is based off Timer4 in PWM mode
10 = CCP1 is based off Timer6 in PWM mode
11 = Reserved
DS40001657C-page 216
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PIC16LF1824T39A
REGISTER 24-3:
R/W-0/0
CCPxAS: CCPx AUTO-SHUTDOWN CONTROL REGISTER
R/W-0/0
CCPxASE
R/W-0/0
R/W-0/0
CCPxAS
R/W-0/0
R/W-0/0
R/W-0/0
PSSxAC
bit 7
R/W-0/0
PSSxBD
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
CCPxASE: CCPx Auto-Shutdown Event Status bit
1 = A shutdown event has occurred; CCPx outputs are in shutdown state
0 = CCPx outputs are operating
bit 6-4
CCPxAS: CCPx Auto-Shutdown Source Select bits
000 = Auto-shutdown is disabled
001 = Comparator C1 output high(1)
010 = Comparator C2 output high(1)
011 = Either Comparator C1 or C2 high(1)
100 = VIL on FLT0 pin
101 = VIL on FLT0 pin or Comparator C1 high(1)
110 = VIL on FLT0 pin or Comparator C2 high(1)
111 = VIL on FLT0 pin or Comparator C1 or Comparator C2 high(1)
bit 3-2
PSSxAC: Pins PxA and PxC Shutdown State Control bits
00 = Drive pins PxA and PxC to ‘0’
01 = Drive pins PxA and PxC to ‘1’
1x = Pins PxA and PxC tri-state
bit 1-0
PSSxBD: Pins PxB and PxD Shutdown State Control bits
00 = Drive pins PxB and PxD to ‘0’
01 = Drive pins PxB and PxD to ‘1’
1x = Pins PxB and PxD tri-state
Note 1:
If CxSYNC is enabled, the shutdown will be delayed by Timer1.
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PIC16LF1824T39A
REGISTER 24-4:
R/W-0/0
PWMxCON: ENHANCED PWM CONTROL REGISTER
R/W-0/0
R/W-0/0
R/W-0/0
PxRSEN
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
PxDC
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
PxRSEN: PWM Restart Enable bit
1 = Upon auto-shutdown, the CCPxASE bit clears automatically once the shutdown event goes away;
the PWM restarts automatically
0 = Upon auto-shutdown, CCPxASE must be cleared in software to restart the PWM
bit 6-0
PxDC: PWM Delay Count bits
PxDCx = Number of FOSC/4 (4 * TOSC) cycles between the scheduled time when a PWM signal
should transition active and the actual time it transitions active
Note 1:
Bit resets to ‘0’ with Two-Speed Start-up and LP, XT or HS selected as the Oscillator mode or Fail-Safe
mode is enabled.
DS40001657C-page 218
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PIC16LF1824T39A
PSTRxCON: PWM STEERING CONTROL REGISTER(1)
REGISTER 24-5:
U-0
U-0
U-0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-1/1
—
—
—
STRxSYNC
STRxD
STRxC
STRxB
STRxA
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-5
Unimplemented: Read as ‘0’
bit 4
STRxSYNC: Steering Sync bit
1 = Output steering update occurs on next PWM period
0 = Output steering update occurs at the beginning of the instruction cycle boundary
bit 3
STRxD: Steering Enable bit D
1 = PxD pin has the PWM waveform with polarity control from CCPxM
0 = PxD pin is assigned to port pin
bit 2
STRxC: Steering Enable bit C
1 = PxC pin has the PWM waveform with polarity control from CCPxM
0 = PxC pin is assigned to port pin
bit 1
STRxB: Steering Enable bit B
1 = PxB pin has the PWM waveform with polarity control from CCPxM
0 = PxB pin is assigned to port pin
bit 0
STRxA: Steering Enable bit A
1 = PxA pin has the PWM waveform with polarity control from CCPxM
0 = PxA pin is assigned to port pin
Note 1:
The PWM Steering mode is available only when the CCPxCON register bits CCPxM = 11 and
PxM = 00.
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PIC16LF1824T39A
25.0
MASTER SYNCHRONOUS
SERIAL PORT MODULE
25.1
Master SSP (MSSP1) Module
Overview
The Master Synchronous Serial Port (MSSP1) module
is a serial interface useful for communicating with other
peripheral or microcontroller devices. These peripheral
devices may be Serial EEPROMs, shift registers,
display drivers, A/D converters, etc. The MSSP1
module can operate in one of two modes:
• Serial Peripheral Interface (SPI)
• Inter-Integrated Circuit (I2C)
The SPI interface supports the following modes and
features:
•
•
•
•
•
Master mode
Slave mode
Clock Parity
Slave Select Synchronization (Slave mode only)
Daisy chain connection of slave devices
Figure 25-1 is a block diagram of the SPI interface
module.
FIGURE 25-1:
MSSP1 BLOCK DIAGRAM (SPI MODE)
Data Bus
Read
Write
SSP1BUF Reg
SDI
SSP1SR Reg
SDO
bit 0
SS
SS Control
Enable
Shift
Clock
2 (CKP, CKE)
Clock Select
Edge
Select
SSP1M
4
SCK
Edge
Select
TRIS bit
DS40001657C-page 220
( TMR22Output )
Prescaler TOSC
4, 16, 64
Baud Rate
Generator
(SSP1ADD)
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PIC16LF1824T39A
The I2C interface supports the following modes and
features:
•
•
•
•
•
•
•
•
•
•
•
•
•
Master mode
Slave mode
Byte NACKing (Slave mode)
Limited multi-master support
7-bit and 10-bit addressing
Start and Stop interrupts
Interrupt masking
Clock stretching
Bus collision detection
General call address matching
Address masking
Address Hold and Data Hold modes
Selectable SDA hold times
Figure 25-2 is a block diagram of the I2C interface
module in Master mode. Figure 25-3 is a diagram of the
I2C interface module in Slave mode.
MSSP1 BLOCK DIAGRAM (I2C MASTER MODE)
Internal
data bus
Read
[SSPM 3:0]
Write
SSP1BUF
Baud Rate
Generator
(SSP1ADD)
SDA in
Receive Enable (RCEN)
SCL
SCL in
Bus Collision
2012-2017 Microchip Technology Inc.
LSb
Start bit, Stop bit,
Acknowledge
Generate (SSP1CON2)
Start bit detect,
Stop bit detect
Write collision detect
Clock arbitration
State counter for
end of XMIT/RCV
Address Match detect
Clock Cntl
SSP1SR
MSb
(Hold off clock source)
Shift
Clock
SDA
Clock arbitrate/BCOL detect
FIGURE 25-2:
Set/Reset: S, P, SSP1STAT, WCOL, SSPOV
Reset SEN, PEN (SSP1CON2)
Set SSP1IF, BCL1IF
DS40001657C-page 221
PIC16LF1824T39A
FIGURE 25-3:
MSSP1 BLOCK DIAGRAM (I2C SLAVE MODE)
Internal
Data Bus
Read
Write
SSP1BUF Reg
SCL
Shift
Clock
SSP1SR Reg
SDA
LSb
MSb
SSP1MSK Reg
Match Detect
Addr Match
SSP1ADD Reg
Start and
Stop bit Detect
DS40001657C-page 222
Set, Reset
S, P bits
(SSP1STAT Reg)
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
25.2
SPI Mode Overview
The Serial Peripheral Interface (SPI) bus is a
synchronous serial data communication bus that
operates in Full Duplex mode. Devices communicate in
a master/slave environment where the master device
initiates the communication. A slave device is
controlled through a Chip Select known as Slave
Select.
The SPI bus specifies four signal connections:
•
•
•
•
Serial Clock (SCK)
Serial Data Out (SDO)
Serial Data In (SDI)
Slave Select (SS)
Figure 25-1 shows the block diagram of the MSSP1
module when operating in SPI mode.
The SPI bus operates with a single master device and
one or more slave devices. When multiple slave
devices are used, an independent Slave Select connection is required from the master device to each
slave device.
Figure 25-4 shows a typical connection between a
master device and multiple slave devices.
The master selects only one slave at a time. Most slave
devices have tri-state outputs so their output signal
appears disconnected from the bus when they are not
selected.
its SDO pin) and the slave device is reading this bit and
saving it as the LSb of its shift register, that the slave
device is also sending out the MSb from its shift register
(on its SDO pin) and the master device is reading this
bit and saving it as the LSb of its shift register.
After eight bits have been shifted out, the master and
slave have exchanged register values.
If there is more data to exchange, the shift registers are
loaded with new data and the process repeats itself.
Whether the data is meaningful or not (dummy data),
depends on the application software. This leads to
three scenarios for data transmission:
• Master sends useful data and slave sends dummy
data.
• Master sends useful data and slave sends useful
data.
• Master sends dummy data and slave sends useful
data.
Transmissions may involve any number of clock
cycles. When there is no more data to be transmitted,
the master stops sending the clock signal and it
deselects the slave.
Every slave device connected to the bus that has not
been selected through its slave select line must
disregard the clock and transmission signals and must
not transmit out any data of its own.
Transmissions involve two shift registers, eight bits in
size, one in the master and one in the slave. With either
the master or the slave device, data is always shifted
out one bit at a time, with the Most Significant bit (MSb)
shifted out first. At the same time, a new Least
Significant bit (LSb) is shifted into the same register.
Figure 25-5 shows a typical connection between two
processors configured as master and slave devices.
Data is shifted out of both shift registers on the
programmed clock edge and latched on the opposite
edge of the clock.
The master device transmits information out on its SDO
output pin which is connected to, and received by, the
slave’s SDI input pin. The slave device transmits information out on its SDO output pin, which is connected
to, and received by, the master’s SDI input pin.
To begin communication, the master device first sends
out the clock signal. Both the master and the slave
devices should be configured for the same clock
polarity.
The master device starts a transmission by sending out
the MSb from its shift register. The slave device reads
this bit from that same line and saves it into the LSb
position of its shift register.
During each SPI clock cycle, a full duplex data
transmission occurs. This means that while the master
device is sending out the MSb from its shift register (on
2012-2017 Microchip Technology Inc.
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PIC16LF1824T39A
FIGURE 25-4:
SPI MASTER AND MULTIPLE SLAVE CONNECTION
SPI Master
SCK
SCK
SDO
SDI
General I/O
General I/O
SDI
General I/O
SCK
SDO
SPI Slave
#1
SS
SDI
SDO
SPI Slave
#2
SS
SCK
SDI
SDO
SPI Slave
#3
SS
25.2.1 SPI MODE REGISTERS
The MSSP1 module has five registers for SPI mode
operation. These are:
•
•
•
•
•
•
MSSP1 STATUS Register (SSP1STAT)
MSSP1 Control Register 1 (SSP1CON1)
MSSP1 Control Register 3 (SSP1CON3)
MSSP1 Data Buffer Register (SSP1BUF)
MSSP1 Address Register (SSP1ADD)
MSSP1 Shift Register (SSP1SR)
(Not directly accessible)
SSP1CON1 and SSP1STAT are the control
STATUS registers in SPI mode operation.
SSP1CON1 register is readable and writable.
lower six bits of the SSP1STAT are read-only.
upper two bits of the SSP1STAT are read/write.
and
The
The
The
In SPI master mode, SSP1ADD can be loaded with a
value used in the Baud Rate Generator. More information on the Baud Rate Generator is available in
Section 25.7 “Baud Rate Generator”.
SSP1SR is the shift register used for shifting data in
and out. SSP1BUF provides indirect access to the
SSP1SR register. SSP1BUF is the buffer register to
which data bytes are written, and from which data
bytes are read.
In receive operations, SSP1SR and SSP1BUF
together create a buffered receiver. When SSP1SR
receives a complete byte, it is transferred to SSP1BUF
and the SSP1IF interrupt is set.
During transmission, the SSP1BUF is not buffered. A
write to SSP1BUF will write to both SSP1BUF and
SSP1SR.
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25.2.2 SPI MODE OPERATION
When initializing the SPI, several options need to be
specified. This is done by programming the appropriate
control bits (SSP1CON1 and SSP1STAT).
These control bits allow the following to be specified:
•
•
•
•
Master mode (SCK1 is the clock output)
Slave mode (SCK1 is the clock input)
Clock Polarity (Idle state of SCK1)
Data Input Sample Phase (middle or end of data
output time)
• Clock Edge (output data on rising/falling edge of
SCK1)
• Clock Rate (Master mode only)
• Slave Select mode (Slave mode only)
To enable the serial port, SSP1 Enable bit, SSP1EN of
the SSP1CON1 register, must be set. To reset or
reconfigure SPI mode, clear the SSP1EN bit, re-initialize the SSP1CONx registers and then set the SSP1EN
bit. This configures the SDI, SDO, SCK and SS pins as
serial port pins. For the pins to behave as the serial port
function, some must have their data direction bits (in
the TRIS register) appropriately programmed as
follows:
When the application software is expecting to receive
valid data, the SSP1BUF should be read before the
next byte of data to transfer is written to the SSP1BUF.
The Buffer Full bit, BF of the SSP1STAT register,
indicates when SSP1BUF has been loaded with the
received data (transmission is complete). When the
SSP1BUF is read, the BF bit is cleared. This data may
be irrelevant if the SPI is only a transmitter. Generally,
the MSSP1 interrupt is used to determine when the
transmission/reception has completed. If the interrupt
method is not going to be used, then software polling
can be done to ensure that a write collision does not
occur.
The SSP1SR is not directly readable or writable and
can only be accessed by addressing the SSP1BUF
register. Additionally, the SSP1STAT register indicates
the various Status conditions.
• SDI must have corresponding TRIS bit set
• SDO must have corresponding TRIS bit cleared
• SCK (Master mode) must have corresponding
TRIS bit cleared
• SCK (Slave mode) must have corresponding
TRIS bit set
• SS must have corresponding TRIS bit set
Any serial port function that is not desired may be
overridden by programming the corresponding data
direction (TRIS) register to the opposite value.
The MSSP1 consists of a transmit/receive shift register
(SSP1SR) and a buffer register (SSP1BUF). The
SSP1SR shifts the data in and out of the device, MSb
first. The SSP1BUF holds the data that was written to
the SSP1SR until the received data is ready. Once the
eight bits of data have been received, that byte is
moved to the SSP1BUF register. Then, the Buffer Full
Detect bit, BF of the SSP1STAT register, and the
interrupt flag bit, SSP1IF, are set. This double-buffering
of the received data (SSP1BUF) allows the next byte to
start reception before reading the data that was just
received. Any write to the SSP1BUF register during
transmission/reception of data will be ignored and the
write collision detect bit WCOL of the SSP1CON1
register, will be set. User software must clear the
WCOL bit to allow the following write(s) to the
SSP1BUF register to complete successfully.
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FIGURE 25-5:
SPI MASTER/SLAVE CONNECTION
SPI Master SSP1M = 00xx
= 1010
SPI Slave SSP1M = 010x
SDO
SDI
Serial Input Buffer
(BUF)
SDI
Shift Register
(SSP1SR)
MSb
Serial Input Buffer
(SSP1BUF)
LSb
SCK
General I/O
Processor 1
DS40001657C-page 226
SDO
Serial Clock
Slave Select
(optional)
Shift Register
(SSP1SR)
MSb
LSb
SCK
SS
Processor 2
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25.2.3
SPI MASTER MODE
The master can initiate the data transfer at any time
because it controls the SCK line. The master
determines when the slave (Processor 2, Figure 25-5)
is to broadcast data by the software protocol.
In Master mode, the data is transmitted/received as
soon as the SSP1BUF register is written to. If the SPI
is only going to receive, the SDO output could be
disabled (programmed as an input). The SSP1SR
register will continue to shift in the signal present on the
SDI pin at the programmed clock rate. As each byte is
received, it will be loaded into the SSP1BUF register as
if a normal received byte (interrupts and Status bits
appropriately set).
The clock polarity is selected by appropriately
programming the CKP bit of the SSP1CON1 register
and the CKE bit of the SSP1STAT register. This then,
would give waveforms for SPI communication as
shown in Figure 25-6, Figure 25-9 and Figure 25-10,
where the MSb is transmitted first. In Master mode, the
SPI clock rate (bit rate) is user programmable to be one
of the following:
•
•
•
•
•
FOSC/4 (or TCY)
FOSC/16 (or 4 * TCY)
FOSC/64 (or 16 * TCY)
Timer2 output/2
Fosc/(4 * (SSP1ADD + 1))
Figure 25-6 shows the waveforms for Master mode.
When the CKE bit is set, the SDO data is valid before
there is a clock edge on SCK. The change of the input
sample is shown based on the state of the SMP bit. The
time when the SSP1BUF is loaded with the received
data is shown.
FIGURE 25-6:
SPI MODE WAVEFORM (MASTER MODE)
Write to
SSP1BUF
SCK
(CKP = 0
CKE = 0)
SCK
(CKP = 1
CKE = 0)
4 Clock
Modes
SCK
(CKP = 0
CKE = 1)
SCK
(CKP = 1
CKE = 1)
SDO
(CKE = 0)
bit 7
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
SDO
(CKE = 1)
bit 7
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
SDI
(SMP = 0)
bit 0
bit 7
Input
Sample
(SMP = 0)
SDI
(SMP = 1)
bit 7
bit 0
Input
Sample
(SMP = 1)
SSP1IF
SSP1SR to
SSP1BUF
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25.2.4
SPI SLAVE MODE
In Slave mode, the data is transmitted and received as
external clock pulses appear on SCK. When the last
bit is latched, the SSP1IF interrupt flag bit is set.
Before enabling the module in SPI Slave mode, the clock
line must match the proper Idle state. The clock line can
be observed by reading the SCK pin. The Idle state is
determined by the CKP bit of the SSP1CON1 register.
While in Slave mode, the external clock is supplied by
the external clock source on the SCK pin. This external
clock must meet the minimum high and low times as
specified in the electrical specifications.
While in Sleep mode, the slave can transmit/receive
data. The shift register is clocked from the SCK pin
input and when a byte is received, the device will
generate an interrupt. If enabled, the device will
wake-up from Sleep.
25.2.4.1 Daisy-Chain Configuration
The SPI bus can sometimes be connected in a
daisy-chain configuration. The first slave output is connected to the second slave input, the second slave
output is connected to the third slave input, and so on.
The final slave output is connected to the master input.
Each slave sends out, during a second group of clock
pulses, an exact copy of what was received during the
first group of clock pulses. The whole chain acts as
one large communication shift register. The
daisy-chain feature only requires a single Slave Select
line from the master device.
Figure 25-7 shows the block diagram of a typical
Daisy-Chain connection when operating in SPI mode.
In a daisy-chain configuration, only the most recent
byte on the bus is required by the slave. Setting the
BOEN bit of the SSP1CON3 register will enable writes
to the SSP1BUF register, even if the previous byte has
not been read. This allows the software to ignore data
that may not apply to it.
25.2.5
SLAVE SELECT
SYNCHRONIZATION
The Slave Select can also be used to synchronize communication. The Slave Select line is held high until the
master device is ready to communicate. When the
Slave Select line is pulled low, the slave knows that a
new transmission is starting.
If the slave fails to receive the communication properly,
it will be reset at the end of the transmission, when the
Slave Select line returns to a high state. The slave is
then ready to receive a new transmission when the
Slave Select line is pulled low again. If the Slave Select
line is not used, there is a risk that the slave will eventually become out of sync with the master. If the slave
misses a bit, it will always be one bit off in future transmissions. Use of the Slave Select line allows the slave
and master to align themselves at the beginning of
each transmission.
The SS pin allows a Synchronous Slave mode. The
SPI must be in Slave mode with SS pin control enabled
(SSP1CON1 = 0100).
When the SS pin is low, transmission and reception are
enabled and the SDO pin is driven.
When the SS pin goes high, the SDO pin is no longer
driven, even if in the middle of a transmitted byte and
becomes a floating output. External pull-up/pull-down
resistors may be desirable depending on the application.
Note 1: When the SPI is in Slave mode with SS pin
control enabled (SSP1CON1 =
0100), the SPI module will reset if the SS
pin is set to VDD.
2: When the SPI is used in Slave mode with
CKE set; the user must enable SS pin
control.
3: While operated in SPI Slave mode the
SMP bit of the SSP1STAT register must
remain clear.
When the SPI module resets, the bit counter is forced
to ‘0’. This can be done by either forcing the SS pin to
a high level or clearing the SSP1EN bit.
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FIGURE 25-7:
SPI DAISY-CHAIN CONNECTION
SPI Master
SCK
SCK
SDO
SDI
General I/O
SDI
SPI Slave
#1
SDO
SS
SCK
SDI
SPI Slave
#2
SDO
SS
SCK
SDI
SPI Slave
#3
SDO
SS
FIGURE 25-8:
SLAVE SELECT SYNCHRONOUS WAVEFORM
SS
SCK
(CKP = 0
CKE = 0)
SCK
(CKP = 1
CKE = 0)
Write to
SSP1BUF
Shift register SSP1SR
and bit count are reset
SSP1BUF to
SSP1SR
SDO
bit 7
bit 6
bit 7
SDI
bit 6
bit 0
bit 0
bit 7
bit 7
Input
Sample
SSP1IF
Interrupt
Flag
SSP1SR to
SSP1BUF
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FIGURE 25-9:
SPI MODE WAVEFORM (SLAVE MODE WITH CKE = 0)
SS
Optional
SCK
(CKP = 0
CKE = 0)
SCK
(CKP = 1
CKE = 0)
Write to
SSP1BUF
Valid
SDO
bit 7
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
SDI
bit 0
bit 7
Input
Sample
SSP1IF
Interrupt
Flag
SSP1SR to
SSP1BUF
Write Collision
detection active
FIGURE 25-10:
SPI MODE WAVEFORM (SLAVE MODE WITH CKE = 1)
SS
Not Optional
SCK
(CKP = 0
CKE = 1)
SCK
(CKP = 1
CKE = 1)
Write to
SSP1BUF
Valid
SDO
bit 7
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
SDI
bit 7
bit 0
Input
Sample
SSP1IF
Interrupt
Flag
SSP1SR to
SSP1BUF
Write Collision
detection active
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25.2.6 SPI OPERATION IN SLEEP MODE
In SPI Master mode, module clocks may be operating
at a different speed than when in Full Power mode; in
the case of the Sleep mode, all clocks are halted.
Special care must be taken by the user when the
MSSP1 clock is much faster than the system clock.
In Slave mode, when MSSP1 interrupts are enabled,
after the master completes sending data, an MSSP1
interrupt will wake the controller from Sleep.
If an exit from Sleep mode is not desired, MSSP1
interrupts should be disabled.
TABLE 25-1:
Name
ANSELA
In SPI Master mode, when the Sleep mode is selected,
all module clocks are halted and the transmission/reception will remain in that state until the device
wakes. After the device returns to Run mode, the
module will resume transmitting and receiving data.
In SPI Slave mode, the SPI Transmit/Receive Shift
register operates asynchronously to the device. This
allows the device to be placed in Sleep mode and data
to be shifted into the SPI Transmit/Receive Shift
register. When all eight bits have been received, the
MSSP1 interrupt flag bit will be set and if enabled, will
wake the device.
SUMMARY OF REGISTERS ASSOCIATED WITH SPI OPERATION
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register on
Page
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
118
124
—
—
—
—
ANSC3
ANSC2
ANSC1
ANSC0
RXDTSEL
SDOSEL
SSSEL
—
T1GSEL
TXCKSEL
—
—
113
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
ANSELC
APFCON0
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
INTCON
SSP1BUF
Synchronous Serial Port Receive Buffer/Transmit Register
88
224*
SSP1CON1
WCOL
SSPOV
SSPEN
CKP
SSP1CON3
ACKTIM
PCIE
SCIE
BOEN
SDAHT
SBCDE
AHEN
DHEN
272
SSP1STAT
SMP
CKE
D/A
P
S
R/W
UA
BF
269
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
TRISA
TRISC
Legend:
*
SSPM
270
— = Unimplemented location, read as ‘0’. Shaded cells are not used by the MSSP1 in SPI mode.
Page provides register information.
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25.3
I2C Mode Overview
The Inter-Integrated Circuit Bus (I²C) is a multi-master
serial data communication bus. Devices communicate
in a master/slave environment where the master
devices initiate the communication. A Slave device is
controlled through addressing.
VDD
SCL
The I2C bus specifies two signal connections:
• Serial Clock (SCL)
• Serial Data (SDA)
Figure 25-2 and Figure 25-3 shows the block diagram
of the MSSP1 module when operating in I2C mode.
Both the SCL and SDA connections are bidirectional
open-drain lines, each requiring pull-up resistors for the
supply voltage. Pulling the line to ground is considered
a logical zero and letting the line float is considered a
logical one.
Figure 25-11 shows a typical connection between two
processors configured as master and slave devices.
The I2C bus can operate with one or more master
devices and one or more slave devices.
There are four potential modes of operation for a given
device:
• Master Transmit mode
(master is transmitting data to a slave)
• Master Receive mode
(master is receiving data from a slave)
• Slave Transmit mode
(slave is transmitting data to a master)
• Slave Receive mode
(slave is receiving data from the master)
To begin communication, a master device starts out in
Master Transmit mode. The master device sends out a
Start bit followed by the address byte of the slave it
intends to communicate with. This is followed by a
single Read/Write bit, which determines whether the
master intends to transmit to or receive data from the
slave device.
If the requested slave exists on the bus, it will respond
with an Acknowledge bit, otherwise known as an ACK.
The master then continues in either Transmit mode or
Receive mode and the slave continues in the complement, either in Receive mode or Transmit mode,
respectively.
A Start bit is indicated by a high-to-low transition of the
SDA line while the SCL line is held high. Address and
data bytes are sent out, Most Significant bit (MSb) first.
The Read/Write bit is sent out as a logical one when the
master intends to read data from the slave, and is sent
out as a logical zero when it intends to write data to the
slave.
DS40001657C-page 232
I2C MASTER/
SLAVE CONNECTION
FIGURE 25-11:
SCL
VDD
Master
Slave
SDA
SDA
The Acknowledge bit (ACK) is an active-low signal,
which holds the SDA line low to indicate to the transmitter that the slave device has received the transmitted
data and is ready to receive more.
The transition of a data bit is always performed while
the SCL line is held low. Transitions that occur while the
SCL line is held high are used to indicate Start and Stop
bits.
If the master intends to write to the slave, then it repeatedly sends out a byte of data, with the slave responding
after each byte with an ACK bit. In this example, the
master device is in Master Transmit mode and the
slave is in Slave Receive mode.
If the master intends to read from the slave, then it
repeatedly receives a byte of data from the slave, and
responds after each byte with an ACK bit. In this example, the master device is in Master Receive mode and
the slave is Slave Transmit mode.
On the last byte of data communicated, the master
device may end the transmission by sending a Stop bit.
If the master device is in Receive mode, it sends the
Stop bit in place of the last ACK bit. A Stop bit is indicated by a low-to-high transition of the SDA line while
the SCL line is held high.
In some cases, the master may want to maintain
control of the bus and re-initiate another transmission.
If so, the master device may send another Start bit in
place of the Stop bit or last ACK bit when it is in receive
mode.
The I2C bus specifies three message protocols;
• Single message where a master writes data to a
slave.
• Single message where a master reads data from
a slave.
• Combined message where a master initiates a
minimum of two writes, or two reads, or a
combination of writes and reads, to one or more
slaves.
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When one device is transmitting a logical one, or letting
the line float, and a second device is transmitting a logical zero, or holding the line low, the first device can
detect that the line is not a logical one. This detection,
when used on the SCL line, is called clock stretching.
Clock stretching gives slave devices a mechanism to
control the flow of data. When this detection is used on
the SDA line, it is called arbitration. Arbitration ensures
that there is only one master device communicating at
any single time.
Slave Transmit mode can also be arbitrated, when a
master addresses multiple slaves, but this is less
common.
25.3.1
Arbitration usually occurs very rarely, but it is a necessary process for proper multi-master support.
CLOCK STRETCHING
When a slave device has not completed processing
data, it can delay the transfer of more data through the
process of clock stretching. An addressed slave device
may hold the SCL clock line low after receiving or sending a bit, indicating that it is not yet ready to continue.
The master that is communicating with the slave will
attempt to raise the SCL line in order to transfer the
next bit, but will detect that the clock line has not yet
been released. Because the SCL connection is
open-drain, the slave has the ability to hold that line low
until it is ready to continue communicating.
Clock stretching allows receivers that cannot keep up
with a transmitter to control the flow of incoming data.
25.3.2
ARBITRATION
Each master device must monitor the bus for Start and
Stop bits. If the device detects that the bus is busy, it
cannot begin a new message until the bus returns to an
Idle state.
However, two master devices may try to initiate a transmission on or about the same time. When this occurs,
the process of arbitration begins. Each transmitter
checks the level of the SDA data line and compares it
to the level that it expects to find. The first transmitter to
observe that the two levels do not match, loses arbitration, and must stop transmitting on the SDA line.
For example, if one transmitter holds the SDA line to a
logical one (lets it float) and a second transmitter holds
it to a logical zero (pulls it low), the result is that the
SDA line will be low. The first transmitter then observes
that the level of the line is different than expected and
concludes that another transmitter is communicating.
The first transmitter to notice this difference is the one
that loses arbitration and must stop driving the SDA
line. If this transmitter is also a master device, it also
must stop driving the SCL line. It then can monitor the
lines for a Stop condition before trying to reissue its
transmission. In the meantime, the other device that
has not noticed any difference between the expected
and actual levels on the SDA line continues with its
original transmission. It can do so without any complications, because so far, the transmission appears
exactly as expected with no other transmitter disturbing
the message.
2012-2017 Microchip Technology Inc.
If two master devices are sending a message to two
different slave devices at the address stage, the master
sending the lower slave address always wins arbitration. When two master devices send messages to the
same slave address, and addresses can sometimes
refer to multiple slaves, the arbitration process must
continue into the data stage.
25.4
I2C Mode Operation
All MSSP1 I2C communication is byte oriented and
shifted out MSb first. Six SFR registers and two
interrupt flags interface the module with the PIC®
microcontroller and user software. Two pins, SDA and
SCL, are exercised by the module to communicate
with other external I2C devices.
25.4.1 BYTE FORMAT
All communication in I2C is done in 9-bit segments. A
byte is sent from a master to a slave or vice-versa,
followed by an Acknowledge bit sent back. After the
8th falling edge of the SCL line, the device outputting
data on the SDA changes that pin to an input and
reads in an acknowledge value on the next clock
pulse.
The clock signal, SCL, is provided by the master. Data
is valid to change while the SCL signal is low, and
sampled on the rising edge of the clock. Changes on
the SDA line while the SCL line is high define special
conditions on the bus, explained below.
25.4.2 DEFINITION OF I2C TERMINOLOGY
There is language and terminology in the description
of I2C communication that have definitions specific to
I2C. That word usage is defined below and may be
used in the rest of this document without explanation. This table was adapted from the Phillips I2C
specification.
25.4.3 SDA AND SCL PINS
Selection of any I2C mode with the SSP1EN bit set,
forces the SCL and SDA pins to be open-drain. These
pins should be set by the user to inputs by setting the
appropriate TRIS bits.
Note: Data is tied to output zero when an I2C
mode is enabled.
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25.4.4 SDA HOLD TIME
The hold time of the SDA pin is selected by the SDAHT
bit of the SSP1CON3 register. Hold time is the time
SDA is held valid after the falling edge of SCL. Setting
the SDAHT bit selects a longer 300 ns minimum hold
time and may help on buses with large capacitance.
TABLE 25-2:
I2C BUS TERMS
TERM
Description
Transmitter
The device which shifts data out
onto the bus.
Receiver
The device which shifts data in
from the bus.
Master
The device that initiates a transfer,
generates clock signals and
terminates a transfer.
Slave
The device addressed by the
master.
Multi-master
A bus with more than one device
that can initiate data transfers.
Arbitration
Procedure to ensure that only one
master at a time controls the bus.
Winning arbitration ensures that
the message is not corrupted.
Synchronization Procedure to synchronize the
clocks of two or more devices on
the bus.
Idle
No master is controlling the bus,
and both SDA and SCL lines are
high.
Active
Any time one or more master
devices are controlling the bus.
Addressed
Slave device that has received a
Slave
matching address and is actively
being clocked by a master.
Matching
Address byte that is clocked into a
Address
slave that matches the value
stored in SSP1ADD.
Write Request
Slave receives a matching
address with R/W bit clear, and is
ready to clock in data.
Read Request
Master sends an address byte with
the R/W bit set, indicating that it
wishes to clock data out of the
Slave. This data is the next and all
following bytes until a Restart or
Stop.
Clock Stretching When a device on the bus hold
SCL low to stall communication.
Bus Collision
Any time the SDA line is sampled
low by the module while it is outputting and expected high state.
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25.4.5
START CONDITION
has the same effect on the slave that a Start would,
resetting all slave logic and preparing it to clock in an
address. The master may want to address the same or
another slave.
2
The I C specification defines a Start condition as a
transition of SDA from a high to a low state while SCL
line is high. A Start condition is always generated by
the master and signifies the transition of the bus from
an Idle to an Active state. Figure 25-12 shows wave
forms for Start and Stop conditions.
In 10-bit Addressing Slave mode a Restart is required
for the master to clock data out of the addressed
slave. Once a slave has been fully addressed, matching both high and low address bytes, the master can
issue a Restart and the high address byte with the
R/W bit set. The slave logic will then hold the clock
and prepare to clock out data.
A bus collision can occur on a Start condition if the
module samples the SDA line low before asserting it
low. This does not conform to the I2C specification that
states no bus collision can occur on a Start.
After a full match with R/W clear in 10-bit mode, a prior
match flag is set and maintained. Until a Stop
condition, a high address with R/W clear, or high
address match fails.
25.4.6 STOP CONDITION
A Stop condition is a transition of the SDA line from
low-to-high state while the SCL line is high.
25.4.8 START/STOP CONDITION INTERRUPT
MASKING
Note: At least one SCL low time must appear
before a Stop is valid, therefore, if the SDA
line goes low then high again while the SCL
line stays high, only the Start condition is
detected.
25.4.7
The SCIE and PCIE bits of the SSP1CON3 register
can enable the generation of an interrupt in Slave
modes that do not typically support this function. Slave
modes where interrupt on Start and Stop detect are
already enabled, these bits will have no effect.
RESTART CONDITION
A Restart is valid any time that a Stop would be valid.
A master can issue a Restart if it wishes to hold the
bus after terminating the current transfer. A Restart
FIGURE 25-12:
I2C START AND STOP CONDITIONS
SDA
SCL
S
Start
P
Change of
Change of
Data Allowed
Data Allowed
Condition
FIGURE 25-13:
Stop
Condition
I2C RESTART CONDITION
Sr
Change of
Change of
Data Allowed
Restart
Data Allowed
Condition
2012-2017 Microchip Technology Inc.
DS40001657C-page 235
PIC16LF1824T39A
I2C Slave Mode Operation
25.4.9 ACKNOWLEDGE SEQUENCE
25.5
The 9th SCL pulse for any transferred byte in I2C is
dedicated as an Acknowledge. It allows receiving
devices to respond back to the transmitter by pulling
the SDA line low. The transmitter must release control
of the line during this time to shift in the response. The
Acknowledge (ACK) is an active-low signal, pulling the
SDA line low indicated to the transmitter that the
device has received the transmitted data and is ready
to receive more.
The MSSP1 Slave mode operates in one of four
modes selected in the SSPM bits of SSP1CON1 register. The modes can be divided into 7-bit and 10-bit
Addressing mode. 10-bit Addressing modes operate
the same as 7-bit with some additional overhead for
handling the larger addresses.
The result of an ACK is placed in the ACKSTAT bit of
the SSP1CON2 register.
Slave software, when the AHEN and DHEN bits are
set, allow the user to set the ACK value sent back to
the transmitter. The ACKDT bit of the SSP1CON2
register is set/cleared to determine the response.
Slave hardware will generate an ACK response if the
AHEN and DHEN bits of the SSP1CON3 register are
clear.
There are certain conditions where an ACK will not be
sent by the slave. If the BF bit of the SSP1STAT register or the SSPOV bit of the SSP1CON1 register are
set when a byte is received.
When the module is addressed, after the 8th falling
edge of SCL on the bus, the ACKTIM bit of the
SSP1CON3 register is set. The ACKTIM bit indicates
the acknowledge time of the active bus. The ACKTIM
Status bit is only active when the AHEN bit or DHEN
bit is enabled.
Modes with Start and Stop bit interrupts operate the
same as the other modes with SSP1IF additionally
getting set upon detection of a Start, Restart, or Stop
condition.
25.5.1 SLAVE MODE ADDRESSES
The SSP1ADD register (Register 25-6) contains the
Slave mode address. The first byte received after a
Start or Restart condition is compared against the
value stored in this register. If the byte matches, the
value is loaded into the SSP1BUF register and an
interrupt is generated. If the value does not match, the
module goes idle and no indication is given to the
software that anything happened.
The SSP Mask register (Register 25-5) affects the
address matching process. See Section 25.5.9
“SSP1 Mask Register” for more information.
25.5.1.1 I2C Slave 7-bit Addressing Mode
In 7-bit Addressing mode, the LSb of the received data
byte is ignored when determining if there is an address
match.
25.5.1.2 I2C Slave 10-bit Addressing Mode
In 10-bit Addressing mode, the first received byte is
compared to the binary value of ‘1 1 1 1 0 A9 A8
0’. A9 and A8 are the two MSb of the 10-bit address
and stored in bits 2 and 1 of the SSP1ADD register.
After the acknowledge of the high byte the UA bit is set
and SCL is held low until the user updates SSP1ADD
with the low address. The low address byte is clocked
in and all eight bits are compared to the low address
value in SSP1ADD. Even if there is not an address
match; SSP1IF and UA are set, and SCL is held low
until SSP1ADD is updated to receive a high byte
again. When SSP1ADD is updated, the UA bit is
cleared. This ensures the module is ready to receive
the high address byte on the next communication.
A high and low address match as a write request is
required at the start of all 10-bit addressing communication. A transmission can be initiated by issuing a
Restart once the slave is addressed, and clocking in
the high address with the R/W bit set. The slave
hardware will then acknowledge the read request and
prepare to clock out data. This is only valid for a slave
after it has received a complete high and low address
byte match.
DS40001657C-page 236
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
25.5.2 SLAVE RECEPTION
25.5.2.2 7-bit Reception with AHEN and DHEN
When the R/W bit of a matching received address byte
is clear, the R/W bit of the SSP1STAT register is
cleared. The received address is loaded into the
SSP1BUF register and acknowledged.
Slave device reception with AHEN and DHEN set
operate the same as without these options with extra
interrupts and clock stretching added after the 8th falling edge of SCL. These additional interrupts allow the
slave software to decide whether it wants to ACK the
receive address or data byte, rather than the hardware. This functionality adds support for PMBus™ that
was not present on previous versions of this module.
When the overflow condition exists for a received
address, then not Acknowledge is given. An overflow
condition is defined as either bit BF bit of the
SSP1STAT register is set, or bit SSPOV bit of the
SSP1CON1 register is set. The BOEN bit of the
SSP1CON3 register modifies this operation. For more
information see Register 25-4.
An MSSP1 interrupt is generated for each transferred
data byte. Flag bit, SSP1IF, must be cleared by
software.
When the SEN bit of the SSP1CON2 register is set,
SCL will be held low (clock stretch) following each
received byte. The clock must be released by setting
the CKP bit of the SSP1CON1 register, except
sometimes in 10-bit mode. See Section 25.2.3 “SPI
Master Mode” for more detail.
25.5.2.1 7-bit Addressing Reception
This section describes a standard sequence of events
for the MSSP1 module configured as an I2C Slave in
7-bit Addressing mode. Figure 25-14 and Figure 25-15
are used as a visual reference for this description.
This is a step by step process of what typically must
be done to accomplish I2C communication.
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
Start bit detected.
S bit of SSP1STAT is set; SSP1IF is set if
interrupt on Start detect is enabled.
Matching address with R/W bit clear is received.
The slave pulls SDA low sending an ACK to the
master, and sets SSP1IF bit.
Software clears the SSP1IF bit.
Software reads received address from
SSP1BUF clearing the BF flag.
If SEN = 1; Slave software sets CKP bit to
release the SCL line.
The master clocks out a data byte.
Slave drives SDA low sending an ACK to the
master, and sets SSP1IF bit.
Software clears SSP1IF.
Software reads the received byte from
SSP1BUF clearing BF.
Steps 8-12 are repeated for all received bytes
from the Master.
Master sends Stop condition, setting P bit of
SSP1STAT, and the bus goes idle.
2012-2017 Microchip Technology Inc.
This list describes the steps that need to be taken by
slave software to use these options for I2C communication. Figure 25-16 displays a module using both
address and data holding. Figure 25-17 includes the
operation with the SEN bit of the SSP1CON2 register
set.
1.
S bit of SSP1STAT is set; SSP1IF is set if
interrupt on Start detect is enabled.
2. Matching address with R/W bit clear is clocked
in. SSP1IF is set and CKP cleared after the 8th
falling edge of SCL.
3. Slave clears the SSP1IF.
4. Slave can look at the ACKTIM bit of the
SSP1CON3 register to determine if the SSP1IF
was after or before the ACK.
5. Slave reads the address value from SSP1BUF,
clearing the BF flag.
6. Slave sets ACK value clocked out to the master
by setting ACKDT.
7. Slave releases the clock by setting CKP.
8. SSP1IF is set after an ACK, not after a NACK.
9. If SEN = 1 the slave hardware will stretch the
clock after the ACK.
10. Slave clears SSP1IF.
Note: SSP1IF is still set after the 9th falling edge
of SCL even if there is no clock stretching
and BF has been cleared. Only if NACK is
sent to Master is SSP1IF not set
11. SSP1IF set and CKP cleared after 8th falling
edge of SCL for a received data byte.
12. Slave looks at ACKTIM bit of SSP1CON3 to
determine the source of the interrupt.
13. Slave reads the received data from SSP1BUF
clearing BF.
14. Steps 7-14 are the same for each received data
byte.
15. Communication is ended by either the slave
sending an ACK = 1, or the master sending a
Stop condition. If a Stop is sent and Interrupt on
Stop Detect is disabled, the slave will only know
by polling the P bit of the SSPSTAT register.
DS40001657C-page 237
DS40001657C-page 238
SSPOV
BF
SSP1IF
S
1
A7
2
A6
3
A5
4
A4
5
A3
6
A2
7
A1
8
9
ACK
1
D7
2
D6
4
D4
5
D3
6
D2
7
D1
SSP1BUF is read
Cleared by software
3
D5
Receiving Data
8
9
2
D6
First byte
of data is
available
in SSP1BUF
1
D0 ACK D7
4
D4
5
D3
6
D2
7
D1
SSPOV set because
SSP1BUF is still full.
ACK is not sent.
Cleared by software
3
D5
Receiving Data
From Slave to Master
8
D0
9
P
SSP1IF set on 9th
falling edge of
SCL
ACK = 1
FIGURE 25-14:
SCL
SDA
Receiving Address
Bus Master sends
Stop condition
PIC16LF1824T39A
I2C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 0, AHEN = 0, DHEN = 0)
2012-2017 Microchip Technology Inc.
2012-2017 Microchip Technology Inc.
CKP
SSPOV
BF
SSP1IF
1
SCL
S
A7
2
A6
3
A5
4
A4
5
A3
6
A2
7
A1
8
9
R/W=0 ACK
SEN
2
D6
3
D5
4
D4
5
D3
6
D2
7
D1
8
D0
CKP is written to ‘1’ in software,
releasing SCL
SSP1BUF is read
Cleared by software
Clock is held low until CKP is set to ‘1’
1
D7
Receive Data
9
ACK
SEN
3
D5
4
D4
5
D3
First byte
of data is
available
in SSP1BUF
6
D2
7
D1
SSPOV set because
SSP1BUF is still full.
ACK is not sent.
Cleared by software
2
D6
CKP is written to 1 in software,
releasing SCL
1
D7
Receive Data
8
D0
9
ACK
SCL is not held
low because
ACK= 1
SSP1IF set on 9th
falling edge of SCL
P
FIGURE 25-15:
SDA
Receive Address
Bus Master sends
Stop condition
PIC16LF1824T39A
I2C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 1, AHEN = 0, DHEN = 0)
DS40001657C-page 239
DS40001657C-page 240
P
S
ACKTIM
CKP
ACKDT
BF
SSP1IF
S
Receiving Address
1
3
5
6
7
8
ACK the received
byte
Slave software
clears ACKDT to
Address is
read from
SSBUF
If AHEN = 1:
SSP1IF is set
4
ACKTIM set by hardware
on 8th falling edge of SCL
When AHEN=1:
CKP is cleared by hardware
and SCL is stretched
2
A7 A6 A5 A4 A3 A2 A1
Receiving Data
9
2
3
4
5
6
7
ACKTIM cleared by
hardware in 9th
rising edge of SCL
When DHEN=1:
CKP is cleared by
hardware on 8th falling
edge of SCL
SSP1IF is set on
9th falling edge of
SCL, after ACK
1
8
ACK D7 D6 D5 D4 D3 D2 D1 D0
Received Data
1
2
4
5
6
ACKTIM set by hardware
on 8th falling edge of SCL
CKP set by software,
SCL is released
8
Slave software
sets ACKDT to
not ACK
7
Cleared by software
3
D7 D6 D5 D4 D3 D2 D1 D0
Data is read from SSP1BUF
9
ACK
9
P
No interrupt
after not ACK
from Slave
ACK=1
Master sends
Stop condition
FIGURE 25-16:
SCL
SDA
Master Releases SDA
to slave for ACK sequence
PIC16LF1824T39A
I2C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 0, AHEN = 1, DHEN = 1)
2012-2017 Microchip Technology Inc.
2012-2017 Microchip Technology Inc.
P
S
ACKTIM
CKP
ACKDT
BF
SSP1IF
S
Receiving Address
4
5
6 7
8
When AHEN = 1;
on the 8th falling edge
of SCL of an address
byte, CKP is cleared
Slave software clears
ACKDT to ACK
the received byte
Received
address is loaded into
SSP1BUF
2 3
ACKTIM is set by hardware
on 8th falling edge of SCL
1
A7 A6 A5 A4 A3 A2 A1
9
ACK
Receive Data
2 3
4
5
6 7
8
ACKTIM is cleared by hardware
on 9th rising edge of SCL
When DHEN = 1;
on the 8th falling edge
of SCL of a received
data byte, CKP is cleared
Received data is
available on SSP1BUF
Cleared by software
1
D7 D6 D5 D4 D3 D2 D1 D0
9
ACK
Receive Data
1
3 4
5
6 7
8
Set by software,
release SCL
Slave sends
not ACK
SSP1BUF can be
read any time before
next byte is loaded
2
D7 D6 D5 D4 D3 D2 D1 D0
9
ACK
CKP is not cleared
if not ACK
No interrupt after
if not ACK
from Slave
P
Master sends
Stop condition
FIGURE 25-17:
SCL
SDA
R/W = 0
Master releases
SDA to slave for ACK sequence
PIC16LF1824T39A
I2C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 1, AHEN = 1, DHEN = 1)
DS40001657C-page 241
PIC16LF1824T39A
25.5.3
SLAVE TRANSMISSION
25.5.3.2
7-bit Transmission
When the R/W bit of the incoming address byte is set
and an address match occurs, the R/W bit of the
SSP1STAT register is set. The received address is
loaded into the SSP1BUF register, and an ACK pulse
is sent by the slave on the ninth bit.
A master device can transmit a read request to a
slave, and then clock data out of the slave. The list
below outlines what software for a slave will need to
do to accomplish a standard transmission.
Figure 25-18 can be used as a reference to this list.
Following the ACK, slave hardware clears the CKP bit
and the SCL pin is held low (see Section 25.5.6
“Clock Stretching” for more detail). By stretching the
clock, the master will be unable to assert another clock
pulse until the slave is done preparing the transmit
data.
1.
The transmit data must be loaded into the SSP1BUF
register, which also loads the SSP1SR register. Then
the SCL pin should be released by setting the CKP bit
of the SSP1CON1 register. The eight data bits are
shifted out on the falling edge of the SCL input. This
ensures that the SDA signal is valid during the SCL
high time.
The ACK pulse from the master-receiver is latched on
the rising edge of the ninth SCL input pulse. This ACK
value is copied to the ACKSTAT bit of the SSP1CON2
register. If ACKSTAT is set (not ACK), then the data
transfer is complete. In this case, when the not ACK is
latched by the slave, the slave goes idle and waits for
another occurrence of the Start bit. If the SDA line was
low (ACK), the next transmit data must be loaded into
the SSP1BUF register. Again, the SCL pin must be
released by setting bit CKP.
An MSSP1 interrupt is generated for each data transfer
byte. The SSP1IF bit must be cleared by software and
the SSP1STAT register is used to determine the status
of the byte. The SSP1IF bit is set on the falling edge of
the ninth clock pulse.
25.5.3.1
Slave Mode Bus Collision
A slave receives a read request and begins shifting
data out on the SDA line. If a bus collision is detected
and the SBCDE bit of the SSP1CON3 register is set,
the BCL1IF bit of the PIRx register is set. Once a bus
collision is detected, the slave goes Idle and waits to be
addressed again. User software can use the BCL1IF bit
to handle a slave bus collision.
DS40001657C-page 242
Master sends a Start condition on SDA and
SCL.
2. S bit of SSP1STAT is set; SSP1IF is set if
interrupt on Start detect is enabled.
3. Matching address with R/W bit set is received by
the Slave setting SSP1IF bit.
4. Slave hardware generates an ACK and sets
SSP1IF.
5. SSP1IF bit is cleared by user.
6. Software reads the received address from
SSP1BUF, clearing BF.
7. R/W is set so CKP was automatically cleared
after the ACK.
8. The slave software loads the transmit data into
SSP1BUF.
9. CKP bit is set releasing SCL, allowing the
master to clock the data out of the slave.
10. SSP1IF is set after the ACK response from the
master is loaded into the ACKSTAT register.
11. SSP1IF bit is cleared.
12. The slave software checks the ACKSTAT bit to
see if the master wants to clock out more data.
Note 1: If the master ACKs the clock will be
stretched.
2: ACKSTAT is the only bit updated on the
rising edge of SCL (9th) rather than the
falling.
13. Steps 9-13 are repeated for each transmitted
byte.
14. If the master sends a not ACK; the clock is not
held, but SSP1IF is still set.
15. The master sends a Restart condition or a Stop.
16. The slave is no longer addressed.
2012-2017 Microchip Technology Inc.
2012-2017 Microchip Technology Inc.
P
S
D/A
R/W
ACKSTAT
CKP
BF
SSP1IF
S
Receiving Address
1
2
5
6
7
8
Indicates an address
has been received
R/W is copied from the
matching address byte
9
R/W = 1 Automatic
ACK
Received address
is read from SSP1BUF
4
When R/W is set
SCL is always
held low after 9th SCL
falling edge
3
A7 A6 A5 A4 A3 A2 A1
Transmitting Data
Automatic
2
3
4
5
Set by software
Data to transmit is
loaded into SSP1BUF
Cleared by software
1
6
7
8
9
D7 D6 D5 D4 D3 D2 D1 D0 ACK
Transmitting Data
2
3
4
5
7
8
CKP is not
held for not
ACK
6
Masters not ACK
is copied to
ACKSTAT
BF is automatically
cleared after 8th falling
edge of SCL
1
D7 D6 D5 D4 D3 D2 D1 D0
9
ACK
P
FIGURE 25-18:
SCL
SDA
Master sends
Stop condition
PIC16LF1824T39A
I2C SLAVE, 7-BIT ADDRESS, TRANSMISSION (AHEN = 0)
DS40001657C-page 243
PIC16LF1824T39A
25.5.3.3
7-bit Transmission with Address
Hold Enabled
Setting the AHEN bit of the SSP1CON3 register
enables additional clock stretching and interrupt
generation after the 8th falling edge of a received
matching address. Once a matching address has
been clocked in, CKP is cleared and the SSP1IF
interrupt is set.
Figure 25-19 displays a standard waveform of a 7-bit
Address Slave Transmission with AHEN enabled.
1.
2.
Bus starts Idle.
Master sends Start condition; the S bit of
SSP1STAT is set; SSP1IF is set if interrupt on
Start detect is enabled.
3. Master sends matching address with R/W bit
set. After the 8th falling edge of the SCL line the
CKP bit is cleared and SSP1IF interrupt is
generated.
4. Slave software clears SSP1IF.
5. Slave software reads ACKTIM bit of SSP1CON3
register, and R/W and D/A of the SSP1STAT
register to determine the source of the interrupt.
6. Slave reads the address value from the
SSP1BUF register clearing the BF bit.
7. Slave software decides from this information if it
wishes to ACK or not ACK and sets ACKDT bit
of the SSP1CON2 register accordingly.
8. Slave sets the CKP bit releasing SCL.
9. Master clocks in the ACK value from the slave.
10. Slave hardware automatically clears the CKP bit
and sets SSP1IF after the ACK if the R/W bit is
set.
11. Slave software clears SSP1IF.
12. Slave loads value to transmit to the master into
SSP1BUF setting the BF bit.
Note: SSP1BUF cannot be loaded until after the
ACK.
13. Slave sets CKP bit releasing the clock.
14. Master clocks out the data from the slave and
sends an ACK value on the 9th SCL pulse.
15. Slave hardware copies the ACK value into the
ACKSTAT bit of the SSP1CON2 register.
16. Steps 10-15 are repeated for each byte transmitted to the master from the slave.
17. If the master sends a not ACK the slave
releases the bus allowing the master to send a
Stop and end the communication.
Note: Master must send a not ACK on the last byte
to ensure that the slave releases the SCL
line to receive a Stop.
DS40001657C-page 244
2012-2017 Microchip Technology Inc.
2012-2017 Microchip Technology Inc.
D/A
R/W
ACKTIM
CKP
ACKSTAT
ACKDT
BF
SSP1IF
S
Receiving Address
2
4
5
6
7
8
Slave clears
ACKDT to ACK
address
ACKTIM is set on 8th falling
edge of SCL
9
ACK
When R/W = 1;
CKP is always
cleared after ACK
R/W = 1
Received address
is read from SSP1BUF
3
When AHEN = 1;
CKP is cleared by hardware
after receiving matching
address.
1
A7 A6 A5 A4 A3 A2 A1
3
4
5
6
Cleared by software
2
Set by software,
releases SCL
Data to transmit is
loaded into SSP1BUF
1
7
8
9
Transmitting Data
Automatic
D7 D6 D5 D4 D3 D2 D1 D0 ACK
ACKTIM is cleared
on 9th rising edge of SCL
Automatic
Transmitting Data
1
3
4
5
6
7
CKP not cleared
after not ACK
Master’s ACK
response is copied
to SSP1STAT
BF is automatically
cleared after 8th falling
edge of SCL
2
8
D7 D6 D5 D4 D3 D2 D1 D0
9
ACK
P
Master sends
Stop condition
FIGURE 25-19:
SCL
SDA
Master releases SDA
to slave for ACK sequence
PIC16LF1824T39A
I2C SLAVE, 7-BIT ADDRESS, TRANSMISSION (AHEN = 1)
DS40001657C-page 245
PIC16LF1824T39A
25.5.4 SLAVE MODE 10-BIT ADDRESS
RECEPTION
25.5.5 10-BIT ADDRESSING WITH ADDRESS
OR DATA HOLD
This section describes a standard sequence of events
for the MSSP1 module configured as an I2C slave in
10-bit Addressing mode.
Reception using 10-bit addressing with AHEN or
DHEN set is the same as with 7-bit modes. The only
difference is the need to update the SSP1ADD register
using the UA bit. All functionality, specifically when the
CKP bit is cleared and SCL line is held low are the
same. Figure 25-21 can be used as a reference of a
slave in 10-bit addressing with AHEN set.
Figure 25-20 is used as a visual reference for this
description.
This is a step by step process of what must be done by
slave software to accomplish I2C communication.
1.
2.
3.
4.
5.
6.
7.
8.
Bus starts Idle.
Master sends Start condition; S bit of
SSP1STAT is set; SSP1IF is set if interrupt on
Start detect is enabled.
Master sends matching high address with R/W
bit clear; UA bit of the SSP1STAT register is set.
Slave sends ACK and SSP1IF is set.
Software clears the SSP1IF bit.
Software reads received address from
SSP1BUF clearing the BF flag.
Slave loads low address into SSP1ADD,
releasing SCL.
Master sends matching low address byte to the
Slave; UA bit is set.
Figure 25-22 shows a standard waveform for a slave
transmitter in 10-bit Addressing mode.
Note: Updates to the SSP1ADD register are not
allowed until after the ACK sequence.
9.
Slave sends ACK and SSP1IF is set.
Note: If the low address does not match, SSP1IF
and UA are still set so that the slave software can set SSP1ADD back to the high
address. BF is not set because there is no
match. CKP is unaffected.
10. Slave clears SSP1IF.
11. Slave reads the received matching address
from SSP1BUF clearing BF.
12. Slave loads high address into SSP1ADD.
13. Master clocks a data byte to the slave and
clocks out the slaves ACK on the 9th SCL pulse;
SSP1IF is set.
14. If SEN bit of SSP1CON2 is set, CKP is cleared
by hardware and the clock is stretched.
15. Slave clears SSP1IF.
16. Slave reads the received byte from SSP1BUF
clearing BF.
17. If SEN is set the slave sets CKP to release the
SCL.
18. Steps 13-17 repeat for each received byte.
19. Master sends Stop to end the transmission.
DS40001657C-page 246
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2012-2017 Microchip Technology Inc.
CKP
UA
BF
SSP1IF
S
1
1
2
1
5
6
7
0 A9 A8
8
Set by hardware
on 9th falling edge
4
1
When UA = 1;
SCL is held low
9
ACK
If address matches
SSP1ADD it is loaded into
SSP1BUF
3
1
Receive First Address Byte
1
3
4
5
6
7
8
Software updates SSP1ADD
and releases SCL
2
9
A7 A6 A5 A4 A3 A2 A1 A0 ACK
Receive Second Address Byte
1
3
4
5
6
7
8
9
1
3
4
5
6
7
Data is read
from SSP1BUF
SCL is held low
while CKP = 0
2
8
9
D7 D6 D5 D4 D3 D2 D1 D0 ACK
Receive Data
Set by software,
When SEN = 1;
releasing SCL
CKP is cleared after
9th falling edge of received byte
Receive address is
read from SSP1BUF
Cleared by software
2
D7 D6 D5 D4 D3 D2 D1 D0 ACK
Receive Data
P
FIGURE 25-20:
SCL
SDA
Master sends
Stop condition
PIC16LF1824T39A
I2C SLAVE, 10-BIT ADDRESS, RECEPTION (SEN = 1, AHEN = 0, DHEN = 0)
DS40001657C-page 247
DS40001657C-page 248
ACKTIM
CKP
UA
ACKDT
BF
2
1
5
0
6
A9
7
A8
Set by hardware
on 9th falling edge
4
1
ACKTIM is set by hardware
on 8th falling edge of SCL
If when AHEN = 1;
on the 8th falling edge
of SCL of an address
byte, CKP is cleared
Slave software clears
ACKDT to ACK
the received byte
3
1
8
R/W = 0
9
ACK
UA
2
A6
3
A5
4
A4
5
A3
6
A2
7
A1
Update to SSP1ADD is
not allowed until 9th
falling edge of SCL
SSP1BUF can be
read anytime before
the next received byte
Cleared by software
1
A7
Receive Second Address Byte
8
A0
9
ACK
UA
2
D6
3
D5
4
D4
6
D2
Set CKP with software
releases SCL
7
D1
Update of SSP1ADD,
clears UA and releases
SCL
5
D3
Receive Data
Cleared by software
1
D7
8
9
2
Received data
is read from
SSP1BUF
1
D6 D5
Receive Data
D0 ACK D7
FIGURE 25-21:
SSP1IF
1
SCL
S
1
SDA
Receive First Address Byte
PIC16LF1824T39A
I2C SLAVE, 10-BIT ADDRESS, RECEPTION (SEN = 0, AHEN = 1, DHEN = 0)
2012-2017 Microchip Technology Inc.
2012-2017 Microchip Technology Inc.
D/A
R/W
ACKSTAT
CKP
UA
BF
SSP1IF
4
5
6
7
Set by hardware
3
Indicates an address
has been received
UA indicates SSP1ADD
must be updated
SSP1BUF loaded
with received address
2
8
9
1
SCL
S
Receiving Address R/W = 0
1 1 1 1 0 A9 A8
ACK
3
4
5
6
7 8
After SSP1ADD is
updated, UA is cleared
and SCL is released
Cleared by software
2
9
1
4
5
6
7 8
Set by hardware
2 3
R/W is copied from the
matching address byte
When R/W = 1;
CKP is cleared on
9th falling edge of SCL
High address is loaded
back into SSP1ADD
Received address is
read from SSP1BUF
Sr
1 1 1 1 0 A9 A8
A7 A6 A5 A4 A3 A2 A1 A0 ACK
1
Receive First Address Byte
Receiving Second Address Byte
9
ACK
2
3
4
5
6
7
8
Masters not ACK
is copied
Set by software
releases SCL
Data to transmit is
loaded into SSP1BUF
1
D7 D6 D5 D4 D3 D2 D1 D0
Transmitting Data Byte
9
P
Master sends
Stop condition
ACK = 1
Master sends
not ACK
FIGURE 25-22:
SDA
Master sends
Restart event
PIC16LF1824T39A
I2C SLAVE, 10-BIT ADDRESS, TRANSMISSION (SEN = 0, AHEN = 0, DHEN = 0)
DS40001657C-page 249
PIC16LF1824T39A
25.5.6
CLOCK STRETCHING
25.5.6.2 10-bit Addressing Mode
Clock stretching occurs when a device on the bus
holds the SCL line low, effectively pausing communication. The slave may stretch the clock to allow more
time to handle data or prepare a response for the master device. A master device is not concerned with
stretching, as anytime it is active on the bus and not
transferring data it is stretching. Any stretching done
by a slave is invisible to the master software and
handled by the hardware that generates SCL.
The CKP bit of the SSP1CON1 register is used to
control stretching in software. Any time the CKP bit is
cleared, the module will wait for the SCL line to go low
and then hold it. Setting CKP will release SCL and
allow more communication.
25.5.6.1 Normal Clock Stretching
Following an ACK if the R/W bit of SSP1STAT is set, a
read request, the slave hardware will clear CKP. This
allows the slave time to update SSP1BUF with data to
transfer to the master. If the SEN bit of SSP1CON2 is
set, the slave hardware will always stretch the clock
after the ACK sequence. Once the slave is ready; CKP
is set by software and communication resumes.
Note 1: The BF bit has no effect on if the clock will
be stretched or not. This is different than
previous versions of the module that
would not stretch the clock, clear CKP, if
SSP1BUF was read before the 9th falling
edge of SCL.
2: Previous versions of the module did not
stretch the clock for a transmission if
SSP1BUF was loaded before the 9th falling edge of SCL. It is now always cleared
for read requests.
FIGURE 25-23:
In 10-bit Addressing mode, when the UA bit is set, the
clock is always stretched. This is the only time the SCL
is stretched without CKP being cleared. SCL is
released immediately after a write to SSP1ADD.
Note: Previous versions of the module did not
stretch the clock if the second address byte
did not match.
25.5.6.3 Byte NACKing
When AHEN bit of SSP1CON3 is set; CKP is cleared
by hardware after the 8th falling edge of SCL for a
received matching address byte. When DHEN bit of
SSP1CON3 is set; CKP is cleared after the 8th falling
edge of SCL for received data.
Stretching after the 8th falling edge of SCL allows the
slave to look at the received address or data and
decide if it wants to ACK the received data.
25.5.7 CLOCK SYNCHRONIZATION AND
THE CKP BIT
Any time the CKP bit is cleared, the module will wait
for the SCL line to go low and then hold it. However,
clearing the CKP bit will not assert the SCL output low
until the SCL output is already sampled low. Therefore, the CKP bit will not assert the SCL line until an
external I2C master device has already asserted the
SCL line. The SCL output will remain low until the CKP
bit is set and all other devices on the I2C bus have
released SCL. This ensures that a write to the CKP bit
will not violate the minimum high time requirement for
SCL (see Figure 25-23).
CLOCK SYNCHRONIZATION TIMING
Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4
SDA
DX ‚ – 1
DX
SCL
CKP
Master device
asserts clock
Master device
releases clock
WR
SSP1CON1
DS40001657C-page 250
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PIC16LF1824T39A
25.5.8 GENERAL CALL ADDRESS SUPPORT
In 10-bit Address mode, the UA bit will not be set on
the reception of the general call address. The slave
will prepare to receive the second byte as data, just as
it would in 7-bit mode.
The addressing procedure for the I2C bus is such that
the first byte after the Start condition usually determines which device will be the slave addressed by the
master device. The exception is the general call
address which can address all devices. When this
address is used, all devices should, in theory, respond
with an acknowledge.
If the AHEN bit of the SSP1CON3 register is set, just
as with any other address reception, the slave hardware will stretch the clock after the 8th falling edge of
SCL. The slave must then set its ACKDT value and
release the clock with communication progressing as it
would normally.
The general call address is a reserved address in the
I2C protocol, defined as address 0x00. When the
GCEN bit of the SSP1CON2 register is set, the slave
module will automatically ACK the reception of this
address regardless of the value stored in SSP1ADD.
After the slave clocks in an address of all zeros with
the R/W bit clear, an interrupt is generated and slave
software can read SSP1BUF and respond.
Figure 25-24 shows a general call reception
sequence.
FIGURE 25-24:
SLAVE MODE GENERAL CALL ADDRESS SEQUENCE
Address is compared to General Call Address
after ACK, set interrupt
R/W = 0
ACK D7
General Call Address
SDA
SCL
S
1
2
3
4
5
6
7
8
9
1
Receiving Data
ACK
D6
D5
D4
D3
D2
D1
D0
2
3
4
5
6
7
8
9
SSP1IF
BF (SSP1STAT)
Cleared by software
GCEN (SSP1CON2)
SSP1BUF is read
’1’
25.5.9 SSP1 MASK REGISTER
An SSP1 Mask (SSP1MSK) register (Register 25-5) is
available in I2C Slave mode as a mask for the value
held in the SSP1SR register during an address
comparison operation. A zero (‘0’) bit in the SSP1MSK
register has the effect of making the corresponding bit
of the received address a “don’t care.”
This register is reset to all ‘1’s upon any Reset
condition and, therefore, has no effect on standard
SSP1 operation until written with a mask value.
The SSP1 Mask register is active during:
• 7-bit Address mode: address compare of A.
• 10-bit Address mode: address compare of A
only. The SSP1 mask has no effect during the
reception of the first (high) byte of the address.
2012-2017 Microchip Technology Inc.
DS40001657C-page 251
PIC16LF1824T39A
25.6
I2C Master Mode
Master mode is enabled by setting and clearing the
appropriate SSPM bits in the SSP1CON1 register and
by setting the SSP1EN bit. In Master mode, the SCL
and SDA lines are set as inputs and are manipulated by
the MSSP1 hardware.
Master mode of operation is supported by interrupt
generation on the detection of the Start and Stop conditions. The Stop (P) and Start (S) bits are cleared from
a Reset or when the MSSP1 module is disabled. Control of the I 2C bus may be taken when the P bit is set,
or the bus is Idle.
In Firmware Controlled Master mode, user code
conducts all I 2C bus operations based on Start and
Stop bit condition detection. Start and Stop condition
detection is the only active circuitry in this mode. All
other communication is done by the user software
directly manipulating the SDA and SCL lines.
The following events will cause the SSP1 Interrupt Flag
bit, SSP1IF, to be set (SSP1 interrupt, if enabled):
•
•
•
•
•
Start condition detected
Stop condition detected
Data transfer byte transmitted/received
Acknowledge transmitted/received
Repeated Start generated
Note 1: The MSSP1 module, when configured in
I2C Master mode, does not allow queueing of events. For instance, the user is not
allowed to initiate a Start condition and
immediately write the SSP1BUF register
to initiate transmission before the Start
condition is complete. In this case, the
SSP1BUF will not be written to and the
WCOL bit will be set, indicating that a
write to the SSP1BUF did not occur
25.6.1 I2C MASTER MODE OPERATION
The master device generates all of the serial clock
pulses and the Start and Stop conditions. A transfer is
ended with a Stop condition or with a Repeated Start
condition. Since the Repeated Start condition is also
the beginning of the next serial transfer, the I2C bus will
not be released.
In Master Transmitter mode, serial data is output
through SDA, while SCL outputs the serial clock. The
first byte transmitted contains the slave address of the
receiving device (7 bits) and the Read/Write (R/W) bit.
In this case, the R/W bit will be logic ‘0’. Serial data is
transmitted eight bits at a time. After each byte is transmitted, an Acknowledge bit is received. Start and Stop
conditions are output to indicate the beginning and the
end of a serial transfer.
In Master Receive mode, the first byte transmitted
contains the slave address of the transmitting device
(7 bits) and the R/W bit. In this case, the R/W bit will be
logic ‘1’. Thus, the first byte transmitted is a 7-bit slave
address followed by a ‘1’ to indicate the receive bit.
Serial data is received via SDA, while SCL outputs the
serial clock. Serial data is received eight bits at a time.
After each byte is received, an Acknowledge bit is
transmitted. Start and Stop conditions indicate the
beginning and end of transmission.
A Baud Rate Generator is used to set the clock
frequency output on SCL. See Section 25.7 “Baud
Rate Generator” for more detail.
2: When in Master mode, Start/Stop
detection is masked and an interrupt is
generated when the SEN/PEN bit is
cleared and the generation is complete.
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PIC16LF1824T39A
25.6.2 CLOCK ARBITRATION
Clock arbitration occurs when the master, during any
receive, transmit or Repeated Start/Stop condition,
releases the SCL pin (SCL allowed to float high). When
the SCL pin is allowed to float high, the Baud Rate
Generator (BRG) is suspended from counting until the
SCL pin is actually sampled high. When the SCL pin is
sampled high, the Baud Rate Generator is reloaded
with the contents of SSP1ADD and begins counting. This ensures that the SCL high time will always be
at least one BRG rollover count in the event that the
clock is held low by an external device (Figure 25-25).
FIGURE 25-25:
BAUD RATE GENERATOR TIMING WITH CLOCK ARBITRATION
SDA
DX ‚ – 1
DX
SCL deasserted but slave holds
SCL low (clock arbitration)
SCL allowed to transition high
SCL
BRG decrements on
Q2 and Q4 cycles
BRG
Value
03h
02h
01h
00h (hold off)
03h
02h
SCL is sampled high, reload takes
place and BRG starts its count
BRG
Reload
25.6.3 WCOL STATUS FLAG
If the user writes the SSP1BUF when a Start, Restart,
Stop, Receive or Transmit sequence is in progress, the
WCOL is set and the contents of the buffer are
unchanged (the write does not occur). Any time the
WCOL bit is set, it indicates that an action on
SSP1BUF was attempted while the module was not
Idle.
Note:
Because queueing of events is not
allowed, writing to the lower five bits of
SSP1CON2 is disabled until the Start
condition is complete.
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DS40001657C-page 253
PIC16LF1824T39A
25.6.4 I2C MASTER MODE START
CONDITION TIMING
register will be automatically cleared by hardware; the
Baud Rate Generator is suspended, leaving the SDA
line held low and the Start condition is complete.
To initiate a Start condition, the user sets the Start
Enable bit, SEN bit of the SSP1CON2 register. If the
SDA and SCL pins are sampled high, the Baud Rate
Generator is reloaded with the contents of
SSP1ADD and starts its count. If SCL and SDA
are both sampled high when the Baud Rate Generator
times out (TBRG), the SDA pin is driven low. The action
of the SDA being driven low while SCL is high is the
Start condition and causes the S bit of the SSP1STAT1
register to be set. Following this, the Baud Rate Generator is reloaded with the contents of SSP1ADD
and resumes its count. When the Baud Rate Generator times out (TBRG), the SEN bit of the SSP1CON2
FIGURE 25-26:
Note 1: If at the beginning of the Start condition,
the SDA and SCL pins are already
sampled low, or if during the Start condition, the SCL line is sampled low before
the SDA line is driven low, a bus collision
occurs, the Bus Collision Interrupt Flag,
BCL1IF, is set, the Start condition is
aborted and the I2C module is reset into
its Idle state.
2: The Philips I2C Specification states that a
bus collision cannot occur on a Start.
FIRST START BIT TIMING
Write to SEN bit occurs here
Set S bit (SSP1STAT)
At completion of Start bit,
hardware clears SEN bit
and sets SSP1IF bit
SDA = 1,
SCL = 1
TBRG
TBRG
Write to SSP1BUF occurs here
SDA
2nd bit
1st bit
TBRG
SCL
S
DS40001657C-page 254
TBRG
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
25.6.5 I2C MASTER MODE REPEATED
START CONDITION TIMING
SSP1CON2 register will be automatically cleared and
the Baud Rate Generator will not be reloaded, leaving
the SDA pin held low. As soon as a Start condition is
detected on the SDA and SCL pins, the S bit of the
SSP1STAT register will be set. The SSP1IF bit will not
be set until the Baud Rate Generator has timed out.
A Repeated Start condition occurs when the RSEN bit
of the SSP1CON2 register is programmed high and the
Master state machine is no longer active. When the
RSEN bit is set, the SCL pin is asserted low. When the
SCL pin is sampled low, the Baud Rate Generator is
loaded and begins counting. The SDA pin is released
(brought high) for one Baud Rate Generator count
(TBRG). When the Baud Rate Generator times out, if
SDA is sampled high, the SCL pin will be deasserted
(brought high). When SCL is sampled high, the Baud
Rate Generator is reloaded and begins counting. SDA
and SCL must be sampled high for one TBRG. This
action is then followed by assertion of the SDA pin
(SDA = 0) for one TBRG while SCL is high. SCL is
asserted low. Following this, the RSEN bit of the
FIGURE 25-27:
Note 1: If RSEN is programmed while any other
event is in progress, it will not take effect.
2: A bus collision during the Repeated Start
condition occurs if:
• SDA is sampled low when SCL
goes from low-to-high.
• SCL goes low before SDA is
asserted low. This may indicate
that another master is attempting to
transmit a data ‘1’.
REPEAT START CONDITION WAVEFORM
S bit set by hardware
Write to SSP1CON2
occurs here
SDA = 1,
SCL (no change)
At completion of Start bit,
hardware clears RSEN bit
and sets SSP1IF
SDA = 1,
SCL = 1
TBRG
TBRG
TBRG
1st bit
SDA
Write to SSP1BUF occurs here
TBRG
SCL
Sr
TBRG
Repeated Start
2012-2017 Microchip Technology Inc.
DS40001657C-page 255
PIC16LF1824T39A
25.6.6 I2C MASTER MODE TRANSMISSION
25.6.6.3
Transmission of a data byte, a 7-bit address or the
other half of a 10-bit address is accomplished by simply
writing a value to the SSP1BUF register. This action will
set the Buffer Full flag bit, BF and allow the Baud Rate
Generator to begin counting and start the next transmission. Each bit of address/data will be shifted out
onto the SDA pin after the falling edge of SCL is
asserted. SCL is held low for one Baud Rate Generator
rollover count (TBRG). Data should be valid before SCL
is released high. When the SCL pin is released high, it
is held that way for TBRG. The data on the SDA pin
must remain stable for that duration and some hold
time after the next falling edge of SCL. After the eighth
bit is shifted out (the falling edge of the eighth clock),
the BF flag is cleared and the master releases SDA.
This allows the slave device being addressed to
respond with an ACK bit during the ninth bit time if an
address match occurred, or if data was received properly. The status of ACK is written into the ACKSTAT bit
on the rising edge of the ninth clock. If the master
receives an Acknowledge, the Acknowledge Status bit,
ACKSTAT, is cleared. If not, the bit is set. After the ninth
clock, the SSP1IF bit is set and the master clock (Baud
Rate Generator) is suspended until the next data byte
is loaded into the SSP1BUF, leaving SCL low and SDA
unchanged (Figure 25-28).
In Transmit mode, the ACKSTAT bit of the SSP1CON2
register is cleared when the slave has sent an Acknowledge (ACK = 0) and is set when the slave does not
Acknowledge (ACK = 1). A slave sends an Acknowledge when it has recognized its address (including a
general call), or when the slave has properly received
its data.
After the write to the SSP1BUF, each bit of the address
will be shifted out on the falling edge of SCL until all
seven address bits and the R/W bit are completed. On
the falling edge of the eighth clock, the master will
release the SDA pin, allowing the slave to respond with
an Acknowledge. On the falling edge of the ninth clock,
the master will sample the SDA pin to see if the address
was recognized by a slave. The status of the ACK bit is
loaded into the ACKSTAT Status bit of the SSP1CON2
register. Following the falling edge of the ninth clock
transmission of the address, the SSP1IF is set, the BF
flag is cleared and the Baud Rate Generator is turned
off until another write to the SSP1BUF takes place,
holding SCL low and allowing SDA to float.
25.6.6.1
BF Status Flag
ACKSTAT Status Flag
25.6.6.4 Typical Transmit Sequence:
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
The user generates a Start condition by setting
the SEN bit of the SSP1CON2 register.
SSP1IF is set by hardware on completion of the
Start.
SSP1IF is cleared by software.
The MSSP1 module will wait the required start
time before any other operation takes place.
The user loads the SSP1BUF with the slave
address to transmit.
Address is shifted out the SDA pin until all eight
bits are transmitted. Transmission begins as
soon as SSP1BUF is written to.
The MSSP1 module shifts in the ACK bit from
the slave device and writes its value into the
ACKSTAT bit of the SSP1CON2 register.
The MSSP1 module generates an interrupt at
the end of the ninth clock cycle by setting the
SSP1IF bit.
The user loads the SSP1BUF with eight bits of
data.
Data is shifted out the SDA pin until all eight bits
are transmitted.
The MSSP1 module shifts in the ACK bit from
the slave device and writes its value into the
ACKSTAT bit of the SSP1CON2 register.
Steps 8-11 are repeated for all transmitted data
bytes.
The user generates a Stop or Restart condition
by setting the PEN or RSEN bits of the
SSP1CON2 register. Interrupt is generated
once the Stop/Restart condition is complete.
In Transmit mode, the BF bit of the SSP1STAT register
is set when the CPU writes to SSP1BUF and is cleared
when all eight bits are shifted out.
25.6.6.2
WCOL Status Flag
If the user writes the SSP1BUF when a transmit is
already in progress (i.e., SSP1SR is still shifting out a
data byte), the WCOL bit is set and the contents of the
buffer are unchanged (the write does not occur).
The WCOL must be cleared by software before the
next transmission.
DS40001657C-page 256
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2012-2017 Microchip Technology Inc.
S
R/W
PEN
SEN
BF (SSP1STAT)
SSP1IF
SCL
SDA
A6
A5
A4
A3
A2
A1
3
4
5
Cleared by software
2
6
7
8
9
After Start condition, SEN cleared by hardware
SSP1BUF written
1
D7
1
SCL held low
while CPU
responds to SSP1IF
ACK = 0
R/W = 0
SSP1BUF written with 7-bit address and R/W
start transmit
A7
Transmit Address to Slave
3
D5
4
D4
5
D3
6
D2
7
D1
8
D0
SSP1BUF is written by software
Cleared by software service routine
from SSP1 interrupt
2
D6
Transmitting Data or Second Half
of 10-bit Address
P
ACKSTAT in
SSP1CON2 = 1
Cleared by software
9
ACK
From slave, clear ACKSTAT bit SSP1CON2
FIGURE 25-28:
SEN = 0
Write SSP1CON2 SEN = 1
Start condition begins
PIC16LF1824T39A
I2C MASTER MODE WAVEFORM (TRANSMISSION, 7 OR 10-BIT ADDRESS)
DS40001657C-page 257
PIC16LF1824T39A
25.6.7
I2C MASTER MODE RECEPTION
Master mode reception is enabled by programming the
Receive Enable bit, RCEN bit of the SSP1CON2
register.
Note:
The MSSP1 module must be in an Idle
state before the RCEN bit is set or the
RCEN bit will be disregarded.
The Baud Rate Generator begins counting and on each
rollover, the state of the SCL pin changes
(high-to-low/low-to-high) and data is shifted into the
SSP1SR. After the falling edge of the eighth clock, the
receive enable flag is automatically cleared, the contents of the SSP1SR are loaded into the SSP1BUF, the
BF flag bit is set, the SSP1IF flag bit is set and the Baud
Rate Generator is suspended from counting, holding
SCL low. The MSSP1 is now in Idle state awaiting the
next command. When the buffer is read by the CPU,
the BF flag bit is automatically cleared. The user can
then send an Acknowledge bit at the end of reception
by setting the Acknowledge Sequence Enable, ACKEN
bit of the SSP1CON2 register.
25.6.7.1
BF Status Flag
25.6.7.4 Typical Receive Sequence:
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
In receive operation, the BF bit is set when an address
or data byte is loaded into SSP1BUF from SSP1SR. It
is cleared when the SSP1BUF register is read.
11.
25.6.7.2
12.
SSPOV Status Flag
In receive operation, the SSPOV bit is set when eight
bits are received into the SSP1SR and the BF flag bit is
already set from a previous reception.
25.6.7.3
WCOL Status Flag
If the user writes the SSP1BUF when a receive is
already in progress (i.e., SSP1SR is still shifting in a
data byte), the WCOL bit is set and the contents of the
buffer are unchanged (the write does not occur).
DS40001657C-page 258
13.
14.
15.
The user generates a Start condition by setting
the SEN bit of the SSP1CON2 register.
SSP1IF is set by hardware on completion of the
Start.
SSP1IF is cleared by software.
User writes SSP1BUF with the slave address to
transmit and the R/W bit set.
Address is shifted out the SDA pin until all eight
bits are transmitted. Transmission begins as
soon as SSP1BUF is written to.
The MSSP1 module shifts in the ACK bit from
the slave device and writes its value into the
ACKSTAT bit of the SSP1CON2 register.
The MSSP1 module generates an interrupt at
the end of the ninth clock cycle by setting the
SSP1IF bit.
User sets the RCEN bit of the SSP1CON2 register and the master clocks in a byte from the slave.
After the 8th falling edge of SCL, SSP1IF and
BF are set.
Master clears SSP1IF and reads the received
byte from SSP1UF, clears BF.
Master sets ACK value sent to slave in ACKDT
bit of the SSP1CON2 register and initiates the
ACK by setting the ACKEN bit.
Masters ACK is clocked out to the slave and
SSP1IF is set.
User clears SSP1IF.
Steps 8-13 are repeated for each received byte
from the slave.
Master sends a not ACK or Stop to end
communication.
2012-2017 Microchip Technology Inc.
2012-2017 Microchip Technology Inc.
S
RCEN
ACKEN
SSPOV
BF
(SSP1STAT)
SDA = 0, SCL = 1
while CPU
responds to SSP1IF
SSP1IF
SCL
SDA
1
A7
2
4
5
6
Cleared by software
3
A6 A5 A4 A3 A2
Transmit Address to Slave
7
A1
8
ACK
Receiving Data from Slave
2
3
5
6
7
8
D0
9
ACK
Receiving Data from Slave
2
3
4
RCEN cleared
automatically
5
6
7
Cleared by software
Set SSP1IF interrupt
at end of Acknowledge
sequence
Data shifted in on falling edge of CLK
1
ACK from Master
SDA\ = ACKDT = 0
Cleared in
software
Set SSP1IF at end
of receive
9
ACK is not sent
ACK
RCEN cleared
automatically
P
Set SSP1IF interrupt
at end of Acknowledge sequence
Bus master
terminates
transfer
Set P bit
(SSP1STAT)
and SSP1IF
PEN bit = 1
written here
SSPOV is set because
SSP1BUF is still full
8
D0
RCEN cleared
automatically
Set ACKEN, start Acknowledge sequence
SDA = ACKDT = 1
D7 D6 D5 D4 D3 D2 D1
Last bit is shifted into SSP1SR and
contents are unloaded into SSP1BUF
Cleared by software
Set SSP1IF interrupt
at end of receive
4
Cleared by software
1
D7 D6 D5 D4 D3 D2 D1
Master configured as a receiver
by programming SSP1CON2 (RCEN = 1)
9
R/W = 1
RCEN = 1, start
next receive
ACK from Master
SDA = ACKDT = 0
FIGURE 25-29:
RCEN cleared
automatically
Master configured as a receiver
by programming SSP1CON2 (RCEN = 1)
SEN = 0
Write to SSP1BUF occurs here,
ACK from Slave
start XMIT
Write to SSP1CON2(SEN = 1),
begin Start condition
Write to SSP1CON2
to start Acknowledge sequence
SDA = ACKDT (SSP1CON2) = 0
PIC16LF1824T39A
I2C MASTER MODE WAVEFORM (RECEPTION, 7-BIT ADDRESS)
DS40001657C-page 259
PIC16LF1824T39A
25.6.8
ACKNOWLEDGE SEQUENCE
TIMING
25.6.9
A Stop bit is asserted on the SDA pin at the end of a
receive/transmit by setting the Stop Sequence Enable
bit, PEN bit of the SSP1CON2 register. At the end of a
receive/transmit, the SCL line is held low after the
falling edge of the ninth clock. When the PEN bit is set,
the master will assert the SDA line low. When the SDA
line is sampled low, the Baud Rate Generator is
reloaded and counts down to ‘0’. When the Baud Rate
Generator times out, the SCL pin will be brought high
and one TBRG (Baud Rate Generator rollover count)
later, the SDA pin will be deasserted. When the SDA
pin is sampled high while SCL is high, the P bit of the
SSP1STAT register is set. A TBRG later, the PEN bit is
cleared and the SSP1IF bit is set (Figure 25-31).
An Acknowledge sequence is enabled by setting the
Acknowledge Sequence Enable bit, ACKEN bit of the
SSP1CON2 register. When this bit is set, the SCL pin is
pulled low and the contents of the Acknowledge data bit
are presented on the SDA pin. If the user wishes to generate an Acknowledge, then the ACKDT bit should be
cleared. If not, the user should set the ACKDT bit before
starting an Acknowledge sequence. The Baud Rate
Generator then counts for one rollover period (TBRG)
and the SCL pin is deasserted (pulled high). When the
SCL pin is sampled high (clock arbitration), the Baud
Rate Generator counts for TBRG. The SCL pin is then
pulled low. Following this, the ACKEN bit is automatically
cleared, the Baud Rate Generator is turned off and the
MSSP1 module then goes into Idle mode
(Figure 25-30).
25.6.8.1
25.6.9.1
WCOL Status Flag
If the user writes the SSP1BUF when a Stop sequence
is in progress, then the WCOL bit is set and the
contents of the buffer are unchanged (the write does
not occur).
WCOL Status Flag
If the user writes the SSP1BUF when an Acknowledge
sequence is in progress, then the WCOL bit is set and
the contents of the buffer are unchanged (the write
does not occur).
FIGURE 25-30:
STOP CONDITION TIMING
ACKNOWLEDGE SEQUENCE WAVEFORM
Acknowledge sequence starts here,
write to SSP1CON2
ACKEN = 1, ACKDT = 0
ACKEN automatically cleared
TBRG
TBRG
SDA
SCL
D0
ACK
8
9
SSP1IF
SSP1IF set at
the end of receive
Cleared in
software
Cleared in
software
SSP1IF set at the end
of Acknowledge sequence
Note: TBRG = one Baud Rate Generator period.
DS40001657C-page 260
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PIC16LF1824T39A
FIGURE 25-31:
STOP CONDITION RECEIVE OR TRANSMIT MODE
SCL = 1 for TBRG, followed by SDA = 1 for TBRG
after SDA sampled high. P bit (SSP1STAT) is set.
Write to SSP1CON2,
set PEN
PEN bit (SSP1CON2) is cleared by
hardware and the SSP1IF bit is set
Falling edge of
9th clock
TBRG
SCL
SDA
ACK
P
TBRG
TBRG
TBRG
SCL brought high after TBRG
SDA asserted low before rising edge of clock
to set up Stop condition
Note: TBRG = one Baud Rate Generator period.
25.6.10
SLEEP OPERATION
While in Sleep mode, the I2C slave module can receive
addresses or data and when an address match or
complete byte transfer occurs, wake the processor
from Sleep (if the MSSP1 interrupt is enabled).
25.6.11
EFFECTS OF A RESET
A Reset disables the MSSP1 module and terminates
the current transfer.
25.6.12
MULTI-MASTER MODE
In Multi-Master mode, the interrupt generation on the
detection of the Start and Stop conditions allows the
determination of when the bus is free. The Stop (P) and
Start (S) bits are cleared from a Reset or when the
MSSP1 module is disabled. Control of the I 2C bus may
be taken when the P bit of the SSP1STAT register is
set, or the bus is Idle, with both the S and P bits clear.
When the bus is busy, enabling the SSP interrupt will
generate the interrupt when the Stop condition occurs.
In multi-master operation, the SDA line must be
monitored for arbitration to see if the signal level is the
expected output level. This check is performed by
hardware with the result placed in the BCL1IF bit.
The states where arbitration can be lost are:
•
•
•
•
•
Address Transfer
Data Transfer
A Start Condition
A Repeated Start Condition
An Acknowledge Condition
25.6.13
MULTI -MASTER COMMUNICATION,
BUS COLLISION AND BUS
ARBITRATION
Multi-Master mode support is achieved by bus arbitration. When the master outputs address/data bits onto
the SDA pin, arbitration takes place when the master
outputs a ‘1’ on SDA, by letting SDA float high and
another master asserts a ‘0’. When the SCL pin floats
high, data should be stable. If the expected data on
SDA is a ‘1’ and the data sampled on the SDA pin is ‘0’,
then a bus collision has taken place. The master will set
the Bus Collision Interrupt Flag, BCL1IF and reset the
I2C port to its Idle state (Figure 25-32).
If a transmit was in progress when the bus collision
occurred, the transmission is halted, the BF flag is
cleared, the SDA and SCL lines are deasserted and the
SSP1BUF can be written to. When the user services
the bus collision Interrupt Service Routine and if the I2C
bus is free, the user can resume communication by
asserting a Start condition.
If a Start, Repeated Start, Stop or Acknowledge
condition was in progress when the bus collision
occurred, the condition is aborted, the SDA and SCL
lines are deasserted and the respective control bits in
the SSP1CON2 register are cleared. When the user
services the bus collision Interrupt Service Routine and
if the I2C bus is free, the user can resume communication by asserting a Start condition.
The master will continue to monitor the SDA and SCL
pins. If a Stop condition occurs, the SSP1IF bit will be set.
A write to the SSP1BUF will start the transmission of
data at the first data bit, regardless of where the
transmitter left off when the bus collision occurred.
In Multi-Master mode, the interrupt generation on the
detection of Start and Stop conditions allows the determination of when the bus is free. Control of the I2C bus
can be taken when the P bit is set in the SSP1STAT
register, or the bus is Idle and the S and P bits are
cleared.
2012-2017 Microchip Technology Inc.
DS40001657C-page 261
PIC16LF1824T39A
FIGURE 25-32:
BUS COLLISION TIMING FOR TRANSMIT AND ACKNOWLEDGE
Data changes
while SCL = 0
SDA line pulled low
by another source
SDA released
by master
Sample SDA. While SCL is high,
data does not match what is driven
by the master.
Bus collision has occurred.
SDA
SCL
Set bus collision
interrupt (BCL1IF)
BCL1IF
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PIC16LF1824T39A
25.6.13.1
Bus Collision During a Start
Condition
During a Start condition, a bus collision occurs if:
a)
b)
SDA or SCL are sampled low at the beginning of
the Start condition (Figure 25-33).
SCL is sampled low before SDA is asserted low
(Figure 25-34).
During a Start condition, both the SDA and the SCL
pins are monitored.
If the SDA pin is sampled low during this count, the
BRG is reset and the SDA line is asserted early
(Figure 25-35). If, however, a ‘1’ is sampled on the SDA
pin, the SDA pin is asserted low at the end of the BRG
count. The Baud Rate Generator is then reloaded and
counts down to zero; if the SCL pin is sampled as ‘0’
during this time, a bus collision does not occur. At the
end of the BRG count, the SCL pin is asserted low.
Note:
If the SDA pin is already low, or the SCL pin is already
low, then all of the following occur:
• the Start condition is aborted,
• the BCL1IF flag is set and
• the MSSP1 module is reset to its Idle state
(Figure 25-33).
The Start condition begins with the SDA and SCL pins
deasserted. When the SDA pin is sampled high, the
Baud Rate Generator is loaded and counts down. If the
SCL pin is sampled low while SDA is high, a bus collision occurs because it is assumed that another master
is attempting to drive a data ‘1’ during the Start
condition.
FIGURE 25-33:
The reason that bus collision is not a
factor during a Start condition is that no
two bus masters can assert a Start condition at the exact same time. Therefore,
one master will always assert SDA before
the other. This condition does not cause a
bus collision because the two masters
must be allowed to arbitrate the first
address following the Start condition. If the
address is the same, arbitration must be
allowed to continue into the data portion,
Repeated Start or Stop conditions.
BUS COLLISION DURING START CONDITION (SDA ONLY)
SDA goes low before the SEN bit is set.
Set BCL1IF,
S bit and SSP1IF set because
SDA = 0, SCL = 1.
SDA
SCL
Set SEN, enable Start
condition if SDA = 1, SCL = 1
SEN cleared automatically because of bus collision.
SSP1 module reset into Idle state.
SEN
BCL1IF
SDA sampled low before
Start condition. Set BCL1IF.
S bit and SSP1IF set because
SDA = 0, SCL = 1.
SSP1IF and BCL1IF are
cleared by software
S
SSP1IF
SSP1IF and BCL1IF are
cleared by software
2012-2017 Microchip Technology Inc.
DS40001657C-page 263
PIC16LF1824T39A
FIGURE 25-34:
BUS COLLISION DURING START CONDITION (SCL = 0)
SDA = 0, SCL = 1
TBRG
TBRG
SDA
Set SEN, enable Start
sequence if SDA = 1, SCL = 1
SCL
SCL = 0 before SDA = 0,
bus collision occurs. Set BCL1IF.
SEN
SCL = 0 before BRG time-out,
bus collision occurs. Set BCL1IF.
BCL1IF
Interrupt cleared
by software
‘0’
‘0’
SSP1IF ‘0’
‘0’
S
FIGURE 25-35:
BRG RESET DUE TO SDA ARBITRATION DURING START CONDITION
SDA = 0, SCL = 1
Set S
Less than TBRG
SDA
SCL
TBRG
SDA pulled low by other master.
Reset BRG and assert SDA.
S
SCL pulled low after BRG
time-out
SEN
BCL1IF
Set SSP1IF
Set SEN, enable Start
sequence if SDA = 1, SCL = 1
‘0’
S
SSP1IF
SDA = 0, SCL = 1,
set SSP1IF
DS40001657C-page 264
Interrupts cleared
by software
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
25.6.13.2
Bus Collision During a Repeated
Start Condition
If SDA is low, a bus collision has occurred (i.e., another
master is attempting to transmit a data ‘0’, Figure 25-36).
If SDA is sampled high, the BRG is reloaded and begins
counting. If SDA goes from high-to-low before the BRG
times out, no bus collision occurs because no two
masters can assert SDA at exactly the same time.
During a Repeated Start condition, a bus collision
occurs if:
a)
b)
A low level is sampled on SDA when SCL goes
from low level to high level.
SCL goes low before SDA is asserted low,
indicating that another master is attempting to
transmit a data ‘1’.
If SCL goes from high-to-low before the BRG times out
and SDA has not already been asserted, a bus collision
occurs. In this case, another master is attempting to
transmit a data ‘1’ during the Repeated Start condition,
see Figure 25-37.
When the user releases SDA and the pin is allowed to
float high, the BRG is loaded with SSP1ADD and
counts down to zero. The SCL pin is then deasserted
and when sampled high, the SDA pin is sampled.
FIGURE 25-36:
If, at the end of the BRG time-out, both SCL and SDA
are still high, the SDA pin is driven low and the BRG is
reloaded and begins counting. At the end of the count,
regardless of the status of the SCL pin, the SCL pin is
driven low and the Repeated Start condition is
complete.
BUS COLLISION DURING A REPEATED START CONDITION (CASE 1)
SDA
SCL
Sample SDA when SCL goes high.
If SDA = 0, set BCL1IF and release SDA and SCL.
RSEN
BCL1IF
Cleared by software
S
‘0’
SSP1IF
‘0’
FIGURE 25-37:
BUS COLLISION DURING REPEATED START CONDITION (CASE 2)
TBRG
TBRG
SDA
SCL
BCL1IF
SCL goes low before SDA,
set BCL1IF. Release SDA and SCL.
Interrupt cleared
by software
RSEN
S
‘0’
SSP1IF
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DS40001657C-page 265
PIC16LF1824T39A
25.6.13.3
Bus Collision During a Stop
Condition
The Stop condition begins with SDA asserted low.
When SDA is sampled low, the SCL pin is allowed to
float. When the pin is sampled high (clock arbitration),
the Baud Rate Generator is loaded with SSP1ADD and
counts down to zero. After the BRG times out, SDA is
sampled. If SDA is sampled low, a bus collision has
occurred. This is due to another master attempting to
drive a data ‘0’ (Figure 25-38). If the SCL pin is sampled
low before SDA is allowed to float high, a bus collision
occurs. This is another case of another master
attempting to drive a data ‘0’ (Figure 25-39).
Bus collision occurs during a Stop condition if:
a)
b)
After the SDA pin has been deasserted and
allowed to float high, SDA is sampled low after
the BRG has timed out.
After the SCL pin is deasserted, SCL is sampled
low before SDA goes high.
FIGURE 25-38:
BUS COLLISION DURING A STOP CONDITION (CASE 1)
TBRG
TBRG
TBRG
SDA
SDA sampled
low after TBRG,
set BCL1IF
SDA asserted low
SCL
PEN
BCL1IF
P
‘0’
SSP1IF
‘0’
FIGURE 25-39:
BUS COLLISION DURING A STOP CONDITION (CASE 2)
TBRG
TBRG
TBRG
SDA
Assert SDA
SCL
SCL goes low before SDA goes high,
set BCL1IF
PEN
BCL1IF
P
‘0’
SSP1IF
‘0’
DS40001657C-page 266
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PIC16LF1824T39A
TABLE 25-3:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH I2C™ OPERATION
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Reset
Values on
Page:
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
INTCON
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIE2
OSFIE
C2IE
C1IE
EEIE
BCL1IE
—
—
CCP2IE
86
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
PIR2
OSFIF
C2IF
C1IF
EEIF
BCL1IF
—
—
CCP2IF
ADD7
ADD6
ADD5
ADD4
ADD3
ADD2
ADD1
ADD0
SSP1ADD
SSP1BUF
TMR1IF
Synchronous Serial Port Receive Buffer/Transmit Register
88
89
273
224*
SSP1CON1
WCOL
SSPOV
SSPEN
CKP
SSP1CON2
GCEN
ACKSTAT
ACKDT
ACKEN
RCEN
PEN
SSPM
RSEN
SEN
270
271
SSP1CON3
ACKTIM
PCIE
SCIE
BOEN
SDAHT
SBCDE
AHEN
DHEN
272
SSP1MSK
MSK7
MSK6
MSK5
MSK4
MSK3
MSK2
MSK1
MSK0
273
SSP1STAT
SMP
CKE
D/A
P
S
R/W
UA
BF
269
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
TRISC
Legend:
*
— = unimplemented location, read as ‘0’. Shaded cells are not used by the MSSP module in I2C™ mode.
Page provides register information.
2012-2017 Microchip Technology Inc.
DS40001657C-page 267
PIC16LF1824T39A
25.7
Baud Rate Generator
The MSSP1 module has a Baud Rate Generator available for clock generation in both I2C and SPI Master
modes. The Baud Rate Generator (BRG) reload value
is placed in the SSP1ADD register (Register 25-6).
When a write occurs to SSP1BUF, the Baud Rate
Generator will automatically begin counting down.
Once the given operation is complete, the internal clock
will automatically stop counting and the clock pin will
remain in its last state.
module clock line. The logic dictating when the reload
signal is asserted depends on the mode the MSSP1 is
being operated in.
Table 25-4 demonstrates clock rates based on
instruction cycles and the BRG value loaded into
SSP1ADD.
EQUATION 25-1:
FOSC
FCLOCK = ------------------------------------------------ SSPxADD + 1 4
An internal signal “Reload” in Figure 25-40 triggers the
value from SSP1ADD to be loaded into the BRG
counter. This occurs twice for each oscillation of the
FIGURE 25-40:
BAUD RATE GENERATOR BLOCK DIAGRAM
SSP1M
SSP1M
Reload
SCL
Control
SSP1CLK
SSP1ADD
Reload
BRG Down Counter
FOSC/2
Note: Values of 0x00, 0x01 and 0x02 are not valid
for SSP1ADD when used as a Baud Rate
Generator for I2C. This is an implementation
limitation.
TABLE 25-4:
Note 1:
25.7.1
MSSP1 CLOCK RATE W/BRG
FOSC
FCY
BRG Value
FCLOCK
(2 Rollovers of BRG)
32 MHz
8 MHz
13h
400 kHz(1)
32 MHz
8 MHz
19h
308 kHz
32 MHz
8 MHz
4Fh
100 kHz
16 MHz
4 MHz
09h
400 kHz(1)
16 MHz
4 MHz
0Ch
308 kHz
16 MHz
4 MHz
27h
100 kHz
4 MHz
1 MHz
09h
100 kHz
The I2C interface does not conform to the 400 kHz I2C specification (which applies to rates greater than
100 kHz) in all details, but may be used with care where higher rates are required by the application.
ALTERNATE PIN LOCATIONS
This module incorporates I/O pins that can be moved to
other locations with the use of the alternate pin function
registers, APFCON0 and APFCON1. To determine
which pins can be moved and what their default
locations are upon a Reset, see Section 12.1 “Alternate Pin Function” for more information.
DS40001657C-page 268
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PIC16LF1824T39A
REGISTER 25-1:
SSP1STAT: SSP1 STATUS REGISTER
R/W-0/0
R/W-0/0
R-0/0
R-0/0
R-0/0
R-0/0
R-0/0
R-0/0
SMP
CKE
D/A
P
S
R/W
UA
BF
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
SMP: SPI Data Input Sample bit
SPI Master mode:
1 = Input data sampled at end of data output time
0 = Input data sampled at middle of data output time
SPI Slave mode:
SMP must be cleared when SPI is used in Slave mode
In I2 C Master or Slave mode:
1 = Slew rate control disabled for standard speed mode (100 kHz and 1 MHz)
0 = Slew rate control enabled for high speed mode (400 kHz)
bit 6
CKE: SPI Clock Edge Select bit (SPI mode only)
In SPI Master or Slave mode:
1 = Transmit occurs on transition from active to Idle clock state
0 = Transmit occurs on transition from Idle to active clock state
In I2 C™ mode only:
1 = Enable input logic so that thresholds are compliant with SMbus specification
0 = Disable SMbus specific inputs
bit 5
D/A: Data/Address bit (I2C mode only)
1 = Indicates that the last byte received or transmitted was data
0 = Indicates that the last byte received or transmitted was address
bit 4
P: Stop bit
(I2C mode only. This bit is cleared when the MSSP1 module is disabled, SSP1EN is cleared.)
1 = Indicates that a Stop bit has been detected last (this bit is ‘0’ on Reset)
0 = Stop bit was not detected last
bit 3
S: Start bit
(I2C mode only. This bit is cleared when the MSSP1 module is disabled, SSP1EN is cleared.)
1 = Indicates that a Start bit has been detected last (this bit is ‘0’ on Reset)
0 = Start bit was not detected last
bit 2
R/W: Read/Write bit information (I2C mode only)
This bit holds the R/W bit information following the last address match. This bit is only valid from the address match
to the next Start bit, Stop bit, or not ACK bit.
In I2 C Slave mode:
1 = Read
0 = Write
In I2 C Master mode:
1 = Transmit is in progress
0 = Transmit is not in progress
OR-ing this bit with SEN, RSEN, PEN, RCEN or ACKEN will indicate if the MSSP1 is in Idle mode.
bit 1
UA: Update Address bit (10-bit I2C mode only)
1 = Indicates that the user needs to update the address in the SSP1ADD register
0 = Address does not need to be updated
bit 0
BF: Buffer Full Status bit
Receive (SPI and I2 C modes):
1 = Receive complete, SSP1BUF is full
0 = Receive not complete, SSP1BUF is empty
Transmit (I2 C mode only):
1 = Data transmit in progress (does not include the ACK and Stop bits), SSP1BUF is full
0 = Data transmit complete (does not include the ACK and Stop bits), SSP1BUF is empty
2012-2017 Microchip Technology Inc.
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PIC16LF1824T39A
REGISTER 25-2:
SSP1CON1: SSP1 CONTROL REGISTER 1
R/C/HS-0/0
R/C/HS-0/0
R/W-0/0
R/W-0/0
WCOL
SSPOV
SSPEN
CKP
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
SSPM
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
u = Bit is unchanged
x = Bit is unknown
U = Unimplemented bit, read as ‘0’
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
HS = Bit is set by hardware
C = User cleared
bit 7
WCOL: Write Collision Detect bit
Master mode:
1 = A write to the SSP1BUF register was attempted while the I2C™ conditions were not valid for a transmission to be started
0 = No collision
Slave mode:
1 = The SSP1BUF register is written while it is still transmitting the previous word (must be cleared in software)
0 = No collision
bit 6
SSPOV: Receive Overflow Indicator bit(1)
In SPI mode:
1 = A new byte is received while the SSP1BUF register is still holding the previous data. In case of overflow, the data in SSP1SR is lost.
Overflow can only occur in Slave mode. In Slave mode, the user must read the SSP1BUF, even if only transmitting data, to avoid
setting overflow. In Master mode, the overflow bit is not set since each new reception (and transmission) is initiated by writing to the
SSP1BUF register (must be cleared in software).
0 = No overflow
In I2 C mode:
1 = A byte is received while the SSP1BUF register is still holding the previous byte. SSPOV is a “don’t care” in Transmit mode
(must be cleared in software).
0 = No overflow
bit 5
SSPEN: Synchronous Serial Port Enable bit
In both modes, when enabled, these pins must be properly configured as input or output
In SPI mode:
1 = Enables serial port and configures SCK, SDO, SDI and SS as the source of the serial port pins(2)
0 = Disables serial port and configures these pins as I/O port pins
In I2 C mode:
1 = Enables the serial port and configures the SDA and SCL pins as the source of the serial port pins(3)
0 = Disables serial port and configures these pins as I/O port pins
bit 4
CKP: Clock Polarity Select bit
In SPI mode:
1 = Idle state for clock is a high level
0 = Idle state for clock is a low level
In I2 C Slave mode:
SCL release control
1 = Enable clock
0 = Holds clock low (clock stretch). (Used to ensure data setup time.)
In I2 C Master mode:
Unused in this mode
bit 3-0
SSPM: Synchronous Serial Port Mode Select bits
0000 = SPI Master mode, clock = FOSC/4
0001 = SPI Master mode, clock = FOSC/16
0010 = SPI Master mode, clock = FOSC/64
0011 = SPI Master mode, clock = TMR2 output/2
0100 = SPI Slave mode, clock = SCK pin, SS pin control enabled
0101 = SPI Slave mode, clock = SCK pin, SS pin control disabled, SS can be used as I/O pin
0110 = I2C Slave mode, 7-bit address
0111 = I2C Slave mode, 10-bit address
1000 = I2C Master mode, clock = FOSC/(4 * (SSP1ADD+1))(4)
1001 = Reserved
1010 = SPI Master mode, clock = FOSC/(4 * (SSP1ADD+1))(5)
1011 = I2C firmware controlled Master mode (Slave idle)
1100 = Reserved
1101 = Reserved
1110 = I2C Slave mode, 7-bit address with Start and Stop bit interrupts enabled
1111 = I2C Slave mode, 10-bit address with Start and Stop bit interrupts enabled
Note
1:
2:
3:
4:
5:
In Master mode, the overflow bit is not set since each new reception (and transmission) is initiated by writing to the SSP1BUF register.
When enabled, these pins must be properly configured as input or output.
When enabled, the SDA and SCL pins must be configured as inputs.
SSP1ADD values of 0, 1 or 2 are not supported for I2C™ mode.
SSPxADD value of 0 is not supported. Use SSPxM = 0000 instead.
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REGISTER 25-3:
SSP1CON2: SSP1 CONTROL REGISTER 2
R/W-0/0
R-0/0
R/W-0/0
R/S/HS-0/0
R/S/HS-0/0
R/S/HS-0/0
R/S/HS-0/0
R/W/HS-0/0
GCEN
ACKSTAT
ACKDT
ACKEN
RCEN
PEN
RSEN
SEN
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
HC = Cleared by hardware
S = User set
bit 7
GCEN: General Call Enable bit (in I2C Slave mode only)
1 = Enable interrupt when a general call address (0x00 or 00h) is received in the SSP1SR
0 = General call address disabled
bit 6
ACKSTAT: Acknowledge Status bit (in I2C mode only)
1 = Acknowledge was not received
0 = Acknowledge was received
bit 5
ACKDT: Acknowledge Data bit (in I2C mode only)
In Receive mode:
Value transmitted when the user initiates an Acknowledge sequence at the end of a receive
1 = Not Acknowledge
0 = Acknowledge
bit 4
ACKEN: Acknowledge Sequence Enable bit (in I2C Master mode only)
In Master Receive mode:
1 = Initiate Acknowledge sequence on SDA and SCL pins, and transmit ACKDT data bit.
Automatically cleared by hardware.
0 = Acknowledge sequence idle
bit 3
RCEN: Receive Enable bit (in I2C Master mode only)
1 = Enables Receive mode for I2C
0 = Receive idle
bit 2
PEN: Stop Condition Enable bit (in I2C Master mode only)
SCK Release Control:
1 = Initiate Stop condition on SDA and SCL pins. Automatically cleared by hardware.
0 = Stop condition Idle
bit 1
RSEN: Repeated Start Condition Enabled bit (in I2C Master mode only)
1 = Initiate Repeated Start condition on SDA and SCL pins. Automatically cleared by hardware.
0 = Repeated Start condition Idle
bit 0
SEN: Start Condition Enabled bit (in I2C Master mode only)
In Master mode:
1 = Initiate Start condition on SDA and SCL pins. Automatically cleared by hardware.
0 = Start condition Idle
In Slave mode:
1 = Clock stretching is enabled for both slave transmit and slave receive (stretch enabled)
0 = Clock stretching is disabled
Note 1:
For bits ACKEN, RCEN, PEN, RSEN, SEN: If the I2C module is not in the Idle mode, this bit may not be
set (no spooling) and the SSP1BUF may not be written (or writes to the SSP1BUF are disabled).
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REGISTER 25-4:
SSP1CON3: SSP1 CONTROL REGISTER 3
R-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
ACKTIM
PCIE
SCIE
BOEN
SDAHT
SBCDE
AHEN
DHEN
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
ACKTIM: Acknowledge Time Status bit (I2C mode only)(3)
1 = Indicates the I2C bus is in an Acknowledge sequence, set on 8TH falling edge of SCL clock
0 = Not an Acknowledge sequence, cleared on 9TH rising edge of SCL clock
bit 6
PCIE: Stop Condition Interrupt Enable bit (I2C mode only)
1 = Enable interrupt on detection of Stop condition
0 = Stop detection interrupts are disabled(2)
bit 5
SCIE: Start Condition Interrupt Enable bit (I2C mode only)
1 = Enable interrupt on detection of Start or Restart conditions
0 = Start detection interrupts are disabled(2)
bit 4
BOEN: Buffer Overwrite Enable bit
In SPI Slave mode:(1)
1 = SSP1BUF updates every time that a new data byte is shifted in ignoring the BF bit
0 = If new byte is received with BF bit of the SSP1STAT register already set, SSPOV bit of the
SSP1CON1 register is set, and the buffer is not updated
In I2C Master mode and SPI Master mode:
This bit is ignored.
In I2C Slave mode:
1 = SSP1BUF is updated and ACK is generated for a received address/data byte, ignoring the
state of the SSPOV bit only if the BF bit = 0.
0 = SSP1BUF is only updated when SSPOV is clear
bit 3
SDAHT: SDA Hold Time Selection bit (I2C mode only)
1 = Minimum of 300 ns hold time on SDA after the falling edge of SCL
0 = Minimum of 100 ns hold time on SDA after the falling edge of SCL
bit 2
SBCDE: Slave Mode Bus Collision Detect Enable bit (I2C Slave mode only)
If on the rising edge of SCL, SDA is sampled low when the module is outputting a high state, the
BCL1IF bit of the PIR2 register is set, and bus goes idle
1 = Enable slave bus collision interrupts
0 = Slave bus collision interrupts are disabled
bit 1
AHEN: Address Hold Enable bit (I2C Slave mode only)
1 = Following the 8th falling edge of SCL for a matching received address byte; CKP bit of the
SSP1CON1 register will be cleared and the SCL will be held low.
0 = Address holding is disabled
bit 0
DHEN: Data Hold Enable bit (I2C Slave mode only)
1 = Following the 8th falling edge of SCL for a received data byte; slave hardware clears the CKP bit
of the SSP1CON1 register and SCL is held low.
0 = Data holding is disabled
Note 1:
2:
3:
For daisy-chained SPI operation; allows the user to ignore all but the last received byte. SSPOV is still set
when a new byte is received and BF = 1, but hardware continues to write the most recent byte to
SSP1BUF.
This bit has no effect in Slave modes that Start and Stop condition detection is explicitly listed as enabled.
The ACKTIM Status bit is only active when the AHEN bit or DHEN bit is set.
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REGISTER 25-5:
R/W-1/1
SSP1MSK: SSP1 MASK REGISTER
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
R/W-1/1
MSK
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-1
MSK: Mask bits
1 = The received address bit n is compared to SSP1ADD to detect I2C address match
0 = The received address bit n is not used to detect I2C address match
bit 0
MSK: Mask bit for I2C Slave mode, 10-bit Address
I2C Slave mode, 10-bit address (SSP1M = 0111 or 1111):
1 = The received address bit 0 is compared to SSP1ADD to detect I2C address match
0 = The received address bit 0 is not used to detect I2C address match I2C Slave mode, 7-bit address,
the bit is ignored
REGISTER 25-6:
R/W-0/0
SSP1ADD: MSSP1 ADDRESS AND BAUD RATE REGISTER (I2C MODE)
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
ADD
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
Master mode:
bit 7-0
ADD: Baud Rate Clock Divider bits
SCL pin clock period = ((ADD + 1) *4)/FOSC
10-Bit Slave mode — Most Significant Address Byte:
bit 7-3
Not used: Unused for Most Significant Address Byte. Bit state of this register is a “don’t care.” Bit
pattern sent by master is fixed by I2C specification and must be equal to ‘11110’. However, those bits
are compared by hardware and are not affected by the value in this register.
bit 2-1
ADD: Two Most Significant bits of 10-bit address
bit 0
Not used: Unused in this mode. Bit state is a “don’t care.”
10-Bit Slave mode — Least Significant Address byte:
bit 7-0
ADD: Eight Least Significant bits of 10-bit address
7-Bit Slave mode:
bit 7-1
ADD: 7-bit address
bit 0
Not used: Unused in this mode. Bit state is a “don’t care.”
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NOTES:
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PIC16LF1824T39A
26.0
ENHANCED UNIVERSAL
SYNCHRONOUS
ASYNCHRONOUS RECEIVER
TRANSMITTER (EUSART)
The EUSART module includes the following capabilities:
•
•
•
•
•
•
•
•
•
•
Full-duplex asynchronous transmit and receive
Two-character input buffer
One-character output buffer
Programmable 8-bit or 9-bit character length
Address detection in 9-bit mode
Input buffer overrun error detection
Received character framing error detection
Half-duplex synchronous master
Half-duplex synchronous slave
Programmable clock polarity in synchronous
modes
• Sleep operation
The Enhanced Universal Synchronous Asynchronous
Receiver Transmitter (EUSART) module is a serial I/O
communications peripheral. It contains all the clock
generators, shift registers and data buffers necessary
to perform an input or output serial data transfer
independent of device program execution. The
EUSART, also known as a Serial Communications
Interface (SCI), can be configured as a full-duplex
asynchronous system or half-duplex synchronous
system.
Full-Duplex
mode
is
useful
for
communications with peripheral systems, such as CRT
terminals and personal computers. Half-Duplex
Synchronous mode is intended for communications
with peripheral devices, such as A/D or D/A integrated
circuits, serial EEPROMs or other microcontrollers.
These devices typically do not have internal clocks for
baud rate generation and require the external clock
signal provided by a master synchronous device.
FIGURE 26-1:
The EUSART module implements the following
additional features, making it ideally suited for use in
Local Interconnect Network (LIN) bus systems:
• Automatic detection and calibration of the baud rate
• Wake-up on Break reception
• 13-bit Break character transmit
Block diagrams of the EUSART transmitter and
receiver are shown in Figure 26-1 and Figure 26-2.
EUSART TRANSMIT BLOCK DIAGRAM
Data Bus
TXIE
Interrupt
TXIF
TXREG Register
8
MSb
TX/CK pin
LSb
(8)
• • •
0
Pin Buffer
and Control
TRMT
SPEN
Transmit Shift Register (TSR)
TXEN
Baud Rate Generator
FOSC
÷n
+1
SPBRGH
TX9
n
BRG16
SPBRGL
Multiplier
x4
x16 x64
SYNC
1 X 0 0
0
BRGH
X 1 1 0
0
BRG16
X 1 0 1
0
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TX9D
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FIGURE 26-2:
EUSART RECEIVE BLOCK DIAGRAM
SPEN
CREN
RX/DT pin
Baud Rate Generator
Data
Recovery
FOSC
BRG16
SPBRGH
SPBRGL
Multiplier
x4
x16 x64
SYNC
1 X 0 0
0
BRGH
X 1 1 0
0
BRG16
X 1 0 1
0
Stop
RCIDL
RSR Register
MSb
Pin Buffer
and Control
+1
OERR
(8)
•••
7
1
LSb
0 START
RX9
÷n
n
FERR
RX9D
RCREG Register
8
FIFO
Data Bus
RCIF
RCIE
Interrupt
The operation of the EUSART module is controlled
through three registers:
• Transmit Status and Control (TXSTA)
• Receive Status and Control (RCSTA)
• Baud Rate Control (BAUDCON)
These registers are detailed in Register 26-1,
Register 26-2 and Register 26-3, respectively.
When the receiver or transmitter section is not enabled
then the corresponding RX or TX pin may be used for
general purpose input and output.
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26.1
EUSART Asynchronous Mode
The EUSART transmits and receives data using the
standard non-return-to-zero (NRZ) format. NRZ is
implemented with two levels: a VOH Mark state which
represents a ‘1’ data bit, and a VOL Space state which
represents a ‘0’ data bit. NRZ refers to the fact that
consecutively transmitted data bits of the same value
stay at the output level of that bit without returning to a
neutral level between each bit transmission. An NRZ
transmission port idles in the mark state. Each character
transmission consists of one Start bit followed by eight
or nine data bits and is always terminated by one or
more Stop bits. The Start bit is always a space and the
Stop bits are always marks. The most common data
format is eight bits. Each transmitted bit persists for a
period of 1/(Baud Rate). An on-chip dedicated
8-bit/16-bit Baud Rate Generator is used to derive
standard baud rate frequencies from the system
oscillator. See Table 26-5 for examples of baud rate
configurations.
The EUSART transmits and receives the LSb first. The
EUSART’s transmitter and receiver are functionally
independent, but share the same data format and baud
rate. Parity is not supported by the hardware, but can
be implemented in software and stored as the ninth
data bit.
26.1.1
EUSART ASYNCHRONOUS
TRANSMITTER
The EUSART transmitter block diagram is shown in
Figure 26-1. The heart of the transmitter is the serial
Transmit Shift Register (TSR), which is not directly
accessible by software. The TSR obtains its data from
the transmit buffer, which is the TXREG register.
26.1.1.1
Enabling the Transmitter
26.1.1.2
Transmitting Data
A transmission is initiated by writing a character to the
TXREG register. If this is the first character, or the
previous character has been completely flushed from
the TSR, the data in the TXREG is immediately
transferred to the TSR register. If the TSR still contains
all or part of a previous character, the new character
data is held in the TXREG until the Stop bit of the
previous character has been transmitted. The pending
character in the TXREG is then transferred to the TSR
in one TCY immediately following the Stop bit
transmission. The transmission of the Start bit, data bits
and Stop bit sequence commences immediately
following the transfer of the data to the TSR from the
TXREG.
26.1.1.3
Transmit Interrupt Flag
The TXIF interrupt flag bit of the PIR1 register is set
whenever the EUSART transmitter is enabled and no
character is being held for transmission in the TXREG.
In other words, the TXIF bit is only clear when the TSR
is busy with a character and a new character has been
queued for transmission in the TXREG. The TXIF flag bit
is not cleared immediately upon writing TXREG. TXIF
becomes valid in the second instruction cycle following
the write execution. Polling TXIF immediately following
the TXREG write will return invalid results. The TXIF bit
is read-only, it cannot be set or cleared by software.
The TXIF interrupt can be enabled by setting the TXIE
interrupt enable bit of the PIE1 register. However, the
TXIF flag bit will be set whenever the TXREG is empty,
regardless of the state of TXIE enable bit.
To use interrupts when transmitting data, set the TXIE
bit only when there is more data to send. Clear the
TXIE interrupt enable bit upon writing the last character
of the transmission to the TXREG.
The EUSART transmitter is enabled for asynchronous
operations by configuring the following three control
bits:
• TXEN = 1
• SYNC = 0
• SPEN = 1
All other EUSART control bits are assumed to be in
their default state.
Setting the TXEN bit of the TXSTA register enables the
transmitter circuitry of the EUSART. Clearing the SYNC
bit of the TXSTA register configures the EUSART for
asynchronous operation. Setting the SPEN bit of the
RCSTA register enables the EUSART and automatically
configures the TX/CK I/O pin as an output. If the TX/CK
pin is shared with an analog peripheral, the analog I/O
function must be disabled by clearing the corresponding
ANSEL bit.
Note 1: The TXIF Transmitter Interrupt flag is set
when the TXEN enable bit is set.
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26.1.1.4
TSR Status
26.1.1.6
The TRMT bit of the TXSTA register indicates the
status of the TSR register. This is a read-only bit. The
TRMT bit is set when the TSR register is empty and is
cleared when a character is transferred to the TSR
register from the TXREG. The TRMT bit remains clear
until all bits have been shifted out of the TSR register.
No interrupt logic is tied to this bit, so the user has to
poll this bit to determine the TSR status.
Note:
26.1.1.5
1.
2.
3.
The TSR register is not mapped in data
memory, so it is not available to the user.
4.
Transmitting 9-bit Characters
The EUSART supports 9-bit character transmissions.
When the TX9 bit of the TXSTA register is set, the
EUSART will shift nine bits out for each character transmitted. The TX9D bit of the TXSTA register is the ninth,
and Most Significant, data bit. When transmitting 9-bit
data, the TX9D data bit must be written before writing
the eight Least Significant bits into the TXREG. All nine
bits of data will be transferred to the TSR shift register
immediately after the TXREG is written.
5.
6.
7.
Asynchronous Transmission Setup:
Initialize the SPBRGH, SPBRGL register pair and
the BRGH and BRG16 bits to achieve the desired
baud rate (see Section 26.3 “EUSART Baud
Rate Generator (BRG)”).
Enable the asynchronous serial port by clearing
the SYNC bit and setting the SPEN bit.
If 9-bit transmission is desired, set the TX9 control bit. A set ninth data bit will indicate that the
eight Least Significant data bits are an address
when the receiver is set for address detection.
Enable the transmission by setting the TXEN
control bit. This will cause the TXIF interrupt bit
to be set.
If interrupts are desired, set the TXIE interrupt
enable bit of the PIE1 register. An interrupt will
occur immediately provided that the GIE and
PEIE bits of the INTCON register are also set.
If 9-bit transmission is selected, the ninth bit
should be loaded into the TX9D data bit.
Load 8-bit data into the TXREG register. This
will start the transmission.
A special 9-bit Address mode is available for use with
multiple receivers. See Section 26.1.2.7 “Address
Detection” for more information on the address mode.
FIGURE 26-3:
Write to TXREG
BRG Output
(Shift Clock)
TX/CK
pin
TXIF bit
(Transmit Buffer
Reg. Empty Flag)
TRMT bit
(Transmit Shift
Reg. Empty Flag)
DS40001657C-page 278
ASYNCHRONOUS TRANSMISSION
Word 1
Start bit
bit 0
bit 1
bit 7/8
Stop bit
Word 1
1 TCY
Word 1
Transmit Shift Reg.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 26-4:
ASYNCHRONOUS TRANSMISSION (BACK-TO-BACK)
Write to TXREG
Word 1
BRG Output
(Shift Clock)
TX/CK
pin
Start bit
bit 1
Word 1
bit 7/8
Stop bit
Start bit
bit 0
Word 2
1 TCY
Word 1
Transmit Shift Reg.
TRMT bit
(Transmit Shift
Reg. Empty Flag)
Word 2
Transmit Shift Reg.
This timing diagram shows two consecutive transmissions.
TABLE 26-1:
Name
bit 0
1 TCY
TXIF bit
(Transmit Buffer
Reg. Empty Flag)
Note:
Word 2
SUMMARY OF REGISTERS ASSOCIATED WITH ASYNCHRONOUS TRANSMISSION
Bit 1
Bit 0
Register on
Page
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
APFCON0
RXDTSEL
SDOSEL
BAUDCON
ABDOVF
RCIDL
SSSEL
—
T1GSEL
TXCKSEL
—
—
113
—
SCKP
BRG16
—
WUE
ABDEN
286
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
285
INTCON
RCSTA
SPBRGL
BRG7
BRG6
BRG5
BRG4
BRG3
BRG2
BRG1
BRG0
287*
SPBRGH
BRG15
BRG14
BRG13
BRG12
BRG11
BRG10
BRG9
BRG8
287*
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
SYNC
SENDB
BRGH
TRMT
TX9D
TXREG
TXSTA
Legend:
*
EUSART Transmit Data Register
CSRC
TX9
TXEN
277*
284
— = unimplemented location, read as ‘0’. Shaded cells are not used for asynchronous transmission.
Page provides register information.
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26.1.2
EUSART ASYNCHRONOUS
RECEIVER
The Asynchronous mode is typically used in RS-232
systems. The receiver block diagram is shown in
Figure 26-2. The data is received on the RX/DT pin and
drives the data recovery block. The data recovery block
is actually a high-speed shifter operating at 16 times
the baud rate, whereas the serial Receive Shift
Register (RSR) operates at the bit rate. When all eight
or nine bits of the character have been shifted in, they
are immediately transferred to a two character
First-In-First-Out (FIFO) memory. The FIFO buffering
allows reception of two complete characters and the
start of a third character before software must start
servicing the EUSART receiver. The FIFO and RSR
registers are not directly accessible by software.
Access to the received data is via the RCREG register.
26.1.2.1
Enabling the Receiver
The EUSART receiver is enabled for asynchronous
operation by configuring the following three control bits:
• CREN = 1
• SYNC = 0
• SPEN = 1
All other EUSART control bits are assumed to be in
their default state.
Setting the CREN bit of the RCSTA register enables the
receiver circuitry of the EUSART. Clearing the SYNC bit
of the TXSTA register configures the EUSART for
asynchronous operation. Setting the SPEN bit of the
RCSTA register enables the EUSART. The programmer
must set the corresponding TRIS bit to configure the
TX/CK I/O pin as an input.
Note 1: If the RX/DT function is on an analog pin,
the corresponding ANSEL bit must be
cleared for the receiver to function.
26.1.2.2
Receiving Data
The receiver data recovery circuit initiates character
reception on the falling edge of the first bit. The first bit,
also known as the Start bit, is always a zero. The data
recovery circuit counts one-half bit time to the center of
the Start bit and verifies that the bit is still a zero. If it is
not a zero then the data recovery circuit aborts
character reception, without generating an error, and
resumes looking for the falling edge of the Start bit. If
the Start bit zero verification succeeds then the data
recovery circuit counts a full bit time to the center of the
next bit. The bit is then sampled by a majority detect
circuit and the resulting ‘0’ or ‘1’ is shifted into the RSR.
This repeats until all data bits have been sampled and
shifted into the RSR. One final bit time is measured and
the level sampled. This is the Stop bit, which is always
a ‘1’. If the data recovery circuit samples a ‘0’ in the
Stop bit position then a framing error is set for this
character, otherwise the framing error is cleared for this
character. See Section 26.1.2.4 “Receive Framing
Error” for more information on framing errors.
Immediately after all data bits and the Stop bit have
been received, the character in the RSR is transferred
to the EUSART receive FIFO and the RCIF interrupt
flag bit of the PIR1 register is set. The top character in
the FIFO is transferred out of the FIFO by reading the
RCREG register.
Note:
26.1.2.3
If the receive FIFO is overrun, no additional
characters will be received until the overrun
condition is cleared. See Section 26.1.2.5
“Receive Overrun Error” for more
information on overrun errors.
Receive Interrupts
The RCIF interrupt flag bit of the PIR1 register is set
whenever the EUSART receiver is enabled and there is
an unread character in the receive FIFO. The RCIF
interrupt flag bit is read-only, it cannot be set or cleared
by software.
RCIF interrupts are enabled by setting all of the
following bits:
• RCIE interrupt enable bit of the PIE1 register
• PEIE peripheral interrupt enable bit of the
INTCON register
• GIE global interrupt enable bit of the INTCON
register
The RCIF interrupt flag bit will be set when there is an
unread character in the FIFO, regardless of the state of
interrupt enable bits.
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26.1.2.4
Receive Framing Error
Each character in the receive FIFO buffer has a
corresponding framing error Status bit. A framing error
indicates that a Stop bit was not seen at the expected
time. The framing error status is accessed via the
FERR bit of the RCSTA register. The FERR bit
represents the status of the top unread character in the
receive FIFO. Therefore, the FERR bit must be read
before reading the RCREG.
The FERR bit is read-only and only applies to the top
unread character in the receive FIFO. A framing error
(FERR = 1) does not preclude reception of additional
characters. It is not necessary to clear the FERR bit.
Reading the next character from the FIFO buffer will
advance the FIFO to the next character and the next
corresponding framing error.
The FERR bit can be forced clear by clearing the SPEN
bit of the RCSTA register which resets the EUSART.
Clearing the CREN bit of the RCSTA register does not
affect the FERR bit. A framing error by itself does not
generate an interrupt.
Note:
26.1.2.5
26.1.2.7
Address Detection
A special Address Detection mode is available for use
when multiple receivers share the same transmission
line, such as in RS-485 systems. Address detection is
enabled by setting the ADDEN bit of the RCSTA
register.
Address detection requires 9-bit character reception.
When address detection is enabled, only characters
with the ninth data bit set will be transferred to the
receive FIFO buffer, thereby setting the RCIF interrupt
bit. All other characters will be ignored.
Upon receiving an address character, user software
determines if the address matches its own. Upon
address match, user software must disable address
detection by clearing the ADDEN bit before the next
Stop bit occurs. When user software detects the end of
the message, determined by the message protocol
used, software places the receiver back into the
Address Detection mode by setting the ADDEN bit.
If all receive characters in the receive
FIFO have framing errors, repeated reads
of the RCREG will not clear the FERR bit.
Receive Overrun Error
The receive FIFO buffer can hold two characters. An
overrun error will be generated if a third character, in its
entirety, is received before the FIFO is accessed. When
this happens the OERR bit of the RCSTA register is set.
The characters already in the FIFO buffer can be read
but no additional characters will be received until the
error is cleared. The error must be cleared by either
clearing the CREN bit of the RCSTA register or by
resetting the EUSART by clearing the SPEN bit of the
RCSTA register.
26.1.2.6
Receiving 9-bit Characters
The EUSART supports 9-bit character reception. When
the RX9 bit of the RCSTA register is set the EUSART
will shift nine bits into the RSR for each character
received. The RX9D bit of the RCSTA register is the
ninth and Most Significant data bit of the top unread
character in the receive FIFO. When reading 9-bit data
from the receive FIFO buffer, the RX9D data bit must
be read before reading the eight Least Significant bits
from the RCREG.
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26.1.2.8
Asynchronous Reception Setup:
26.1.2.9
1.
Initialize the SPBRGH, SPBRGL register pair
and the BRGH and BRG16 bits to achieve the
desired baud rate (see Section 26.3 “EUSART
Baud Rate Generator (BRG)”).
2. Clear the ANSEL bit for the RX pin (if applicable).
3. Enable the serial port by setting the SPEN bit.
The SYNC bit must be clear for asynchronous
operation.
4. If interrupts are desired, set the RCIE bit of the
PIE1 register and the GIE and PEIE bits of the
INTCON register.
5. If 9-bit reception is desired, set the RX9 bit.
6. Enable reception by setting the CREN bit.
7. The RCIF interrupt flag bit will be set when a
character is transferred from the RSR to the
receive buffer. An interrupt will be generated if
the RCIE interrupt enable bit was also set.
8. Read the RCSTA register to get the error flags
and, if 9-bit data reception is enabled, the ninth
data bit.
9. Get the received eight Least Significant data bits
from the receive buffer by reading the RCREG
register.
10. If an overrun occurred, clear the OERR flag by
clearing the CREN receiver enable bit.
FIGURE 26-5:
Rcv Shift
Reg
Rcv Buffer Reg.
RCIDL
This mode would typically be used in RS-485 systems.
To set up an Asynchronous Reception with Address
Detect Enable:
1.
Initialize the SPBRGH, SPBRGL register pair
and the BRGH and BRG16 bits to achieve the
desired baud rate (see Section 26.3 “EUSART
Baud Rate Generator (BRG)”).
2. Clear the ANSEL bit for the RX pin (if applicable).
3. Enable the serial port by setting the SPEN bit.
The SYNC bit must be clear for asynchronous
operation.
4. If interrupts are desired, set the RCIE bit of the
PIE1 register and the GIE and PEIE bits of the
INTCON register.
5. Enable 9-bit reception by setting the RX9 bit.
6. Enable address detection by setting the ADDEN
bit.
7. Enable reception by setting the CREN bit.
8. The RCIF interrupt flag bit will be set when a
character with the ninth bit set is transferred
from the RSR to the receive buffer. An interrupt
will be generated if the RCIE interrupt enable bit
was also set.
9. Read the RCSTA register to get the error flags.
The ninth data bit will always be set.
10. Get the received eight Least Significant data bits
from the receive buffer by reading the RCREG
register. Software determines if this is the
device’s address.
11. If an overrun occurred, clear the OERR flag by
clearing the CREN receiver enable bit.
12. If the device has been addressed, clear the
ADDEN bit to allow all received data into the
receive buffer and generate interrupts.
ASYNCHRONOUS RECEPTION
Start
bit
bit 0
RX/DT pin
9-bit Address Detection Mode Setup
bit 1
bit 7/8 Stop
bit
Start
bit
Word 1
RCREG
bit 0
bit 7/8 Stop
bit
Start
bit
bit 7/8 Stop
bit
Word 2
RCREG
Read Rcv
Buffer Reg.
RCREG
RCIF
(Interrupt Flag)
OERR bit
CREN
Note:
This timing diagram shows three words appearing on the RX input. The RCREG (receive buffer) is read after the third word,
causing the OERR (overrun) bit to be set.
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TABLE 26-2:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH ASYNCHRONOUS RECEPTION
Bit 1
Bit 0
Register
on Page
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
APFCON0
RXDTSEL
SDOSEL
BAUDCON
ABDOVF
RCIDL
SSSEL
—
T1GSEL
TXCKSEL
—
—
113
—
SCKP
BRG16
—
WUE
ABDEN
286
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
INTCON
RCREG
EUSART Receive Data Register
88
280*
RCSTA
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
285
SPBRGL
BRG7
BRG6
BRG5
BRG4
BRG3
BRG2
BRG1
BRG0
287*
SPBRGH
BRG15
BRG14
BRG13
BRG12
BRG11
BRG10
BRG9
BRG8
287*
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISA
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
TXSTA
CSRC
TX9
TXEN
SYNC
SENDB
BRGH
TRMT
TX9D
284
Legend:
*
— = unimplemented location, read as ‘0’. Shaded cells are not used for asynchronous reception.
Page provides register information.
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26.2
Clock Accuracy with
Asynchronous Operation
The factory calibrates the internal oscillator block output (INTOSC). However, the INTOSC frequency may
drift as VDD or temperature changes, and this directly
affects the asynchronous baud rate. Two methods may
be used to adjust the baud rate clock, but both require
a reference clock source of some kind.
REGISTER 26-1:
The first (preferred) method uses the OSCTUNE
register to adjust the INTOSC output. Adjusting the
value in the OSCTUNE register allows for fine resolution
changes to the system clock source. See Section 5.2.2
“Internal Clock Sources” for more information.
The other method adjusts the value in the Baud Rate
Generator. This can be done automatically with the
Auto-Baud Detect feature (see Section 26.3.1
“Auto-Baud Detect”). There may not be fine enough
resolution when adjusting the Baud Rate Generator to
compensate for a gradual change in the peripheral
clock frequency.
TXSTA: TRANSMIT STATUS AND CONTROL REGISTER
R/W-/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R-1/1
R/W-0/0
CSRC
TX9
TXEN(1)
SYNC
SENDB
BRGH
TRMT
TX9D
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
CSRC: Clock Source Select bit
Asynchronous mode:
Don’t care
Synchronous mode:
1 = Master mode (clock generated internally from BRG)
0 = Slave mode (clock from external source)
bit 6
TX9: 9-bit Transmit Enable bit
1 = Selects 9-bit transmission
0 = Selects 8-bit transmission
bit 5
TXEN: Transmit Enable bit(1)
1 = Transmit enabled
0 = Transmit disabled
bit 4
SYNC: EUSART Mode Select bit
1 = Synchronous mode
0 = Asynchronous mode
bit 3
SENDB: Send Break Character bit
Asynchronous mode:
1 = Send Sync Break on next transmission (cleared by hardware upon completion)
0 = Sync Break transmission completed
Synchronous mode:
Don’t care
bit 2
BRGH: High Baud Rate Select bit
Asynchronous mode:
1 = High speed
0 = Low speed
Synchronous mode:
Unused in this mode
bit 1
TRMT: Transmit Shift Register Status bit
1 = TSR empty
0 = TSR full
bit 0
TX9D: Ninth bit of Transmit Data
Can be address/data bit or a parity bit.
Note 1:
SREN/CREN overrides TXEN in Sync mode.
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PIC16LF1824T39A
RCSTA: RECEIVE STATUS AND CONTROL REGISTER(1)
REGISTER 26-2:
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
R-0/0
R-0/0
R-x/x
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
SPEN: Serial Port Enable bit
1 = Serial port enabled (configures RX/DT and TX/CK pins as serial port pins)
0 = Serial port disabled (held in Reset)
bit 6
RX9: 9-bit Receive Enable bit
1 = Selects 9-bit reception
0 = Selects 8-bit reception
bit 5
SREN: Single Receive Enable bit
Asynchronous mode:
Don’t care
Synchronous mode – Master:
1 = Enables single receive
0 = Disables single receive
This bit is cleared after reception is complete.
Synchronous mode – Slave
Don’t care
bit 4
CREN: Continuous Receive Enable bit
Asynchronous mode:
1 = Enables receiver
0 = Disables receiver
Synchronous mode:
1 = Enables continuous receive until enable bit CREN is cleared (CREN overrides SREN)
0 = Disables continuous receive
bit 3
ADDEN: Address Detect Enable bit
Asynchronous mode 9-bit (RX9 = 1):
1 = Enables address detection, enable interrupt and load the receive buffer when RSR is set
0 = Disables address detection, all bytes are received and ninth bit can be used as parity bit
Asynchronous mode 8-bit (RX9 = 0):
Don’t care
bit 2
FERR: Framing Error bit
1 = Framing error (can be updated by reading RCREG register and receive next valid byte)
0 = No framing error
bit 1
OERR: Overrun Error bit
1 = Overrun error (can be cleared by clearing bit CREN)
0 = No overrun error
bit 0
RX9D: Ninth bit of Received Data
This can be address/data bit or a parity bit and must be calculated by user firmware.
2012-2017 Microchip Technology Inc.
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REGISTER 26-3:
BAUDCON: BAUD RATE CONTROL REGISTER
R-0/0
R-1/1
U-0
R/W-0/0
R/W-0/0
U-0
R/W-0/0
R/W-0/0
ABDOVF
RCIDL
—
SCKP
BRG16
—
WUE
ABDEN
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
ABDOVF: Auto-Baud Detect Overflow bit
Asynchronous mode:
1 = Auto-baud timer overflowed
0 = Auto-baud timer did not overflow
Synchronous mode:
Don’t care
bit 6
RCIDL: Receive Idle Flag bit
Asynchronous mode:
1 = Receiver is Idle
0 = Start bit has been received and the receiver is receiving
Synchronous mode:
Don’t care
bit 5
Unimplemented: Read as ‘0’
bit 4
SCKP: Synchronous Clock Polarity Select bit
Asynchronous mode:
1 = Transmit inverted data to the TX/CK pin
0 = Transmit non-inverted data to the TX/CK pin
Synchronous mode:
1 = Data is clocked on rising edge of the clock
0 = Data is clocked on falling edge of the clock
bit 3
BRG16: 16-bit Baud Rate Generator bit
1 = 16-bit Baud Rate Generator is used
0 = 8-bit Baud Rate Generator is used
bit 2
Unimplemented: Read as ‘0’
bit 1
WUE: Wake-up Enable bit
Asynchronous mode:
1 = Receiver is waiting for a falling edge. No character will be received, byte RCIF will be set. WUE
will automatically clear after RCIF is set.
0 = Receiver is operating normally
Synchronous mode:
Don’t care
bit 0
ABDEN: Auto-Baud Detect Enable bit
Asynchronous mode:
1 = Auto-Baud Detect mode is enabled (clears when auto-baud is complete)
0 = Auto-Baud Detect mode is disabled
Synchronous mode:
Don’t care
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PIC16LF1824T39A
26.3
EUSART Baud Rate Generator
(BRG)
The Baud Rate Generator (BRG) is an 8-bit or 16-bit
timer that is dedicated to the support of both the
asynchronous and synchronous EUSART operation.
By default, the BRG operates in 8-bit mode. Setting the
BRG16 bit of the BAUDCON register selects 16-bit
mode.
The SPBRGH, SPBRGL register pair determines the
period of the free running baud rate timer. In
Asynchronous mode the multiplier of the baud rate
period is determined by both the BRGH bit of the TXSTA
register and the BRG16 bit of the BAUDCON register. In
Synchronous mode, the BRGH bit is ignored.
Table 26-3 contains the formulas for determining the
baud rate. Example 26-1 provides a sample calculation
for determining the baud rate and baud rate error.
Typical baud rates and error values for various
asynchronous modes have been computed for your
convenience and are shown in Table 26-3. It may be
advantageous to use the high baud rate (BRGH = 1),
or the 16-bit BRG (BRG16 = 1) to reduce the baud rate
error. The 16-bit BRG mode is used to achieve slow
baud rates for fast oscillator frequencies.
EXAMPLE 26-1:
CALCULATING BAUD
RATE ERROR
For a device with FOSC of 16 MHz, desired baud rate
of 9600, Asynchronous mode, 8-bit BRG:
F OS C
Desired Baud Rate = -----------------------------------------------------------------------64 [SPBRGH:SPBRGL] + 1
Solving for SPBRGH:SPBRGL:
F OS C
-------------------------------------------Desired Baud Rate
X = --------------------------------------------- – 1
64
16000000
-----------------------9600
= ------------------------ – 1
64
= 25.042 = 25
16000000
Calculated Baud Rate = --------------------------64 25 + 1
= 9615
Calc. Baud Rate – Desired Baud Rate
Error = -------------------------------------------------------------------------------------------Desired Baud Rate
9615 – 9600
= ---------------------------------- = 0.16%
9600
Writing a new value to the SPBRGH, SPBRGL register
pair causes the BRG timer to be reset (or cleared). This
ensures that the BRG does not wait for a timer overflow
before outputting the new baud rate.
If the system clock is changed during an active receive
operation, a receive error or data loss may result. To
avoid this problem, check the status of the RCIDL bit to
make sure that the receive operation is Idle before
changing the system clock.
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TABLE 26-3:
BAUD RATE FORMULAS
Configuration Bits
BRG/EUSART Mode
Baud Rate Formula
0
8-bit/Asynchronous
FOSC/[64 (n+1)]
0
1
8-bit/Asynchronous
0
1
0
16-bit/Asynchronous
0
1
1
16-bit/Asynchronous
1
0
x
8-bit/Synchronous
1
1
x
16-bit/Synchronous
SYNC
BRG16
BRGH
0
0
0
FOSC/[16 (n+1)]
FOSC/[4 (n+1)]
Legend: x = Don’t care, n = value of SPBRGH, SPBRGL register pair
TABLE 26-4:
SUMMARY OF REGISTERS ASSOCIATED WITH THE BAUD RATE GENERATOR
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
ABDOVF
RCIDL
—
SCKP
BRG16
—
WUE
ABDEN
286
RCSTA
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
285
SPBRGL
BRG7
BRG6
BRG5
BRG4
BRG3
BRG2
BRG1
BRG0
287*
SPBRGH
BRG15
BRG14
BRG13
BRG12
BRG11
BRG10
BRG9
BRG8
287*
TXSTA
CSRC
TX9
TXEN
SYNC
SENDB
BRGH
TRMT
TX9D
284
Name
BAUDCON
Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used for the Baud Rate Generator.
* Page provides register information.
DS40001657C-page 288
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PIC16LF1824T39A
TABLE 26-5:
BAUD RATES FOR ASYNCHRONOUS MODES
SYNC = 0, BRGH = 0, BRG16 = 0
BAUD
RATE
FOSC = 32.000 MHz
FOSC = 20.000 MHz
FOSC = 18.432 MHz
FOSC = 11.0592 MHz
%
Error
SPBRG
value
(decimal)
Actual
Rate
%
Error
SPBRG
value
(decimal)
—
1200
—
0.00
—
239
—
1200
—
0.00
—
143
%
Error
SPBRG
value
(decimal)
Actual
Rate
—
1.73
—
255
Actual
Rate
%
Error
SPBRG
value
(decimal)
300
1200
—
—
—
—
—
—
—
1221
2400
2404
0.16
207
2404
0.16
129
2400
0.00
119
2400
0.00
71
9600
9615
0.16
51
9470
-1.36
32
9600
0.00
29
9600
0.00
17
10417
10417
0.00
47
10417
0.00
29
10286
-1.26
27
10165
-2.42
16
19.2k
19.23k
0.16
25
19.53k
1.73
15
19.20k
0.00
14
19.20k
0.00
8
57.6k
55.55k
—
-3.55
—
3
—
—
—
—
—
—
—
57.60k
—
0.00
7
—
57.60k
—
0.00
2
—
—
115.2k
Actual
Rate
—
SYNC = 0, BRGH = 0, BRG16 = 0
BAUD
RATE
FOSC = 8.000 MHz
FOSC = 4.000 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 3.6864 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 1.000 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
Actual
Rate
%
Error
SPBRG
value
(decimal)
300
1200
—
1202
—
0.16
—
103
300
1202
0.16
0.16
207
51
300
1200
0.00
191
47
300
1202
0.16
0.16
51
12
2400
2404
0.16
51
2404
0.16
25
2400
0.00
23
—
—
—
0.00
9600
9615
0.16
12
—
—
—
9600
0.00
5
—
—
—
10417
10417
0.00
11
10417
0.00
5
—
—
—
—
—
—
19.2k
—
—
—
—
—
—
19.20k
0.00
2
—
—
—
57.6k
—
—
—
—
—
—
0
—
—
—
115.2k
—
—
—
—
—
—
57.60k
—
0.00
—
—
—
—
—
SYNC = 0, BRGH = 1, BRG16 = 0
BAUD
RATE
FOSC = 32.000 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
FOSC = 20.000 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
FOSC = 18.432 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
FOSC = 11.0592 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
300
—
—
—
—
—
—
—
—
—
—
—
—
1200
—
—
—
—
—
—
—
—
—
—
—
—
2400
—
—
—
—
—
—
—
—
—
—
—
—
9600
9615
0.16
207
9615
0.16
129
9600
0.00
119
9600
0.00
71
10417
10417
0.00
191
10417
0.00
119
10378
-0.37
110
10473
0.53
65
19.2k
19.23k
0.16
103
19.23k
0.16
64
19.20k
0.00
59
19.20k
0.00
35
57.6k
57.14k
-0.79
34
56.82k
-1.36
21
57.60k
0.00
19
57.60k
0.00
11
115.2k
117.64k
2.12
16
113.64k
-1.36
10
115.2k
0.00
9
115.2k
0.00
5
2012-2017 Microchip Technology Inc.
DS40001657C-page 289
PIC16LF1824T39A
TABLE 26-5:
BAUD RATES FOR ASYNCHRONOUS MODES (CONTINUED)
SYNC = 0, BRGH = 1, BRG16 = 0
BAUD
RATE
FOSC = 8.000 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
FOSC = 4.000 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
FOSC = 3.6864 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
FOSC = 1.000 MHz
Actual
Rate
%
Error
SPBRG
value
(decimal)
207
300
—
—
—
—
—
—
—
—
—
300
0.16
1200
—
—
—
1202
0.16
207
1200
0.00
191
1202
0.16
51
2400
2404
0.16
207
2404
0.16
103
2400
0.00
95
2404
0.16
25
—
9600
9615
0.16
51
9615
0.16
25
9600
0.00
23
—
—
10417
10417
0.00
47
10417
0.00
23
10473
0.53
21
10417
0.00
5
19.2k
19231
0.16
25
19.23k
0.16
12
19.2k
0.00
11
—
—
—
57.6k
55556
-3.55
8
—
—
—
57.60k
0.00
3
—
—
—
115.2k
—
—
—
—
—
—
115.2k
0.00
1
—
—
—
SYNC = 0, BRGH = 0, BRG16 = 1
FOSC = 32.000 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 20.000 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 18.432 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 11.0592 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
300
1200
300.0
1200
0.00
-0.02
6666
3332
300.0
1200
-0.01
-0.03
4166
1041
300.0
1200
0.00
0.00
3839
959
300.0
1200
0.00
0.00
2303
575
2400
2401
-0.04
832
2399
-0.03
520
2400
0.00
479
2400
0.00
287
BAUD
RATE
9600
9615
0.16
207
9615
0.16
129
9600
0.00
119
9600
0.00
71
10417
10417
0.00
191
10417
0.00
119
10378
-0.37
110
10473
0.53
65
19.2k
19.23k
0.16
103
19.23k
0.16
64
19.20k
0.00
59
19.20k
0.00
35
57.6k
57.14k
-0.79
34
56.818
-1.36
21
57.60k
0.00
19
57.60k
0.00
11
115.2k
117.6k
2.12
16
113.636
-1.36
10
115.2k
0.00
9
115.2k
0.00
5
SYNC = 0, BRGH = 0, BRG16 = 1
BAUD
RATE
FOSC = 8.000 MHz
Actual
Rate
FOSC = 4.000 MHz
%
Error
SPBRG
value
(decimal)
Actual
Rate
FOSC = 3.6864 MHz
%
Error
SPBRG
value
(decimal)
Actual
Rate
FOSC = 1.000 MHz
%
Error
SPBRG
value
(decimal)
Actual
Rate
%
Error
SPBRG
value
(decimal)
300
299.9
-0.02
1666
300.1
0.04
832
300.0
0.00
767
300.5
0.16
207
1200
1199
-0.08
416
1202
0.16
207
1200
0.00
191
1202
0.16
51
2400
2404
0.16
207
2404
0.16
103
2400
0.00
95
2404
0.16
25
9600
9615
0.16
51
9615
0.16
25
9600
0.00
23
—
—
—
10417
10417
0.00
47
10417
0.00
23
10473
0.53
21
10417
0.00
5
19.2k
19.23k
0.16
25
19.23k
0.16
12
19.20k
0.00
11
—
—
—
57.6k
55556
-3.55
8
—
—
—
57.60k
0.00
3
—
—
—
115.2k
—
—
—
—
—
—
115.2k
0.00
1
—
—
—
DS40001657C-page 290
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 26-5:
BAUD RATES FOR ASYNCHRONOUS MODES (CONTINUED)
SYNC = 0, BRGH = 1, BRG16 = 1 or SYNC = 1, BRG16 = 1
BAUD
RATE
FOSC = 32.000 MHz
Actual
Rate
FOSC = 20.000 MHz
%
Error
SPBRG
value
(decimal)
Actual
Rate
FOSC = 18.432 MHz
%
Error
SPBRG
value
(decimal)
Actual
Rate
FOSC = 11.0592 MHz
%
Error
SPBRG
value
(decimal)
Actual
Rate
%
Error
SPBRG
value
(decimal)
300
300.0
0.00
26666
300.0
0.00
16665
300.0
0.00
15359
300.0
0.00
9215
1200
1200
0.00
6666
1200
-0.01
4166
1200
0.00
3839
1200
0.00
2303
2400
2400
0.01
3332
2400
0.02
2082
2400
0.00
1919
2400
0.00
1151
9600
9604
0.04
832
9597
-0.03
520
9600
0.00
479
9600
0.00
287
10417
10417
0.00
767
10417
0.00
479
10425
0.08
441
10433
0.16
264
19.2k
19.18k
-0.08
416
19.23k
0.16
259
19.20k
0.00
239
19.20k
0.00
143
57.6k
57.55k
-0.08
138
57.47k
-0.22
86
57.60k
0.00
79
57.60k
0.00
47
115.2k
115.9k
0.64
68
116.3k
0.94
42
115.2k
0.00
39
115.2k
0.00
23
SYNC = 0, BRGH = 1, BRG16 = 1 or SYNC = 1, BRG16 = 1
FOSC = 8.000 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 4.000 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 3.6864 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
FOSC = 1.000 MHz
SPBRG
Actual
%
value
Rate
Error
(decimal)
300
1200
300.0
1200
0.00
-0.02
6666
1666
300.0
1200
0.01
0.04
3332
832
300.0
1200
0.00
0.00
3071
767
300.1
1202
0.04
0.16
832
207
2400
2401
0.04
832
2398
0.08
416
2400
0.00
383
2404
0.16
103
BAUD
RATE
9600
9615
0.16
207
9615
0.16
103
9600
0.00
95
9615
0.16
25
10417
10417
0
191
10417
0.00
95
10473
0.53
87
10417
0.00
23
19.2k
19.23k
0.16
103
19.23k
0.16
51
19.20k
0.00
47
19.23k
0.16
12
57.6k
57.14k
-0.79
34
58.82k
2.12
16
57.60k
0.00
15
—
—
—
115.2k
117.6k
2.12
16
111.1k
-3.55
8
115.2k
0.00
7
—
—
—
2012-2017 Microchip Technology Inc.
DS40001657C-page 291
PIC16LF1824T39A
26.3.1
AUTO-BAUD DETECT
The EUSART module supports automatic detection
and calibration of the baud rate.
and SPBRGL registers are clocked at 1/8th the BRG
base clock rate. The resulting byte measurement is the
average bit time when clocked at full speed.
Note 1: If the WUE bit is set with the ABDEN bit,
auto-baud detection will occur on the byte
following the Break character (see
Section 26.3.3 “Auto-Wake-up on
Break”).
In the Auto-Baud Detect (ABD) mode, the clock to the
BRG is reversed. Rather than the BRG clocking the
incoming RX signal, the RX signal is timing the BRG.
The Baud Rate Generator is used to time the period of
a received 55h (ASCII “U”) which is the Sync character
for the LIN bus. The unique feature of this character is
that it has five rising edges including the Stop bit edge.
Setting the ABDEN bit of the BAUDCON register starts
the auto-baud calibration sequence (Figure 26-6).
While the ABD sequence takes place, the EUSART
state machine is held in Idle. On the first rising edge of
the receive line, after the Start bit, the SPBRG begins
counting up using the BRG counter clock as shown in
Table 26-6. The fifth rising edge will occur on the RX pin
at the end of the eighth bit period. At that time, an
accumulated value totaling the proper BRG period is
left in the SPBRGH, SPBRGL register pair, the ABDEN
bit is automatically cleared and the RCIF interrupt flag
is set. The value in the RCREG needs to be read to
clear the RCIF interrupt. RCREG content should be
discarded. When calibrating for modes that do not use
the SPBRGH register the user can verify that the
SPBRGL register did not overflow by checking for 00h
in the SPBRGH register.
2: It is up to the user to determine that the
incoming character baud rate is within the
range of the selected BRG clock source.
Some combinations of oscillator frequency
and EUSART baud rates are not possible.
3: During the auto-baud process, the
auto-baud counter starts counting at 1.
Upon completion of the auto-baud
sequence, to achieve maximum accuracy,
subtract 1 from the SPBRGH:SPBRGL
register pair.
TABLE 26-6:
The BRG auto-baud clock is determined by the BRG16
and BRGH bits as shown in Table 26-6. During ABD,
both the SPBRGH and SPBRGL registers are used as
a 16-bit counter, independent of the BRG16 bit setting.
While calibrating the baud rate period, the SPBRGH
FIGURE 26-6:
BRG16
BRGH
BRG Base
Clock
BRG ABD
Clock
0
0
FOSC/64
FOSC/512
0
1
FOSC/16
FOSC/128
1
0
FOSC/16
FOSC/128
1
1
FOSC/4
FOSC/32
Note:
During the ABD sequence, SPBRGL and
SPBRGH registers are both used as a 16-bit
counter, independent of BRG16 setting.
AUTOMATIC BAUD RATE CALIBRATION
XXXXh
BRG Value
BRG COUNTER CLOCK RATES
RX pin
0000h
001Ch
Start
Edge #1
bit 1
bit 0
Edge #2
bit 3
bit 2
Edge #3
bit 5
bit 4
Edge #4
bit 7
bit 6
Edge #5
Stop bit
BRG Clock
Auto Cleared
Set by User
ABDEN bit
RCIDL
RCIF bit
(Interrupt)
Read
RCREG
SPBRGL
XXh
1Ch
SPBRGH
XXh
00h
Note 1:
The ABD sequence requires the EUSART module to be configured in Asynchronous mode.
DS40001657C-page 292
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
26.3.2
AUTO-BAUD OVERFLOW
During the course of automatic baud detection, the
ABDOVF bit of the BAUDCON register will be set if the
baud rate counter overflows before the fifth rising edge
is detected on the RX pin. The ABDOVF bit indicates
that the counter has exceeded the maximum count that
can fit in the 16 bits of the SPBRGH:SPBRGL register
pair. After the ABDOVF has been set, the counter continues to count until the fifth rising edge is detected on
the RX pin. Upon detecting the fifth RX edge, the hardware will set the RCIF interrupt flag and clear the
ABDEN bit of the BAUDCON register. The RCIF flag
can be subsequently cleared by reading the RCREG
register. The ABDOVF flag of the BAUDCON register
can be cleared by software directly.
To terminate the auto-baud process before the RCIF
flag is set, clear the ABDEN bit then clear the ABDOVF
bit of the BAUDCON register. The ABDOVF bit will
remain set if the ABDEN bit is not cleared first.
26.3.3
AUTO-WAKE-UP ON BREAK
During Sleep mode, all clocks to the EUSART are
suspended. Because of this, the Baud Rate Generator
is inactive and a proper character reception cannot be
performed. The Auto-Wake-up feature allows the
controller to wake-up due to activity on the RX/DT line.
This feature is available only in Asynchronous mode.
The Auto-Wake-up feature is enabled by setting the
WUE bit of the BAUDCON register. Once set, the normal
receive sequence on RX/DT is disabled, and the
EUSART remains in an Idle state, monitoring for a
wake-up event independent of the CPU mode. A
wake-up event consists of a high-to-low transition on the
RX/DT line. (This coincides with the start of a Sync Break
or a wake-up signal character for the LIN protocol.)
The EUSART module generates an RCIF interrupt
coincident with the wake-up event. The interrupt is
generated synchronously to the Q clocks in normal CPU
operating modes (Figure 26-7), and asynchronously if
the device is in Sleep mode (Figure 26-8). The interrupt
condition is cleared by reading the RCREG register.
26.3.3.1
Special Considerations
Break Character
To avoid character errors or character fragments during
a wake-up event, the wake-up character must be all
zeros.
When the wake-up is enabled the function works
independent of the low time on the data stream. If the
WUE bit is set and a valid non-zero character is
received, the low time from the Start bit to the first rising
edge will be interpreted as the wake-up event. The
remaining bits in the character will be received as a
fragmented character and subsequent characters can
result in framing or overrun errors.
Therefore, the initial character in the transmission must
be all ‘0’s. This must be ten or more bit times, 13-bit
times recommended for LIN bus, or any number of bit
times for standard RS-232 devices.
Oscillator Startup Time
Oscillator start-up time must be considered, especially
in applications using oscillators with longer start-up
intervals (i.e., LP, XT or HS/PLL mode). The Sync
Break (or wake-up signal) character must be of
sufficient length, and be followed by a sufficient
interval, to allow enough time for the selected oscillator
to start and provide proper initialization of the EUSART.
WUE Bit
The wake-up event causes a receive interrupt by
setting the RCIF bit. The WUE bit is cleared in
hardware by a rising edge on RX/DT. The interrupt
condition is then cleared in software by reading the
RCREG register and discarding its contents.
To ensure that no actual data is lost, check the RCIDL
bit to verify that a receive operation is not in process
before setting the WUE bit. If a receive operation is not
occurring, the WUE bit may then be set just prior to
entering the Sleep mode.
The WUE bit is automatically cleared by the low-to-high
transition on the RX line at the end of the Break. This
signals to the user that the Break event is over. At this
point, the EUSART module is in Idle mode waiting to
receive the next character.
2012-2017 Microchip Technology Inc.
DS40001657C-page 293
PIC16LF1824T39A
FIGURE 26-7:
AUTO-WAKE-UP BIT (WUE) TIMING DURING NORMAL OPERATION
Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4
OSC1
Auto Cleared
Bit set by user
WUE bit
RX/DT Line
RCIF
Note 1:
Cleared due to User Read of RCREG
The EUSART remains in Idle while the WUE bit is set.
FIGURE 26-8:
AUTO-WAKE-UP BIT (WUE) TIMINGS DURING SLEEP
Q1Q2 Q3 Q4 Q1Q2 Q3 Q4 Q1 Q2 Q3 Q4
Q1
Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1Q2 Q3 Q4
OSC1
Auto Cleared
Bit Set by User
WUE bit
RX/DT Line
Note 1
RCIF
Sleep Command Executed
Note 1:
2:
Sleep Ends
Cleared due to User Read of RCREG
If the wake-up event requires long oscillator warm-up time, the automatic clearing of the WUE bit can occur while the stposc signal is
still active. This sequence should not depend on the presence of Q clocks.
The EUSART remains in Idle while the WUE bit is set.
DS40001657C-page 294
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
26.3.4
BREAK CHARACTER SEQUENCE
The EUSART module has the capability of sending the
special Break character sequences that are required by
the LIN bus standard. A Break character consists of a
Start bit, followed by 12 ‘0’ bits and a Stop bit.
To send a Break character, set the SENDB and TXEN
bits of the TXSTA register. The Break character transmission is then initiated by a write to the TXREG. The
value of data written to TXREG will be ignored and all
‘0’s will be transmitted.
The SENDB bit is automatically reset by hardware after
the corresponding Stop bit is sent. This allows the user
to preload the transmit FIFO with the next transmit byte
following the Break character (typically, the Sync
character in the LIN specification).
The TRMT bit of the TXSTA register indicates when the
transmit operation is active or Idle, just as it does during
normal transmission. See Figure 26-9 for the timing of
the Break character sequence.
26.3.4.1
Break and Sync Transmit Sequence
The following sequence will start a message frame
header made up of a Break, followed by an auto-baud
Sync byte. This sequence is typical of a LIN bus
master.
1.
2.
3.
4.
5.
26.3.5
RECEIVING A BREAK CHARACTER
The Enhanced EUSART module can receive a Break
character in two ways.
The first method to detect a Break character uses the
FERR bit of the RCSTA register and the Received data
as indicated by RCREG. The Baud Rate Generator is
assumed to have been initialized to the expected baud
rate.
A Break character has been received when;
• RCIF bit is set
• FERR bit is set
• RCREG = 00h
The second method uses the Auto-Wake-up feature
described in Section 26.3.3 “Auto-Wake-up on
Break”. By enabling this feature, the EUSART will
sample the next two transitions on RX/DT, cause an
RCIF interrupt, and receive the next data byte followed
by another interrupt.
Note that following a Break character, the user will
typically want to enable the Auto-Baud Detect feature.
For both methods, the user can set the ABDEN bit of
the BAUDCON register before placing the EUSART in
Sleep mode.
Configure the EUSART for the desired mode.
Set the TXEN and SENDB bits to enable the
Break sequence.
Load the TXREG with a dummy character to
initiate transmission (the value is ignored).
Write ‘55h’ to TXREG to load the Sync character
into the transmit FIFO buffer.
After the Break has been sent, the SENDB bit is
reset by hardware and the Sync character is
then transmitted.
When the TXREG becomes empty, as indicated by the
TXIF, the next data byte can be written to TXREG.
FIGURE 26-9:
Write to TXREG
SEND BREAK CHARACTER SEQUENCE
Dummy Write
BRG Output
(Shift Clock)
TX (pin)
Start bit
bit 0
bit 1
bit 11
Stop bit
Break
TXIF bit
(Transmit
Interrupt Flag)
TRMT bit
(Transmit Shift
Empty Flag)
SENDB
(send Break
control bit)
2012-2017 Microchip Technology Inc.
SENDB Sampled Here
Auto Cleared
DS40001657C-page 295
PIC16LF1824T39A
26.4
EUSART Synchronous Mode
Synchronous serial communications are typically used
in systems with a single master and one or more
slaves. The master device contains the necessary
circuitry for baud rate generation and supplies the clock
for all devices in the system. Slave devices can take
advantage of the master clock by eliminating the
internal clock generation circuitry.
There are two signal lines in Synchronous mode: a
bidirectional data line and a clock line. Slaves use the
external clock supplied by the master to shift the serial
data into and out of their respective receive and transmit shift registers. Since the data line is bidirectional,
synchronous operation is half-duplex only. Half-duplex
refers to the fact that master and slave devices can
receive and transmit data but not both simultaneously.
The EUSART can operate as either a master or slave
device.
Start and Stop bits are not used in synchronous
transmissions.
26.4.1
SYNCHRONOUS MASTER MODE
The following bits are used to configure the EUSART
for Synchronous Master operation:
•
•
•
•
•
SYNC = 1
CSRC = 1
SREN = 0 (for transmit); SREN = 1 (for receive)
CREN = 0 (for transmit); CREN = 1 (for receive)
SPEN = 1
Setting the SYNC bit of the TXSTA register configures
the device for synchronous operation. Setting the CSRC
bit of the TXSTA register configures the device as a
master. Clearing the SREN and CREN bits of the RCSTA
register ensures that the device is in the Transmit mode,
otherwise the device will be configured to receive. Setting
the SPEN bit of the RCSTA register enables the
EUSART.
26.4.1.1
Master Clock
Synchronous data transfers use a separate clock line,
which is synchronous with the data. A device configured as a master transmits the clock on the TX/CK line.
The TX/CK pin output driver is automatically enabled
when the EUSART is configured for synchronous
transmit or receive operation. Serial data bits change
on the leading edge to ensure they are valid at the
trailing edge of each clock. One clock cycle is generated for each data bit. Only as many clock cycles are
generated as there are data bits.
DS40001657C-page 296
26.4.1.2
Clock Polarity
A clock polarity option is provided for Microwire
compatibility. Clock polarity is selected with the SCKP
bit of the BAUDCON register. Setting the SCKP bit sets
the clock Idle state as high. When the SCKP bit is set,
the data changes on the falling edge of each clock.
Clearing the SCKP bit sets the Idle state as low. When
the SCKP bit is cleared, the data changes on the rising
edge of each clock.
26.4.1.3
Synchronous Master Transmission
Data is transferred out of the device on the RX/DT pin.
The RX/DT and TX/CK pin output drivers are automatically enabled when the EUSART is configured for
synchronous master transmit operation.
A transmission is initiated by writing a character to the
TXREG register. If the TSR still contains all or part of a
previous character the new character data is held in the
TXREG until the last bit of the previous character has
been transmitted. If this is the first character, or the
previous character has been completely flushed from
the TSR, the data in the TXREG is immediately transferred to the TSR. The transmission of the character
commences immediately following the transfer of the
data to the TSR from the TXREG.
Each data bit changes on the leading edge of the
master clock and remains valid until the subsequent
leading clock edge.
Note:
The TSR register is not mapped in data
memory, so it is not available to the user.
26.4.1.4
Synchronous Master Transmission
Setup:
1.
2.
3.
4.
5.
6.
7.
8.
Initialize the SPBRGH, SPBRGL register pair
and the BRGH and BRG16 bits to achieve the
desired baud rate (see Section 26.3 “EUSART
Baud Rate Generator (BRG)”).
Enable the synchronous master serial port by
setting bits SYNC, SPEN and CSRC.
Disable Receive mode by clearing bits SREN
and CREN.
Enable Transmit mode by setting the TXEN bit.
If 9-bit transmission is desired, set the TX9 bit.
If interrupts are desired, set the TXIE bit of the
PIE1 register and the GIE and PEIE bits of the
INTCON register.
If 9-bit transmission is selected, the ninth bit
should be loaded in the TX9D bit.
Start transmission by loading data to the TXREG
register.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 26-10:
SYNCHRONOUS TRANSMISSION
RX/DT
pin
bit 0
bit 1
Word 1
bit 2
bit 7
bit 0
bit 1
Word 2
bit 7
TX/CK pin
(SCKP = 0)
TX/CK pin
(SCKP = 1)
Write to
TXREG Reg
Write Word 1
Write Word 2
TXIF bit
(Interrupt Flag)
TRMT bit
‘1’
TXEN bit
Note:
‘1’
Sync Master mode, SPBRGL = 0, continuous transmission of two 8-bit words.
FIGURE 26-11:
SYNCHRONOUS TRANSMISSION (THROUGH TXEN)
RX/DT pin
bit 0
bit 2
bit 1
bit 6
bit 7
TX/CK pin
Write to
TXREG reg
TXIF bit
TRMT bit
TXEN bit
TABLE 26-7:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS MASTER
TRANSMISSION
Bit 7
Bit 6
Bit 5
APFCON0
RXDTSEL
SDOSEL
BAUDCON
ABDOVF
RCIDL
GIE
PIE1
PIR1
INTCON
Bit 0
Register on
Page
—
—
113
WUE
ABDEN
286
Bit 4
Bit 3
Bit 2
Bit 1
SSSEL
—
T1GSEL
TXCKSEL
—
SCKP
BRG16
—
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
88
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
RCSTA
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
285
SPBRGL
BRG7
BRG6
BRG5
BRG4
BRG3
BRG2
BRG1
BRG0
287*
SPBRGH
BRG15
BRG14
BRG13
BRG12
BRG11
BRG10
BRG9
BRG8
287*
BRGH
TRMT
TX9D
TXREG
EUSART Transmit Data Register
TXSTA
CSRC
Legend:
*
TX9
TXEN
SYNC
SENDB
277*
284
— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous master transmission.
Page provides register information.
2012-2017 Microchip Technology Inc.
DS40001657C-page 297
PIC16LF1824T39A
26.4.1.5
Synchronous Master Reception
Data is received at the RX/DT pin. The RX/DT pin
output driver is automatically disabled when the
EUSART is configured for synchronous master receive
operation.
In Synchronous mode, reception is enabled by setting
either the Single Receive Enable bit (SREN of the
RCSTA register) or the Continuous Receive Enable bit
(CREN of the RCSTA register).
When SREN is set and CREN is clear, only as many
clock cycles are generated as there are data bits in a
single character. The SREN bit is automatically cleared
at the completion of one character. When CREN is set,
clocks are continuously generated until CREN is
cleared. If CREN is cleared in the middle of a character
the CK clock stops immediately and the partial character is discarded. If SREN and CREN are both set, then
SREN is cleared at the completion of the first character
and CREN takes precedence.
To initiate reception, set either SREN or CREN. Data is
sampled at the RX/DT pin on the trailing edge of the
TX/CK clock pin and is shifted into the Receive Shift
Register (RSR). When a complete character is
received into the RSR, the RCIF bit is set and the character is automatically transferred to the two character
receive FIFO. The Least Significant eight bits of the top
character in the receive FIFO are available in RCREG.
The RCIF bit remains set as long as there are unread
characters in the receive FIFO.
Note:
26.4.1.6
If the RX/DT function is on an analog pin,
the corresponding ANSEL bit must be
cleared for the receiver to function.
Slave Clock
Synchronous data transfers use a separate clock line,
which is synchronous with the data. A device configured
as a slave receives the clock on the TX/CK line. The
TX/CK pin output driver is automatically disabled when
the device is configured for synchronous slave transmit
or receive operation. Serial data bits change on the
leading edge to ensure they are valid at the trailing edge
of each clock. One data bit is transferred for each clock
cycle. Only as many clock cycles should be received as
there are data bits.
Note:
If the device is configured as a slave and
the TX/CK function is on an analog pin, the
corresponding ANSEL bit must be
cleared.
DS40001657C-page 298
26.4.1.7
Receive Overrun Error
The receive FIFO buffer can hold two characters. An
overrun error will be generated if a third character, in its
entirety, is received before RCREG is read to access
the FIFO. When this happens the OERR bit of the
RCSTA register is set. Previous data in the FIFO will
not be overwritten. The two characters in the FIFO
buffer can be read, however, no additional characters
will be received until the error is cleared. The OERR bit
can only be cleared by clearing the overrun condition.
If the overrun error occurred when the SREN bit is set
and CREN is clear then the error is cleared by reading
RCREG. If the overrun occurred when the CREN bit is
set then the error condition is cleared by either clearing
the CREN bit of the RCSTA register or by clearing the
SPEN bit which resets the EUSART.
26.4.1.8
Receiving 9-bit Characters
The EUSART supports 9-bit character reception. When
the RX9 bit of the RCSTA register is set the EUSART
will shift 9-bits into the RSR for each character
received. The RX9D bit of the RCSTA register is the
ninth, and Most Significant, data bit of the top unread
character in the receive FIFO. When reading 9-bit data
from the receive FIFO buffer, the RX9D data bit must
be read before reading the eight Least Significant bits
from the RCREG.
26.4.1.9
Synchronous Master Reception
Setup:
1.
Initialize the SPBRGH, SPBRGL register pair for
the appropriate baud rate. Set or clear the
BRGH and BRG16 bits, as required, to achieve
the desired baud rate.
2. Clear the ANSEL bit for the RX pin (if applicable).
3. Enable the synchronous master serial port by
setting bits SYNC, SPEN and CSRC.
4. Ensure bits CREN and SREN are clear.
5. If interrupts are desired, set the RCIE bit of the
PIE1 register and the GIE and PEIE bits of the
INTCON register.
6. If 9-bit reception is desired, set bit RX9.
7. Start reception by setting the SREN bit or for
continuous reception, set the CREN bit.
8. Interrupt flag bit RCIF will be set when reception
of a character is complete. An interrupt will be
generated if the enable bit RCIE was set.
9. Read the RCSTA register to get the ninth bit (if
enabled) and determine if any error occurred
during reception.
10. Read the 8-bit received data by reading the
RCREG register.
11. If an overrun error occurs, clear the error by
either clearing the CREN bit of the RCSTA
register or by clearing the SPEN bit which resets
the EUSART.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 26-12:
SYNCHRONOUS RECEPTION (MASTER MODE, SREN)
RX/DT
pin
bit 0
bit 1
bit 2
bit 3
bit 4
bit 5
bit 6
bit 7
TX/CK pin
(SCKP = 0)
TX/CK pin
(SCKP = 1)
Write to
bit SREN
SREN bit
CREN bit ‘0’
‘0’
RCIF bit
(Interrupt)
Read
RCREG
Note:
Timing diagram demonstrates Sync Master mode with bit SREN = 1 and bit BRGH = 0.
TABLE 26-8:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS MASTER
RECEPTION
Bit 7
Bit 6
Bit 5
APFCON0
RXDTSEL
SDOSEL
BAUDCON
ABDOVF
RCIDL
Bit 1
Bit 0
Register
on Page
Bit 4
Bit 3
Bit 2
SSSEL
—
T1GSEL
TXCKSEL
—
—
113
—
SCKP
BRG16
—
WUE
ABDEN
286
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
RCSTA
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
285
SPBRGL
BRG7
BRG6
BRG5
BRG4
BRG3
BRG2
BRG1
BRG0
287*
SPBRGH
BRG15
BRG14
BRG13
BRG12
BRG11
BRG10
BRG9
BRG8
287*
TXSTA
CSRC
TX9
TXEN
SYNC
SENDB
BRGH
TRMT
TX9D
284
INTCON
RCREG
Legend:
*
EUSART Receive Data Register
280*
— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous master reception.
Page provides register information.
2012-2017 Microchip Technology Inc.
DS40001657C-page 299
PIC16LF1824T39A
26.4.2
SYNCHRONOUS SLAVE MODE
The following bits are used to configure the EUSART
for Synchronous slave operation:
•
•
•
•
•
SYNC = 1
CSRC = 0
SREN = 0 (for transmit); SREN = 1 (for receive)
CREN = 0 (for transmit); CREN = 1 (for receive)
SPEN = 1
1.
2.
3.
4.
Setting the SYNC bit of the TXSTA register configures the
device for synchronous operation. Clearing the CSRC bit
of the TXSTA register configures the device as a slave.
Clearing the SREN and CREN bits of the RCSTA register
ensures that the device is in the Transmit mode,
otherwise the device will be configured to receive. Setting
the SPEN bit of the RCSTA register enables the
EUSART.
26.4.2.1
If two words are written to the TXREG and then the
SLEEP instruction is executed, the following will occur:
EUSART Synchronous Slave
Transmit
5.
26.4.2.2
1.
The operation of the Synchronous Master and Slave
modes
are
identical
(see
Section 26.4.1.3
“Synchronous Master Transmission”), except in the
case of the Sleep mode.
2.
3.
4.
5.
6.
7.
8.
TABLE 26-9:
The first character will immediately transfer to
the TSR register and transmit.
The second word will remain in the TXREG
register.
The TXIF bit will not be set.
After the first character has been shifted out of
TSR, the TXREG register will transfer the second
character to the TSR and the TXIF bit will now be
set.
If the PEIE and TXIE bits are set, the interrupt
will wake the device from Sleep and execute the
next instruction. If the GIE bit is also set, the
program will call the Interrupt Service Routine.
Synchronous Slave Transmission
Setup:
Set the SYNC and SPEN bits and clear the
CSRC bit.
Clear the ANSEL bit for the CK pin (if applicable).
Clear the CREN and SREN bits.
If interrupts are desired, set the TXIE bit of the
PIE1 register and the GIE and PEIE bits of the
INTCON register.
If 9-bit transmission is desired, set the TX9 bit.
Enable transmission by setting the TXEN bit.
If 9-bit transmission is selected, insert the Most
Significant bit into the TX9D bit.
Start transmission by writing the Least
Significant 8 bits to the TXREG register.
SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS SLAVE
TRANSMISSION
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
APFCON0
RXDTSEL
SDOSEL
SSSEL
—
T1GSEL
TXCKSEL
—
—
113
BAUDCON
ABDOVF
RCIDL
—
SCKP
BRG16
—
WUE
ABDEN
286
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
Name
INTCON
RCSTA
TXREG
TXSTA
Legend:
*
EUSART Transmit Data Register
CSRC
TX9
TXEN
SYNC
SENDB
BRGH
285
277*
TRMT
TX9D
284
— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous slave transmission.
Page provides register information.
DS40001657C-page 300
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
26.4.2.3
EUSART Synchronous Slave
Reception
26.4.2.4
The operation of the Synchronous Master and Slave
modes is identical (Section 26.4.1.5 “Synchronous
Master Reception”), with the following exceptions:
• Sleep
• CREN bit is always set, therefore the receiver is
never Idle
• SREN bit, which is a “don’t care” in Slave mode
1.
2.
3.
A character may be received while in Sleep mode by
setting the CREN bit prior to entering Sleep. Once the
word is received, the RSR register will transfer the data
to the RCREG register. If the RCIE enable bit is set, the
interrupt generated will wake the device from Sleep
and execute the next instruction. If the GIE bit is also
set, the program will branch to the interrupt vector.
4.
5.
6.
7.
8.
9.
Synchronous Slave Reception
Setup:
Set the SYNC and SPEN bits and clear the
CSRC bit.
Clear the ANSEL bit for both the CK and DT pins
(if applicable).
If interrupts are desired, set the RCIE bit of the
PIE1 register and the GIE and PEIE bits of the
INTCON register.
If 9-bit reception is desired, set the RX9 bit.
Set the CREN bit to enable reception.
The RCIF bit will be set when reception is
complete. An interrupt will be generated if the
RCIE bit was set.
If 9-bit mode is enabled, retrieve the Most
Significant bit from the RX9D bit of the RCSTA
register.
Retrieve the eight Least Significant bits from the
receive FIFO by reading the RCREG register.
If an overrun error occurs, clear the error by
either clearing the CREN bit of the RCSTA
register or by clearing the SPEN bit which resets
the EUSART.
TABLE 26-10: SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS SLAVE
RECEPTION
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Register
on Page
APFCON0
RXDTSEL
SDOSEL
SSSEL
—
T1GSEL
TXCKSEL
—
—
113
BAUDCON
ABDOVF
RCIDL
—
SCKP
BRG16
—
WUE
ABDEN
286
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
PIE1
TMR1GIE
ADIE
RCIE
TXIE
SSP1IE
CCP1IE
TMR2IE
TMR1IE
85
PIR1
TMR1GIF
ADIF
RCIF
TXIF
SSP1IF
CCP1IF
TMR2IF
TMR1IF
88
SPEN
RX9
SREN
CREN
ADDEN
FERR
OERR
RX9D
285
CSRC
TX9
TXEN
SYNC
SENDB
BRGH
TRMT
TX9D
284
Name
INTCON
RCREG
RCSTA
TXSTA
Legend:
*
EUSART Receive Data Register
280*
— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous slave reception.
Page provides register information.
2012-2017 Microchip Technology Inc.
DS40001657C-page 301
PIC16LF1824T39A
26.5
EUSART Operation During Sleep
The EUSART will remain active during Sleep only in the
Synchronous Slave mode. All other modes require the
system clock and therefore cannot generate the
necessary signals to run the Transmit or Receive Shift
registers during Sleep.
Synchronous Slave mode uses an externally generated
clock to run the Transmit and Receive Shift registers.
26.5.1
SYNCHRONOUS RECEIVE DURING
SLEEP
To receive during Sleep, all the following conditions
must be met before entering Sleep mode:
• RCSTA and TXSTA Control registers must be
configured for Synchronous Slave Reception (see
Section 26.4.2.4 “Synchronous Slave
Reception Setup:”).
• If interrupts are desired, set the RCIE bit of the
PIE1 register and the GIE and PEIE bits of the
INTCON register.
• The RCIF interrupt flag must be cleared by reading RCREG to unload any pending characters in
the receive buffer.
Upon entering Sleep mode, the device will be ready to
accept data and clocks on the RX/DT and TX/CK pins,
respectively. When the data word has been completely
clocked in by the external device, the RCIF interrupt
flag bit of the PIR1 register will be set. Thereby, waking
the processor from Sleep.
Upon waking from Sleep, the instruction following the
SLEEP instruction will be executed. If the Global Interrupt Enable (GIE) bit of the INTCON register is also set,
then the Interrupt Service Routine at address 004h will
be called.
DS40001657C-page 302
26.5.2
SYNCHRONOUS TRANSMIT
DURING SLEEP
To transmit during Sleep, all the following conditions
must be met before entering Sleep mode:
• RCSTA and TXSTA Control registers must be
configured for Synchronous Slave Transmission
(see Section 26.4.2.2 “Synchronous Slave
Transmission Setup:”).
• The TXIF interrupt flag must be cleared by writing
the output data to the TXREG, thereby filling the
TSR and transmit buffer.
• If interrupts are desired, set the TXIE bit of the
PIE1 register and the PEIE bit of the INTCON
register.
• Interrupt enable bits TXIE of the PIE1 register and
PEIE of the INTCON register must set.
Upon entering Sleep mode, the device will be ready to
accept clocks on the TX/CK pin and transmit data on
the RX/DT pin. When the data word in the TSR has
been completely clocked out by the external device, the
pending byte in the TXREG will transfer to the TSR and
the TXIF flag will be set. Thereby, waking the processor
from Sleep. At this point, the TXREG is available to
accept another character for transmission, which will
clear the TXIF flag.
Upon waking from Sleep, the instruction following the
SLEEP instruction will be executed. If the Global
Interrupt Enable (GIE) bit is also set then the Interrupt
Service Routine at address 0004h will be called.
26.5.3
ALTERNATE PIN LOCATIONS
This module incorporates I/O pins that can be moved to
other locations with the use of the alternate pin function
registers, APFCON0 and APFCON1. To determine
which pins can be moved and what their default
locations are upon a Reset, see Section 12.1
“Alternate Pin Function” for more information.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
27.0
CAPACITIVE SENSING (CPS)
MODULE
The Capacitive Sensing (CPS) module allows for an
interaction with an end user without a mechanical
interface. In a typical application, the CPS module is
attached to a pad on a Printed Circuit Board (PCB),
which is electrically isolated from the end user. When the
end user places their finger over the PCB pad, a
capacitive load is added, causing a frequency shift in the
capacitive sensing module. The CPS module requires
software and at least one timer resource to determine
the change in frequency. Key features of this module
include:
•
•
•
•
•
•
•
Analog MUX for monitoring multiple inputs
Capacitive sensing oscillator
Multiple current ranges
Multiple voltage reference modes
Multiple timer resources
Software control
Operation during Sleep
FIGURE 27-1:
CAPACITIVE SENSING BLOCK DIAGRAM
Timer0 Module
FOSC/4
T0CKI
CPSCH
CPSON(2)
Set
TMR0IF
TMR0CS
T0XCS
0
1
0
TMR0
Overflow
1
CPSRNG
CPSON
CPS0
Capacitive
Sensing
Oscillator
CPS1
CPSOSC
Timer1 Module
T1CS
CPS2
CPS3
CPS4
CPS5
CPS6
CPS7
Ref-
Int.
Ref.
0
1
CPSCLK
FOSC
FOSC/4
T1OSC/
T1CKI
DAC
Output 0
Ref+
1 FVR
EN
TMR1H:TMR1L
T1GSEL
T1G
CPSOUT
SYNCC1OUT
SYNCC2OUT
Timer1 Gate
Control Logic
CPSRM
Note
1:
If CPSON = 0, disabling capacitive sensing, no channel is selected.
2012-2017 Microchip Technology Inc.
DS40001657C-page 303
PIC16LF1824T39A
FIGURE 27-2:
CAPACITIVE SENSING OSCILLATOR BLOCK DIAGRAM
Oscillator Module
VDD
(1)
+
(2)
-
S
CPSx
(1)
Analog Pin
-
Q
CPSCLK
R
(2)
+
Internal
References
Ref-
0
0
1
Ref+
DAC
1
FVR
CPSRM
Note 1:
2:
Module Enable and Power mode selections are not shown.
Comparators remain active in Noise Detection mode.
DS40001657C-page 304
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
27.1
Analog MUX
The capacitive sensing module can monitor up to four
inputs for the PIC16LF1824T39A (CPSCH). See
Register 27-2 for details. The capacitive sensing inputs
are defined as CPS, as applicable to device. To
determine if a frequency change has occurred the user
must:
• Select the appropriate CPS pin by setting the
appropriate CPSCH bits of the CPSCON1 register
• Set the corresponding ANSEL bit
• Set the corresponding TRIS bit
• Run the software algorithm
Selection of the CPSx pin while the module is enabled
will cause the capacitive sensing oscillator to be on the
CPSx pin. Failure to set the corresponding ANSEL and
TRIS bits can cause the capacitive sensing oscillator to
stop, leading to false frequency readings.
27.2
Capacitive Sensing Oscillator
27.3
Voltage Reference Modes
The capacitive sensing oscillator uses voltage references to provide two voltage thresholds for oscillation.
The upper voltage threshold is referred to as Ref+ and
the lower voltage threshold is referred to as Ref-.
The user can elect to use Fixed Voltage References,
which are internal to the capacitive sensing oscillator,
or variable voltage references, which are supplied by
the Fixed Voltage Reference (FVR) module and the
Digital-to-Analog Converter (DAC) module.
When the Fixed Voltage References are used, the VSS
voltage determines the lower threshold level (Ref-) and
the VDD voltage determines the upper threshold level
(Ref+).
When the variable voltage references are used, the
DAC voltage determines the lower threshold level
(Ref-) and the FVR voltage determines the upper
threshold level (Ref+). An advantage of using these reference sources is that oscillation frequency remains
constant with changes in VDD.
The capacitive sensing oscillator consists of a constant
current source and a constant current sink, to produce
a triangle waveform. The CPSOUT bit of the
CPSCON0 register shows the status of the capacitive
sensing oscillator, whether it is a sinking or sourcing
current. The oscillator is designed to drive a capacitive
load (single PCB pad) and at the same time, be a clock
source to either Timer0 or Timer1. The oscillator has
three different current settings as defined by CPSRNG of the CPSCON0 register. The different current settings for the oscillator serve two purposes:
Different oscillation frequencies can be obtained
through the use of these variable voltage references.
The more the upper voltage reference level is lowered
and the more the lower voltage reference level is
raised, the higher the capacitive sensing oscillator
frequency becomes.
• Maximize the number of counts in a timer for a
fixed time base.
• Maximize the count differential in the timer during
a change in frequency.
Please see Section 14.0 “Fixed Voltage Reference
(FVR)” and Section 17.0 “Digital-to-Analog Converter
(DAC) Module” for more information on configuring the
variable voltage levels.
2012-2017 Microchip Technology Inc.
Selection between the voltage references is controlled
by the CPSRM bit of the CPSCON0 register. Setting
this bit selects the variable voltage references and
clearing this bit selects the Fixed Voltage References.
DS40001657C-page 305
PIC16LF1824T39A
27.4
Current Ranges
The Noise Detection mode is unique in that it disables
the constant current source associated with the
selected input pin, but leaves the rest of the oscillator
circuitry and pin structure active. This eliminates the
oscillation frequency on the analog pin and greatly
reduces the current consumed by the oscillator
module. When noise is introduced onto the pin, the
oscillator is driven at the frequency determined by the
noise. This produces a detectable signal at the
comparator stage, indicating the presence of activity
on the pin. Figure 27-2 shows a more detailed drawing
of the constant current sources and comparators
associated with the oscillator and input pin.
The Capacitive Sensing Oscillator can operate within
several different current ranges, depending on the
voltage reference mode and current range selections.
Within each of the two voltage reference modes there
are four current ranges.
Selection between the voltage reference modes is
controlled by the CPSRM bit of the CPSCON0
register. Clearing this bit selects the fixed voltage
references provided by the capacitive sensing
oscillator module. Setting this bit selects the variable
voltage references supplied by the Fixed Voltage
Reference (FVR) module and the Digital-to-Analog
Converter (DAC) module. See Section 27.3 “Voltage
Reference Modes” for more information on
configuring the voltage references. Selecting the
current range within the voltage reference mode is
controlled by configuring the CPSRNG bits in the
CPSCON0 register. See Table 27-1 for proper current
mode selection.
TABLE 27-1:
CURRENT MODE SELECTION
CPSRM
0
1
Note 1:
Voltage Reference
Mode
Fixed
Variable
CPSRNG
Current Range
Nominal Current(1)
00
Off
0.0 A
01
Low
0.1 A
10
Medium
1.2 A
11
High
18 A
00
Noise Detection
0.0 A
01
Low
9 A
10
Medium
30 A
11
High
100 A
See Section 31.0 “Electrical Specifications” for more information.
DS40001657C-page 306
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PIC16LF1824T39A
27.5
Timer Resources
27.7
To measure the change in frequency of the capacitive
sensing oscillator, a fixed time base is required. For the
period of the fixed time base, the capacitive sensing
oscillator is used to clock either Timer0 or Timer1. The
frequency of the capacitive sensing oscillator is equal
to the number of counts in the timer divided by the
period of the fixed time base.
27.6
Fixed Time Base
To measure the frequency of the capacitive sensing
oscillator, a fixed time base is required. Any timer
resource or software loop can be used to establish the
fixed time base. It is up to the end user to determine the
method in which the fixed time base is generated.
Note:
27.6.1
The fixed time base cannot be generated
by the timer resource that the capacitive
sensing oscillator is clocking.
TIMER0
To select Timer0 as the timer resource for the capacitive
sensing module:
• Set the T0XCS bit of the CPSCON0 register
• Clear the TMR0CS bit of the OPTION_REG
register
Software Control
The software portion of the capacitive sensing module
is required to determine the change in frequency of the
capacitive sensing oscillator. This is accomplished by
the following:
• Setting a fixed time base to acquire counts on
Timer0 or Timer1
• Establishing the nominal frequency for the
capacitive sensing oscillator
• Establishing the reduced frequency for the
capacitive sensing oscillator due to an additional
capacitive load
• Set the frequency threshold
27.7.1
NOMINAL FREQUENCY
(NO CAPACITIVE LOAD)
To determine the nominal frequency of the capacitive
sensing oscillator:
• Remove any extra capacitive load on the selected
CPSx pin
• At the start of the fixed time base, clear the timer
resource
• At the end of the fixed time base save the value in
the timer resource
When Timer0 is chosen as the timer resource, the
capacitive sensing oscillator will be the clock source for
Timer0. Refer to Section 20.0 “Timer0 Module” for
additional information.
The value of the timer resource is the number of
oscillations of the capacitive sensing oscillator for the
given time base. The frequency of the capacitive
sensing oscillator is equal to the number of counts on
in the timer divided by the period of the fixed time base.
27.6.2
27.7.2
TIMER1
To select Timer1 as the timer resource for the
capacitive sensing module, set the TMR1CS of
the T1CON register to ‘11’. When Timer1 is chosen as
the timer resource, the capacitive sensing oscillator will
be the clock source for Timer1. Because the Timer1
module has a gate control, developing a time base for
the frequency measurement can be simplified by using
the Timer0 overflow flag.
It is recommend that the Timer0 overflow flag, in conjunction with the Toggle mode of the Timer1 Gate, be
used to develop the fixed time base required by the
software portion of the capacitive sensing module.
Refer to Section 20.1.2 “8-bit Counter Mode” for
additional information.
TABLE 27-2:
TIMER1 ENABLE FUNCTION
TMR1ON
TMR1GE
Timer1 Operation
0
0
Off
0
1
Off
1
0
On
1
1
Count Enabled by input
2012-2017 Microchip Technology Inc.
REDUCED FREQUENCY
(ADDITIONAL CAPACITIVE LOAD)
The extra capacitive load will cause the frequency of the
capacitive sensing oscillator to decrease. To determine
the reduced frequency of the capacitive sensing
oscillator:
• Add a typical capacitive load on the selected
CPSx pin
• Use the same fixed time base as the nominal
frequency measurement
• At the start of the fixed time base, clear the timer
resource
• At the end of the fixed time base save the value in
the timer resource
The value of the timer resource is the number of
oscillations of the capacitive sensing oscillator with an
additional capacitive load. The frequency of the capacitive sensing oscillator is equal to the number of counts
on in the timer divided by the period of the fixed time
base. This frequency should be less than the value
obtained during the nominal frequency measurement.
DS40001657C-page 307
PIC16LF1824T39A
27.7.3
FREQUENCY THRESHOLD
The frequency threshold should be placed midway
between the value of nominal frequency and the
reduced frequency of the capacitive sensing oscillator.
Refer to Application Note AN1103, “Software Handling
for Capacitive Sensing” (DS01103) for more detailed
information on the software required for capacitive
sensing module.
Note:
For more information on general capacitive
sensing refer to Application Notes:
27.8
Operation during Sleep
The capacitive sensing oscillator will continue to run as
long as the module is enabled, independent of the part
being in Sleep. In order for the software to determine if
a frequency change has occurred, the part must be
awake. However, the part does not have to be awake
when the timer resource is acquiring counts.
Note:
Timer0 does not operate when in Sleep,
and therefore cannot be used for
capacitive sense measurements in Sleep.
• AN1101, “Introduction to Capacitive
Sensing” (DS01101)
• AN1102, “Layout and Physical
Design Guidelines for Capacitive
Sensing” (DS01102)
DS40001657C-page 308
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PIC16LF1824T39A
REGISTER 27-1:
CPSCON0: CAPACITIVE SENSING CONTROL REGISTER 0
R/W-0/0
R/W-0/0
U-0
U-0
CPSON
CPSRM
—
—
R/W-0/0
R/W-0/0
CPSRNG
R-0/0
R/W-0/0
CPSOUT
T0XCS
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7
CPSON: Capacitive Sensing Module Enable bit
1 = CPS module is enabled
0 = CPS module is disabled
bit 6
CPSRM: Capacitive Sensing Reference Mode bit
1 = Capacitive Sensing module is in Variable Voltage Reference mode
0 = Capacitive Sensing module is in Fixed Voltage Reference mode
bit 5-4
Unimplemented: Read as ‘0’
bit 3-2
CPSRNG: Capacitive Sensing Current Range bits
If CPSRM = 0 (Fixed Voltage Reference mode):
00 = Oscillator is off
01 = Oscillator is in low range
10 = Oscillator is in medium range
11 = Oscillator is in high range
If CPSRM = 1 (Variable Voltage Reference mode):
00 = Oscillator is on. Noise Detection mode. No Charge/Discharge current is supplied.
01 = Oscillator is in low range
10 = Oscillator is in medium range
11 = Oscillator is in high range
bit 1
CPSOUT: Capacitive Sensing Oscillator Status bit
1 = Oscillator is sourcing current (Current flowing out of the pin)
0 = Oscillator is sinking current (Current flowing into the pin)
bit 0
T0XCS: Timer0 External Clock Source Select bit
If TMR0CS = 1:
The T0XCS bit controls which clock external to the core/Timer0 module supplies Timer0:
1 = Timer0 clock source is the capacitive sensing oscillator
0 = Timer0 clock source is the T0CKI pin
If TMR0CS = 0:
Timer0 clock source is controlled by the core/Timer0 module and is FOSC/4
2012-2017 Microchip Technology Inc.
DS40001657C-page 309
PIC16LF1824T39A
REGISTER 27-2:
CPSCON1: CAPACITIVE SENSING CONTROL REGISTER 1
U-0
U-0
U-0
U-0
—
—
—
—
R/W-0/0
R/W-0/0
R/W-0/0
R/W-0/0
CPSCH
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
u = Bit is unchanged
x = Bit is unknown
-n/n = Value at POR and BOR/Value at all other Resets
‘1’ = Bit is set
‘0’ = Bit is cleared
bit 7-4
Unimplemented: Read as ‘0’
bit 3-0
CPSCH: Capacitive Sensing Channel Select bits
If CPSON = 0:
These bits are ignored. No channel is selected.
If CPSON = 1:
0000 = channel 0, (CPS0)
0001 = channel 1, (CPS1)
0010 = channel 2, (CPS2)
0011 = channel 3, (CPS3)
0100 = channel 4, (CPS4)
0101 = channel 5, (CPS5)
0110 = channel 6, (CPS6)
0111 = channel 7, (CPS7)
1100 = Reserved. Do not use.
•
•
•
1111 = Reserved. Do not use.
TABLE 27-3:
Name
SUMMARY OF REGISTERS ASSOCIATED WITH CAPACITIVE SENSING
Bit 6
Bit 5
Bit 4
ANSELA
—
—
—
ANSA4
—
ANSA2
ANSA1
ANSA0
118
ANSELC
—
—
—
—
ANSC3
ANSC2
ANSC1
ANSC0
124
CPSCON0
CPSON
CPSRM
—
—
CPSOUT
T0XCS
309
CPSCON1
—
—
—
—
INLVLA
—
—
INLVLA5
INLVLA4
INLVLA3
INLVLA2
INLVLA1
INLVLA0
119
INLVLC
—
—
INLVLC5
INLVLC4
INLVLC3
INLVLC2
INLVLC1
INLVLC0
125
INTCON
OPTION_REG
Bit 3
Bit 2
CPSRNG
Bit 1
Bit 0
Register
on Page
Bit 7
CPSCH
310
GIE
PEIE
TMR0IE
INTE
IOCIE
TMR0IF
INTF
IOCIF
84
WPUEN
INTEDG
TMR0CS
TMR0SE
PSA
PS2
PS1
PS0
165
T1CON
TMR1CS1
TMR1CS0
T1CKPS1
T1CKPS0
T1OSCEN
T1SYNC
—
TMR1ON
175
TRISA
—
—
TRISA5
TRISA4
TRISA3
TRISA2
TRISA1
TRISA0
117
TRISC
—
—
TRISC5
TRISC4
TRISC3
TRISC2
TRISC1
TRISC0
123
Legend: — = Unimplemented locations, read as ‘0’. Shaded cells are not used by the capacitive sensing module.
DS40001657C-page 310
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PIC16LF1824T39A
28.0
RF TRANSMITTER
The RF transmitter is an ultra low-power, integrated
multi-band Sub-GHz transmitter. It is capable of
operating in the 310, 433, 868, and 915 MHz
license-free frequency bands using Frequency Shift
Keying (FSK) or On-Off Keying (OOK) modulation of an
input data stream.
28.1
Circuit Description
The RF transmitter block diagram is shown in
Figure 28-1 and the I/O pin definitions are shown in
Table 28-1.
FIGURE 28-1:
RF TRANSMITTER BLOCK DIAGRAM
DATA
PA
CP
RFOUT
VDDRF
VSSRF
PFD
XTAL
M/N
Sigma/
Delta
CTRL
2012-2017 Microchip Technology Inc.
Control Logic
DS40001657C-page 311
PIC16LF1824T39A
TABLE 28-1:
RF TRANSMITTER PIN DESCRIPTION
Name
Function
Input Type
Output Type
Description
VDDRF
VDDRF
Power
—
RF Power Supply
CTRL
CTRL
CMOS
—
Configuration Selection and Configuration Clock
RFOUT
RFOUT
—
RF
Transmitter RF output
VSSRF
VSSRF
Power
—
RF Power Supply
DATA
DATA
CMOS
CMOS
XTAL
XTAL
XTAL
—
Configuration Data and Transmit Data
Crystal Oscillator
FIGURE 28-2:
Note: The RF transmitter pins are independent
from the microcontroller pins.
The RF transmitter contains of a sigma-delta
fractional-N Phase-Locked Loop (PLL) frequency
synthesizer. Frequency Shift Keying (FSK) modulation
is made inside the PLL bandwidth. On-Off Keying
(OOK) modulation is made by turning on and off the
Power Amplifier (PA).
The reference frequency is generated by an internal
crystal oscillator. An external quartz crystal resonator is
connected to the XTAL pin and Ground (VSSRF). The
choice of crystal frequency depends on the frequency
band of choice.
The RF transmitter can deliver 0 dBm or +10 dBm into
a 50Ω load via the RFOUT pin. An external matching
network is required for each power setting and
frequency band for the best efficiency to the antenna.
28.2
Configuring the RF Transmitter
The CTRL and DATA pins are used to configure the RF
transmitter for transmit frequency, output power, modulation, FSK frequency deviation, and Sleep time. Once
configured, the DATA pin is used to encode transmit
data.
28.2.1
POWER-ON RESET (POR)
At power-on, the CTRL pin is sampled as shown in
Figure 28-2 and depending on the CTRL pin logic level,
the RF transmitter will enter one of two Power-on Reset
(POR) values as shown in Table 28-3 and Table 28-4.
To continue using the RF transmitter with these POR
values, maintain the CTRL pin stable and at the powered-on logic level. With the DATA pin at logic ‘0’, the
RF transmitter will enter Sleep mode.
MODE SELECTION
TIMING DIAGRAM
tSTART
VDDRF
CTRL
CTRL pin Sampled
If the POR settings are satisfactory for the application,
a microcontroller output pin can be freed by placing a
weak pull-up or pull-down resistor on the CTRL pin.
Only the DATA pin needs to be connected to an I/O pin.
28.2.2
RF TRANSMITTER REGISTERS
RF transmitter has three registers: Application,
Frequency, and Status. These are used to write and
read configuration parameters related to transmit
frequency, output power, modulation, FSK frequency
deviation, and Sleep time. A summary of register
values are shown in Table 28-2. A detailed explanation
of Application register is shown in Table 28-3,
Frequency register values in Table 28-4, and STATUS
register in Table 28-5.
To access the registers, the DATA line is sampled at
each low-to-high transition on the CTRL pin. A total of
24 transitions are required on the CTRL pin to successfully write or read a value in the registers. Register write
and read operations are shown in Figure 28-3.
Writing and reading the RF transmitter registers should
be done when the device is in Sleep mode. See
Section 28.2.4 “Sleep Mode”.
Note: It is recommended that a weak pull-up or
pull-down resistor be placed on the CTRL
pin to ensure the desired preset mode is
selected at power-on.
DS40001657C-page 312
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PIC16LF1824T39A
In the event that spurious activity (for example MCU
interrupt or Reset) or less than 24 clock cycles on the
CTRL pin, a special sequence over the CTRL and
FIGURE 28-3:
DATA pins can be used to recover serial
communications with the RF transmitter. The recover
sequence is shown in Figure 28-4.
REGISTER WRITE AND READ OPERATIONS
CTRL
DATA
23
22
21
20
19
18
17
16
15
...
3
2
1
0
Write Operation
DATA pin transition
from read to write
DATA pin transition
from write to read
CTRL
DATA
23
22
21
20
19
18
17
16
15
...
3
Write
2
1
0
Read
Read Operation
Note 1:
2:
Refer to Section TABLE 31-7: “RF Transmitter Electrical Specifications”.
Exactly 24 clock cycles are required for proper configuration.
FIGURE 28-4:
RECOVERY SEQUENCE TIMING
t1 t0
CTRL
DATA
23
22
21
2012-2017 Microchip Technology Inc.
20
19
18
17
16
15
...
3
2
1
0
DS40001657C-page 313
PIC16LF1824T39A
TABLE 28-2:
RF TRANSMITTER REGISTER SUMMARY
23 22
21 20 19 18 17 16 15 14 13
0
0
0
0
0
0
0
0
DA
Write
0
0
1
1
0
0
1
1
DA
Read
0
0
0
1
1
0
1
0
0
0
1
0
0
0
1
0
1
0
1
0
1
TABLE 28-3:
Bit
DA15
12 11
10
9 8
7 6 5
4
3
2
1
0
DF
Write
DF
DV
Instruction
Read
DS
DF
Read
Name
Value
Setting
Mode
0
Automatic
1
Manual
0
FSK
Modulation
DA13
Band
Power-on Reset
CTRL = 0 CTRL = 1
0
0
Refer to Section 28.2.5 “Manual
Transmit Mode”.
0
1
Refer to Section 28.3 “Modulation Selection”.
1
0
Refer to Section 28.4 “Frequency Selection and Configuration”.
OOK
0
310 - 450 MHz
1
860 - 870 MHz
902 - 928 MHz
Frequency
Deviation (fDEV)
—
—
—
0x06(1)
DA4
Output Power
0
0 dBm
1
1
—
1
10 dBm
DA3
Transmitter Off
Time (tOFFT)
0
2 ms
1
0
—
1
20 ms
Reserved
100(2)
—
100
100
—
Note 1:
2:
DF
Note 1:
FSK mode only. Refer to
Section 28.4.3 “Frequency Calculation”.
Actual frequency deviation value dependant on crystal frequency.
When writing to the Application register, DA must be 0b100.
TABLE 28-4:
Bit
STATUS
register (see
Table 28-5)
Notes
1
DA
Frequency
register (see
Table 28-4)
APPLICATION REGISTER
DA14
DA
Application
register (see
Table 28-3)
FREQUENCY REGISTER
Name
Transmit
Frequency
(fTX)
Value
Setting
—
—
Power-on Reset
CTRL = 0
0x42C1C(1)
CTRL = 1
Notes
0x42CAD(1) Refer to Section 28.4 “Frequency
Selection and Configuration”. When
reading frequency, the Most Significant
three bits are read from the STATUS
register (see Table 28-5)
Actual frequency value dependant on crystal frequency.
DS40001657C-page 314
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PIC16LF1824T39A
28.2.3
DATA TRANSMISSION
TABLE 28-5:
STATUS REGISTER
Bit
Name
Value
Setting
Power-on Reset
CTRL = 0 CTRL = 1
DV
Chip Version
0x11
—
0x11
0x11
DS
Reserved
—
—
—
—
DS1
TX Ready
0
Sleep
—
—
1
Transmitting
—
—
DS0
Reserved
—
—
—
—
DF
Transmit Frequency (fTX)
—
—
0b100
0b100
Notes
0x11 = Version A1
—
Refer to Section 28.4
“Frequency Selection and Configuration”. When reading
frequency, the Most
Significant three bits
are read from the
STATUS register (see
Table 28-5)
RF data is transmitted when the DATA pin is at a logic
‘1’ for greater than tWAKE, as shown in Figure 28-5. The
CTRL pin must remain stable (either logic ‘0’ or ‘1’). If
the modulation mode is OOK, the transmitted signal is
turned on and off by the DATA pin. If the modulation
mode is FSK, the transmitted signal is frequency
shifted by the DATA pin. The encoding of the transmitted signal is determined by the length of time the DATA
pin is held logic ‘0’ or ‘1’.
2012-2017 Microchip Technology Inc.
DS40001657C-page 315
PIC16LF1824T39A
28.2.4
SLEEP MODE
The RF transmitter will automatically enter Sleep mode
when the DATA pin is a logic ‘0’ for greater than tOFFT,
as shown in Figure 28-5. tOFFT can be configured for 2
or 20 ms in the Application register (see Table 28-3).
FIGURE 28-5:
DATA PIN TRANSMIT TIMING DIAGRAM
tWAKE
tOFFT
DATA
CTRL(1)
RFOUT (OOK)
RFOUT (FSK)
Sleep
Wake
Sleep
Note 1: The CTRL pin must remain stable (logic ‘0’ or ‘1’).
DS40001657C-page 316
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PIC16LF1824T39A
28.2.5
MANUAL TRANSMIT MODE
The RF transmitter can continuously transmit by setting
the mode bit (DA15) to a logic ‘1’ in the Applications
register (see Table 28-3). It will continuously transmit
RF data presented on the DATA pin without
automatically entering Sleep mode. To cease
transmission the Mode bit must be cleared (DA15 =
‘0’). Figure 28-6 shows the Manual Transmit mode
timing.
FIGURE 28-6:
MANUAL TRANSMIT MODE TIMING
DA15 = 1
DA15 = 0
CTRL
DATA
tWAKE
tRAMP
RFOUT (OOK)
RFOUT (FSK)
28.3
28.3.1
Sleep
Wake
Modulation Selection
28.3.3
ON-OFF KEYING (OOK)
OOK modulation can be configured by setting the
modulation DA14 bit in the Application register
(Table 28-3). Data is transmitted as stated in
Section 28.2.3 “Data Transmission”.
28.3.2
FREQUENCY SHIFT KEYING (FSK)
Sleep
DIGITAL TRANSMISSION SYSTEM
(DTS)
In the United States and Canada, digital modulation
techniques are permitted (FCC Part 15.247 and
RSS-210, respectively). The RF transmitter can be
configured for DTS mode by selecting FSK and fDEV =
200 kHz. Data encoding techniques, such as data
whitening, may be needed to ensure that the minimum
6 dB bandwidth is at least 500 kHz.
FSK modulation can be configured by clearing the
Modulation DA14 bit in the Application register.
Frequency Deviation (fDEV) is configured by setting the
DA bits in the Application register. Data is
transmitted as stated in Section 28.2.3 “Data Transmission”.
2012-2017 Microchip Technology Inc.
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PIC16LF1824T39A
28.4
Frequency Selection and
Configuration
28.4.1
The Band bit, DA13, in the Application register
configures the RF transmitter for a range of frequencies
for a given crystal frequency, as shown in Table 28-6.
The RF transmitter is capable of generating many of
the popular RF frequencies that are permitted within
the Radio Regulations of the country the finished
product will be sold. The RF frequency configuration is
performed by determining which frequency band,
selecting the crystal frequency, and setting the
frequency value in the Frequency register DF. If
FSK modulation is used, the frequency deviation is set
in the Application register DA. See
Section 28.2.2 “RF Transmitter Registers” for
information on Configuration register settings.
TABLE 28-6:
BAND SELECTION
FREQUENCY BAND SELECTION
Band Setting DA
Frequency Band (fRF)
Crystal Frequency (fXTAL)
0
310 - 450 MHz
22 MHz
312 - 450 MHz
24 MHz
338 - 450 MHz
26 MHz
863 - 870 MHz
1
22 MHz
902 - 924 MHz
28.4.2
863 - 870 MHz
24 MHz
902 - 928 MHz
26 MHz
CRYSTAL SELECTION
Once the frequency band has been selected, the
choice of crystal frequency is flexible provided the
crystal meets the specifications summarized in
Table 28-7. The boundaries of the Frequency register
DF are followed as shown in Figure 28-7, and
RF transmit frequency error is acceptable (see
Section 28.4.3 “Frequency Calculation”).
TABLE 28-7:
CRYSTAL RESONATOR SPECIFICATIONS
Symbol
Min.
Typ.
Max.
Unit
Crystal Frequency
22
—
26
MHz
CL
Load Capacitance
—
15
—
pF
ESR
Equivalent Series Resistance
—
—
100
Ohms
FXTAL
Description
The crystal frequency tolerance and frequency stability
over the operating temperature range depends on the
system frequency budget. Typically, the receiver crystal
frequency tolerance, stability, and receiver bandwidth
will have the greatest influence. For OOK modulation,
the transmitted RF signal (fRF) should remain inside the
receiver bandwidth, otherwise signal degradation will
occur. For FSK modulation, fRF should remain inside
the receiver bandwidth and within 0.5 * fDEV.
As a general practice, do not choose a RF transmit
signal (fRF) with an integer or near integer multiple of
fXTAL. This will result in higher noise and spurious
emissions.
DS40001657C-page 318
28.4.3
FREQUENCY CALCULATION
Once the frequency band and crystal frequency are
selected, the RF transmit signal (fRF) is calculated by
setting the Frequency register DF(18:0) bits according
to the formula shown in Figure 28-7. If the calculated
value for DF(18:0) is not an integer, there will be an
associated transmit frequency error. Ensure that this
error is within the acceptable system frequency budget.
Similarly, the frequency deviation is calculated as
shown in Figure 28-7.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 28-7:
FREQUENCY CALCULATION
Band 0
DF(18:0) =
Band 1
fRF * 16384
fXTAL
212992 < DF(18:0) < 344064
Note: Check fRF frequency
error by calculating fRF with
integer value of DF(18:0).
DA(12:5) =
fDEV * 16384
fXTAL
DF(18:0) =
fRF * 8192
fXTAL
212992 < DF(18:0) < 344064
Note: Check fRF frequency
error by calculating fRF with
integer value of DF(18:0).
DA(12:5) =
fDEV * 8192
fXTAL
10 kHz d fDEV d 200 kHz
10 kHz d fDEV d 200 kHz
Note: Check fDEV frequency
error by calculating fDEV with
integer value of DA(12:5).
Note: Check fDEV frequency
error by calculating fDEV with
integer value of DA(12:5).
fRF and fXTAL values in the range shown in Table 9-6
2012-2017 Microchip Technology Inc.
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PIC16LF1824T39A
28.5
Applications
28.5.1
SOFTWARE INITIALIZATION
EXAMPLE 28-1:
SAMPLE INITIALIZATION CODE
#define APP_REG_PREFIX 0
#define FREQ_REG_PREFIX 0x18
void sendTxCommand(unsigned char cmd)
{
// The ‘T39A samples data on the rising edge of clock. Clock is idle low.
unsigned char i;
for (i=0; i 8;
unsigned char app_low = (T39A_APP_CONFIG & 0x0000FF);
unsigned char f_upper = (T39A_FREQ_CONFIG & 0x70000) >> 16;
unsigned char f_high = (T39A_FREQ_CONFIG & 0x0FF00) >> 8;
unsigned char f_low
= (T39A_FREQ_CONFIG & 0x000FF);
sendTxCommand(APP_REG_PREFIX);
sendTxCommand(app_high);
sendTxCommand(app_low);
sendTxCommand(FREQ_REG_PREFIX | f_upper);
sendTxCommand(f_high);
sendTxCommand(f_low);
return;
}
28.5.2
APPLICATION CIRCUIT
Figure 28-8 describes a sample four-button remote
transmitter application schematic. Table 28-8 contains
its bill of materials. This schematic and bill of materials
is a design suggestion only. Actual component values
will be dependent on implementation parameters.
DS40001657C-page 320
2012-2017 Microchip Technology Inc.
APPLICATION SCHEMATIC
VCC
L2
L4
C3
RFOUT
VCC
GND
1
2
TP6
3
TP7
MCLR_SW3 4
5
TP3
6
TP4
7
VCC TP5
8
CTRL 9
C6 RFOUT 10
VDD
RA5
RA4
MCLR/VPP/RA3
RC5
RC4
RC3
VDDRF
CTRL
RFOUT
VSS
RA0/ICSPDAT
RAI/ICSPCLK
RA2
RC0
RC1
RC2
XTAL
DATA
VSSRF
20
19
18
17
16
15
14
13
12
11
PGD_SW0
PGC_SW1
SW2
LED
DATA
CTRL
XTAL
DATA
0.1UF
GND
TP2
GND
GND
TP1
L5
C5
C2
L3
C1
U1
PIC16LF1824T39A-X_SS
GND
120nH
GND
L1
C7
0.1UF
C4
1000pF
VCC
1pF
2012-2017 Microchip Technology Inc.
FIGURE 28-8:
GND
GND
VCC
BT1
3
4
5
VCC
BK-912
PGD_SW0
GND
6
D1
RED
R4
470R
R2
DNP
CTRL
R3
10K
PGD_SW0
SW0
XTAL
SW2
SW2
GND
DS40001657C-page 321
315 MHz 434 MHz 868 MHz 915 MHz
GND
24 MHZ
MCLR_SW3
GND GND
SW3
GND
C5
C3
L4
L3
C2
L2
L1
X1
3
1
SW1
LED
GND
X1
PGC_SW1
PIC16LF1824T39A
2
VCC
VCC
2
1
R1
DNP
MCLR_SW3
VCC
4
Do Not Populate
J1
PIC16LF1824T39A
915 MHz
868 MHz
434 MHz
Common
TABLE 28-8:
BILL OF MATERIALS
Designator
Value
U1
PIC16LF1824T39A
C6, C7
0.1 µF
Description
Microcontroller with integrated UHF transmitter
Decoupling
R4
470
Current limiting
DS1
RED
LED
R2
DNP
Optional weak pull-up for RF configuration
C1
1pF
BT1
Lithium 3V coin battery
R1
DNP
Optional pull-up resistor for MCLR
R3
10 k
Weak pull-down for RF configuration
C4
1000 pF
L5
120 nH
C5
100 pF
C3, L1, L3
0
L4
39 nH
C2
6.8 pF
L2
2.2 nH
X1
24 MHz
L5
12 nH
C5
1 pF
C3, L4
DNP
L3
27 nH
C2
2.7 pF
L1, L2
0
X1
26 MHz
L5
8.2 nH
L1, L4, C2
0
C5
4.7 pF
C3
1.2 pF
L3
2.4 nH
L2
10 nH
X1
26 MHz
DS40001657C-page 322
Antenna impedance matching
Battery power
Decoupling
Matching to 50
Matching to 50
Matching to 50
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
29.0
IN-CIRCUIT SERIAL
PROGRAMMING™ (ICSP™)
ICSP™ programming allows customers to manufacture
circuit boards with unprogrammed devices. Programming
can be done after the assembly process allowing the
device to be programmed with the most recent firmware
or a custom firmware. Five pins are needed for ICSP™
programming:
• ICSPCLK
• ICSPDAT
• MCLR/VPP
• VDD
• VSS
In Program/Verify mode the Program Memory, User IDs
and the Configuration Words are programmed through
serial communications. The ICSPDAT pin is a bidirectional I/O used for transferring the serial data and the
ICSPCLK pin is the clock input. For more information on
ICSP™ refer to the “PIC16F/LF182X/PIC12F/LF1822
Memory Programming Specification” (DS41390).
29.1
High-Voltage Programming Entry
Mode
The device is placed into High-Voltage Programming
Entry mode by holding the ICSPCLK and ICSPDAT
pins low then raising the voltage on MCLR/VPP to VIHH.
Some programmers produce VPP greater than VIHH
(9.0V), an external circuit is required to limit the VPP
voltage. See Figure 29-1 for example circuit.
FIGURE 29-1:
VPP LIMITER EXAMPLE CIRCUIT
RJ11-6PIN
VPP
VDD
VSS
ICSP_DATA
ICSP_CLOCK
NC
6
5
4
3
2
1
1
2
3
4
5
6
RJ11-6PIN
®
To MPLAB ICD 2
R1
To Target Board
270 Ohm
LM431BCMX
1
2 A
K
3 A U1
6 A
NC 4
7 A
NC 5
R2
VREF
8
10k 1%
Note:
R3
24k 1%
The MPLAB ICD 2 produces a VPP
voltage greater than the maximum VPP
specification of the PIC16LF1824T39A.
2012-2017 Microchip Technology Inc.
DS40001657C-page 323
PIC16LF1824T39A
29.2
Low-Voltage Programming Entry
Mode
FIGURE 29-2:
The Low-Voltage Programming Entry mode allows the
PIC16LF1824T39A device to be programmed using
VDD only, without high voltage. When the LVP bit of
Configuration Word 2 is set to ‘1’, the low-voltage ICSP
programming entry is enabled. To disable the
Low-Voltage ICSP mode, the LVP bit must be
programmed to ‘0’.
VDD
Entry into the Low-Voltage Programming Entry mode
requires the following steps:
1.
2.
ICSPDAT
NC
2 4 6
ICSPCLK
1 3 5
VPP/MCLR
MCLR is brought to VIL.
A 32-bit key sequence is presented on
ICSPDAT, while clocking ICSPCLK.
VSS
Target
PC Board
Bottom Side
Pin Description*
1 = VPP/MCLR
Once the key sequence is complete, MCLR must be
held at VIL for as long as Program/Verify mode is to be
maintained.
2 = VDD Target
3 = VSS (ground)
4 = ICSPDAT
If low-voltage programming is enabled (LVP = 1), the
MCLR Reset function is automatically enabled and
cannot be disabled. See Section 7.3 “MCLR” for more
information.
5 = ICSPCLK
6 = No Connect
The LVP bit can only be reprogrammed to ‘0’ by using
the High-Voltage Programming mode.
29.3
ICD RJ-11 STYLE
CONNECTOR INTERFACE
Another connector often found in use with the PICkit™
programmers is a standard 6-pin header with 0.1 inch
spacing. Refer to Figure 29-3.
Common Programming Interfaces
Connection to a target device is typically done through
an ICSP™ header. A commonly found connector on
development tools is the RJ-11 in the 6P6C (6 pin, 6
connector) configuration. See Figure 29-2.
FIGURE 29-3:
PICkit™ STYLE CONNECTOR INTERFACE
Pin 1 Indicator
Pin Description*
1
2
3
4
5
6
1 = VPP/MCLR
2 = VDD Target
3 = VSS (ground)
4 = ICSPDAT
5 = ICSPCLK
6 = No Connect
*
DS40001657C-page 324
The 6-pin header (0.100" spacing) accepts 0.025" square pins.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
For additional interface recommendations, refer to your
specific device programmer manual prior to PCB
design.
It is recommended that isolation devices be used to
separate the programming pins from other circuitry.
The type of isolation is highly dependent on the specific
application and may include devices such as resistors,
diodes, or even jumpers. See Figure 29-4 for more
information.
FIGURE 29-4:
TYPICAL CONNECTION FOR ICSP™ PROGRAMMING
External
Programming
Signals
Device to be
Programmed
VDD
VDD
VDD
VPP
MCLR/VPP
VSS
VSS
Data
ICSPDAT
Clock
ICSPCLK
*
*
*
To Normal Connections
* Isolation devices (as required).
2012-2017 Microchip Technology Inc.
DS40001657C-page 325
PIC16LF1824T39A
30.0
INSTRUCTION SET SUMMARY
30.1
Read-Modify-Write Operations
• Byte Oriented
• Bit Oriented
• Literal and Control
Any instruction that specifies a file register as part of
the instruction performs a Read-Modify-Write (R-M-W)
operation. The register is read, the data is modified,
and the result is stored according to either the instruction, or the destination designator ‘d’. A read operation
is performed on a register even if the instruction writes
to that register.
The literal and control category contains the most varied instruction word format.
TABLE 30-1:
Each PIC16 instruction is a 14-bit word containing the
operation code (opcode) and all required operands.
The opcodes are broken into three broad categories.
Table 30-3 lists the instructions recognized by the
MPASMTM assembler.
All instructions are executed within a single instruction
cycle, with the following exceptions, which may take
two or three cycles:
• Subroutine takes two cycles (CALL, CALLW)
• Returns from interrupts or subroutines take two
cycles (RETURN, RETLW, RETFIE)
• Program branching takes two cycles (GOTO, BRA,
BRW, BTFSS, BTFSC, DECFSZ, INCSFZ)
• One additional instruction cycle will be used when
any instruction references an indirect file register
and the file select register is pointing to program
memory.
One instruction cycle consists of 4 oscillator cycles; for
an oscillator frequency of 4 MHz, this gives a nominal
instruction execution rate of 1 MHz.
All instruction examples use the format ‘0xhh’ to
represent a hexadecimal number, where ‘h’ signifies a
hexadecimal digit.
OPCODE FIELD
DESCRIPTIONS
Field
f
Description
Register file address (0x00 to 0x7F)
W
Working register (accumulator)
b
Bit address within an 8-bit file register
k
Literal field, constant data or label
x
Don’t care location (= 0 or 1).
The assembler will generate code with x = 0.
It is the recommended form of use for
compatibility with all Microchip software tools.
d
Destination select; d = 0: store result in W,
d = 1: store result in file register f.
Default is d = 1.
n
FSR or INDF number. (0-1)
mm
Pre-post increment-decrement mode
selection
TABLE 30-2:
ABBREVIATION
DESCRIPTIONS
Field
Program Counter
TO
Time-out bit
C
DC
Z
PD
DS40001657C-page 326
Description
PC
Carry bit
Digit carry bit
Zero bit
Power-down bit
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 30-1:
GENERAL FORMAT FOR
INSTRUCTIONS
Byte-oriented file register operations
13
8 7 6
OPCODE
d
f (FILE #)
0
d = 0 for destination W
d = 1 for destination f
f = 7-bit file register address
Bit-oriented file register operations
13
10 9
7 6
OPCODE
b (BIT #)
f (FILE #)
0
b = 3-bit bit address
f = 7-bit file register address
Literal and control operations
General
13
OPCODE
8
7
0
k (literal)
k = 8-bit immediate value
CALL and GOTO instructions only
13
11 10
OPCODE
0
k (literal)
k = 11-bit immediate value
MOVLP instruction only
13
OPCODE
7
6
0
k (literal)
k = 7-bit immediate value
MOVLB instruction only
13
OPCODE
5 4
0
k (literal)
k = 5-bit immediate value
BRA instruction only
13
OPCODE
9
8
0
k (literal)
k = 9-bit immediate value
FSR Offset instructions
13
OPCODE
7
6
n
5
0
k (literal)
n = appropriate FSR
k = 6-bit immediate value
FSR Increment instructions
13
OPCODE
3
2 1
0
n m (mode)
n = appropriate FSR
m = 2-bit mode value
OPCODE only
13
0
OPCODE
2012-2017 Microchip Technology Inc.
DS40001657C-page 327
PIC16LF1824T39A
TABLE 30-3:
PIC16LF1824T39A ENHANCED INSTRUCTION SET
Mnemonic,
Operands
Description
Cycles
14-Bit Opcode
MSb
LSb
Status
Affected
Notes
BYTE-ORIENTED FILE REGISTER OPERATIONS
ADDWF
ADDWFC
ANDWF
ASRF
LSLF
LSRF
CLRF
CLRW
COMF
DECF
INCF
IORWF
MOVF
MOVWF
RLF
RRF
SUBWF
SUBWFB
SWAPF
XORWF
f, d
f, d
f, d
f, d
f, d
f, d
f
–
f, d
f, d
f, d
f, d
f, d
f
f, d
f, d
f, d
f, d
f, d
f, d
Add W and f
Add with Carry W and f
AND W with f
Arithmetic Right Shift
Logical Left Shift
Logical Right Shift
Clear f
Clear W
Complement f
Decrement f
Increment f
Inclusive OR W with f
Move f
Move W to f
Rotate Left f through Carry
Rotate Right f through Carry
Subtract W from f
Subtract with Borrow W from f
Swap nibbles in f
Exclusive OR W with f
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
00
11
00
11
11
11
00
00
00
00
00
00
00
00
00
00
00
11
00
00
0111
1101
0101
0111
0101
0110
0001
0001
1001
0011
1010
0100
1000
0000
1101
1100
0010
1011
1110
0110
dfff
dfff
dfff
dfff
dfff
dfff
lfff
0000
dfff
dfff
dfff
dfff
dfff
1fff
dfff
dfff
dfff
dfff
dfff
dfff
ffff
ffff
ffff
ffff
ffff
ffff
ffff
00xx
ffff
ffff
ffff
ffff
ffff
ffff
ffff
ffff
ffff
ffff
ffff
ffff
C, DC, Z
C, DC, Z
Z
C, Z
C, Z
C, Z
Z
Z
Z
Z
Z
Z
Z
C
C
C, DC, Z
C, DC, Z
Z
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
BYTE ORIENTED SKIP OPERATIONS
DECFSZ
INCFSZ
f, d
f, d
Decrement f, Skip if 0
Increment f, Skip if 0
BCF
BSF
f, b
f, b
Bit Clear f
Bit Set f
1(2)
1(2)
00
00
1, 2
1, 2
1011 dfff ffff
1111 dfff ffff
BIT-ORIENTED FILE REGISTER OPERATIONS
1
1
00bb bfff ffff
01bb bfff ffff
2
2
01
01
10bb bfff ffff
11bb bfff ffff
1, 2
1, 2
11
11
11
00
11
11
11
11
1110
1001
1000
0000
0001
0000
1100
1010
01
01
BIT-ORIENTED SKIP OPERATIONS
BTFSC
BTFSS
f, b
f, b
Bit Test f, Skip if Clear
Bit Test f, Skip if Set
ADDLW
ANDLW
IORLW
MOVLB
MOVLP
MOVLW
SUBLW
XORLW
k
k
k
k
k
k
k
k
Add literal and W
AND literal with W
Inclusive OR literal with W
Move literal to BSR
Move literal to PCLATH
Move literal to W
Subtract W from literal
Exclusive OR literal with W
1 (2)
1 (2)
LITERAL OPERATIONS
1
1
1
1
1
1
1
1
kkkk
kkkk
kkkk
001k
1kkk
kkkk
kkkk
kkkk
kkkk
kkkk
kkkk
kkkk
kkkk
kkkk
kkkk
kkkk
C, DC, Z
Z
Z
C, DC, Z
Z
Note 1: If the Program Counter (PC) is modified, or a conditional test is true, the instruction requires two cycles. The second cycle
is executed as a NOP.
2: If this instruction addresses an INDF register and the MSb of the corresponding FSR is set, this instruction will require one
additional instruction cycle.
DS40001657C-page 328
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 30-3:
PIC16LF1824T39A ENHANCED INSTRUCTION SET (CONTINUED)
Mnemonic,
Operands
Description
Cycles
14-Bit Opcode
MSb
LSb
Status
Affected
Notes
CONTROL OPERATIONS
2
2
2
2
2
2
2
2
BRA
BRW
CALL
CALLW
GOTO
RETFIE
RETLW
RETURN
k
–
k
–
k
k
k
–
Relative Branch
Relative Branch with W
Call Subroutine
Call Subroutine with W
Go to address
Return from interrupt
Return with literal in W
Return from Subroutine
CLRWDT
NOP
OPTION
RESET
SLEEP
TRIS
–
–
–
–
–
f
Clear Watchdog Timer
No Operation
Load OPTION_REG register with W
Software device Reset
Go into Standby mode
Load TRIS register with W
ADDFSR
MOVIW
n, k
n mm
MOVWI
k[n]
n mm
Add Literal k to FSRn
Move Indirect FSRn to W with pre/post inc/dec
modifier, mm
Move INDFn to W, Indexed Indirect.
Move W to Indirect FSRn with pre/post inc/dec
modifier, mm
Move W to INDFn, Indexed Indirect.
11
00
10
00
10
00
11
00
001k
0000
0kkk
0000
1kkk
0000
0100
0000
kkkk
0000
kkkk
0000
kkkk
0000
kkkk
0000
kkkk
1011
kkkk
1010
kkkk
1001
kkkk
1000
00
00
00
00
00
00
0000
0000
0000
0000
0000
0000
0110
0000
0110
0000
0110
0110
0100 TO, PD
0000
0010
0001
0011 TO, PD
0fff
INHERENT OPERATIONS
1
1
1
1
1
1
C-COMPILER OPTIMIZED
k[n]
1
1
11
00
1
1
11
00
0001 0nkk kkkk
0000 0001 0nmm Z
kkkk
1111 0nkk 1nmm Z
0000 0001 kkkk
1
11
1111 1nkk
2, 3
2
2, 3
2
Note 1: If the Program Counter (PC) is modified, or a conditional test is true, the instruction requires two cycles. The second cycle
is executed as a NOP.
2: If this instruction addresses an INDF register and the MSb of the corresponding FSR is set, this instruction will require
one additional instruction cycle.
3: See Table in the MOVIW and MOVWI instruction descriptions.
2012-2017 Microchip Technology Inc.
DS40001657C-page 329
PIC16LF1824T39A
30.2
Instruction Descriptions
ADDFSR
Add Literal to FSRn
ANDLW
Syntax:
[ label ] ADDFSR FSRn, k
Syntax:
[ label ] ANDLW
Operands:
-32 k 31
n [ 0, 1]
Operands:
0 k 255
Operation:
(W) .AND. (k) (W)
Operation:
FSR(n) + k FSR(n)
Status Affected:
Z
Status Affected:
None
Description:
Description:
The signed 6-bit literal ‘k’ is added to
the contents of the FSRnH:FSRnL
register pair.
The contents of W register are
AND’ed with the eight-bit literal ‘k’.
The result is placed in the W register.
AND W with f
AND literal with W
k
FSRn is limited to the range 0000h FFFFh. Moving beyond these bounds
will cause the FSR to wrap around.
ADDLW
Add literal and W
ANDWF
Syntax:
[ label ] ADDLW
Syntax:
[ label ] ANDWF
Operands:
0 f 127
d 0,1
Operation:
(W) .AND. (f) (destination)
k
Operands:
0 k 255
Operation:
(W) + k (W)
Status Affected:
C, DC, Z
Description:
The contents of the W register are
added to the eight-bit literal ‘k’ and the
result is placed in the W register.
ADDWF
Add W and f
f,d
Status Affected:
Z
Description:
AND the W register with register ‘f’. If
‘d’ is ‘0’, the result is stored in the W
register. If ‘d’ is ‘1’, the result is stored
back in register ‘f’.
ASRF
Arithmetic Right Shift
Syntax:
[ label ] ADDWF
Syntax:
[ label ] ASRF
Operands:
0 f 127
d 0,1
Operands:
0 f 127
d [0,1]
Operation:
(W) + (f) (destination)
Operation:
Status Affected:
C, DC, Z
(f) dest
(f) dest,
(f) C,
Description:
Add the contents of the W register
with register ‘f’. If ‘d’ is ‘0’, the result is
stored in the W register. If ‘d’ is ‘1’, the
result is stored back in register ‘f’.
Status Affected:
C, Z
Description:
The contents of register ‘f’ are shifted
one bit to the right through the Carry
flag. The MSb remains unchanged. If
‘d’ is ‘0’, the result is placed in W. If ‘d’
is ‘1’, the result is stored back in
register ‘f’.
f,d
ADDWFC
ADD W and CARRY bit to f
Syntax:
[ label ] ADDWFC
Operands:
0 f 127
d [0,1]
register f
C
f {,d}
Operation:
(W) + (f) + (C) dest
Status Affected:
C, DC, Z
Description:
Add W, the Carry flag and data memory location ‘f’. If ‘d’ is ‘0’, the result is
placed in W. If ‘d’ is ‘1’, the result is
placed in data memory location ‘f’.
DS40001657C-page 330
f {,d}
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
BCF
Bit Clear f
Syntax:
[ label ] BCF
BTFSC
f,b
Bit Test f, Skip if Clear
Syntax:
[ label ] BTFSC f,b
0 f 127
0b7
Operands:
0 f 127
0b7
Operands:
Operation:
0 (f)
Operation:
skip if (f) = 0
Status Affected:
None
Status Affected:
None
Description:
Bit ‘b’ in register ‘f’ is cleared.
Description:
If bit ‘b’ in register ‘f’ is ‘1’, the next
instruction is executed.
If bit ‘b’, in register ‘f’, is ‘0’, the next
instruction is discarded, and a NOP is
executed instead, making this a
2-cycle instruction.
BRA
Relative Branch
BTFSS
Bit Test f, Skip if Set
Syntax:
[ label ] BRA label
[ label ] BRA $+k
Syntax:
[ label ] BTFSS f,b
Operands:
0 f 127
0b VDD)20 mA
Maximum output current
sunk by any I/O pin .............................................................................................................................. 25 mA
sourced by any I/O pin ......................................................................................................................... 25 mA
Note 1:
Power dissipation is calculated as follows: PDIS = VDD x {IDD – IOH} + {(VDD – VOH) x IOH} + (VOl x IOL).
† NOTICE: Stresses above those listed under “Absolute Maximum Ratings” may cause permanent damage to the
device. This is a stress rating only and functional operation of the device at those or any other conditions above those
indicated in the operation listings of this specification is not implied. Exposure to maximum rating conditions for
extended periods may affect device reliability.
DS40001657C-page 340
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
31.2
Standard Operating Conditions
The standard operating conditions for any device are defined as:
Operating Voltage:
Operating Temperature:
VDDMIN VDD VDDMAX
TA_MIN TA TA_MAX
VDD — Operating Supply Voltage(2)
VDDMIN (Fosc 16 MHz) ......................................................................................................... +1.8V
VDDMIN (Fosc 20 MHz) ......................................................................................................... +2.5V
VDDMAX .................................................................................................................................... +3.6V
TA — Operating Ambient Temperature Range
Industrial Temperature
TA_MIN ..................................................................................................................................... -40°C
TA_MAX.................................................................................................................................... +85°C
Extended Temperature
TA_MIN ..................................................................................................................................... -40°C
TA_MAX.................................................................................................................................. +125°C
Note 1:
2:
Maximum current rating requires even load distribution across I/O pins. Maximum current rating may be
limited by the device package power dissipation characterizations, see Table 31-6 to calculate device
specifications.
See Parameter D001, DS Characteristics: Supply Voltage.
2012-2017 Microchip Technology Inc.
DS40001657C-page 341
PIC16LF1824T39A
PIC16LF1824T39A VOLTAGE FREQUENCY GRAPH, -40°C TA +125°C
VDD (V)
FIGURE 31-1:
3.6
2.5
1.8
10
4
0
16
32
Frequency (MHz)
Note 1: The shaded region indicates the permissible combinations of voltage and frequency.
2: Refer to Table 31-8 for each Oscillator mode’s supported frequencies.
HFINTOSC FREQUENCY ACCURACY OVER DEVICE VDD AND TEMPERATURE
FIGURE 31-2:
125
± 5%
Temperature (°C)
85
± 3%
60
± 2%
25
0
-20
-40
1.8
± 5%
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
VDD (V)
DS40001657C-page 342
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
31.3
DC Characteristics
TABLE 31-1:
SUPPLY VOLTAGE
Standard Operating Conditions (unless otherwise stated)
PIC16LF1824T39A
Param.
No.
D001
Sym.
VDD
Characteristic
Min.
Typ†
Max.
Units
Conditions
1.8
2.5
—
—
3.6
3.6
V
V
FOSC 16 MHz:
FOSC 32 MHz (Note 2)
Device in Sleep mode
Supply Voltage (VDDMIN, VDDMAX)
PIC16LF1824T39A
D002*
VDR
RAM Data Retention Voltage (Note 1)
D002A*
VPOR
Power-on Reset Release Voltage
D002B*
VPORR
Power-on Reset Rearm Voltage
D003
VADFVR
D003A
VCDAFVR
D004*
SVDD
PIC16LF1824T39A
1.5
—
—
V
—
1.6
—
V
PIC16LF1824T39A
—
0.8
—
V
Device in Sleep mode
Fixed Voltage Reference Voltage for
ADC
-8
—
6
%
1.024V, VDD 2.5V
2.048V, VDD 2.5V
Fixed Voltage Reference Voltage for
Comparator and DAC
-11
—
7
%
1.024V, VDD 2.5V
2.048V, VDD 2.5V
VDD Rise Rate to ensure internal
Power-on Reset signal
0.05
—
—
V/ms
See Section 7.1 “Power-on Reset
(POR)” for details.
*
†
Note
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not
tested.
1: This is the limit to which VDD can be lowered in Sleep mode without losing RAM data.
2: PLL required for 32 MHz operation.
2012-2017 Microchip Technology Inc.
DS40001657C-page 343
PIC16LF1824T39A
FIGURE 31-3:
POR AND POR REARM WITH SLOW RISING VDD
VDD
VPOR
VPORR
VSS
NPOR
POR REARM
VSS
TVLOW(2)
Note 1:
2:
3:
DS40001657C-page 344
TPOR(3)
When NPOR is low, the device is held in Reset.
TPOR 1 s typical.
TVLOW 2.7 s typical.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 31-2:
SUPPLY CURRENT (IDD)
Standard Operating Conditions (unless otherwise stated)
PIC16LF1824T39A
Param
No.
Device
Characteristics
Min.
Conditions
Typ†
Max.
Units
—
5.0
10
A
1.8
—
7.5
12
A
3.0
D011
—
88
110
A
1.8
—
133
190
A
3.0
D012
—
220
290
A
1.8
—
370
480
A
3.0
D013
—
55
160
A
1.8
—
90
230
A
3.0
VDD
Note
Supply Current (IDD) (Note 1, 2)
D010
FOSC = 32 kHz
LP Oscillator mode, -40°C TA +85°C
FOSC = 1 MHz
XT Oscillator mode
FOSC = 4 MHz
XT Oscillator mode
FOSC = 1 MHz
EC Oscillator mode, Medium-Power mode
Supply Current (IDD) (Note 1, 2)
D014
D015
D016
D017*
D018
D019
—
187
250
A
1.8
—
324
430
A
3.0
—
6
18
A
1.8
—
8
20
A
3.0
—
113
165
A
1.8
—
140
190
A
3.0
—
0.44
0.70
mA
1.8
—
0.70
1.10
mA
3.0
—
0.70
1.20
mA
1.8
—
1.10
1.80
mA
3.0
—
2.10
3.30
mA
3.0
—
3.20
3.60
mA
3.6
—
2.50
3.30
mA
3.0
—
3.00
3.60
mA
3.6
—
210
350
A
1.8
—
362
680
A
3.0
FOSC = 4 MHz
EC Oscillator mode,
Medium-Power mode
FOSC = 31 kHz
LFINTOSC mode, -40°C TA +85°C
FOSC = 500 kHz
MFINTOSC mode
FOSC = 8 MHz
HFINTOSC mode
FOSC = 16 MHz
HFINTOSC mode
FOSC = 32 MHz
HFINTOSC mode (Note 3)
Supply Current (IDD) (Note 1, 2)
D020
D021
*
†
Note 1:
2:
3:
4:
5:
FOSC = 32 MHz
HS Oscillator mode (Note 4)
FOSC = 4 MHz
EXTRC mode (Note 5)
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are
not tested.
The test conditions for all IDD measurements in active operation mode are: OSC1 = external square wave, from
rail-to-rail; all I/O pins tri-stated, pulled to VDD; MCLR = VDD; WDT disabled.
The supply current is mainly a function of the operating voltage and frequency. Other factors, such as I/O pin loading
and switching rate, oscillator type, internal code execution pattern and temperature, also have an impact on the current
consumption.
8 MHz internal oscillator with 4xPLL enabled.
8 MHz crystal oscillator with 4xPLL enabled.
For RC oscillator configurations, current through REXT is not included. The current through the resistor can be extended
by the formula IR = VDD/2REXT (mA) with REXT in k.
2012-2017 Microchip Technology Inc.
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PIC16LF1824T39A
TABLE 31-3:
POWER-DOWN CURRENTS (IPD)
Standard Operating Conditions (unless otherwise stated)
PIC16LF1824T39A
Param
No.
Device
Characteristics
Min.
Typ†
Max.
+85°C
Units
Max.
+125°C
Units
Conditions
VDD
Note
Power-down Base Current (IPD) (Note 2)
—
0.02
1.0
A
2.4
A
1.8
—
0.03
1.5
A
3.0
A
3.0
WDT, BOR, FVR, and T1OSC disabled, all Peripherals Inactive
D023
—
0.2
2.0
A
3.0
A
1.8
LPWDT Current (Note 1)
—
0.5
2.0
A
4.0
A
3.0
D023A
—
12
22
A
25
A
1.8
—
13
24
A
27
A
3.0
D024
—
7.0
14
A
16
A
3.0
BOR Current (Note 1)
D025
—
0.65
3.5
A
4.0
A
1.8
T1OSC Current (Note 1)
—
2.3
4.0
A
4.5
A
3.0
—
0.03
1.5
A
3.0
A
1.8
—
0.04
2.0
A
3.5
A
3.0
D022
D026
FVR current
A/D Current (Note 1, 3),
no conversion in progress
Power-down Base Current (IPD) (Note 2)
—
250
—
A
—
A
1.8
—
250
—
A
—
A
3.0
D027
—
2.0
5.0
A
6.0
A
1.8
—
4.0
7.0
A
9.0
A
3.0
D027A
—
5.0
8.0
A
10
A
1.8
—
8.0
13
A
14
A
3.0
D027B
—
13
22
A
24
A
1.8
—
35
45
A
47
A
3.0
D028
—
7.3
16
A
17
A
1.8
—
7.4
18
A
19
A
3.0
—
28
46
A
48
A
1.8
—
29
48
A
49
A
3.0
D026A*
D028B
*
†
Note 1:
2:
3:
A/D Current (Note 1, 3),
conversion in progress
Cap Sense, Low Power, CPSRM =
0, CPSRNG = 01 (Note 1)
Cap Sense, Medium Power, CPSRM
= 0, CPSRNG = 10 (Note 1)
Cap Sense, High Power, CPSRM =
0, CPSRNG = 11 (Note 1)
Comparator Current, Low-Power
mode (Note 1)
Comparator Current, High-Power
mode (Note 1)
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are
not tested.
The peripheral current is the sum of the base IDD or IPD and the additional current consumed when this peripheral is
enabled. The peripheral current can be determined by subtracting the base IDD or IPD current from this limit. Max
values should be used when calculating total current consumption.
The power-down current in Sleep mode does not depend on the oscillator type. Power-down current is measured with
the part in Sleep mode, with all I/O pins in high-impedance state and tied to VDD.
A/D oscillator source is FRC.
DS40001657C-page 346
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PIC16LF1824T39A
TABLE 31-4:
I/O PORTS
DC CHARACTERISTICS
Param
No.
Sym.
VIL
Standard Operating Conditions (unless otherwise stated)
Characteristic
Min.
Typ†
Max.
Units
—
—
with Schmitt Trigger buffer
Conditions
—
0.8
V
4.5V VDD 5.5V
—
0.15 VDD
V
1.8V VDD 3.6V
—
—
0.2 VDD
V
2.0V VDD 3.6V
with I2C™ levels
—
—
0.3 VDD
V
Input Low Voltage
I/O PORT:
D030
with TTL buffer
D030A
D031
with SMBus levels
—
—
0.8
V
2.7V VDD 3.6V
D032
MCLR, OSC1 (RC mode)
—
—
0.2 VDD
V
(Note 1)
D033
OSC1 (HS mode)
—
—
0.3 VDD
V
VIH
Input High Voltage
I/O PORT:
D040
2.0
—
—
V
4.5V VDD 5.5V
0.25 VDD +
0.8
—
—
V
1.8V VDD 3.6V
with Schmitt Trigger buffer
0.8 VDD
—
—
V
2.0V VDD 3.6V
with I2C™ levels
0.7 VDD
—
—
V
with TTL buffer
D040A
D041
with SMBus levels
D042
MCLR
2.1
—
—
V
0.8 VDD
—
—
V
2.7V VDD 3.6V
D043A
OSC1 (HS mode)
0.7 VDD
—
—
V
D043B
OSC1 (RC mode)
0.9 VDD
—
—
V
VDD > 2.0V (Note 1)
I/O ports
—
±5
± 125
nA
VSS VPIN VDD, Pin at highimpedance at 85°C
MCLR (Note 3)
—
± 50
± 200
nA
VSS VPIN VDD at 85°C
25
100
200
—
0.6
V
IOL = 6 mA, VDD = 3.3V
IOL = 1.8 mA, VDD = 1.8V
—
—
V
IOH = 3 mA, VDD = 3.3V
IOH = 1 mA, VDD = 1.8V
—
—
15
pF
IIL
D060
D061
Input Leakage Current (Note 2)
IPUR
Weak Pull-up Current
VOL
Output Low Voltage (Note 4)
D070*
D080
I/O ports
—
VOH
D090
VDD = 3.3V, VPIN = VSS
Output High Voltage (Note 4)
I/O ports
VDD - 0.7
Capacitive Loading Specs on Output Pins
D101*
COSC2 OSC2 pin
D101A* CIO
All Microcontroller I/O pins
—
—
50
pF
D101B* CIORF
All RF I/O pins
—
—
25
pF
*
†
Note 1:
2:
3:
4:
In XT, HS and LP modes when
external clock is used to drive
OSC1
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are
not tested.
In RC oscillator configuration, the OSC1/CLKIN pin is a Schmitt Trigger input. It is not recommended to use an external
clock in RC mode.
Negative current is defined as current sourced by the pin.
The leakage current on the MCLR pin is strongly dependent on the applied voltage level. The specified levels represent
normal operating conditions. Higher leakage current may be measured at different input voltages.
Including OSC2 in CLKOUT mode.
2012-2017 Microchip Technology Inc.
DS40001657C-page 347
PIC16LF1824T39A
TABLE 31-5:
MEMORY PROGRAMMING REQUIREMENTS
Standard Operating Conditions (unless otherwise stated)
DC CHARACTERISTICS
Param
No.
Sym.
Characteristic
Min.
Typ†
Max.
Units
Conditions
Program Memory
Programming Specifications
D110
VIHH
Voltage on MCLR/VPP/RA5 pin
8.0
—
9.0
V
D111
IDDP
Supply Current during
Programming
—
—
10
mA
D112
VBE
VDD for Bulk Erase
2.7
—
VDDMAX
V
D113
VPEW
VDD for Write or Row Erase
VDDMIN
—
VDDMAX
V
D114
IPPPGM Current on MCLR/VPP during
Erase/Write
—
1.0
—
mA
D115
IDDPGM Current on VDD during Erase/
Write
—
5.0
—
mA
D116
ED
Byte Endurance
100K
—
—
E/W
D117
VDRW
VDD for Read/Write
VDDMIN
—
VDDMAX
V
D118
TDEW
Erase/Write Cycle Time
—
4.0
5.0
ms
D119
TRETD
Characteristic Retention
—
40
—
Year
Provided no other
specifications are violated
D120
TREF
Number of Total Erase/Write
Cycles before Refresh (Note 2)
1M
10M
—
E/W
-40°C to +85°C
D121
EP
Cell Endurance
10K
—
—
E/W
-40C to +85C (Note 1)
D122
VPRW
VDD for Read/Write
VDDMIN
—
VDDMAX
V
D123
TIW
Self-timed Write Cycle Time
—
2
2.5
ms
D124
TRETD
Characteristic Retention
—
40
—
Year
(Note 3, 4)
Data EEPROM Memory
-40C to +85C
Program Flash Memory
Provided no other
specifications are violated
† Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only
and are not tested.
Note 1: Self-write and Block Erase.
2: Refer to Section 11.2 “Using the Data EEPROM” for a more detailed discussion on data EEPROM
endurance.
3: Required only if single-supply programming is disabled.
4: The MPLAB® ICD 2 does not support variable VPP output. Circuitry to limit the ICD 2 VPP voltage must be
placed between the ICD 2 and target system when programming or debugging with the ICD 2.
DS40001657C-page 348
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 31-6:
THERMAL CONSIDERATIONS
Standard Operating Conditions (unless otherwise stated)
Param
No.
Sym.
Characteristic
Typ.
Units
TH01
JA
Thermal Resistance Junction to Ambient
74
C/W
20-pin TSSOP package
TH02
JC
Thermal Resistance Junction to Case
17
C/W
20-pin TSSOP package
TH03
TJMAX
Maximum Junction Temperature
150
C
TH04
PD
TH05
Power Dissipation
PINTERNAL Internal Power Dissipation
Conditions
—
W
PD = PINTERNAL + PI/O
—
W
PINTERNAL = IDD x VDD (Note 1)
TH06
P I /O
I/O Power Dissipation
—
W
PI/O = (IOL * VOL) + (IOH * (VDD - VOH))
TH07
PDER
Derated Power
—
W
PDER = PDMAX (TJ - TA)/JA (Note 2)
Note 1: IDD is current to run the chip alone without driving any load on the output pins.
2: TA = Ambient Temperature; TJ = Junction Temperature
TABLE 31-7:
RF TRANSMITTER ELECTRICAL SPECIFICATIONS
Symbol
Description
Conditions
Min.
Typ.
Max.
—
Unit
Current Consumption
IDDSL
Supply Current in Sleep mode
—
125
—
nA
IDDT_315
Supply Current in Transmit
mode at 315 MHz(1)
RFOP = +10 dBm 50% OOK
RFOP = +10 dBm FSK
RFOP = 0 dBm FSK
—
—
—
11
15
9
—
—
—
mA
mA
mA
IDDT_915
Supply Current in Transmit
mode at 915 MHz(1)
RFOP = +10 dBm FSK
RFOP = 0 dBm FSK
—
—
17.5
10.5
—
—
mA
mA
Band 0, with FXOSC = 22 MHz
310
—
450
MHz
Band 0, with FXOSC = 24 MHz
312
—
450
MHz
Band 0, with FXOSC = 26 MHz
338
—
450
MHz
Band 1, with FXOSC = 26 MHz
860
902
—
—
870
928
MHz
MHz
RF and Baseband Specifications
FBAND
Accessible Frequency Bands
See details in Table 28-6.
FDA
Frequency deviation, FSK
10
—
200
kHz
BRF
Bit rate, FSK
Permissible Range
0.5
—
100
kbps
BRO
Bit rate, OOK
Permissible Range
0.5
—
10
kbps
OOK_B
OOK Modulation Depth
—
45
—
dB
RFOP
RF output power in 50 Ohms
in either frequency bands
High-Power Setting
Low-Power Setting(1)
7
-3
10
0
—
—
dBm
dBm
RFOPFL
RF output power flatness
From 315 to 390 MHz
—
2
—
dB
DRFOPV
Variation in RF output power
with supply voltage
2.5V to 3.3V
1.8V to 3.7V
—
—
—
—
3
7
dB
dB
PHN
Transmitter phase noise
At offset: 100 kHz
350 kHz
550 kHz
1.15 MHz
—
—
—
—
-82
-92
-96
-103
-76
-81
-91
-101
dBc/Hz
dBc/Hz
dBc/Hz
dBc/Hz
STEP_22
RF frequency step
FXOSC = 22 MHz, Band 0
—
1.34277
—
kHz
STEP_24
RF frequency step
FXOSC = 24 MHz, Band 0
—
1.46484
—
kHz
STEP_26
RF frequency step
FXOSC = 26 MHz, Band 0
FXOSC = 26 MHz, Band 1
—
—
1.58691
3.17383
—
—
kHz
kHz
2012-2017 Microchip Technology Inc.
—
—
DS40001657C-page 349
PIC16LF1824T39A
TABLE 31-7:
RF TRANSMITTER ELECTRICAL SPECIFICATIONS (CONTINUED)
Symbol
FXOSC
Description
Crystal Oscillator Frequency
Conditions
Min.
Typ.
Max.
Unit
—
—
—
—
22
24
26
—
—
—
MHz
MHz
MHz
Timing Specifications
tWAKE
Time from Sleep to Tx mode
XTAL dependant, with spec’d
XTAL
—
650
2000
us
tOFFT
Timer from Tx data activity to
Sleep
Programmable
—
—
2
20
—
—
ms
ms
tRAMP
PA Ramp up and down time
—
20
—
us
tSTART
Time before CTRL pin mode
selection.
—
1
—
ms
fCTRL
CTRL Clock Frequency
—
—
10
MHz
tCH
CTRL Clock High time
—
45
—
—
ns
tCL
CTRL Clock Low time
—
45
—
—
ns
tRISE
CTRL Clock Rise time
—
—
—
5
ns
tFALL
CTRL Clock Fall time
—
—
—
5
ns
tSETUP
DATA Setup time
From DATA transition to CTRL
rising edge
45
—
—
ns
tHOLD
DATA Hold time
From CTRL rising edge to
DATA transition
45
—
—
ns
t0
Time at ‘1’ on DATA during
Recovery Sequence Timing
See Figure 28-4
—
—
5
ns
t1
Time at ‘0’ on DATA during
Recovery Sequence Timing
See Figure 28-4
5
—
—
ns
Note 1:
—
Time from power on to
sampling of CTRL
—
With different matching networks.
DS40001657C-page 350
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
31.4
AC Characteristics
The timing parameter symbols have been created with
one of the following formats:
1. TppS2ppS
2. TppS
T
F
Frequency
Lowercase letters (pp) and their meanings:
pp
cc
CCP1
ck
CLKOUT
cs
CS
di
SDIx
do
SDO
dt
Data in
io
I/O PORT
MCLR
mc
Uppercase letters and their meanings:
S
F
Fall
H
High
I
Invalid (High-impedance)
L
Low
FIGURE 31-4:
T
Time
osc
rd
rw
sc
ss
t0
t1
wr
OSC1
RD
RD or WR
SCKx
SS
T0CKI
T1CKI
WR
P
R
V
Z
Period
Rise
Valid
High-impedance
LOAD CONDITIONS
Load Condition
Pin
CL
VSS
Legend: CL = 50 pF for all pins, 15 pF for
OSC2 output
2012-2017 Microchip Technology Inc.
DS40001657C-page 351
PIC16LF1824T39A
FIGURE 31-5:
CLOCK TIMING
Q4
Q1
Q2
Q3
Q4
Q1
OSC1/CLKIN
OS02
OS04
OS04
OS03
OSC2/CLKOUT
(LP,XT,HS Modes)
OSC2/CLKOUT
(CLKOUT Mode)
TABLE 31-8:
CLOCK OSCILLATOR TIMING REQUIREMENTS
Standard Operating Conditions (unless otherwise stated)
Param
No.
OS01
Sym.
FOSC
Characteristic
External CLKIN Frequency
(Note 1)
Oscillator Frequency (Note 1)
OS02
TOSC
External CLKIN Period (Note 1)
Oscillator Period (Note 1)
Min.
Typ†
Max.
Units
Conditions
DC
—
0.5
MHz
EC Oscillator mode (low)
DC
—
4
MHz
EC Oscillator mode (medium)
DC
—
32
MHz
EC Oscillator mode (high)
—
32.768
—
kHz
LP Oscillator mode
0.1
—
4
MHz
XT Oscillator mode
1
—
4
MHz
HS Oscillator mode, VDD 2.7V
1
—
20
MHz
HS Oscillator mode, VDD > 2.7V
DC
—
4
MHz
RC Oscillator mode
27
—
s
LP Oscillator mode
250
—
ns
XT Oscillator mode
50
—
ns
HS Oscillator mode
50
—
ns
EC Oscillator mode
—
30.5
—
s
LP Oscillator mode
250
—
10,000
ns
XT Oscillator mode
50
—
1,000
ns
HS Oscillator mode
250
—
—
ns
RC Oscillator mode
OS03
TCY
Instruction Cycle Time (Note 1)
200
—
DC
ns
TCY = FOSC/4
OS04*
TosH,
TosL
External CLKIN High,
External CLKIN Low
2
—
—
s
LP oscillator
100
—
—
ns
XT oscillator
20
—
—
ns
HS oscillator
0
—
ns
LP oscillator
0
—
ns
XT oscillator
0
—
ns
HS oscillator
OS05*
TosR,
TosF
External CLKIN Rise,
External CLKIN Fall
*
†
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not
tested.
Note 1: Instruction cycle period (TCY) equals four times the input oscillator time base period. All specified values are based on
characterization data for that particular oscillator type under standard operating conditions with the device executing code.
Exceeding these specified limits may result in an unstable oscillator operation and/or higher than expected current
consumption. All devices are tested to operate at “min” values with an external clock applied to OSC1 pin. When an
external clock input is used, the “max” cycle time limit is “DC” (no clock) for all devices.
DS40001657C-page 352
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PIC16LF1824T39A
TABLE 31-9:
OSCILLATOR PARAMETERS
Standard Operating Conditions (unless otherwise stated)
Param
No.
OS08
Sym.
HFOSC
OS08A MFOSC
Freq.
Tolerance
Characteristic
Internal Calibrated HFINTOSC
Frequency (Note 1)
Internal LFINTOSC Frequency
LFOSC
OS10*
TIOSC ST HFINTOSC
Wake-up from Sleep Start-up Time
Typ†
Max.
Units
Conditions
2%
—
16.0
—
MHz
0°C TA +60°C, VDD 2.5V
3%
—
16.0
—
MHz
60°C TA +85°C, VDD 2.5V
5%
—
16.0
—
MHz
-40°C TA +125°C
2%
—
500
—
kHz
0°C TA +60°C, VDD 2.5V
3%
—
500
—
kHz
60°C TA +85°C, VDD 2.5V
5%
—
500
—
kHz
-40°C TA +125°C
25%
—
31
—
kHz
-40°C TA +125°C
—
—
5
8
s
—
—
20
30
s
Internal Calibrated MFINTOSC
Frequency (Note 1)
OS09
Min.
MFINTOSC
Wake-up from Sleep Start-up Time
*
†
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not
tested.
Note 1: To ensure these oscillator frequency tolerances, VDD and VSS must be capacitively decoupled as close to the device as
possible. 0.1 F and 0.01 F values in parallel are recommended.
TABLE 31-10: PLL CLOCK TIMING SPECIFICATIONS (VDD = 2.7V to 5.5V)
Param
No.
Sym.
F10
F11
Characteristic
Min.
Typ†
Max.
Units
FOSC Oscillator Frequency Range
4
FSYS
On-Chip VCO System Frequency
16
—
8
MHz
—
32
MHz
F12
TRC
PLL Start-up Time (Lock Time)
F13*
CLK
CLKOUT Stability (Jitter)
—
—
2
ms
-0.25%
—
+0.25%
%
Conditions
* These parameters are characterized but not tested.
† Data in “Typ” column is at 3V, 25C unless otherwise stated. These parameters are for design guidance
only and are not tested.
FIGURE 31-6:
Cycle
CLKOUT AND I/O TIMING
Write
Fetch
Read
Execute
Q4
Q1
Q2
Q3
FOSC
OS12
OS11
OS20
OS21
CLKOUT
OS19
OS16
OS13
OS18
OS17
I/O pin
(Input)
OS14
OS15
I/O pin
(Output)
New Value
Old Value
OS18, OS19
2012-2017 Microchip Technology Inc.
DS40001657C-page 353
PIC16LF1824T39A
TABLE 31-11: CLKOUT AND I/O TIMING PARAMETERS
Standard Operating Conditions (unless otherwise stated)
Param
No.
Sym.
Characteristic
Min.
Typ†
Max.
Units
Conditions
OS11
TosH2ckL
FOSC to CLKOUT (Note 1)
—
—
70
ns
VDD = 3.0-5.0V
OS12
TosH2ckH FOSC to CLKOUT (Note 1)
—
—
72
ns
VDD = 3.0-5.0V
OS13
TckL2ioV
CLKOUT to Port out valid (Note 1)
—
—
20
ns
OS14
TioV2ckH
TOSC + 200 ns
—
—
ns
OS15
OS16
TosH2ioV
TosH2ioI
—
50
50
—
70*
—
ns
ns
OS17
TioV2osH
20
—
—
ns
OS18* TioR
Port input valid before CLKOUT
(Note 1)
Fosc (Q1 cycle) to Port out valid
Fosc (Q2 cycle) to Port input invalid
(I/O in hold time)
Port input valid to Fosc(Q2 cycle)
(I/O in setup time)
Port output rise time
Port output fall time
40
15
28
15
—
—
72
32
55
30
—
—
ns
OS19* TioF
—
—
—
—
25
25
OS20* Tinp
OS21* Tioc
INT pin input high or low time
Interrupt-on-change new input level
time
* These parameters are characterized but not tested.
† Data in “Typ” column is at 3.0V, 25C unless otherwise stated.
Note 1: Measurements are taken in RC mode where CLKOUT output is 4 x TOSC.
FIGURE 31-7:
ns
VDD = 3.0-5.0V
VDD = 3.0-5.0V
VDD = 1.8V
VDD = 3.0-5.0V
VDD = 1.8V
VDD = 3.0-5.0V
ns
ns
RESET, WATCHDOG TIMER, OSCILLATOR START-UP TIMER AND POWER-UP
TIMER TIMING
VDD
MCLR
30
Internal
POR
PWRT
Time-out
33
32
OSC
Start-Up Time
Internal Reset(1)
Watchdog Timer
Reset(1)
34
31
34
I/O pins
Note 1: Asserted low.
DS40001657C-page 354
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PIC16LF1824T39A
FIGURE 31-8:
BROWN-OUT RESET TIMING AND CHARACTERISTICS
VDD
VBOR and VHYST
VBOR
(Device in Brown-out Reset)
(Device not in Brown-out Reset)
37
Reset
33(1)
(due to BOR)
Note 1: 64 ms delay only if PWRTE bit in the Configuration Word 1 is programmed to ‘0’.
2 ms delay if PWRTE = 0 and VREGEN = 1.
TABLE 31-12: RESET, WATCHDOG TIMER, OSCILLATOR START-UP TIMER, POWER-UP TIMER
AND BROWN-OUT RESET PARAMETERS
Standard Operating Conditions (unless otherwise stated)
Param
No.
Sym.
Characteristic
Typ†
Max. Units
2
—
—
s
Conditions
30
TMCL
31
TWDTLP Watchdog Timer
Time-out Period (No Prescaler)
12
16
20
ms
32
TOST
Oscillator Start-up Timer Period
(Note 1)
—
1024
—
Tosc
33*
TPWRT
Power-up Timer Period, PWRTE = 0
40
65
140
ms
34*
TIOZ
I/O high-impedance from MCLR Low
or Watchdog Timer Reset
—
—
2.0
s
35
VBOR
Brown-out Reset Voltage (Note 2)
2.55
1.80
2.70
1.9
2.85
2.05
V
V
36*
VHYST
Brown-out Reset Hysteresis
20
35
60
mV
-40°C to +85°C
TBORDC Brown-out Reset DC Response Time
0
1
35
s
VDD VBOR
37*
MCLR Pulse Width (low)
Min.
VDD = 3.3V-5V
BORV = 0
BORV = 1
*
†
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance
only and are not tested.
Note 1: By design, the Oscillator Start-up (OST) counts the first 1024 cycles, independent of frequency.
2: To ensure these voltage tolerances, VDD and VSS must be capacitively decoupled as close to the device as
possible. 0.1 F and 0.01 F values in parallel are recommended.
2012-2017 Microchip Technology Inc.
DS40001657C-page 355
PIC16LF1824T39A
FIGURE 31-9:
TIMER0 AND TIMER1 EXTERNAL CLOCK TIMINGS
T0CKI
40
41
42
T1CKI
45
46
49
47
TMR0 or
TMR1
TABLE 31-13: TIMER0 AND TIMER1 EXTERNAL CLOCK REQUIREMENTS
Standard Operating Conditions (unless otherwise stated)
Param
No.
Sym.
TT0H
40*
Characteristic
T0CKI High Pulse Width
Min.
No Prescaler
With Prescaler
TT0L
41*
T0CKI Low Pulse Width
No Prescaler
With Prescaler
42*
TT0P
T0CKI Period
45*
TT1H
T1CKI High Synchronous, No Prescaler
Time
Synchronous,
with Prescaler
Asynchronous
TT1L
46*
T1CKI Low
Time
Max.
Units
0.5 TCY + 20
—
—
ns
10
—
—
ns
0.5 TCY + 20
—
—
ns
10
—
—
ns
Greater of:
20 or TCY + 40
N
—
—
ns
0.5 TCY + 20
—
—
ns
15
—
—
ns
ns
30
—
—
Synchronous, No Prescaler
0.5 TCY + 20
—
—
ns
Synchronous, with Prescaler
15
—
—
ns
30
—
—
ns
Greater of:
30 or TCY + 40
N
—
—
ns
Asynchronous
47*
TT1P
T1CKI Input Synchronous
Period
48
F T1
Timer1 Oscillator Input Frequency Range
(oscillator enabled by setting bit T1OSCEN)
49*
TCKEZTMR1 Delay from External Clock Edge to Timer
Increment
Asynchronous
*
†
Typ†
60
—
—
ns
32.4
32.768
33.1
kHz
2 TOSC
—
7 TOSC
—
Conditions
N = prescale value
(2, 4, ..., 256)
N = prescale value
(1, 2, 4, 8)
Timers in Sync
mode
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not
tested.
DS40001657C-page 356
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PIC16LF1824T39A
FIGURE 31-10:
CAPTURE/COMPARE/PWM TIMINGS (CCP)
CCP
(Capture mode)
CC01
CC02
CC03
Note:
Refer to Figure 31-5 for load conditions.
TABLE 31-14: CAPTURE/COMPARE/PWM REQUIREMENTS (CCP)
Standard Operating Conditions (unless otherwise stated)
Param
Sym.
No.
CC01* TccL
Characteristic
CCP Input Low Time
CC02* TccH
CCP Input High Time
CC03* TccP
CCP Input Period
Min.
Max.
Units
No Prescaler
0.5TCY + 20
—
—
ns
With Prescaler
20
—
—
ns
No Prescaler
0.5TCY + 20
—
—
ns
20
—
—
ns
3TCY + 40
N
—
—
ns
With Prescaler
*
†
Typ†
Conditions
N = prescale value
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not
tested.
TABLE 31-15: PIC16LF1824T39A A/D CONVERTER (ADC) CHARACTERISTICS (1, 2, 3)
Standard Operating Conditions (unless otherwise stated)
Operating temperature TA 25°C
Param
Sym.
No.
Characteristic
Min.
Typ†
Max.
AD01
NR
Resolution
—
—
10
AD02
EIL
Integral Error
—
—
±1.7
AD03
EDL
Differential Error
—
—
±1
AD04
EOFF Offset Error
AD05
EGN
AD06
VREF Reference Voltage (Note 4)
AD07
VAIN
Full-Scale Range
AD08
ZAIN
Recommended Impedance of
Analog Voltage Source
*
†
Note 1:
2:
3:
4:
Gain Error
Units
Conditions
bit
LSb VREF = 3.0V
LSb No missing codes
VREF = 3.0V
—
—
±2.5
LSb VREF = 3.0V
—
—
±2.0
LSb VREF = 3.0V
1.8
—
VDD
VSS
—
VREF
V
—
—
10
k
V
VREF = (VREF+ minus VREF-)
Can go higher if external 0.01F capacitor is
present on input pin.
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not
tested.
Total Absolute Error includes integral, differential, offset and gain errors.
The A/D conversion result never decreases with an increase in the input voltage and has no missing codes.
ADC VREF is from external VREF, VDD pin or FVR, whichever is selected as reference input.
ADC Reference Voltage (REF+) is the selected input, VREF+ pin, VDD pin or the FVR Buffer1. When the FVR is selected as
the reference input, the FVR Buffer1 output selection must be 2.048 or 4.096V (ADFVR = 1x).
2012-2017 Microchip Technology Inc.
DS40001657C-page 357
PIC16LF1824T39A
TABLE 31-16: PIC16LF1824T39A A/D CONVERSION REQUIREMENTS
Standard Operating Conditions (unless otherwise stated)
Param
No.
Sym.
Characteristic
AD130* TAD
AD131
TCNV
AD132* TACQ
Min.
Typ†
Max.
Units
Conditions
A/D Clock Period
1.0
—
9.0
s
TOSC-based
A/D Internal RC Oscillator
Period
1.0
2.5
6.0
s
ADCS = 11 (ADRC mode)
Conversion Time (not including
Acquisition Time) (Note 1)
—
11
—
TAD
Set GO/DONE bit to conversion
complete
Acquisition Time
—
5.0
—
s
*
†
These parameters are characterized but not tested.
Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not
tested.
Note 1: The ADRES register may be read on the following TCY cycle.
FIGURE 31-11:
PIC16LF1824T39A A/D CONVERSION TIMING (NORMAL MODE)
BSF ADCON0, GO
AD134
1 TCY
(TOSC/2(1))
AD131
Q4
AD130
A/D CLK
7
A/D Data
6
5
4
3
OLD_DATA
ADRES
1
0
NEW_DATA
1 TCY
ADIF
GO
Sample
2
DONE
AD132
Sampling Stopped
Note 1: If the A/D clock source is selected as RC, a time of TCY is added before the A/D clock starts. This allows the
SLEEP instruction to be executed.
DS40001657C-page 358
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 31-12:
PIC16LF1824T39A A/D CONVERSION TIMING (SLEEP MODE)
BSF ADCON0, GO
(TOSC/2 + TCY(1))
AD134
1 TCY
AD131
Q4
AD130
A/D CLK
7
A/D Data
6
5
3
4
2
1
NEW_DATA
OLD_DATA
ADRES
0
ADIF
1 TCY
GO
DONE
Sample
Sampling Stopped
AD132
Note 1: If the A/D clock source is selected as RC, a time of TCY is added before the A/D clock starts. This allows the
SLEEP instruction to be executed.
TABLE 31-17: COMPARATOR SPECIFICATIONS
Standard Operating Conditions (unless otherwise stated)
Param
No.
Sym.
Characteristics
Min.
Typ.
Max.
Units
CM01
VIOFF
(Note 1)
Input Offset Voltage
—
±7.5
±60
mV
CM02
VICM
Input Common Mode Voltage
0
—
VDD
V
CM03
CMRR
Common Mode Rejection Ratio
—
50
—
dB
Response Time Rising Edge
—
400
800
ns
CM04A
CM04B
CM04C
TRESP
(Note 1)
CM04D
Comments
High-Power mode,
VICM = VDD/2
High-Power mode
Response Time Falling Edge
—
200
400
ns
High-Power mode
Response Time Rising Edge
—
1200
—
ns
Low-Power mode
Response Time Falling Edge
—
550
—
ns
Low-Power mode
Comparator Mode Change to
Output Valid*
—
—
10
s
—
45
—
mV
CM05
TMC2OV
CM06
CHYSTER Comparator Hysteresis (Note 2)
*
Note 1:
2:
These parameters are characterized but not tested.
High-Power mode only.
Comparator Hysteresis is available when the CxHYS bit of the CMxCON0 register is enabled.
2012-2017 Microchip Technology Inc.
CxHYS = 1
DS40001657C-page 359
PIC16LF1824T39A
TABLE 31-18: DIGITAL-TO-ANALOG CONVERTER (DAC) SPECIFICATIONS
Standard Operating Conditions (unless otherwise stated)
Param
No.
Sym.
Characteristics
Min.
Typ.
Max.
Units
DAC01*
CLSB
Step Size
—
VDD/
32
—
V
DAC02*
CACC
Absolute Accuracy
—
—
1/2
LSb
DAC03*
CR
Unit Resistor Value (R)
—
5K
—
DAC04*
CST
Settling Time (Note 1)
—
—
10
s
*
Note 1:
Comments
These parameters are characterized but not tested.
Settling time measured while DACR transitions from ‘0000’ to ‘1111’.
FIGURE 31-13:
USART SYNCHRONOUS TRANSMISSION (MASTER/SLAVE) TIMING
CK
US121
US121
DT
US122
US120
Note:
Refer to Figure 31-4 for load conditions.
TABLE 31-19: USART SYNCHRONOUS TRANSMISSION REQUIREMENTS
Standard Operating Conditions (unless otherwise stated)
Param.
No.
Symbol
Characteristic
Min.
Max.
Units
US120 TCKH2DTV SYNC XMIT (Master and Slave)
Clock high to data-out valid
3.0-5.5V
—
80
ns
1.8-5.5V
—
100
ns
US121 TCKRF
Clock out rise time and fall time
(Master mode)
3.0-5.5V
—
45
ns
1.8-5.5V
—
50
ns
Data-out rise time and fall time
3.0-5.5V
—
45
ns
1.8-5.5V
—
50
ns
US122 TDTRF
FIGURE 31-14:
Conditions
USART SYNCHRONOUS RECEIVE (MASTER/SLAVE) TIMING
CK
US125
DT
US126
Note: Refer to Figure 31-4 for load conditions.
DS40001657C-page 360
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PIC16LF1824T39A
TABLE 31-20: USART SYNCHRONOUS RECEIVE REQUIREMENTS
Standard Operating Conditions (unless otherwise stated)
Param.
No.
Symbol
Min.
Max.
Units
US125 TDTV2CKL SYNC RCV (Master and Slave)
Data-hold before CK (DT hold time)
10
—
ns
US126 TCKL2DTL Data-hold after CK (DT hold time)
15
—
ns
FIGURE 31-15:
Characteristic
Conditions
SPI MASTER MODE TIMING (CKE = 0, SMP = 0)
SSx
SP70
SCKx
(CKP = 0)
SP71
SP72
SP78
SP79
SP79
SP78
SCKx
(CKP = 1)
SP80
bit 6 - - - - - -1
MSb
SDOx
LSb
SP75, SP76
SDIx
MSb In
bit 6 - - - -1
LSb In
SP74
SP73
Note: Refer to Figure 31-4 for load conditions.
2012-2017 Microchip Technology Inc.
DS40001657C-page 361
PIC16LF1824T39A
FIGURE 31-16:
SPI MASTER MODE TIMING (CKE = 1, SMP = 1)
SSx
SP81
SCKx
(CKP = 0)
SP71
SP72
SP79
SP73
SCKx
(CKP = 1)
SP80
MSb
SDOx
SP78
LSb
bit 6 - - - - - -1
SP75, SP76
SDIx
MSb In
bit 6 - - - -1
LSb In
SP74
Note: Refer to Figure 31-4 for load conditions.
FIGURE 31-17:
SPI SLAVE MODE TIMING (CKE = 0)
SSx
SP70
SCKx
(CKP = 0)
SP83
SP71
SP72
SP78
SP79
SP79
SP78
SCKx
(CKP = 1)
SP80
SDOx
MSb
bit 6 - - - - - -1
LSb
SP77
SP75, SP76
SDIx
MSb In
bit 6 - - - -1
LSb In
SP74
SP73
Note: Refer to Figure 31-4 for load conditions.
DS40001657C-page 362
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 31-18:
SSx
SPI SLAVE MODE TIMING (CKE = 1)
SP82
SP70
SP83
SCKx
(CKP = 0)
SP71
SP72
SCKx
(CKP = 1)
SP80
SDOx
MSb
bit 6 - - - - - -1
LSb
SP77
SP75, SP76
SDIx
MSb In
bit 6 - - - -1
LSb In
SP74
Note: Refer to Figure 31-4 for load conditions.
2012-2017 Microchip Technology Inc.
DS40001657C-page 363
PIC16LF1824T39A
TABLE 31-21: SPI MODE REQUIREMENTS
Param
No.
Symbol
Characteristic
Min.
Typ†
Max. Units Conditions
SP70* TSSL2SCH, SSx to SCKx or SCKx input
TSSL2SCL
TCY
—
—
ns
SP71* TSCH
SCKx input high time (Slave mode)
TCY + 20
—
—
ns
SP72* TSCL
SCKx input low time (Slave mode)
TCY + 20
—
—
ns
SP73* TDIV2SCH, Setup time of SDIx data input to SCKx edge
TDIV2SCL
100
—
—
ns
SP74* TSCH2DIL,
TSCL2DIL
Hold time of SDIx data input to SCKx edge
100
—
—
ns
SP75* TDOR
SDO data output rise time
3.0-5.5V
—
10
25
ns
1.8-5.5V
—
25
50
ns
SP76* TDOF
SDOx data output fall time
—
10
25
ns
SP77* TSSH2DOZ SSx to SDOx output high-impedance
10
—
50
ns
SP78* TSCR
SCKx output rise time
(Master mode)
—
10
25
ns
—
25
50
ns
SP79* TSCF
SCKx output fall time (Master mode)
—
10
25
ns
SP80* TSCH2DOV, SDOx data output valid after
TSCL2DOV SCKx edge
3.0-5.5V
1.8-5.5V
3.0-5.5V
—
—
50
ns
1.8-5.5V
—
—
145
ns
SP81* TDOV2SCH, SDOx data output setup to SCKx edge
TDOV2SCL
Tcy
—
—
ns
SP82* TSSL2DOV
—
—
50
ns
1.5TCY + 40
—
—
ns
SDOx data output valid after SS edge
SP83* TSCH2SSH, SSx after SCKx edge
TSCL2SSH
* These parameters are characterized but not tested.
† Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance
only and are not tested.
FIGURE 31-19:
I2C™ BUS START/STOP BITS TIMING
SCLx
SP93
SP91
SP90
SP92
SDAx
Start
Condition
Stop
Condition
Note: Refer to Figure 31-4 for load conditions.
DS40001657C-page 364
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PIC16LF1824T39A
TABLE 31-22: I2C™ BUS START/STOP BITS REQUIREMENTS
Param
No.
Symbol
SP90* TSU:STA
SP91* THD:STA
SP92* TSU:STO
THD:STO
SP93
*
Characteristic
Min.
Typ
Max.
Units
ns
Only relevant for Repeated
Start Condition
ns
After this period, the first clock
pulse is generated
Start condition
100 kHz mode
4700
—
—
Setup time
400 kHz mode
600
—
—
Start condition
100 kHz mode
4000
—
—
Hold time
400 kHz mode
600
—
—
Stop condition
100 kHz mode
4700
—
—
Setup time
400 kHz mode
600
10
25
Stop condition
100 kHz mode
4000
25
50
Hold time
400 kHz mode
600
10
25
Conditions
ns
ns
These parameters are characterized but not tested.
FIGURE 31-20:
I2C™ BUS DATA TIMING
SP103
SCLx
SP100
SP90
SP102
SP101
SP106
SP107
SP91
SDAx
In
SP92
SP110
SP109
SP109
SDAx
Out
Note: Refer to Figure 31-4 for load conditions.
2012-2017 Microchip Technology Inc.
DS40001657C-page 365
PIC16LF1824T39A
TABLE 31-23: I2C™ BUS DATA REQUIREMENTS
Param.
No.
Symbol
SP100* THIGH
SP101* TLOW
SP102* TR
SP103* TF
SP106* THD:DAT
SP107* TSU:DAT
SP109* TAA
SP110*
SP111
*
Note 1:
2:
TBUF
CB
Characteristic
Min.
Max.
Units
Conditions
100 kHz mode
4.0
—
s
Device must operate at a
minimum of 1.5 MHz
400 kHz mode
0.6
—
s
Device must operate at a
minimum of 10 MHz
SSPx module
1.5TCY
—
—
100 kHz mode
4.7
—
s
Device must operate at a
minimum of 1.5 MHz
400 kHz mode
1.3
—
s
Device must operate at a
minimum of 10 MHz
SSPx module
1.5TCY
—
—
100 kHz mode
—
1000
ns
400 kHz mode
20 + 0.1CB
300
ns
SDAx and SCLx fall 100 kHz mode
time
400 kHz mode
—
250
ns
20 + 0.1CB
250
ns
Data input hold time 100 kHz mode
0
—
ns
400 kHz mode
0
0.9
s
Data input setup
time
100 kHz mode
250
—
ns
400 kHz mode
100
—
ns
Output valid from
clock
100 kHz mode
—
3500
ns
400 kHz mode
—
—
ns
Bus free time
100 kHz mode
4.7
—
s
400 kHz mode
1.3
—
s
—
400
pF
Clock high time
Clock low time
SDAx and SCLx
rise time
Bus capacitive loading
CB is specified to be from
10-400 pF
CB is specified to be from
10-400 pF
(Note 2)
(Note 1)
Time the bus must be free
before a new transmission
can start
These parameters are characterized but not tested.
As a transmitter, the device must provide this internal minimum delay time to bridge the undefined region
(min. 300 ns) of the falling edge of SCLx to avoid unintended generation of Start or Stop conditions.
A Fast mode (400 kHz) I2C™ bus device can be used in a Standard mode (100 kHz) I2C bus system, but
the requirement TSU:DAT 250 ns must then be met. This will automatically be the case if the device does
not stretch the low period of the SCLx signal. If such a device does stretch the low period of the SCLx
signal, it must output the next data bit to the SDAx line TR max. + TSU:DAT = 1000 + 250 = 1250 ns
(according to the Standard mode I2C bus specification), before the SCLx line is released.
DS40001657C-page 366
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
TABLE 31-24: CAP SENSE OSCILLATOR SPECIFICATIONS
Param.
No.
Symbol
CS01*
ISRC
CS02*
ISNK
Characteristic
Current Source
Current Sink
Min.
Typ†
Max.
Units
High
—
-8
—
A
Medium
—
-1.5
—
A
Low
—
-0.3
—
A
High
—
7.5
—
A
Medium
—
1.5
—
A
—
0.25
—
A
—
0.8
—
V
Low
CS03*
VCTH
Cap Threshold
CS04*
VCTL
Cap Threshold
CS05*
VCHYST Cap Hysteresis
(VCTH - VCTL)
—
0.4
—
V
High
—
525
—
mV
Medium
—
375
—
mV
Low
—
300
—
mV
Conditions
* These parameters are characterized but not tested.
† Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance
only and are not tested.
FIGURE 31-21:
CAP SENSE OSCILLATOR
VCTH
VCTL
ISRC
Enabled
2012-2017 Microchip Technology Inc.
ISNK
Enabled
DS40001657C-page 367
PIC16LF1824T39A
32.0
DC AND AC CHARACTERISTICS GRAPHS AND CHARTS
The graphs and tables provided in this section are for design guidance and are not tested.
In some graphs or tables, the data presented are outside specified operating range (i.e., outside specified VDD
range). This is for information only and devices are ensured to operate properly only within the specified range.
Note:
The graphs and tables provided following this note are a statistical summary based on a limited number of
samples and are provided for informational purposes only. The performance characteristics listed herein
are not tested or guaranteed. In some graphs or tables, the data presented may be outside the specified
operating range (e.g., outside specified power supply range) and therefore, outside the warranted range.
“Typical” represents the mean of the distribution at 25C. “MAXIMUM”, “Max.”, “MINIMUM” or “Min.” represents
(mean + 3) or (mean - 3) respectively, where is a standard deviation, over each temperature range.
DS40001657C-page 368
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-1:
IDD, LP OSCILLATOR MODE (FOSC = 32 kHz)
12
Max: 85°C + 3ı
Typical: 25°C
10
Max.
IDD (µA)
8
Typical
6
4
2
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
FIGURE 32-2:
IDD TYPICAL, XT AND EXTRC OSCILLATOR
400
4 MHz XT
Typical: 25°C
350
4 MHz EXTRC
300
IDD (µA)
250
200
1 MHz XT
150
100
50
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
2012-2017 Microchip Technology Inc.
DS40001657C-page 369
PIC16LF1824T39A
FIGURE 32-3:
IDD MAXIMUM, XT AND EXTRC OSCILLATOR
450
Max: 85°C + 3ı
400
4 MHz XT
350
4 MHz EXTRC
IDD (µA)
300
250
200
1 MHz XT
150
100
50
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
FIGURE 32-4:
IDD TYPICAL, EC OSCILLATOR, MEDIUM-POWER MODE
350
4 MHz
Typical: 25°C
300
IDD (µA)
250
200
150
1 MHz
100
50
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
DS40001657C-page 370
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-5:
IDD MAXIMUM, EC OSCILLATOR, MEDIUM-POWER MODE
400
Max: 85°C + 3ı
350
4 MHz
300
IDD (µA)
250
200
150
1 MHz
100
50
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
FIGURE 32-6:
IDD TYPICAL, EC OSCILLATOR, MEDIUM-POWER MODE
450
4 MHz
400
Typical: 25°C
350
IDD (µA)
300
250
200
1 MHz
150
100
50
0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
VDD (V)
2012-2017 Microchip Technology Inc.
DS40001657C-page 371
PIC16LF1824T39A
FIGURE 32-7:
IDD, LFINTOSC MODE (FOSC = 31 kHz)
12
Max.
10
Typical
IDD (µA)
8
6
4
Max: 85°C + 3ı
Typical: 25°C
2
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
3.2
3.4
3.6
3.8
VDD (V)
IDD, MFINTOSC MODE (FOSC = 500 kHz)
FIGURE 32-8:
160
Max.
Max: 85°C + 3ı
Typical: 25°C
150
Typical
IDD (µA)
140
130
120
110
100
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
VDD (V)
DS40001657C-page 372
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-9:
IDD TYPICAL, HFINTOSC MODE
3.5
32 MHz (PLL)
Typical: 25°C
3.0
IDD (mA)
2.5
2.0
16 MHz
1.5
8 MHz
1.0
0.5
0.0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
3.6
3.8
VDD (V)
FIGURE 32-10:
IDD MAXIMUM, HFINTOSC MODE
3.5
32 MHz (PLL)
Max: 85°C + 3ı
3.0
IDD (mA)
2.5
2.0
16 MHz
1.5
8 MHz
1.0
0.5
0.0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
VDD (V)
2012-2017 Microchip Technology Inc.
DS40001657C-page 373
PIC16LF1824T39A
FIGURE 32-11:
IDD, HS OSCILLATOR, 32 MHz (8 MHz + 4xPLL)
3.5
Max
3.0
Typical: 25°C
Typical
IDD (mA)
2.5
2.0
1.5
1.0
0.5
0.0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
FIGURE 32-12:
IPD BASE, LOW-POWER SLEEP MODE
0.40
0.35
Max.
IPD (µA)
0.30
Max: 85°C + 3ı
Typical: 25°C
0.25
0.20
0.15
0.10
Typical
0.05
0.00
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
VDD (V)
DS40001657C-page 374
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-13:
IPD, WATCHDOG TIMER (WDT)
0.9
Max.
Max: 85°C + 3a
Typical: 25°C
0.8
0.7
IPD (µA)
0.6
0.5
0.4
Typical
0.3
0.2
0.1
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
FIGURE 32-14:
IPD, FIXED VOLTAGE REFERENCE (FVR)
18
16
Max.
14
12
IPD (µA
A)
Typical
10
8
6
4
Max: 85°C + 3ı
yp
Typical:
25°C
2
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
2012-2017 Microchip Technology Inc.
DS40001657C-page 375
PIC16LF1824T39A
FIGURE 32-15:
IPD, BROWN-OUT RESET (BOR)
11
Max.
Max: 85°C + 3ı
Typical: 25°C
10
9
IPD (µA)
8
7
Typical
6
5
4
18
1.8
2
0
2.0
2
2
2.2
2
4
2.4
2
6
2.6
2
8
2.8
3
0
3.0
3
2
3.2
3
4
3.4
3
6
3.6
3
8
3.8
VDD (V)
FIGURE 32-16:
IPD, TIMER1 OSCILLATOR (FOSC = 32 kHz)
6.0
Max: 85°C + 3ı
Typical: 25°C
5.0
Max.
IPD (µA
A)
4.0
3.0
Typical
2.0
1.0
0.0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
DS40001657C-page 376
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-17:
IPD, CAPACITIVE SENSING (CPS) MODULE, LOW-CURRENT RANGE,
CPSRM = 0
6
Max: 85°C + 3
M
3ı
Typical: 25°C
5
Max.
IPD (µA
A)
4
Typical
yp
3
2
1
0
16
1.6
1
8
1.8
2
0
2.0
2
2
2.2
2
4
2.4
2
6
2.6
2
8
2.8
3
0
3.0
3
2
3.2
3
4
3.4
3
6
3.6
3
8
3.8
VDD (V)
FIGURE 32-18:
IPD, CAPACITIVE SENSING (CPS) MODULE, MEDIUM-CURRENT RANGE,
CPSRM = 0
10
Max
Max.
Max: 85°C + 3ı
Typical: 25°C
9
8
7
Typical
IPD
D (µA)
6
5
4
3
2
1
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
VDD (V)
2012-2017 Microchip Technology Inc.
DS40001657C-page 377
PIC16LF1824T39A
FIGURE 32-19:
IPD, CAPACITIVE SENSING (CPS) MODULE, HIGH-CURRENT RANGE,
CPSRM = 0
40
Max.
Max: 85°C + 3
M
3ı
Typical: 25°C
35
30
Typical
IPD (µA
A)
25
20
15
10
5
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
3.8
3.4
3.6
3.8
VDD (V)
IPD, COMPARATOR, LOW-POWER MODE (CxSP = 0)
FIGURE 32-20:
10
9
Max.
8
7
IPD (µA)
Typical
6
5
4
3
2
Max: 85°C + 3ı
Typical: 25°C
1
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
VDD (V)
DS40001657C-page 378
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-21:
IPD, COMPARATOR, NORMAL-POWER MODE (CxSP = 1)
30
Max.
25
IPD (µA
A)
20
Typical
15
10
Max: 85°C + 3ı
Typical: 25°C
5
0
16
1.6
1
8
1.8
2
0
2.0
2
2
2.2
2
4
2.4
2
6
2.6
2
8
2.8
3
0
3.0
3
2
3.2
3
4
3.4
3
6
3.6
3
8
3.8
VDD (V)
FIGURE 32-22:
VOH vs. IOH OVER TEMPERATURE (VDD = 3.0V)
3.5
Graph represents
3ı Limits
3.0
VOH (V)
2.5
2.0
1.5
125°C
Typical
1.0
-40°C
0.5
0.0
-14
-12
-10
-8
-6
-4
-2
0
IOH (mA)
2012-2017 Microchip Technology Inc.
DS40001657C-page 379
PIC16LF1824T39A
FIGURE 32-23:
VOL vs. IOL OVER TEMPERATURE (VDD = 3.0V)
3.0
Graph represents
3ı Limits
2.5
VOL (V)
2.0
-40°C
Typical
1.5
125°C
1.0
0.5
0.0
0
5
10
15
20
25
30
IOL (mA)
FIGURE 32-24:
VOH vs. IOH OVER TEMPERATURE (VDD = 1.8V)
2.0
Graph represents
3ı Limits
1.8
1.6
VOH (V)
1.4
1.2
125°C
1.0
0.8
Typical
-40°C
0.6
0.4
0.2
0.0
-4
-3.5
-3
-2.5
-2
-1.5
-1
-0.5
0
IOH (mA)
DS40001657C-page 380
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-25:
VOL vs. IOL OVER TEMPERATURE (VDD = 1.8V)
1.8
Graph represents
3ı Limits
1.6
1.4
VOL (V)
1.2
1.0
125°C
Typical
0.8
-40°C
0.6
0.4
0.2
0.0
0
1
2
3
4
5
6
7
8
9
10
IOL (mA)
FIGURE 32-26:
POR RELEASE VOLTAGE
1.70
1.68
Max.
1.66
Voltage (V)
1.64
Typical
1.62
Min.
1.60
1.58
1.56
Max: Typical + 3ı
Typical: 25°C
Min: Typical - 3ı
1.54
1.52
1.50
-40
-20
0
20
40
60
80
100
120
Temperature (°C)
2012-2017 Microchip Technology Inc.
DS40001657C-page 381
PIC16LF1824T39A
FIGURE 32-27:
POR REARM VOLTAGE
1.54
Max: Typical + 3ı
Typical: 25°C
Min: Typical - 3ı
1.52
1.50
Max.
Voltage (V)
1.48
1.46
1.44
Typical
1.42
1.40
Min.
1.38
1.36
1.34
-40
-20
0
20
40
60
80
100
120
Temperature (°C)
FIGURE 32-28:
BROWN-OUT RESET VOLTAGE, BORV = 1
2.10
Max: Typical + 3ı
Min: Typical - 3ı
2.05
2.00
Voltage (V)
Max.
1.95
1.90
Min.
1.85
1.80
1.75
1.70
-60
-40
-20
0
20
40
60
80
100
120
140
Temperature (°C)
DS40001657C-page 382
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-29:
BROWN-OUT RESET HYSTERESIS, BORV = 1
70
Max.
60
Voltage (mV)
50
Typical
40
30
Min.
20
Max: Typical + 3ı
Typical: 25°C
Min: Typical - 3ı
10
0
-60
-40
-20
0
20
40
60
80
100
120
140
Temperature (°C)
FIGURE 32-30:
BROWN-OUT RESET VOLTAGE, BORV = 0
2.90
2.85
Max: Typical + 3ı
Min: Typical - 3ı
2.80
Max.
Voltage (V)
2.75
2.70
2.65
Min.
2.60
2.55
2.50
2.45
2.40
-60
-40
-20
0
20
40
60
80
100
120
140
Temperature (°C)
2012-2017 Microchip Technology Inc.
DS40001657C-page 383
PIC16LF1824T39A
FIGURE 32-31:
BROWN-OUT RESET HYSTERESIS, BORV = 0
90
80
Max.
70
Voltage (mV)
60
50
Typical
40
30
20
Max: Typical + 3ı
Typical: 25°C
Min: Typical - 3ı
Min.
10
0
-60
-40
-20
0
20
40
60
80
100
120
140
Temperature (°C)
FIGURE 32-32:
WDT TIME-OUT PERIOD
24
22
Max.
Time (mS)
20
18
Typical
16
14
Min.
Max: Typical + 3ı (-40°C to +125°C)
Typical: statistical mean @ 25°C
Min: Typical - 3ı (-40°C to +125°C)
12
10
1.5
2
2.5
3
3.5
4
4.5
5
5.5
6
Voltage (V)
DS40001657C-page 384
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-33:
PWRT PERIOD
110
100
Max.
Time (mS)
90
80
Typical
70
Min.
60
Max: Typical + 3ı (-40°C to +125°C)
Typical: statistical mean @ 25°C
Min: Typical - 3ı (-40°C to +125°C)
50
40
1.5
2
2.5
3
3.5
4
4.5
5
5.5
6
Voltage (V)
FIGURE 32-34:
COMPARATOR HYSTERESIS, NORMAL-POWER MODE (CxSP = 1, CxHYS = 1)
80
70
Max.
Hysteresis (mV)
60
Typical
50
40
Min.
30
20
Max: Typical + 3ı
Typical: 25°C
Min: Typical - 3ı
10
0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
VDD (V)
2012-2017 Microchip Technology Inc.
DS40001657C-page 385
PIC16LF1824T39A
FIGURE 32-35:
COMPARATOR HYSTERESIS, LOW-POWER MODE (CxSP = 0, CxHYS = 1)
16
14
Max.
Hysteresis (mV)
12
Typical
10
8
Min.
6
4
Max: Typical + 3ı
Typical: 25°C
Min: Typical - 3ı
2
0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
VDD (V)
FIGURE 32-36:
COMPARATOR RESPONSE TIME, NORMAL-POWER MODE (CxSP = 1)
350
300
Time (nS)
250
Max.
200
Typical
150
100
Max: Typical + 3ı
Typical: 25°C
50
0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
VDD (V)
DS40001657C-page 386
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
FIGURE 32-37:
COMPARATOR RESPONSE TIME OVER TEMPERATURE,
NORMAL-POWER MODE (CxSP = 1)
400
Graph represents
3ı Limits
350
Time (nS)
300
250
125°C
200
150
Typical
100
-40°C
50
0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
VDD (V)
2012-2017 Microchip Technology Inc.
DS40001657C-page 387
PIC16LF1824T39A
33.0
DEVELOPMENT SUPPORT
The PIC® microcontrollers (MCU) and dsPIC® digital
signal controllers (DSC) are supported with a full range
of software and hardware development tools:
• Integrated Development Environment
- MPLAB® X IDE Software
• Compilers/Assemblers/Linkers
- MPLAB XC Compiler
- MPASMTM Assembler
- MPLINKTM Object Linker/
MPLIBTM Object Librarian
- MPLAB Assembler/Linker/Librarian for
Various Device Families
• Simulators
- MPLAB X SIM Software Simulator
• Emulators
- MPLAB REAL ICE™ In-Circuit Emulator
• In-Circuit Debuggers/Programmers
- MPLAB ICD 3
- PICkit™ 3
• Device Programmers
- MPLAB PM3 Device Programmer
• Low-Cost Demonstration/Development Boards,
Evaluation Kits and Starter Kits
• Third-party development tools
33.1
MPLAB X Integrated Development
Environment Software
The MPLAB X IDE is a single, unified graphical user
interface for Microchip and third-party software, and
hardware development tool that runs on Windows®,
Linux and Mac OS® X. Based on the NetBeans IDE,
MPLAB X IDE is an entirely new IDE with a host of free
software components and plug-ins for highperformance application development and debugging.
Moving between tools and upgrading from software
simulators to hardware debugging and programming
tools is simple with the seamless user interface.
With complete project management, visual call graphs,
a configurable watch window and a feature-rich editor
that includes code completion and context menus,
MPLAB X IDE is flexible and friendly enough for new
users. With the ability to support multiple tools on
multiple projects with simultaneous debugging, MPLAB
X IDE is also suitable for the needs of experienced
users.
Feature-Rich Editor:
• Color syntax highlighting
• Smart code completion makes suggestions and
provides hints as you type
• Automatic code formatting based on user-defined
rules
• Live parsing
User-Friendly, Customizable Interface:
• Fully customizable interface: toolbars, toolbar
buttons, windows, window placement, etc.
• Call graph window
Project-Based Workspaces:
•
•
•
•
Multiple projects
Multiple tools
Multiple configurations
Simultaneous debugging sessions
File History and Bug Tracking:
• Local file history feature
• Built-in support for Bugzilla issue tracker
DS40001657C-page 388
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PIC16LF1824T39A
33.2
MPLAB XC Compilers
The MPLAB XC Compilers are complete ANSI C
compilers for all of Microchip’s 8, 16, and 32-bit MCU
and DSC devices. These compilers provide powerful
integration capabilities, superior code optimization and
ease of use. MPLAB XC Compilers run on Windows,
Linux or MAC OS X.
For easy source level debugging, the compilers provide
debug information that is optimized to the MPLAB X
IDE.
The free MPLAB XC Compiler editions support all
devices and commands, with no time or memory
restrictions, and offer sufficient code optimization for
most applications.
MPLAB XC Compilers include an assembler, linker and
utilities. The assembler generates relocatable object
files that can then be archived or linked with other relocatable object files and archives to create an executable file. MPLAB XC Compiler uses the assembler to
produce its object file. Notable features of the assembler include:
•
•
•
•
•
•
Support for the entire device instruction set
Support for fixed-point and floating-point data
Command-line interface
Rich directive set
Flexible macro language
MPLAB X IDE compatibility
33.3
MPASM Assembler
The MPASM Assembler is a full-featured, universal
macro assembler for PIC10/12/16/18 MCUs.
The MPASM Assembler generates relocatable object
files for the MPLINK Object Linker, Intel® standard HEX
files, MAP files to detail memory usage and symbol
reference, absolute LST files that contain source lines
and generated machine code, and COFF files for
debugging.
The MPASM Assembler features include:
33.4
MPLINK Object Linker/
MPLIB Object Librarian
The MPLINK Object Linker combines relocatable
objects created by the MPASM Assembler. It can link
relocatable objects from precompiled libraries, using
directives from a linker script.
The MPLIB Object Librarian manages the creation and
modification of library files of precompiled code. When
a routine from a library is called from a source file, only
the modules that contain that routine will be linked in
with the application. This allows large libraries to be
used efficiently in many different applications.
The object linker/library features include:
• Efficient linking of single libraries instead of many
smaller files
• Enhanced code maintainability by grouping
related modules together
• Flexible creation of libraries with easy module
listing, replacement, deletion and extraction
33.5
MPLAB Assembler, Linker and
Librarian for Various Device
Families
MPLAB Assembler produces relocatable machine
code from symbolic assembly language for PIC24,
PIC32 and dsPIC DSC devices. MPLAB XC Compiler
uses the assembler to produce its object file. The
assembler generates relocatable object files that can
then be archived or linked with other relocatable object
files and archives to create an executable file. Notable
features of the assembler include:
•
•
•
•
•
•
Support for the entire device instruction set
Support for fixed-point and floating-point data
Command-line interface
Rich directive set
Flexible macro language
MPLAB X IDE compatibility
• Integration into MPLAB X IDE projects
• User-defined macros to streamline
assembly code
• Conditional assembly for multipurpose
source files
• Directives that allow complete control over the
assembly process
2012-2017 Microchip Technology Inc.
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33.6
MPLAB X SIM Software Simulator
The MPLAB X SIM Software Simulator allows code
development in a PC-hosted environment by simulating the PIC MCUs and dsPIC DSCs on an instruction
level. On any given instruction, the data areas can be
examined or modified and stimuli can be applied from
a comprehensive stimulus controller. Registers can be
logged to files for further run-time analysis. The trace
buffer and logic analyzer display extend the power of
the simulator to record and track program execution,
actions on I/O, most peripherals and internal registers.
The MPLAB X SIM Software Simulator fully supports
symbolic debugging using the MPLAB XC Compilers,
and the MPASM and MPLAB Assemblers. The software simulator offers the flexibility to develop and
debug code outside of the hardware laboratory environment, making it an excellent, economical software
development tool.
33.7
MPLAB REAL ICE In-Circuit
Emulator System
The MPLAB REAL ICE In-Circuit Emulator System is
Microchip’s next generation high-speed emulator for
Microchip Flash DSC and MCU devices. It debugs and
programs all 8, 16 and 32-bit MCU, and DSC devices
with the easy-to-use, powerful graphical user interface of
the MPLAB X IDE.
The emulator is connected to the design engineer’s
PC using a high-speed USB 2.0 interface and is
connected to the target with either a connector
compatible with in-circuit debugger systems (RJ-11)
or with the new high-speed, noise tolerant, LowVoltage Differential Signal (LVDS) interconnection
(CAT5).
The emulator is field upgradable through future firmware
downloads in MPLAB X IDE. MPLAB REAL ICE offers
significant advantages over competitive emulators
including full-speed emulation, run-time variable
watches, trace analysis, complex breakpoints, logic
probes, a ruggedized probe interface and long (up to
three meters) interconnection cables.
DS40001657C-page 390
33.8
MPLAB ICD 3 In-Circuit Debugger
System
The MPLAB ICD 3 In-Circuit Debugger System is
Microchip’s most cost-effective, high-speed hardware
debugger/programmer for Microchip Flash DSC and
MCU devices. It debugs and programs PIC Flash
microcontrollers and dsPIC DSCs with the powerful,
yet easy-to-use graphical user interface of the MPLAB
IDE.
The MPLAB ICD 3 In-Circuit Debugger probe is
connected to the design engineer’s PC using a highspeed USB 2.0 interface and is connected to the target
with a connector compatible with the MPLAB ICD 2 or
MPLAB REAL ICE systems (RJ-11). MPLAB ICD 3
supports all MPLAB ICD 2 headers.
33.9
PICkit 3 In-Circuit Debugger/
Programmer
The MPLAB PICkit 3 allows debugging and programming of PIC and dsPIC Flash microcontrollers at a most
affordable price point using the powerful graphical user
interface of the MPLAB IDE. The MPLAB PICkit 3 is
connected to the design engineer’s PC using a fullspeed USB interface and can be connected to the target via a Microchip debug (RJ-11) connector (compatible with MPLAB ICD 3 and MPLAB REAL ICE). The
connector uses two device I/O pins and the Reset line
to implement in-circuit debugging and In-Circuit Serial
Programming™ (ICSP™).
33.10 MPLAB PM3 Device Programmer
The MPLAB PM3 Device Programmer is a universal,
CE compliant device programmer with programmable
voltage verification at VDDMIN and VDDMAX for
maximum reliability. It features a large LCD display
(128 x 64) for menus and error messages, and a modular, detachable socket assembly to support various
package types. The ICSP cable assembly is included
as a standard item. In Stand-Alone mode, the MPLAB
PM3 Device Programmer can read, verify and program
PIC devices without a PC connection. It can also set
code protection in this mode. The MPLAB PM3
connects to the host PC via an RS-232 or USB cable.
The MPLAB PM3 has high-speed communications and
optimized algorithms for quick programming of large
memory devices, and incorporates an MMC card for file
storage and data applications.
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
33.11 Demonstration/Development
Boards, Evaluation Kits, and
Starter Kits
A wide variety of demonstration, development and
evaluation boards for various PIC MCUs and dsPIC
DSCs allows quick application development on fully
functional systems. Most boards include prototyping
areas for adding custom circuitry and provide application firmware and source code for examination and
modification.
The boards support a variety of features, including LEDs,
temperature sensors, switches, speakers, RS-232
interfaces, LCD displays, potentiometers and additional
EEPROM memory.
33.12 Third-Party Development Tools
Microchip also offers a great collection of tools from
third-party vendors. These tools are carefully selected
to offer good value and unique functionality.
• Device Programmers and Gang Programmers
from companies, such as SoftLog and CCS
• Software Tools from companies, such as Gimpel
and Trace Systems
• Protocol Analyzers from companies, such as
Saleae and Total Phase
• Demonstration Boards from companies, such as
MikroElektronika, Digilent® and Olimex
• Embedded Ethernet Solutions from companies,
such as EZ Web Lynx, WIZnet and IPLogika®
The demonstration and development boards can be
used in teaching environments, for prototyping custom
circuits and for learning about various microcontroller
applications.
In addition to the PICDEM™ and dsPICDEM™
demonstration/development board series of circuits,
Microchip has a line of evaluation kits and demonstration software for analog filter design, KEELOQ® security
ICs, CAN, IrDA®, PowerSmart battery management,
SEEVAL® evaluation system, Sigma-Delta ADC, flow
rate sensing, plus many more.
Also available are starter kits that contain everything
needed to experience the specified device. This usually
includes a single application and debug capability, all
on one board.
Check the Microchip web page (www.microchip.com)
for the complete list of demonstration, development
and evaluation kits.
2012-2017 Microchip Technology Inc.
DS40001657C-page 391
PIC16LF1824T39A
34.0
PACKAGING INFORMATION
34.1
Package Marking Information
20-Lead TSSOP
Example
1824T39A
E/ST e3 123
1220
Legend: XX...X
Y
YY
WW
NNN
e3
*
Note:
*
Customer-specific information
Year code (last digit of calendar year)
Year code (last 2 digits of calendar year)
Week code (week of January 1 is week ‘01’)
Alphanumeric traceability code
Pb-free JEDEC® designator for Matte Tin (Sn)
This package is Pb-free. The Pb-free JEDEC designator ( e3 )
can be found on the outer packaging for this package.
In the event the full Microchip part number cannot be marked on one line, it will
be carried over to the next line, thus limiting the number of available
characters for customer-specific information.
Standard PICmicro® device marking consists of Microchip part number, year code, week code and
traceability code. For PICmicro device marking beyond this, certain price adders apply. Please check
with your Microchip Sales Office. For QTP devices, any special marking adders are included in QTP
price.
DS40001657C-page 392
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
34.2
Package Details
The following sections give the technical details of the packages.
2012-2017 Microchip Technology Inc.
DS40001657C-page 393
PIC16LF1824T39A
DS40001657C-page 394
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
Note:
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
2012-2017 Microchip Technology Inc.
DS40001657C-page 395
PIC16LF1824T39A
APPENDIX A:
DATA SHEET
REVISION HISTORY
Revision A (10/2012)
Initial release of this document.
Revision B (10/2014)
Updated Table 28-3; Updated the Electrical Specifications section; Updated the Packaging Details section;
Other minor corrections.
Revision C (10/2017)
Removed the Preliminary conditional text.
DS40001657C-page 396
2012-2017 Microchip Technology Inc.
PIC16LF1824T39A
THE MICROCHIP WEB SITE
CUSTOMER SUPPORT
Microchip provides online support via our WWW site at
www.microchip.com. This web site is used as a means
to make files and information easily available to
customers. Accessible by using your favorite Internet
browser, the web site contains the following
information:
Users of Microchip products can receive assistance
through several channels:
• Product Support – Data sheets and errata,
application notes and sample programs, design
resources, user’s guides and hardware support
documents, latest software releases and archived
software
• General Technical Support – Frequently Asked
Questions (FAQ), technical support requests,
online discussion groups, Microchip consultant
program member listing
• Business of Microchip – Product selector and
ordering guides, latest Microchip press releases,
listing of seminars and events, listings of
Microchip sales offices, distributors and factory
representatives
•
•
•
•
Distributor or Representative
Local Sales Office
Field Application Engineer (FAE)
Technical Support
Customers
should
contact
their
distributor,
representative or Field Application Engineer (FAE) for
support. Local sales offices are also available to help
customers. A listing of sales offices and locations is
included in the back of this document.
Technical support is available through the web site
at: http://microchip.com/support
CUSTOMER CHANGE NOTIFICATION
SERVICE
Microchip’s customer notification service helps keep
customers current on Microchip products. Subscribers
will receive e-mail notification whenever there are
changes, updates, revisions or errata related to a
specified product family or development tool of interest.
To register, access the Microchip web site at
www.microchip.com. Under “Support”, click on
“Customer Change Notification” and follow the
registration instructions.
2012-2017 Microchip Technology Inc.
DS40001657C-page 397
PIC16LF1824T39A
PRODUCT IDENTIFICATION SYSTEM
To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.
PART NO.
[X](1)
Device
Tape and Reel
Option
X
/XX
XXX
Temperature
Range
Package
Pattern
-
Device:
PIC16LF1824T39A
Tape and Reel
Option:
Blank = Standard packaging (tube or tray)
T = Tape and Reel(1)
Temperature
Range:
I
E
Package:(2)
ST
Pattern:
QTP, SQTP, Code or Special Requirements
(blank otherwise)
DS40001657C-page 398
= -40C to +85C
= -40C to +125C
=
Examples:
a)
PIC16LF1824T39A - I/ST 301 = Industrial
temp., TSSOP package, QTP pattern #301.
(Industrial)
(Extended)
TSSOP, 20 lead
Note 1:
Tape and Reel identifier only appears in the
catalog part number description. This
identifier is used for ordering purposes and
is not printed on the device package. Check
with your Microchip Sales Office for package
availability with the Tape and Reel option.
2:
For other small form-factor package
availability and marking information, please
visit www.microchip.com/packaging or
contact your local sales office.
2012-2017 Microchip Technology Inc.
Note the following details of the code protection feature on Microchip devices:
•
Microchip products meet the specification contained in their particular Microchip Data Sheet.
•
Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the
intended manner and under normal conditions.
•
There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our
knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data
Sheets. Most likely, the person doing so is engaged in theft of intellectual property.
•
Microchip is willing to work with the customer who is concerned about the integrity of their code.
•
Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not
mean that we are guaranteeing the product as “unbreakable.”
Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our
products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts
allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.
Information contained in this publication regarding device
applications and the like is provided only for your convenience
and may be superseded by updates. It is your responsibility to
ensure that your application meets with your specifications.
MICROCHIP MAKES NO REPRESENTATIONS OR
WARRANTIES OF ANY KIND WHETHER EXPRESS OR
IMPLIED, WRITTEN OR ORAL, STATUTORY OR
OTHERWISE, RELATED TO THE INFORMATION,
INCLUDING BUT NOT LIMITED TO ITS CONDITION,
QUALITY, PERFORMANCE, MERCHANTABILITY OR
FITNESS FOR PURPOSE. Microchip disclaims all liability
arising from this information and its use. Use of Microchip
devices in life support and/or safety applications is entirely at
the buyer’s risk, and the buyer agrees to defend, indemnify and
hold harmless Microchip from any and all damages, claims,
suits, or expenses resulting from such use. No licenses are
conveyed, implicitly or otherwise, under any Microchip
intellectual property rights unless otherwise stated.
Microchip received ISO/TS-16949:2009 certification for its worldwide
headquarters, design and wafer fabrication facilities in Chandler and
Tempe, Arizona; Gresham, Oregon and design centers in California
and India. The Company’s quality system processes and procedures
are for its PIC® MCUs and dsPIC® DSCs, KEELOQ® code hopping
devices, Serial EEPROMs, microperipherals, nonvolatile memory and
analog products. In addition, Microchip’s quality system for the design
and manufacture of development systems is ISO 9001:2000 certified.
QUALITY MANAGEMENT SYSTEM
CERTIFIED BY DNV
== ISO/TS 16949 ==
2012-2017 Microchip Technology Inc.
Trademarks
The Microchip name and logo, the Microchip logo, AnyRate, AVR,
AVR logo, AVR Freaks, BeaconThings, BitCloud, CryptoMemory,
CryptoRF, dsPIC, FlashFlex, flexPWR, Heldo, JukeBlox, KEELOQ,
KEELOQ logo, Kleer, LANCheck, LINK MD, maXStylus,
maXTouch, MediaLB, megaAVR, MOST, MOST logo, MPLAB,
OptoLyzer, PIC, picoPower, PICSTART, PIC32 logo, Prochip
Designer, QTouch, RightTouch, SAM-BA, SpyNIC, SST, SST
Logo, SuperFlash, tinyAVR, UNI/O, and XMEGA are registered
trademarks of Microchip Technology Incorporated in the U.S.A.
and other countries.
ClockWorks, The Embedded Control Solutions Company,
EtherSynch, Hyper Speed Control, HyperLight Load, IntelliMOS,
mTouch, Precision Edge, and Quiet-Wire are registered
trademarks of Microchip Technology Incorporated in the U.S.A.
Adjacent Key Suppression, AKS, Analog-for-the-Digital Age, Any
Capacitor, AnyIn, AnyOut, BodyCom, chipKIT, chipKIT logo,
CodeGuard, CryptoAuthentication, CryptoCompanion,
CryptoController, dsPICDEM, dsPICDEM.net, Dynamic Average
Matching, DAM, ECAN, EtherGREEN, In-Circuit Serial
Programming, ICSP, Inter-Chip Connectivity, JitterBlocker,
KleerNet, KleerNet logo, Mindi, MiWi, motorBench, MPASM, MPF,
MPLAB Certified logo, MPLIB, MPLINK, MultiTRAK, NetDetach,
Omniscient Code Generation, PICDEM, PICDEM.net, PICkit,
PICtail, PureSilicon, QMatrix, RightTouch logo, REAL ICE, Ripple
Blocker, SAM-ICE, Serial Quad I/O, SMART-I.S., SQI,
SuperSwitcher, SuperSwitcher II, Total Endurance, TSHARC,
USBCheck, VariSense, ViewSpan, WiperLock, Wireless DNA, and
ZENA are trademarks of Microchip Technology Incorporated in the
U.S.A. and other countries.
SQTP is a service mark of Microchip Technology Incorporated in
the U.S.A.
Silicon Storage Technology is a registered trademark of Microchip
Technology Inc. in other countries.
GestIC is a registered trademark of Microchip Technology
Germany II GmbH & Co. KG, a subsidiary of Microchip Technology
Inc., in other countries.
All other trademarks mentioned herein are property of their
respective companies.
© 2012-2017, Microchip Technology Incorporated, All Rights
Reserved.
ISBN: 978-1-5224-2244-0
DS40001657C-page 399
Worldwide Sales and Service
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San Jose, CA
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Canada - Toronto
Tel: 905-695-1980
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DS40001657C-page 400
China - Dongguan
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China - Guangzhou
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China - Hangzhou
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Tel: 49-7131-67-3636
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Tel: 81-3-6880- 3770
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Germany - Karlsruhe
Tel: 49-721-625370
Germany - Munich
Tel: 49-89-627-144-0
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Korea - Daegu
Tel: 82-53-744-4301
Fax: 82-53-744-4302
Germany - Rosenheim
Tel: 49-8031-354-560
Korea - Seoul
Tel: 82-2-554-7200
Fax: 82-2-558-5932 or
82-2-558-5934
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Tel: 972-9-744-7705
Malaysia - Kuala Lumpur
Tel: 60-3-6201-9857
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Singapore
Tel: 65-6334-8870
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10/10/17