Datasheet
RX110 Group
R01DS0202EJ0120
Rev.1.20
Jul 29, 2016
Renesas MCUs
32 MHz 32-bit RX MCUs, 50 DMIPS,
up to 128 Kbytes of flash memory, up to 5 comms channels, 12-bit A/D, RTC
Features
■ 32-bit RX CPU core
32 MHz maximum operating frequency
Capable of 50 DMIPS when operating at 32 MHz
Accumulator handles 64-bit results (for a single
instruction) from 32-bit × 32-bit operations
Multiplication and division unit handles 32-bit × 32-bit
operations (multiplication instructions take one CPU
clock cycle)
Fast interrupt
CISC Harvard architecture with five-stage pipeline
Variable-length instruction format, ultra-compact code
On-chip debugging circuit
■ Low power consumption functions
Operation from a single 1.8 to 3.6 V supply
Three low power modes
Supply current
High-speed operating mode: 0.1 mA/MHz
Software standby mode: 0.35 μA
Recovery time from software standby mode: 4.8 μs
■ On-chip flash memory for code, no wait states
Operation at 32 MHz, read cycle of 31.25 ns
No wait states for reading at full CPU speed
8 to 128 Kbyte capacities
Programmable at 1.8 V
For instructions and operands
■ On-chip SRAM, no wait states
8 to 16 Kbyte capacities
■ Data transfer controller (DTC)
Four transfer modes
Transfer can be set for each interrupt source.
■ Reset and power supply voltage management
Six types including the power-on reset (POR)
Low voltage detection (LVD) with voltage settings
■ Clock functions
External clock input frequency: Up to 20 MHz
Main clock oscillator frequency: 1 to 20 MHz
Sub-clock oscillator frequency: 32.768 kHz
Low-speed on-chip oscillator: 4 MHz
High-speed on-chip oscillator: 32 MHz±1% (20 to 85°C)
IWDT-dedicated on-chip oscillator: 15 kHz
Generate a dedicated 32.768-kHz clock for the RTC
On-chip clock frequency accuracy measurement circuit
(CAC)
■ Real-time clock (RTC)
30-second, leap year, and error adjustment functions
Calendar count mode or binary count mode selectable
Capable initiating exit from software standby mode
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
PLQP0064KB-A 10 × 10 mm, 0.5 mm pitch
PLQP0064GA-A 14 × 14 mm, 0.8 mm pitch
PLQP0048KB-A 7 × 7 mm, 0.5 mm pitch
PWQN0048KB-A 7 × 7 mm, 0.5 mm pitch
PWQN0040KC-A 6 × 6 mm, 0.5 mm pitch
PWLG0064KA-A 5 × 5 mm, 0.5 mm pitch
PWLG0036KA-A 4 × 4 mm, 0.5 mm pitch
■ Independent watchdog timer (WDT)
15-kHz on-chip oscillator produces a dedicated clock
signal to drive IWDT operation.
■ On-chip functions for IEC 60730 compliance
Clock frequency accuracy measurement circuit, IWDT,
functions to assist in RAM testing, etc.
■ Up to five channels for communication
SCI: Asynchronous mode, clock synchronous mode,
smart card interface (up to seven channels)
I2C bus interface: Transfer at up to 400 kbps, capable of
SMBus operation (one channel)
RSPI: Up to 16 Mbps (one channel)
■ Up to 6 extended-function timers
16-bit MTU: Input capture/output compare,
phase counting mode (four channels)
16-bit CMT (two channels)
■ 12-bit A/D converter
Up to 14 channels
1.0 μs minimum conversion speed
Double trigger (data duplication) function for motor
control
■ Temperature sensor
■ General I/O ports
5-V tolerant, open drain, input pull-up
■ Multi-function pin controller (MPC)
Multiple I/O pins can be selected for peripheral functions.
■ Unique ID
32-byte ID code for the MCU
■ Operating temperature range
40 to 85C
40 to 105°C
Page 1 of 108
RX110 Group
1. Overview
1.
Overview
1.1
Outline of Specifications
Table 1.1 lists the specifications, and Table 1.2 gives a comparison of the functions of the products in different
packages.
Table 1.1 is for products with the greatest number of functions, so the number of peripheral modules and channels will
differ in accordance with the package type. For details, see Table 1.2, Comparison of Functions for Different
Packages.
Table 1.1
Outline of Specifications (1/3)
Classification
Module/Function
Description
CPU
CPU
Memory
Maximum operating frequency: 32 MHz
32-bit RX CPU
Minimum instruction execution time: One instruction per one clock cycle
Address space: 4-Gbyte linear
Register set
General purpose: Sixteen 32-bit registers
Control: Eight 32-bit registers
Accumulator: One 64-bit register
Basic instructions: 73
DSP instructions: 9
Addressing modes: 10
Data arrangement
Instructions: Little endian
Data: Selectable as little endian or big endian
On-chip 32-bit multiplier: 32-bit × 32-bit → 64-bit
On-chip divider: 32-bit ÷ 32-bit → 32 bits
Barrel shifter: 32 bits
ROM
Capacity: 8 K /16 K /32 K /64 K /96 K /128 Kbytes
32 MHz, no-wait memory access
Programming/erasing method:
Serial programming (asynchronous serial communication), self-programming
RAM
Capacity: 8 K /10 K /16 Kbytes
32 MHz, no-wait memory access
MCU operating mode
Single-chip mode
Clock
Main clock oscillator, sub-clock oscillator, low-speed on-chip oscillator, high-speed on-chip oscillator,
and IWDT-dedicated on-chip oscillator
Oscillation stop detection: Available
Clock frequency accuracy measurement circuit (CAC)
Independent settings for the system clock (ICLK), peripheral module clock (PCLK), and FlashIF clock
(FCLK)
The CPU and system sections such as other bus masters run in synchronization with the system
clock (ICLK): 32 MHz (at max.)
Peripheral modules run in synchronization with the PCLK: 32 MHz (at max.)
The flash peripheral circuit runs in synchronization with the FCLK: 32 MHz (at max.)
The ICLK frequency can only be set to FCLK, PCLKB, or PCLKD multiplied by n (n: 1, 2, 4, 8, 16, 32,
64).
Clock generation circuit
Resets
RES# pin reset, power-on reset, voltage monitoring reset, independent watchdog timer reset, and
software reset
Voltage detection
Voltage detection circuit
(LVDAa)
When the voltage on VCC falls below the voltage detection level, an internal reset or internal interrupt
is generated.
Voltage detection circuit 1 is capable of selecting the detection voltage from 10 levels
Voltage detection circuit 2 is capable of selecting the detection voltage from 4 levels
Low power
consumption
Low power consumption
functions
Module stop function
Three low power consumption modes
Sleep mode, deep sleep mode, and software standby mode
Function for lower operating
power consumption
Operating power control modes
High-speed operating mode, middle-speed operating mode, and low-speed operating mode
Interrupt
Interrupt controller (ICUb)
Interrupt vectors: 65
External interrupts: 9 (NMI, IRQ0 to IRQ7 pins)
Non-maskable interrupts: 4 (NMI pin, voltage monitoring 1 interrupt, voltage monitoring 2 interrupt,
and IWDT interrupt)
16 levels specifiable for the order of priority
DMA
Data transfer controller
(DTCa)
Transfer modes: Normal transfer, repeat transfer, and block transfer
Activation sources: Interrupts
Chain transfer function
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 2 of 108
RX110 Group
Table 1.1
1. Overview
Outline of Specifications (2/3)
Classification
Module/Function
Description
I/O ports
General I/O ports
64-pin /48-pin /40-pin /36-pin
I/O: 50/34/28/24
Input: 2/2/1/1
Pull-up resistors: 42/28/23/20
Open-drain outputs: 38/28/23/20
5-V tolerance: 4/4/4/4
Multi-function pin controller (MPC)
Capable of selecting the input/output function from multiple pins
Timers
Multi-function timer pulse
unit 2 (MTU2b)
(16 bits × 4 channels) × 1 unit
Time bases for the four 16-bit timer channels can be provided via up to 8 pulse-input/output lines and
three pulse-input lines
Select from among eight or seven counter-input clock signals for each channel (PCLK/1, PCLK/4,
PCLK/16, PCLK/64, PCLK/256, PCLK/1024, MTCLKA, MTCLKB, MTCLKC, MTCLKD) other than
channel 5, for which only four signals are available.
Input capture function
13 output compare/input capture registers
Pulse output mode
Phase counting mode
Generation of triggers for A/D converter conversion
Compare match timer
(CMT)
(16 bits × 2 channels) × 1 unit
Select from among four clock signals (PCLK/8, PCLK/32, PCLK/128, PCLK/512)
Independent watchdog
timer (IWDTa)
14 bits × 1 channel
Count clock: Dedicated low-speed on-chip oscillator for the IWDT
Frequency divided by 1, 16, 32, 64, 128, or 256
Realtime clock (RTCA)
Clock source: Sub-clock
Calendar count mode or binary count mode selectable
Interrupts: Alarm interrupt, periodic interrupt, and carry interrupt
Serial communications
interfaces (SCIe, SCIf)
I2C bus interface (RIIC)
1 channel
Communications formats:
I2C bus format/SMBus format
Master mode or slave mode selectable
Supports fast mode
Serial peripheral interface
(RSPI)
1 channel
Transfer facility
Using the MOSI (master out, slave in), MISO (master in, slave out), SSL (slave select), and RSPI
clock (RSPCK) signals enables serial transfer through SPI operation (four lines) or clocksynchronous operation (three lines)
Capable of handling serial transfer as a master or slave
Data formats
Choice of LSB first or MSB first transfer
The number of bits in each transfer can be changed to 8, 9, 10, 11, 12, 13, 14, 15, 16, 20, 24, or
32 bits.
128-bit buffers for transmission and reception
Up to four frames can be transmitted or received in a single transfer operation (with each frame
having up to 32 bits)
Double buffers for both transmission and reception
Communication
functions
3 channels (channel 1, 5: SCIe, channel 12: SCIf)
Serial communications modes: Asynchronous, clock synchronous, and smart card interface
On-chip baud rate generator allows selection of the desired bit rate
Choice of LSB first or MSB first transfer
Average transfer rate clock can be input from MTU2 timers
Simple I2C
Simple SPI
Master/slave mode supported (SCIf only)
Start frame and information frame are included (SCIf only)
Start-bit detection in asynchronous mode: Low level or falling edge is selectable (SCIe/SCIf)
12-bit A/D converter (S12ADb)
Temperature sensor (TEMPSA)
1 channel
The voltage of the temperature is converted into a digital value by the 12-bit A/D converter.
CRC calculator (CRC)
CRC code generation for arbitrary amounts of data in 8-bit units
Select any of three generating polynomials:
X8 + X2 + X + 1, X16 + X15 + X2 + 1, or X16 + X12 + X5 + 1
Generation of CRC codes for use with LSB first or MSB first communications is selectable.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
1 unit (1 unit × 14 channels)
12-bit resolution
Minimum conversion time: 1.0 µs per channel when the ADCLK is operating at 32 MHz
Operating modes
Scan mode (single scan mode, continuous scan mode, and group scan mode)
Double trigger mode (duplication of A/D conversion data)
A/D conversion start conditions
A software trigger, a trigger from a timer (MTU), or an external trigger signal
Page 3 of 108
RX110 Group
Table 1.1
Classification
1. Overview
Outline of Specifications (3/3)
Module/Function
Description
Data operation circuit (DOC)
Comparison, addition, and subtraction of 16-bit data
Unique ID
32-byte ID code for the MCU
Power supply voltages/Operating frequencies
VCC = 1.8 to 2.4 V: 8 MHz, VCC = 2.4 to 2.7 V: 16 MHz, VCC = 2.7 to 3.6 V: 32 MHz
Supply current
3.2 mA at 32 MHz (typ.)
Operating temperatures
D version: 40 to +85°C, G version: 40 to +105°C
Packages
64-pin LFQFP (PLQP0064KB-A) 10 × 10 mm, 0.5 mm pitch
64-pin LQFP (PLQP0064GA-A) 14 × 14 mm, 0.8 mm pitch
64-pin WFLGA (PWLG0064KA-A) 5 × 5 mm, 0.5 mm pitch
48-pin LFQFP (PLQP0048KB-A) 7 × 7 mm, 0.5 mm pitch
48-pin HWQFN (PWQN0048KB-A) 7 × 7 mm, 0.5 mm pitch
40-pin HWQFN (PWQN0040KC-A) 6 × 6 mm, 0.5 mm pitch
36-pin WFLGA (PWLG0036KA-A) 4 × 4 mm, 0.5 mm pitch
On-chip debugging system
E1 emulator (FINE interface)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 4 of 108
RX110 Group
Table 1.2
1. Overview
Comparison of Functions for Different Packages
RX110 Group
Module/Functions
Interrupts
External interrupts
DMA
Data transfer controller
Timers
Multi-function timer pulse unit 2
64 Pins
48 Pins
Supported
4 channels (MTU0 to MTU2, MTU5)
2 channels × 1 unit
Realtime clock
Supported
Independent watchdog timer
Not supported
Supported
Serial communications interfaces
[simple I2C, simple SPI]
2 channels
(SCI1, SCI5)
Serial communications interface
[simple I2C, simple SPI]
1 channel (SCI12)
I2C bus interface
Serial peripheral interface
12-bit A/D converter
(including high-precision channels)
1 channel
1 channel
14 channels
(6 channels)
1 channel
1 channel
(SSLA1 and SSLA3 are not supported) (SSLA1 to SSLA3
are not supported)
10 channels
(4 channels)
8 channels
(3 channels)
Temperature sensor
Supported
CRC calculator
Supported
Packages
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
36 Pins
NMI, IRQ0 to IRQ7
Compare match timer
Communication
functions
40 Pins
64-pin LFQFP
64-pin LQFP
64-pin WFLGA
48-pin LFQFP
48-pin HWQFN
40-pin HWQFN
7 channels
(2 channels)
36-pin WFLGA
Page 5 of 108
RX110 Group
1.2
1. Overview
List of Products
Table 1.3 is a list of products, and Figure 1.1 shows how to read the product part no., memory capacity, and package
type.
Table 1.3
List of Products (1/2)
Group
Part No.
Orderable Part No.
Package
RX110
R5F51105AGFM
R5F51105AGFM#30
PLQP0064KB-A
R5F51105AGFK
R5F51105AGFK#30
PLQP0064GA-A
R5F51105AGFL
R5F51105AGFL#30
PLQP0048KB-A
R5F51105AGNE
R5F51105AGNE#U0
PWQN0048KB-A
R5F51104AGFM
R5F51104AGFM#30
PLQP0064KB-A
R5F51104AGFK
R5F51104AGFK#30
PLQP0064GA-A
R5F51104AGFL
R5F51104AGFL#30
PLQP0048KB-A
R5F51104AGNE
R5F51104AGNE#U0
PWQN0048KB-A
R5F51103AGFM
R5F51103AGFM#30
PLQP0064KB-A
R5F51103AGFK
R5F51103AGFK#30
PLQP0064GA-A
R5F51103AGFL
R5F51103AGFL#30
PLQP0048KB-A
R5F51103AGNE
R5F51103AGNE#U0
PWQN0048KB-A
R5F51103AGNF
R5F51103AGNF#U0
PWQN0040KC-A
R5F51101AGFM
R5F51101AGFM#30
PLQP0064KB-A
R5F51101AGFK
R5F51101AGFK#30
PLQP0064GA-A
R5F51101AGFL
R5F51101AGFL#30
PLQP0048KB-A
R5F51101AGNE
R5F51101AGNE#U0
PWQN0048KB-A
R5F51101AGNF
R5F51101AGNF#U0
PWQN0040KC-A
R5F5110JAGFM
R5F5110JAGFM#30
PLQP0064KB-A
R5F5110JAGFK
R5F5110JAGFK#30
PLQP0064GA-A
R5F5110JAGFL
R5F5110JAGFL#30
PLQP0048KB-A
R5F5110JAGNE
R5F5110JAGNE#U0
PWQN0048KB-A
R5F5110JAGNF
R5F5110JAGNF#U0
PWQN0040KC-A
R5F5110HAGNF
R5F5110HAGNF#U0
PWQN0040KC-A
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
ROM
Capacity
RAM
Capacity
Maximum
Operating
Frequency
Operating
Temperature
32 MHz
40 to +105°C
128 Kbytes
16 Kbytes
96 Kbytes
64 Kbytes
10 Kbytes
32 Kbytes
16 Kbytes
8 Kbytes
8 Kbytes
Page 6 of 108
RX110 Group
Table 1.3
1. Overview
List of Products (2/2)
Group
Part No.
Orderable Part No.
Package
RX110
R5F51105ADFM
R5F51105ADFM#30
PLQP0064KB-A
R5F51105ADFK
R5F51105ADFK#30
PLQP0064GA-A
R5F51105ADLF
R5F51105ADLF#U0
PWLG0064KA-A
R5F51105ADFL
R5F51105ADFL#30
PLQP0048KB-A
Note:
R5F51105ADNE
R5F51105ADNE#U0
PWQN0048KB-A
R5F51104ADFM
R5F51104ADFM#30
PLQP0064KB-A
R5F51104ADFK
R5F51104ADFK#30
PLQP0064GA-A
R5F51104ADLF
R5F51104ADLF#U0
PWLG0064KA-A
R5F51104ADFL
R5F51104ADFL#30
PLQP0048KB-A
R5F51104ADNE
R5F51104ADNE#U0
PWQN0048KB-A
R5F51103ADFM
R5F51103ADFM#30
PLQP0064KB-A
R5F51103ADFK
R5F51103ADFK#30
PLQP0064GA-A
R5F51103ADLF
R5F51103ADLF#U0
PWLG0064KA-A
R5F51103ADFL
R5F51103ADFL#30
PLQP0048KB-A
R5F51103ADNE
R5F51103ADNE#U0
PWQN0048KB-A
R5F51103ADLM
R5F51103ADLM#U0
PWLG0036KA-A
R5F51103ADNF
R5F51103ADNF#U0
PWQN0040KC-A
R5F51101ADFM
R5F51101ADFM#30
PLQP0064KB-A
R5F51101ADFK
R5F51101ADFK#30
PLQP0064GA-A
R5F51101ADLF
R5F51101ADLF#U0
PWLG0064KA-A
R5F51101ADFL
R5F51101ADFL#30
PLQP0048KB-A
R5F51101ADNE
R5F51101ADNE#U0
PWQN0048KB-A
R5F51101ADLM
R5F51101ADLM#U0
PWLG0036KA-A
R5F51101ADNF
R5F51101ADNF#U0
PWQN0040KC-A
R5F5110JADFM
R5F5110JADFM#30
PLQP0064KB-A
R5F5110JADFK
R5F5110JADFK#30
PLQP0064GA-A
R5F5110JADLF
R5F5110JADLF#U0
PWLG0064KA-A
R5F5110JADFL
R5F5110JADFL#30
PLQP0048KB-A
R5F5110JADNE
R5F5110JADNE#U0
PWQN0048KB-A
R5F5110JADLM
R5F5110JADLM#U0
PWLG0036KA-A
R5F5110JADNF
R5F5110JADNF#U0
PWQN0040KC-A
R5F5110HADLM
R5F5110HADLM#U0
PWLG0036KA-A
R5F5110HADNF
R5F5110HADNF#U0
PWQN0040KC-A
ROM
Capacity
RAM
Capacity
Maximum
Operating
Frequency
Operating
Temperature
32MHz
40 to +85°C
128 Kbytes
16 Kbytes
96 Kbytes
64 Kbytes
10 Kbytes
32 Kbytes
16 Kbytes
8 Kbytes
8 Kbytes
Orderable part numbers are current as of when this manual was published. Please make sure to refer to the relevant product
page on the Renesas website for the latest part numbers.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 7 of 108
RX110 Group
1. Overview
R 5 F 5
1
1 0
5 A D
F
M
#3
0
Production identification code
Packing, Terminal material (Pb-free)
#3: Tray/Sn (Tin) only
#U: Tray/SnCu and others
Package type, number of pins, and pin pitch
FM: LFQFP/64/0.50
FK: LQFP/64/0.80
LF: WFLGA/64/0.50
FL: LFQFP/48/0.50
NE: HWQFN/48/0.50
NF: HWQFN/40/0.50
LM: WFLGA/36/0.50
D: Operating temperature (-40°C to +85°C)
G: Operating temperature (-40°C to +105°C)
ROM and RAM capacity
5: 128 Kbytes/16 Kbytes
4: 96 Kbytes/16 Kbytes
3: 64 Kbytes/10 Kbytes
1: 32 Kbytes/10 Kbytes
J: 16 Kbytes/8 Kbytes
H: 8 Kbytes/8 Kbytes
Group name
10: RX110 Group
11: RX111 Group
Series name
RX100 Series
Type of memory
F: Flash memory version
Renesas MCU
Renesas semiconductor product
Figure 1.1
How to Read the Product Part No., Memory Capacity, and Package Type
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 8 of 108
RX110 Group
1.3
1. Overview
Block Diagram
Figure 1.2 shows a block diagram.
IWDTa
CRC
SCIe × 2 channels
SCIf × 1 channel
Internal main bus 2
DTCa
RIIC × 1 channel
MTU2b × 4 channels
RX CPU
Clock
generation
circuit
Port 0
Port 1
Port 2
CMT × 2 channels (unit 0)
Port 3
RTCA
Port 4
12-bit A/D converter × 14 channels
Port 5
Temperature sensor
Port A
DOC
Port B
CAC
Port C
Internal main bus 1
RAM
Operand bus
Instruction bus
ROM
Internal peripheral buses 1, 2, 4 to 6
ICUb
RSPI × 1 channel
Port E
Port H
Port J
ICUb:
DTCa:
IWDTa:
CRC:
SCIe/SCIf:
RSPI:
Figure 1.2
Interrupt controller
Data transfer controller
Independent watchdog timer
CRC (cyclic redundancy check) calculator
Serial communications interface
Serial peripheral interface
RIIC:
MTU2b:
CMT:
RTCA:
DOC:
CAC:
I2C bus interface
Multi-function timer pulse unit 2
Compare match timer
Realtime clock
Data operation circuit
Clock frequency accuracy measurement circuit
Block Diagram
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 9 of 108
RX110 Group
1.4
1. Overview
Pin Functions
Table 1.4 lists the pin functions.
Table 1.4
Pin Functions (1/3)
Classifications
Pin Name
I/O
Description
Power supply
VCC
Input
Power supply pin. Connect it to the system power supply.
VCL
—
Connect this pin to the VSS pin via the 4.7 μF smoothing capacitor used to
stabilize the internal power supply. Place the capacitor close to the pin.
VSS
Input
Ground pin. Connect it to the system power supply (0 V).
AVCC0
Input
Analog voltage supply pin for the 12-bit A/D converter. Connect this pin to
VCC when not using the 12-bit A/D converter.
AVSS0
Input
Analog ground pin for the 12-bit A/D converter. Connect this pin to VSS
when not using the 12-bit A/D converter.
VREFH0
Input
Analog reference voltage supply pin for the 12-bit A/D converter. Connect
this pin to VCC when not using the 12-bit A/D converter.
VREFL0
Input
Analog reference ground pin for the 12-bit A/D converter. Connect this pin
to VSS when not using the 12-bit A/D converter.
XTAL
Output/ Pins for connecting a crystal resonator. An external clock can be input
Input *1 through the XTAL pin.
EXTAL
Input
Analog power
supply
Clock
XCIN
Input
XCOUT
Output
CLKOUT
Output
Clock output pin.
Operating mode
control
MD
Input
Pin for setting the operating mode. The signal levels on this pin must not be
changed during operation.
System control
RES#
Input
Reset pin. This LSI enters the reset state when this signal goes low.
CAC
CACREF
Input
Input pin for the clock frequency accuracy measurement circuit.
On-chip
emulator
FINED
I/O
FINE interface pin.
LVD
CMPA2
Input
Detection target voltage pin for voltage detection 2.
Interrupts
NMI
Input
Non-maskable interrupt request pin.
IRQ0 to IRQ7
Input/output pins for the sub-clock oscillator. Connect a crystal resonator
between XCIN and XCOUT.
Input
Interrupt request pins.
Multi-function
MTIOC0A, MTIOC0B
timer pulse unit 2 MTIOC0C, MTIOC0D
I/O
The TGRA0 to TGRD0 input capture input/output compare output/PWM
output pins.
MTIOC1A, MTIOC1B
I/O
The TGRA1 and TGRB1 input capture input/output compare output/PWM
output pins.
MTIOC2A, MTIOC2B
I/O
The TGRA2 and TGRB2 input capture input/output compare output/PWM
output pins.
MTIC5U, MTIC5V, MTIC5W
Input
The TGRU5, TGRV5, and TGRW5 input capture input/external pulse input
pins.
MTCLKA, MTCLKB,
MTCLKC, MTCLKD
Input
Input pins for the external clock.
RTCOUT
Output
Output pin for the 1-Hz/64-Hz clock.
Realtime clock
Serial
communications
interface (SCIe)
Asynchronous mode/clock synchronous mode
SCK1, SCK5
I/O
Input/output pins for the clock.
RXD1, RXD5
Input
Input pins for receiving data.
TXD1, TXD5
Output
Output pins for transmitting data.
CTS1#, CTS5#
Input
Input pins for controlling the start of transmission and reception.
RTS1#, RTS5#
Output
Output pins for controlling the start of transmission and reception.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 10 of 108
RX110 Group
Table 1.4
1. Overview
Pin Functions (2/3)
Classifications
Pin Name
I/O
Description
Serial
communications
interface (SCIe)
Simple
SSCL1, SSCL5
I/O
Input/output pins for the I2C clock.
SSDA1, SSDA5
I/O
Input/output pins for the I2C data.
I2C
mode
Simple SPI mode
Serial
communications
interface (SCIf)
SCK1, SCK5
I/O
Input/output pins for the clock.
SMISO1, SMISO5
I/O
Input/output pins for slave transmit data.
SMOSI1, SMOSI5
I/O
Input/output pins for master transmit data.
SS1#, SS5#
Input
Chip-select input pins.
Asynchronous mode/clock synchronous mode
SCK12
I/O
Input/output pin for the clock.
RXD12
Input
Input pin for receiving data.
TXD12
Output
Output pin for transmitting data.
CTS12#
Input
Input pin for controlling the start of transmission and reception.
RTS12#
Output
Output pin for controlling the start of transmission and reception.
SSCL12
I/O
Input/output pin for the I2C clock.
SSDA12
I/O
Input/output pin for the I2C data.
Simple I2C mode
Simple SPI mode
SCK12
I/O
Input/output pin for the clock.
SMISO12
I/O
Input/output pin for slave transmit data.
SMOSI12
I/O
Input/output pin for master transmit data.
SS12#
Input
Chip-select input pin.
Input
Input pin for data reception by SCIf.
Extended serial mode
RXDX12
I2C bus interface
Serial peripheral
interface
12-bit A/D
converter
I/O ports
TXDX12
Output
Output pin for data transmission by SCIf.
SIOX12
I/O
Input/output pin for data reception or transmission by SCIf.
SCL0
I/O
Input/output pin for I2C bus interface clocks. Bus can be directly driven by
the N-channel open drain output.
SDA0
I/O
Input/output pin for I2C bus interface data. Bus can be directly driven by the
N-channel open drain output.
RSPCKA
I/O
Input/output pin for the RSPI clock.
MOSIA
I/O
Input/output pin for transmitting data from the RSPI master.
MISOA
I/O
Input/output pin for transmitting data from the RSPI slave.
SSLA0
I/O
Input/output pin to select the slave for the RSPI.
SSLA1 to SSLA3
Output
Output pins to select the slave for the RSPI.
AN000 to AN004, AN006,
AN008 to AN015
Input
Input pins for the analog signals to be processed by the A/D converter.
ADTRG0#
Input
Input pin for the external trigger signals that start the A/D conversion.
P03, P05
I/O
2-bit input/output pins.
P14 to P17
I/O
4-bit input/output pins.
P26, P27
I/O
2-bit input/output pins.
P30 to P32, P35
I/O
4-bit input/output pins (P35 input pin).
P40 to P44, P46
I/O
6-bit input/output pins.
P54, P55
I/O
2-bit input/output pins.
PA0, PA1, PA3, PA4, PA6
I/O
5-bit input/output pins.
PB0, PB1, PB3, PB5 to PB7 I/O
6-bit input/output pins.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 11 of 108
RX110 Group
Table 1.4
1. Overview
Pin Functions (3/3)
Classifications
Pin Name
I/O
Description
I/O ports
PC0 to PC7
I/O
8-bit input/output pins.
PE0 to PE7
I/O
8-bit input/output pins.
PH0 to PH3
I/O
4-bit input/output pins.
PH7
Input
1-bit input pin.
PJ6, PJ7
I/O
2-bit input/output pins.
Note 1. For external clock input.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 12 of 108
RX110 Group
1.5
1. Overview
Pin Assignments
VSS
PB0
VCC
PB1
PB3
PB5
PB6/PC0
PB7/PC1
39
38
37
36
35
34
33
PA3
40
PA1
43
PA4
PA0
44
PA6
PE5
45
41
PE4
46
42
PE3
47
PE2
49
32
PC2
PE1
50
31
PC3
PE0
51
30
PC4
PE7
52
29
PC5
PE6
53
28
PC6
P46
54
27
PC7
P44
55
26
P54
P43
56
25
P55
P42
57
24
PH0
P41
58
23
PH1
PJ7/VREFL0
59
22
PH2
P40
60
21
PH3
PJ6/VREFH0
61
20
P14
AVSS0
62
19
P15
AVCC0
63
18
P16
P05
64
17
P17
Note:
Figure 1.3
48
Figure 1.3 to Figure 1.7 show the pin assignments. Table 1.5 to Table 1.9 show the lists of pins and pin functions.
12
13
14
15
16
VCL
VSS
VCC
P32
8
XCOUT
EXTAL
7
RES#
11
6
MD
XTAL
5
P31
9
4
P30
10
3
P26
P35/NMI
2
P27
PH7/XCIN
1
P03
RX110 Group
PLQP0064KB-A
PLQP0064GA-A
(64-pin LFQFP/LQFP)
(Top view)
This figure indicates the power supply pins and I/O ports.
For the pin configuration, see the table “List of Pins and Pin Functions (64-Pin LFQFP/LQFP)”.
Pin Assignments of the 64-Pin LFQFP/LQFP
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 13 of 108
RX110 Group
1. Overview
RX110 Group
PWLG0064KA-A
(64-pin WFLGA)
(Upper perspective view)
A
B
C
D
E
F
G
H
8
PE3
PE4
PA0
VSS
VCC
PB5
PB6
PB7
8
7
PE2
PE1
PA1
PA3
PB0
PC4
PC3
PC2
7
6
P46
PE6
PE5
PA4
PB1
PC7
PC5
PH0
6
5
P43
P44
PE7
PA6
PB3
P54
PC6
PH1
5
4
PJ7/
VREFL0
P42
P41
PE0
P55
P14
P15
PH2
4
3
PJ6/
VREFH0
P40
P27
P26
P31
P35
P16
PH3
3
2
AVCC0
P03
P05
P30
MD
P32
P17
VCC
2
1
AVSS0
XCOUT
PH7/
XCIN
RES#
XTAL
EXTAL
VCL
VSS
1
A
B
C
D
E
F
G
H
Note:
Note:
Figure 1.4
This figure indicates the power supply pins and I/O port pins. For the pin
configuration, see the table “List of Pins and Pin Functions (64-Pin WFLGA)”.
For the position of A1 pin in the package, see “Package Dimensions”.
Pin Assignments of the 64-Pin WFLGA
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 14 of 108
PA4
VSS
PB0/PC0
VCC
PB1/PC1
PB3/PC2
PB5/PC3
30
29
28
27
26
25
PA3
24
PC4
38
23
PC5
PE0
39
22
PC6
PE7
40
21
PC7
P46
41
20
PH0
P42
42
19
PH1
P41
43
18
PH2
PJ7/VREFL0
44
17
PH3
P40
45
16
P14
PJ6/VREFH0
46
15
P15
AVSS0
47
14
P16
AVCC0
48
13
P17
RX110 Group
PLQP0048KB-A
(48-pin LFQFP)
VSS
VCC
26 PB3/PC2
25 PB5/PC3
12
10
VCL
27 PB1/PC1
11
9
EXTAL
7
P35/NMI
30 VSS
28 VCC
6
PH7/XCIN
31 PA6
8
5
XCOUT
32 PA4
XTAL
4
RES#
33 PA3
29 PB0/PC0
3
MD
34 PA1
2
P26
35 PE4
1
P27
36 PE3
(Top view)
PE2 37
24 PC4
PE1 38
23 PC5
PE0 39
22 PC6
RX110 Group
PWQN0048KB-A
(48-pin HWQFN)
P42 42
P41 43
PJ7/VREFL0 44
21 PC7
20 PH0
19 PH1
18 PH2
17 PH3
(Top view)
P40 45
16 P14
VCC 12
VSS 11
VCL 10
EXTAL 9
7
XTAL 8
P35/NMI
PH7/XCIN 6
XCOUT 5
13 P17
RES# 4
14 P16
AVCC0 48
MD 3
15 P15
AVSS0 47
P26 2
PJ6/VREFH0 46
P27 1
Figure 1.5
PA6
PA1
33
37
PE1
P46 41
Note:
31
PE4
34
PE2
PE7 40
Note:
32
PE3
35
1. Overview
36
RX110 Group
This figure indicates the power supply pins and I/O port pins.
For the pin configuration, see the table “List of Pins and Pin Functions (48-Pin LFQFP/HWQFN)”.
It is recommended that the exposed die pad of HWQFN should be connected to VSS .
Pin Assignments of the 48-Pin LFQFP/HWQFN
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 15 of 108
PA4
VSS
PB0
VCC
PB3
24
23
22
21
PA3
19 PH0
18 PH1
RX110 Group
PWQN0040KC-A
(40-pin HWQFN)
(Top view)
P42 35
P41 36
PJ7/VREFL0 37
PJ6/VREFH0 38
Figure 1.6
PA6
PA1
27
20 PC4
PE1 32
P46 34
Note:
25
PE4
28
PE2 31
PE0 33
Note:
26
PE3
29
1. Overview
30
RX110 Group
17 PH2
16 PH3
15 P14
14 P15
13 P16
2
3
4
5
6
7
8
9
MD
RES#
P35/NMI
XTAL
EXTAL
VCL
VSS
VCC 10
1
11 P32
P26
12 P17
AVCC0 40
P27
AVSS0 39
This figure indicates the power supply pins and I/O port pins.
For the pin configuration, see the table “List of Pins and Pin Functions (40-Pin HWQFN)”.
It is recommended that the exposed die pad of HWQFN should be connected to VSS.
Pin Assignments of the 40-Pin HWQFN
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 16 of 108
RX110 Group
1. Overview
RX110 Group
PWLG0036KA-A
(36-pin WFLGA)
(Upper perspective view)
6
PE2
PA3
VSS
PB0
VCC
PH0
5
P41
PE1
PA4
PB3
PC4
PH1
4
P42
PE0
PE4
PA6
P15
PH2
3
PJ6/
VREFH0
PJ7/
VREFL0
PE3
P14
P16
PH3
2
AVCC0
P27
MD
P35
P17
VCC
1
AVSS0
RES#
XTAL
EXTAL
VCL
VSS
A
B
C
D
E
F
Note:
Note:
Figure 1.7
This figure indicates the power supply pins and I/O port pins. For the pin
configuration, see the table “List of Pins and Pin Functions (36-Pin WFLGA)”.
For the position of A1 pin in the package, see “Package Dimensions”.
Pin Assignments of the 36-Pin WFLGA
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 17 of 108
RX110 Group
Table 1.5
Pin
No.
1. Overview
List of Pins and Pin Functions (64-Pin LFQFP/LQFP) (1/2)
Power Supply, Clock,
System Control
I/O Port
Timers (MTU, RTC)
Communication
(SCIe, SCIf, RSPI, RIIC)
Others
1
P03
2
P27
MTIOC2B
SCK1/SCK12
3
P26
MTIOC2A
TXD1/SMOSI1/SSDA1
4
P30
RXD1/SMISO1/SSCL1
IRQ0
5
P31
CTS1#/RTS1#/SS1#
IRQ1
6
MD
7
RES#
8
XCOUT
9
XCIN
10
11
IRQ3/CMPA2/
CACREF/ADTRG0#
FINED
PH7
P35
NMI
XTAL
12
EXTAL
13
VCL
14
VSS
15
VCC
16
P32
MTIOC0C/RTCOUT
IRQ2
17
P17
MTIOC0C
SCK1/MISOA/SDA0/RXD12/RXDX12/
SMISO12/SSCL12
IRQ7
18
P16
RTCOUT
TXD1/SMOSI1/SSDA1/MOSIA/SCL0
IRQ6/ADTRG0#
19
P15
MTIOC0B/MTCLKB
RXD1/SMISO1/SSCL1/RSPCKA
IRQ5/CLKOUT
20
P14
MTIOC0A/MTCLKA
CTS1#/RTS1#/SS1#/SSLA0/TXD12/
TXDX12/SIOX12/SMOSI12/SSDA12
IRQ4
21
PH3
MTIOC1A
22
PH2
IRQ1
23
PH1
IRQ0
24
PH0
25
P55
26
P54
MTIOC1B
CACREF
27
PC7
MTCLKB
TXD1/SMOSI1/SSDA1/MISOA
28
PC6
MTCLKA
RXD1/SMISO1/SSCL1/MOSIA
SCK1/RSPCKA
29
PC5
MTCLKD
30
PC4
MTCLKC
31
PC3
TXD5/SMOSI5/SSDA5
32
PC2
RXD5/SMISO5/SSCL5/SSLA3
33
PB7/PC1
34
PB6/PC0
SCK5/SSLA0
CACREF
IRQ2/CLKOUT
35
PB5
MTIOC2A/MTIOC1B
36
PB3
MTIOC0A
PB1
MTIOC0C
PB0
MTIC5W/MTIOC0C/
RTCOUT
SCL0/RSPCKA
IRQ2/ADTRG0#
PA6
MTIC5V/MTCLKB/MTIOC2A
CTS5#/RTS5#/SS5#/SDA0/MOSIA
IRQ3
37
38
39
40
41
IRQ4
VCC
VSS
42
PA4
MTIC5U/MTCLKA/MTIOC2B
TXD5/SMOSI5/SSDA5/SSLA0
IRQ5
43
PA3
MTIOC0D/MTCLKD/
MTIOC1B
RXD5/SMISO5/SSCL5/MISOA
IRQ6
44
PA1
MTIOC0B/MTCLKC/
RTCOUT
SCK5/SSLA2
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 18 of 108
RX110 Group
Table 1.5
Pin
No.
1. Overview
List of Pins and Pin Functions (64-Pin LFQFP/LQFP) (2/2)
Power Supply, Clock,
System Control
I/O Port
Timers (MTU, RTC)
45
PA0
46
PE5
MTIOC2B
47
PE4
MTIOC1A
MTIOC0A/MTIOC1B
Communication
(SCIe, SCIf, RSPI, RIIC)
Others
SSLA1
CACREF
IRQ5/AN013
MOSIA
IRQ4/AN012
48
PE3
CTS12#/RTS12#/SS12#/RSPCKA
IRQ3/AN011
49
PE2
RXD12/RXDX12/SMISO12/SSCL12
IRQ7/AN010
50
PE1
TXD12/TXDX12/SIOX12/SMOSI12/
SSDA12
IRQ1/AN009
51
PE0
52
PE7
IRQ7/AN015
53
PE6
IRQ6/AN014
54
P46*1
AN006
55
P44*1
AN004
56
P43*1
AN003
57
P42*1
AN002
58
P41*1
AN001
59
VREFL0
P40*1
PJ6*1
61
VREFH0
AVSS0
63
AVCC0
64
SCK12
IRQ0/AN008
PJ7*1
60
62
MTIOC2A
AN000
P05
Note 1. The power source of the I/O buffer for these pins is AVCC0.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 19 of 108
RX110 Group
Table 1.6
1. Overview
List of Pins and Pin Functions (64-Pin WFLGA) (1/2)
Pin
No.
Power Supply, Clock,
System Control
A1
AVSS0
A2
AVCC0
A3
VREFH0
PJ6*1
A4
VREFL0
PJ7*1
I/O Port
Timers (MTU, RTC)
Communication
(SCIe, SCIf, RSPI, RIIC)
Others
A5
P43*1
AN003
A6
P46*1
AN006
A7
PE2
A8
PE3
B1
MTIOC0A/MTIOC1B
RXD12/RXDX12/SMISO12/SSCL12
IRQ7/AN010
CTS12#/RTS12#/SS12#/RSPCKA
IRQ3/AN011
XCOUT
B2
P03
B3
P40*1
AN000
B4
P42*1
AN002
B5
P44*1
AN004
B6
PE6
B7
PE1
B8
PE4
C1
XCIN
IRQ6/AN014
TXD12/TXDX12/SIOX12/SMOSI12/
SSDA12
IRQ1/AN009
MTIOC1A
MOSIA
IRQ4/AN012
MTIOC2B
SCK1/SCK12
IRQ3/CMPA2/
CACREF/ADTRG0#
PH7
C2
P05
C3
P27
C4
P41*1
AN001
C5
PE7
IRQ7/AN015
C6
PE5
MTIOC2B
C7
PA1
MTIOC0B/MTCLKC/
RTCOUT
C8
D1
IRQ5/AN013
SCK5/SSLA2
PA0
SSLA1
CACREF
P30
RXD1/SMISO1/SSCL1
IRQ0
RES#
D2
D3
P26
MTIOC2A
TXD1/SMOSI1/SSDA1
D4
PE0
MTIOC2A
SCK12
IRQ0/AN008
D5
PA6
MTIC5V/MTIOC2A/MTCLKB
CTS5#/RTS5#/SS5#/SDA0/MOSIA
IRQ3
D6
PA4
MTIC5U/MTIOC2B/MTCLKA
TXD5/SMOSI5/SSDA5/SSLA0
IRQ5
D7
PA3
MTIOC0D/MTCLKD/
MTIOC1B
RXD5/SMISO5/SSCL5/MISOA
IRQ6
CTS1#/RTS1#/SS1#
IRQ1
D8
VSS
E1
XTAL
E2
MD
FINED
E3
P31
E4
P55
E5
PB3
MTIOC0A
E6
PB1
MTIOC0C
E7
PB0
MTIC5W/MTIOC0C/
RTCOUT
F2
P32
MTIOC0C/RTCOUT
F3
P35
F4
P14
E8
VCC
F1
EXTAL
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
IRQ4
SCL0/RSPCKA
IRQ2/ADTRG0#
IRQ2
NMI
MTIOC0A/MTCLKA
CTS1#/RTS1#/SS1#/TXD12/
TXDX12/SIOX12/SMOSI12/SSDA12/
SSLA0
IRQ4
Page 20 of 108
RX110 Group
Table 1.6
Pin
No.
1. Overview
List of Pins and Pin Functions (64-Pin WFLGA) (2/2)
Power Supply, Clock,
System Control
I/O Port
Timers (MTU, RTC)
Communication
(SCIe, SCIf, RSPI, RIIC)
Others
F5
P54
F6
PC7
MTCLKB
TXD1/SMOSI1/SSDA1/MISOA
CACREF
F7
PC4
MTCLKC
SCK5/SSLA0
IRQ2/CLKOUT
PB5
MTIOC1B/MTIOC2A
P17
MTIOC0C
SCK1/MISOA/SDA0/RXD12/RXDX12/
SMISO12/SSCL12
IRQ7
F8
G1
VCL
G2
G3
P16
RTCOUT
TXD1/SMOSI1/SSDA1/SCL0/MOSIA
IRQ6/ADTRG0#
G4
P15
MTIOC0B/MTCLKB
RXD1/SMISO1/SSCL1/RSPCKA
IRQ5/CLKOUT
G5
PC6
MTCLKA
RXD1/SMISO1/SSCL1/MOSIA
G6
PC5
MTCLKD
G7
PC3
G8
SCK1/RSPCKA
TXD5/SMOSI5/SSDA5
PB6/PC0
H1
VSS
H2
VCC
H3
PH3
H4
PH2
H5
PH1
H6
PH0
H7
PC2
H8
PB7/PC1
MTIOC1A
IRQ1
IRQ0
MTIOC1B
CACREF
RXD5/SMISO5/SSCL5/SSLA3
Note 1. The power source of the I/O buffer for these pins is AVCC0.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 21 of 108
RX110 Group
Table 1.7
Pin
No.
List of Pins and Pin Functions (48-Pin LFQFP/HWQFN) (1/2)
Power Supply, Clock,
System Control
1
2
3
MD
4
RES#
5
XCOUT
6
XCIN
7
8
1. Overview
I/O Port
Timers (MTU, RTC)
Communication
(SCIe, SCIf, RSPI, RIIC)
P27
MTIOC2B
SCK1/SCK12
P26
MTIOC2A
TXD1/SMOSI1/SSDA1
Others
IRQ3/CMPA2/
CACREF/ADTRG0#
FINED
PH7
P35
NMI
XTAL
9
EXTAL
10
VCL
11
VSS
12
VCC
13
P17
MTIOC0C
SCK1/MISOA/SDA0/RXD12/RXDX12/
SMISO12/SSCL12
IRQ7
14
P16
RTCOUT
TXD1/SMOSI1/SSDA1/MOSIA/SCL0
IRQ6/ADTRG0#
15
P15
MTIOC0B/MTCLKB
RXD1/SMISO1/SSCL1/RSPCKA
IRQ5/CLKOUT
16
P14
MTIOC0A/MTCLKA
CTS1#/RTS1#/SS1#/SSLA0/TXD12/
TXDX12/SIOX12/SMOSI12/SSDA12
IRQ4
17
PH3
MTIOC1A
18
PH2
IRQ1
19
PH1
20
PH0
MTIOC1B
21
PC7
MTCLKB
TXD1/SMOSI1/SSDA1/MISOA
22
PC6
MTCLKA
RXD1/SMISO1/SSCL1/MOSIA
23
PC5
MTCLKD
SCK1/RSPCKA
24
PC4
MTCLKC
SCK5/SSLA0
25
PB5/PC3
MTIOC2A/MTIOC1B
26
PB3/PC2
MTIOC0A
PB1/PC1
MTIOC0C
PB0/PC0
MTIC5W/MTIOC0C/
RTCOUT
SCL0/RSPCKA
IRQ2/ADTRG0#
PA6
MTIC5V/MTCLKB/MTIOC2A
CTS5#/RTS5#/SS5#/SDA0/MOSIA
IRQ3
27
28
CACREF
CACREF
IRQ2/CLKOUT
IRQ4
VCC
29
30
IRQ0
VSS
31
32
PA4
MTIC5U/MTCLKA/MTIOC2B
TXD5/SMOSI5/SSDA5/SSLA0
IRQ5
33
PA3
MTIOC0D/MTCLKD/
MTIOC1B
RXD5/SMISO5/SSCL5/MISOA
IRQ6
34
PA1
MTIOC0B/MTCLKC/
RTCOUT
SCK5/SSLA2
35
PE4
MTIOC1A
MOSIA
IRQ4/AN012
36
PE3
MTIOC0A/MTIOC1B
CTS12#/RTS12#/SS12#/RSPCKA
IRQ3/AN011
37
PE2
RXD12/RXDX12/SMISO12/SSCL12
IRQ7/AN010
38
PE1
TXD12/TXDX12/SIOX12/SMOSI12/
SSDA12
IRQ1/AN009
39
PE0
40
PE7
IRQ7/AN015
41
P46*1
AN006
42
P42*1
AN002
43
P41*1
AN001
44
PJ7*1
VREFL0
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MTIOC2A
SCK12
IRQ0/AN008
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RX110 Group
Table 1.7
Pin
No.
1. Overview
List of Pins and Pin Functions (48-Pin LFQFP/HWQFN) (2/2)
Power Supply, Clock,
System Control
I/O Port
45
P40*1
PJ6*1
46
VREFH0
47
AVSS0
48
AVCC0
Timers (MTU, RTC)
Communication
(SCIe, SCIf, RSPI, RIIC)
Others
AN000
Note 1. The power source of the I/O buffer for these pins is AVCC0.
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Table 1.8
Pin
No.
1. Overview
List of Pins and Pin Functions (40-Pin HWQFN)
Power Supply, Clock,
System Control
1
2
3
MD
4
RES#
5
I/O Port
Timers (MTU, RTC)
Communication
(SCIe, SCIf, RSPI, RIIC)
P27
MTIOC2B
SCK1/SCK12
P26
MTIOC2A
TXD1/SMOSI1/SSDA1
XTAL
7
EXTAL
8
VCL
9
VSS
10
VCC
IRQ3/CMPA2/
CACREF/ADTRG0#
FINED
P35
6
Others
NMI
11
P32
MTIOC0C
12
P17
MTIOC0C
13
P16
IRQ2
SCK1/MISOA/SDA0/RXD12/RXDX12/
SMISO12/SSCL12
IRQ7
TXD1/SMOSI1/SSDA1/SCL0/MOSIA
IRQ6/ADTRG0#
14
P15
MTIOC0B/MTCLKB
RXD1/SMISO1/SSCL1/RSPCKA
IRQ5/CLKOUT
15
P14
MTIOC0A/MTCLKA
CTS1#/RTS1#/SS1#/SSLA0/TXD12/
TXDX12/SIOX12/SMOSI12/SSDA12
IRQ4
16
PH3
MTIOC1A
17
PH2
IRQ1
18
PH1
19
PH0
MTIOC1B
20
PC4
MTCLKC
21
PB3
MTIOC0A
PB0
22
CACREF
SCK5/SSLA0
IRQ2/CLKOUT
MTIOC0C/MTIC5W
SCL0/RSPCKA
IRQ2/ADTRG0#
IRQ3
VCC
23
24
IRQ0
VSS
25
PA6
MTIOC2A/MTIC5V/MTCLKB
CTS5#/RTS5#/SS5#/SDA0/MOSIA
26
PA4
MTIOC2B/MTIC5U/MTCLKA
TXD5/SMOSI5/SSDA5/SSLA0
IRQ5
27
PA3
MTIOC0D/MTIOC1B/
MTCLKD
RXD5/SMISO5/SSCL5/MISOA
IRQ6
28
PA1
MTIOC0B/MTCLKC
SCK5/SSLA2
29
PE4
MTIOC1A
MOSIA
IRQ4/AN012
MTIOC0A/MTIOC1B
30
PE3
CTS12#/RTS12#/SS12#/RSPCKA
IRQ3/AN011
31
PE2
RXD12/RXDX12/SMISO12/SSCL12
IRQ7/AN010
32
PE1
TXD12/TXDX12/SIOX12/SMOSI12/
SSDA12
IRQ1/AN009
33
PE0
34
P46*1
AN006
35
P42*1
AN002
36
P41*1
AN001
37
VREFL0
PJ7*1
38
VREFH0
PJ6*1
39
AVSS0
40
AVCC0
MTIOC2A
SCK12
IRQ0/AN008
Note 1. The power source of the I/O buffer for these pins is AVCC0.
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RX110 Group
Table 1.9
1. Overview
List of Pins and Pin Functions (36-Pin WFLGA)
Pin
No.
Power Supply, Clock,
System Control
A1
AVSS0
A2
AVCC0
A3
VREFH0
I/O Port
P42*1
A5
P41*1
A6
PE2
Others
AN002
AN001
RXD12/RXDX12/SMISO12/SSCL12
IRQ7/AN010
SCK1/SCK12
IRQ3/CMPA2/
CACREF/ADTRG0#
RES#
B2
B3
Communication
(SCIe, SCIf, RSPI, RIIC)
PJ6*1
A4
B1
Timers (MTU, RTC)
P27
VREFL0
PJ7*1
B4
PE0
B5
PE1
B6
PA3
C3
C4
C1
XTAL
C2
MD
C5
C6
VSS
D1
EXTAL
MTIOC2B
MTIOC2A
SCK12
IRQ0/AN008
TXD12/TXDX12/SIOX12/SMOSI12/
SSDA12
IRQ1/AN009
MTIOC0D/MTCLKD/
MTIOC1B
RXD5/SMISO5/SSCL5/MISOA
IRQ6
PE3
MTIOC0A/MTIOC1B
CTS12#/RTS12#/SS12#/RSPCKA
IRQ3/AN011
PE4
MTIOC1A
MOSIA
IRQ4/AN012
PA4
MTIOC2B/MTIC5U/MTCLKA
TXD5/SMOSI5/SSDA5/SSLA0
IRQ5
FINED
D2
P35
D3
P14
MTIOC0A/MTCLKA
CTS1#/RTS1#/SS1#/SSLA0/TXD12/
TXDX12/SIOX12/SMOSI12/SSDA12
IRQ4
D4
PA6
MTIC5V/MTCLKB/MTIOC2A
CTS5#/RTS5#/SS5#/SDA0/MOSIA
IRQ3
D5
PB3
MTIOC0A
D6
PB0
MTIOC0C/MTIC5W
SCL0/RSPCKA
IRQ2/ADTRG0#
E2
P17
MTIOC0C
SCK1/MISOA/SDA0/RXD12/RXDX12/
SMISO12/SSCL12
IRQ7
E3
P16
TXD1/SMOSI1/SSDA1/SCL0/MOSIA
IRQ6/ADTRG0#
E1
NMI
VCL
E4
P15
MTIOC0B/MTCLKB
RXD1/SMISO1/SSCL1/RSPCKA
IRQ5/CLKOUT
E5
PC4
MTCLKC
SCK5/SSLA0
IRQ2/CLKOUT
MTIOC1A
E6
VCC
F1
VSS
F2
VCC
F3
PH3
F4
PH2
IRQ1
F5
PH1
IRQ0
F6
PH0
MTIOC1B
CACREF
Note 1. The power source of the I/O buffer for these pins is AVCC0.
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2.
2. CPU
CPU
Figure 2.1 shows the register set of the CPU.
General-purpose registers
b31
b0
R0 (SP)*1
R1
R2
R3
R4
R5
R6
R7
R8
R9
R10
R11
R12
R13
R14
R15
Control registers
b31
b0
ISP
(Interrupt stack pointer)
USP
(User stack pointer)
INTB
(Interrupt table register)
PC
(Program counter)
PSW
(Processor status word)
BPC
(Backup PC)
BPSW
(Backup PSW)
FINTV
(Fast interrupt vector register)
DSP instruction register
b63
b0
ACC (Accumulator)
Note 1. The stack pointer (SP) can be the interrupt stack pointer (ISP) or user stack pointer (USP), according to
the value of the U bit in the PSW register.
Figure 2.1
Register Set of the CPU
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2.1
2. CPU
General-Purpose Registers (R0 to R15)
This CPU has 16 general-purpose registers (R0 to R15). R0 to R15 can be used as data registers or address registers.
R0, a general-purpose register, also functions as the stack pointer (SP). The stack pointer is switched to operate as the
interrupt stack pointer (ISP) or user stack pointer (USP) by the value of the stack pointer select bit (U) in the processor
status word (PSW).
2.2
(1)
Control Registers
Interrupt Stack Pointer (ISP)/User Stack Pointer (USP)
The stack pointer (SP) can be either of two types, the interrupt stack pointer (ISP) or the user stack pointer (USP).
Whether the stack pointer operates as the ISP or USP depends on the value of the stack pointer select bit (U) in the
processor status word (PSW).
Set the ISP or USP to a multiple of 4, as this reduces the numbers of cycles required to execute interrupt sequences and
instructions entailing stack manipulation.
(2)
Interrupt Table Register (INTB)
The interrupt table register (INTB) specifies the address where the relocatable vector table starts.
(3)
Program Counter (PC)
The program counter (PC) indicates the address of the instruction being executed.
(4)
Processor Status Word (PSW)
The processor status word (PSW) indicates the results of instruction execution or the state of the CPU.
(5)
Backup PC (BPC)
The backup PC (BPC) is provided to speed up response to interrupts.
After a fast interrupt has been generated, the contents of the program counter (PC) are saved in the BPC register.
(6)
Backup PSW (BPSW)
The backup PSW (BPSW) is provided to speed up response to interrupts.
After a fast interrupt has been generated, the contents of the processor status word (PSW) are saved in the BPSW. The
allocation of bits in the BPSW corresponds to that in the PSW.
(7)
Fast Interrupt Vector Register (FINTV)
The fast interrupt vector register (FINTV) is provided to speed up response to interrupts.
The FINTV register specifies a branch destination address when a fast interrupt has been generated.
2.3
(1)
Register Associated with DSP Instructions
Accumulator (ACC)
The accumulator (ACC) is a 64-bit register used for DSP instructions. The accumulator is also used for the multiply and
multiply-and-accumulate instructions; EMUL, EMULU, MUL, and RMPA, in which case the prior value in the
accumulator is modified by execution of the instruction.
Use the MVTACHI and MVTACLO instructions for writing to the accumulator. The MVTACHI and MVTACLO
instructions write data to the higher-order 32 bits (bits 63 to 32) and the lower-order 32 bits (bits 31 to 0), respectively.
Use the MVFACHI and MVFACMI instructions for reading data from the accumulator. The MVFACHI and MVFACMI
instructions read data from the higher-order 32 bits (bits 63 to 32) and the middle 32 bits (bits 47 to 16), respectively.
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3.
Address Space
3.1
Address Space
3. Address Space
This MCU has a 4-Gbyte address space, consisting of the range of addresses from 0000 0000h to FFFF FFFFh. That is,
linear access to an address space of up to 4 Gbytes is possible, and this contains program area.
Figure 3.1 shows the memory map.
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RX110 Group
3. Address Space
Single-chip mode*1
0000 0000h
RAM*2
0000 4000h
Reserved area*3
0008 0000h
Peripheral I/O registers
0010 0000h
Reserved area*3
007F C000h
007F C500h
Peripheral I/O registers
Reserved area*3
007F FC00h
0080 0000h
Peripheral I/O registers
Reserved area*3
FFFE 0000h
On-chip ROM (program ROM)*2
FFFF FFFFh
Note 1.
Note 2.
The address space in boot mode is the same as the address space in single-chip mode.
The capacity of ROM/RAM differs depending on the products.
ROM (bytes)
RAM (bytes)
Capacity
Address
Capacity
Address
128 K
FFFE 0000h to FFFF FFFFh
16 K
0000 0000h to 0000 3FFFh
96 K
FFFE 8000h to FFFF FFFFh
10 K
0000 0000h to 0000 27FFh
8K
0000 0000h to 0000 1FFFh
64 K
FFFF 0000h to FFFF FFFFh
32 K
FFFF 8000h to FFFF FFFFh
16 K
FFFF C000h to FFFF FFFFh
8K
FFFF E000h to FFFF FFFFh
Note:See Table 1.3, List of Products, for the product type name.
Note 3. Reserved areas should not be accessed.
Figure 3.1
Memory Map
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4.
4. I/O Registers
I/O Registers
This section provides information on the on-chip I/O register addresses and bit configuration. The information is given as
shown below. Notes on writing to I/O registers are also given below.
(1)
I/O register addresses (address order)
Registers are listed from the lower allocation addresses.
Registers are classified according to module symbols.
Numbers of cycles for access indicate numbers of cycles of the given base clock.
Among the internal I/O register area, addresses not listed in the list of registers are reserved. Reserved addresses
must not be accessed. Do not access these addresses; otherwise, the operation when accessing these bits and
subsequent operations cannot be guaranteed.
(2)
Notes on writing to I/O registers
While writing to an I/O register, the CPU starts executing subsequent instructions before the I/O register write access is
completed. This may cause the subsequent instructions to be executed before the write value is reflected in the operation.
The examples below show how subsequent instructions must be executed after a write access to an I/O register is
completed.
[Examples of cases requiring special care]
The subsequent instruction must be executed while an interrupt request is disabled with the IENj bit in IERn of the
ICU (interrupt request enable bit) set to 0.
A WAIT instruction is executed immediately after the preprocessing for causing a transition to the low power
consumption state.
In the above cases, after writing to an I/O register, wait until the write operation is completed using the following
procedure and then execute the subsequent instruction.
(a)
(b)
(c)
(d)
Write to an I/O register.
Read the value in the I/O register and write it to a general register.
Execute the operation using the value read.
Execute the subsequent instruction.
Example of instructions
Byte-size I/O registers
MOV.L #SFR_ADDR, R1
MOV.B #SFR_DATA, [R1]
CMP [R1].UB, R1
;; Next process
Word-size I/O registers
MOV.L #SFR_ADDR, R1
MOV.W #SFR_DATA, [R1]
CMP [R1].W, R1
;; Next process
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4. I/O Registers
Longword-size I/O registers
MOV.L #SFR_ADDR, R1
MOV.L #SFR_DATA, [R1]
CMP [R1].L, R1
;; Next process
When executing an instruction after writing to multiple registers, only read the last I/O register written to and execute the
instruction using that value; it is not necessary to execute the instruction using the values written to all the registers.
(3)
Number of cycles necessary for accessing I/O registers
See Table 4.1 for details on the number of clock cycles necessary for accessing I/O registers.
The number of access cycles to I/O registers is obtained by following equation.*1
Number of access cycles to I/O registers = Number of bus cycles for internal main bus 1 +
Number of divided clock synchronization cycles +
Number of bus cycles for internal peripheral buses 1, 2, and 4 to 6
The number of bus cycles of internal peripheral buses 1, 2, and 4 to 6 differs according to the register to be accessed.
When peripheral functions connected to internal peripheral buses 2, and 4 to 6 or registers for the external bus control
unit (except for bus error related registers) are accessed, the number of divided clock synchronization cycles is added.
The number of divided clock synchronization cycles differs depending on the frequency ratio between ICLK and PCLK
(or FCLK) or bus access timing.
In the peripheral function unit, when the frequency ratio of ICLK is equal to or greater than that of PCLK (or FCLK), the
sum of the number of bus cycles for internal main bus 1 and the number of the divided clock synchronization cycles will
be one cycle of PCLK (or FCLK) at a maximum. Therefore, one PCLK (or FCLK) has been added to the number of
access cycles shown in Table 4.1.
When the frequency ratio of ICLK is lower than that of PCLK (or FCLK), the subsequent bus access is started from the
ICLK cycle following the completion of the access to the peripheral functions. Therefore, the access cycles are described
on an ICLK basis.
Note 1. This applies to the number of cycles when the access from the CPU does not conflict with the bus access from
the different bus master (DTC).
(4)
Notes on sleep mode and mode transitions
During sleep mode or mode transitions, do not write to the system control related registers (indicated by ‘SYSTEM’ in
the Module Symbol column in Table 4.1, List of I/O Registers (Address Order)).
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4.1
I/O Register Addresses (Address Order)
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (1/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 0000h
SYSTEM
Mode Monitor Register
MDMONR
16
16
3 ICLK
0008 0008h
SYSTEM
System Control Register 1
SYSCR1
16
16
3 ICLK
3 ICLK
0008 000Ch
SYSTEM
Standby Control Register
SBYCR
16
16
0008 0010h
SYSTEM
Module Stop Control Register A
MSTPCRA
32
32
3 ICLK
0008 0014h
SYSTEM
Module Stop Control Register B
MSTPCRB
32
32
3 ICLK
0008 0018h
SYSTEM
Module Stop Control Register C
MSTPCRC
32
32
3 ICLK
0008 0020h
SYSTEM
System Clock Control Register
SCKCR
32
32
3 ICLK
0008 0026h
SYSTEM
System Clock Control Register 3
SCKCR3
16
16
3 ICLK
0008 0032h
SYSTEM
Main Clock Oscillator Control Register
MOSCCR
8
8
3 ICLK
0008 0033h
SYSTEM
Sub-Clock Oscillator Control Register
SOSCCR
8
8
3 ICLK
0008 0034h
SYSTEM
Low-Speed On-Chip Oscillator Control Register
LOCOCR
8
8
3 ICLK
0008 0035h
SYSTEM
IWDT-Dedicated On-Chip Oscillator Control Register
ILOCOCR
8
8
3 ICLK
0008 0036h
SYSTEM
High-Speed On-Chip Oscillator Control Register
HOCOCR
8
8
3 ICLK
0008 003Ch
SYSTEM
Oscillation Stabilization Flag Register
OSCOVFSR
8
8
3 ICLK
0008 003Eh
SYSTEM
CLKOUT Output Control Register
CKOCR
16
16
3 ICLK
3 ICLK
0008 0040h
SYSTEM
Oscillation Stop Detection Control Register
OSTDCR
8
8
0008 0041h
SYSTEM
Oscillation Stop Detection Status Register
OSTDSR
8
8
3 ICLK
0008 00A0h
SYSTEM
Operating Power Control Register
OPCCR
8
8
3 ICLK
0008 00A1h
SYSTEM
Sleep Mode Return Clock Source Switching Register
RSTCKCR
8
8
3 ICLK
0008 00A2h
SYSTEM
Main Clock Oscillator Wait Control Register
MOSCWTCR
8
8
3 ICLK
0008 00A5h
SYSTEM
High-Speed On-Chip Oscillator Wait Control Register
HOCOWTCR
8
8
3 ICLK
0008 00AAh
SYSTEM
Sub Operating Power Control Register
SOPCCR
8
8
3 ICLK
0008 00C0h
SYSTEM
Reset Status Register 2
RSTSR2
8
8
3 ICLK
0008 00C2h
SYSTEM
Software Reset Register
SWRR
16
16
3 ICLK
3 ICLK
0008 00E0h
SYSTEM
Voltage Monitoring 1 Circuit Control Register 1
LVD1CR1
8
8
0008 00E1h
SYSTEM
Voltage Monitoring 1 Circuit Status Register
LVD1SR
8
8
3 ICLK
0008 00E2h
SYSTEM
Voltage Monitoring 2 Circuit Control Register 1
LVD2CR1
8
8
3 ICLK
0008 00E3h
SYSTEM
Voltage Monitoring 2 Circuit Status Register
LVD2SR
8
8
3 ICLK
0008 03FEh
SYSTEM
Protect Register
PRCR
16
16
3 ICLK
0008 1300h
BSC
Bus Error Status Clear Register
BERCLR
8
8
2 ICLK
0008 1304h
BSC
Bus Error Monitoring Enable Register
BEREN
8
8
2 ICLK
0008 1308h
BSC
Bus Error Status Register 1
BERSR1
8
8
2 ICLK
0008 130Ah
BSC
Bus Error Status Register 2
BERSR2
16
16
2 ICLK
0008 1310h
BSC
Bus Priority Control Register
BUSPRI
16
16
2 ICLK
0008 2400h
DTC
DTC Control Register
DTCCR
8
8
2 ICLK
0008 2404h
DTC
DTC Vector Base Register
DTCVBR
32
32
2 ICLK
0008 2408h
DTC
DTC Address Mode Register
DTCADMOD
8
8
2 ICLK
0008 240Ch
DTC
DTC Module Start Register
DTCST
8
8
2 ICLK
0008 240Eh
DTC
DTC Status Register
DTCSTS
16
16
2 ICLK
0008 7010h
ICU
Interrupt Request Register 016
IR016
8
8
2 ICLK
0008 701Bh
ICU
Interrupt Request Register 027
IR027
8
8
2 ICLK
0008 701Ch
ICU
Interrupt Request Register 028
IR028
8
8
2 ICLK
2 ICLK
0008 701Dh
ICU
Interrupt Request Register 029
IR029
8
8
0008 7020h
ICU
Interrupt Request Register 032
IR032
8
8
2 ICLK
0008 7021h
ICU
Interrupt Request Register 033
IR033
8
8
2 ICLK
0008 7022h
ICU
Interrupt Request Register 034
IR034
8
8
2 ICLK
0008 7024h
ICU
Interrupt Request Register 036
IR036
8
8
2 ICLK
0008 7025h
ICU
Interrupt Request Register 037
IR037
8
8
2 ICLK
0008 7026h
ICU
Interrupt Request Register 038
IR038
8
8
2 ICLK
0008 702Ch
ICU
Interrupt Request Register 044
IR044
8
8
2 ICLK
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Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (2/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 702Dh
ICU
Interrupt Request Register 045
IR045
8
8
2 ICLK
0008 702Eh
ICU
Interrupt Request Register 046
IR046
8
8
2 ICLK
0008 702Fh
ICU
Interrupt Request Register 047
IR047
8
8
2 ICLK
0008 7039h
ICU
Interrupt Request Register 057
IR057
8
8
2 ICLK
0008 703Fh
ICU
Interrupt Request Register 063
IR063
8
8
2 ICLK
0008 7040h
ICU
Interrupt Request Register 064
IR064
8
8
2 ICLK
0008 7041h
ICU
Interrupt Request Register 065
IR065
8
8
2 ICLK
0008 7042h
ICU
Interrupt Request Register 066
IR066
8
8
2 ICLK
0008 7043h
ICU
Interrupt Request Register 067
IR067
8
8
2 ICLK
0008 7044h
ICU
Interrupt Request Register 068
IR068
8
8
2 ICLK
0008 7045h
ICU
Interrupt Request Register 069
IR069
8
8
2 ICLK
0008 7046h
ICU
Interrupt Request Register 070
IR070
8
8
2 ICLK
0008 7047h
ICU
Interrupt Request Register 071
IR071
8
8
2 ICLK
0008 7058h
ICU
Interrupt Request Register 088
IR088
8
8
2 ICLK
0008 7059h
ICU
Interrupt Request Register 089
IR089
8
8
2 ICLK
0008 705Ah
ICU
Interrupt Request Register 090
IR090
8
8
2 ICLK
0008 705Ch
ICU
Interrupt Request Register 092
IR092
8
8
2 ICLK
0008 705Dh
ICU
Interrupt Request Register 093
IR093
8
8
2 ICLK
0008 7066h
ICU
Interrupt Request Register 102
IR102
8
8
2 ICLK
0008 7067h
ICU
Interrupt Request Register 103
IR103
8
8
2 ICLK
0008 706Ah
ICU
Interrupt Request Register 106
IR106
8
8
2 ICLK
0008 7072h
ICU
Interrupt Request Register 114
IR114
8
8
2 ICLK
0008 7073h
ICU
Interrupt Request Register 115
IR115
8
8
2 ICLK
0008 7074h
ICU
Interrupt Request Register 116
IR116
8
8
2 ICLK
0008 7075h
ICU
Interrupt Request Register 117
IR117
8
8
2 ICLK
0008 7076h
ICU
Interrupt Request Register 118
IR118
8
8
2 ICLK
0008 7077h
ICU
Interrupt Request Register 119
IR119
8
8
2 ICLK
0008 7078h
ICU
Interrupt Request Register 120
IR120
8
8
2 ICLK
0008 7079h
ICU
Interrupt Request Register 121
IR121
8
8
2 ICLK
0008 707Ah
ICU
Interrupt Request Register 122
IR122
8
8
2 ICLK
0008 707Bh
ICU
Interrupt Request Register 123
IR123
8
8
2 ICLK
0008 707Ch
ICU
Interrupt Request Register 124
IR124
8
8
2 ICLK
0008 707Dh
ICU
Interrupt Request Register 125
IR125
8
8
2 ICLK
0008 707Eh
ICU
Interrupt Request Register 126
IR126
8
8
2 ICLK
0008 707Fh
ICU
Interrupt Request Register 127
IR127
8
8
2 ICLK
0008 7080h
ICU
Interrupt Request Register 128
IR128
8
8
2 ICLK
0008 7081h
ICU
Interrupt Request Register 129
IR129
8
8
2 ICLK
0008 7082h
ICU
Interrupt Request Register 130
IR130
8
8
2 ICLK
0008 7083h
ICU
Interrupt Request Register 131
IR131
8
8
2 ICLK
0008 7084h
ICU
Interrupt Request Register 132
IR132
8
8
2 ICLK
0008 7085h
ICU
Interrupt Request Register 133
IR133
8
8
2 ICLK
0008 7086h
ICU
Interrupt Request Register 134
IR134
8
8
2 ICLK
0008 7087h
ICU
Interrupt Request Register 135
IR135
8
8
2 ICLK
0008 7088h
ICU
Interrupt Request Register 136
IR136
8
8
2 ICLK
0008 7089h
ICU
Interrupt Request Register 137
IR137
8
8
2 ICLK
0008 708Ah
ICU
Interrupt Request Register 138
IR138
8
8
2 ICLK
0008 708Bh
ICU
Interrupt Request Register 139
IR139
8
8
2 ICLK
0008 708Ch
ICU
Interrupt Request Register 140
IR140
8
8
2 ICLK
0008 708Dh
ICU
Interrupt Request Register 141
IR141
8
8
2 ICLK
0008 70AAh
ICU
Interrupt Request Register 170
IR170
8
8
2 ICLK
0008 70ABh
ICU
Interrupt Request Register 171
IR171
8
8
2 ICLK
0008 70DAh
ICU
Interrupt Request Register 218
IR218
8
8
2 ICLK
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 33 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (3/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 70DBh
ICU
Interrupt Request Register 219
IR219
8
8
2 ICLK
0008 70DCh
ICU
Interrupt Request Register 220
IR220
8
8
2 ICLK
0008 70DDh
ICU
Interrupt Request Register 221
IR221
8
8
2 ICLK
0008 70DEh
ICU
Interrupt Request Register 222
IR222
8
8
2 ICLK
0008 70DFh
ICU
Interrupt Request Register 223
IR223
8
8
2 ICLK
0008 70E0h
ICU
Interrupt Request Register 224
IR224
8
8
2 ICLK
0008 70E1h
ICU
Interrupt Request Register 225
IR225
8
8
2 ICLK
0008 70EEh
ICU
Interrupt Request Register 238
IR238
8
8
2 ICLK
0008 70EFh
ICU
Interrupt Request Register 239
IR239
8
8
2 ICLK
0008 70F0h
ICU
Interrupt Request Register 240
IR240
8
8
2 ICLK
0008 70F1h
ICU
Interrupt Request Register 241
IR241
8
8
2 ICLK
0008 70F2h
ICU
Interrupt Request Register 242
IR242
8
8
2 ICLK
0008 70F3h
ICU
Interrupt Request Register 243
IR243
8
8
2 ICLK
0008 70F4h
ICU
Interrupt Request Register 244
IR244
8
8
2 ICLK
0008 70F5h
ICU
Interrupt Request Register 245
IR245
8
8
2 ICLK
0008 70F6h
ICU
Interrupt Request Register 246
IR246
8
8
2 ICLK
0008 70F7h
ICU
Interrupt Request Register 247
IR247
8
8
2 ICLK
0008 70F8h
ICU
Interrupt Request Register 248
IR248
8
8
2 ICLK
0008 70F9h
ICU
Interrupt Request Register 249
IR249
8
8
2 ICLK
0008 711Bh
ICU
DTC Activation Enable Register 027
DTCER027
8
8
2 ICLK
0008 711Ch
ICU
DTC Activation Enable Register 028
DTCER028
8
8
2 ICLK
0008 711Dh
ICU
DTC Activation Enable Register 029
DTCER029
8
8
2 ICLK
0008 712Dh
ICU
DTC Activation Enable Register 045
DTCER045
8
8
2 ICLK
0008 712Eh
ICU
DTC Activation Enable Register 046
DTCER046
8
8
2 ICLK
0008 7140h
ICU
DTC Activation Enable Register 064
DTCER064
8
8
2 ICLK
0008 7141h
ICU
DTC Activation Enable Register 065
DTCER065
8
8
2 ICLK
0008 7142h
ICU
DTC Activation Enable Register 066
DTCER066
8
8
2 ICLK
0008 7143h
ICU
DTC Activation Enable Register 067
DTCER067
8
8
2 ICLK
0008 7144h
ICU
DTC Activation Enable Register 068
DTCER068
8
8
2 ICLK
0008 7145h
ICU
DTC Activation Enable Register 069
DTCER069
8
8
2 ICLK
0008 7146h
ICU
DTC Activation Enable Register 070
DTCER070
8
8
2 ICLK
0008 7147h
ICU
DTC Activation Enable Register 071
DTCER071
8
8
2 ICLK
0008 7166h
ICU
DTC Activation Enable Register 102
DTCER102
8
8
2 ICLK
0008 7167h
ICU
DTC Activation Enable Register 103
DTCER103
8
8
2 ICLK
0008 7172h
ICU
DTC Activation Enable Register 114
DTCER114
8
8
2 ICLK
0008 7173h
ICU
DTC Activation Enable Register 115
DTCER115
8
8
2 ICLK
0008 7174h
ICU
DTC Activation Enable Register 116
DTCER116
8
8
2 ICLK
0008 7175h
ICU
DTC Activation Enable Register 117
DTCER117
8
8
2 ICLK
0008 7179h
ICU
DTC Activation Enable Register 121
DTCER121
8
8
2 ICLK
0008 717Ah
ICU
DTC Activation Enable Register 122
DTCER122
8
8
2 ICLK
0008 717Dh
ICU
DTC Activation Enable Register 125
DTCER125
8
8
2 ICLK
0008 717Eh
ICU
DTC Activation Enable Register 126
DTCER126
8
8
2 ICLK
0008 718Bh
ICU
DTC Activation Enable Register 139
DTCER139
8
8
2 ICLK
0008 718Ch
ICU
DTC Activation Enable Register 140
DTCER140
8
8
2 ICLK
0008 718Dh
ICU
DTC Activation Enable Register 141
DTCER141
8
8
2 ICLK
0008 71DBh
ICU
DTC Activation Enable Register 219
DTCER219
8
8
2 ICLK
0008 71DCh
ICU
DTC Activation Enable Register 220
DTCER220
8
8
2 ICLK
0008 71DFh
ICU
DTC Activation Enable Register 223
DTCER223
8
8
2 ICLK
0008 71E0h
ICU
DTC Activation Enable Register 224
DTCER224
8
8
2 ICLK
0008 71EFh
ICU
DTC Activation Enable Register 239
DTCER239
8
8
2 ICLK
0008 71F0h
ICU
DTC Activation Enable Register 240
DTCER240
8
8
2 ICLK
0008 71F7h
ICU
DTC Activation Enable Register 247
DTCER247
8
8
2 ICLK
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 34 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (4/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 71F8h
ICU
DTC Activation Enable Register 248
DTCER248
8
8
2 ICLK
0008 7202h
ICU
Interrupt Request Enable Register 02
IER02
8
8
2 ICLK
0008 7203h
ICU
Interrupt Request Enable Register 03
IER03
8
8
2 ICLK
0008 7204h
ICU
Interrupt Request Enable Register 04
IER04
8
8
2 ICLK
0008 7205h
ICU
Interrupt Request Enable Register 05
IER05
8
8
2 ICLK
0008 7207h
ICU
Interrupt Request Enable Register 07
IER07
8
8
2 ICLK
0008 7208h
ICU
Interrupt Request Enable Register 08
IER08
8
8
2 ICLK
0008 720Bh
ICU
Interrupt Request Enable Register 0B
IER0B
8
8
2 ICLK
0008 720Ch
ICU
Interrupt Request Enable Register 0C
IER0C
8
8
2 ICLK
0008 720Eh
ICU
Interrupt Request Enable Register 0E
IER0E
8
8
2 ICLK
0008 720Fh
ICU
Interrupt Request Enable Register 0F
IER0F
8
8
2 ICLK
0008 7210h
ICU
Interrupt Request Enable Register 10
IER10
8
8
2 ICLK
0008 7211h
ICU
Interrupt Request Enable Register 11
IER11
8
8
2 ICLK
0008 721Bh
ICU
Interrupt Request Enable Register 1B
IER1B
8
8
2 ICLK
0008 721Ch
ICU
Interrupt Request Enable Register 1C
IER1C
8
8
2 ICLK
0008 721Dh
ICU
Interrupt Request Enable Register 1D
IER1D
8
8
2 ICLK
0008 721Eh
ICU
Interrupt Request Enable Register 1E
IER1E
8
8
2 ICLK
0008 721Fh
ICU
Interrupt Request Enable Register 1F
IER1F
8
8
2 ICLK
0008 72E0h
ICU
Software Interrupt Activation Register
SWINTR
8
8
2 ICLK
0008 72F0h
ICU
Fast Interrupt Set Register
FIR
16
16
2 ICLK
0008 7300h
ICU
Interrupt Source Priority Register 000
IPR000
8
8
2 ICLK
0008 7303h
ICU
Interrupt Source Priority Register 003
IPR003
8
8
2 ICLK
0008 7304h
ICU
Interrupt Source Priority Register 004
IPR004
8
8
2 ICLK
0008 7305h
ICU
Interrupt Source Priority Register 005
IPR005
8
8
2 ICLK
0008 7320h
ICU
Interrupt Source Priority Register 032
IPR032
8
8
2 ICLK
0008 7321h
ICU
Interrupt Source Priority Register 033
IPR033
8
8
2 ICLK
0008 7322h
ICU
Interrupt Source Priority Register 034
IPR034
8
8
2 ICLK
0008 732Ch
ICU
Interrupt Source Priority Register 044
IPR044
8
8
2 ICLK
0008 7339h
ICU
Interrupt Source Priority Register 057
IPR057
8
8
2 ICLK
0008 733Fh
ICU
Interrupt Source Priority Register 063
IPR063
8
8
2 ICLK
0008 7340h
ICU
Interrupt Source Priority Register 064
IPR064
8
8
2 ICLK
0008 7341h
ICU
Interrupt Source Priority Register 065
IPR065
8
8
2 ICLK
0008 7342h
ICU
Interrupt Source Priority Register 066
IPR066
8
8
2 ICLK
0008 7343h
ICU
Interrupt Source Priority Register 067
IPR067
8
8
2 ICLK
0008 7344h
ICU
Interrupt Source Priority Register 068
IPR068
8
8
2 ICLK
0008 7345h
ICU
Interrupt Source Priority Register 069
IPR069
8
8
2 ICLK
0008 7346h
ICU
Interrupt Source Priority Register 070
IPR070
8
8
2 ICLK
0008 7347h
ICU
Interrupt Source Priority Register 071
IPR071
8
8
2 ICLK
0008 7358h
ICU
Interrupt Source Priority Register 088
IPR088
8
8
2 ICLK
0008 7359h
ICU
Interrupt Source Priority Register 089
IPR089
8
8
2 ICLK
0008 735Ch
ICU
Interrupt Source Priority Register 092
IPR092
8
8
2 ICLK
0008 735Dh
ICU
Interrupt Source Priority Register 093
IPR093
8
8
2 ICLK
0008 7366h
ICU
Interrupt Source Priority Register 102
IPR102
8
8
2 ICLK
0008 7367h
ICU
Interrupt Source Priority Register 103
IPR103
8
8
2 ICLK
0008 7372h
ICU
Interrupt Source Priority Register 114
IPR114
8
8
2 ICLK
0008 7376h
ICU
Interrupt Source Priority Register 118
IPR118
8
8
2 ICLK
0008 7379h
ICU
Interrupt Source Priority Register 121
IPR121
8
8
2 ICLK
0008 737Bh
ICU
Interrupt Source Priority Register 123
IPR123
8
8
2 ICLK
0008 737Dh
ICU
Interrupt Source Priority Register 125
IPR125
8
8
2 ICLK
0008 737Fh
ICU
Interrupt Source Priority Register 127
IPR127
8
8
2 ICLK
0008 738Bh
ICU
Interrupt Source Priority Register 139
IPR139
8
8
2 ICLK
0008 73DAh
ICU
Interrupt Source Priority Register 218
IPR218
8
8
2 ICLK
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 35 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (5/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 73DEh
ICU
Interrupt Source Priority Register 222
IPR222
8
8
2 ICLK
0008 73EEh
ICU
Interrupt Source Priority Register 238
IPR238
8
8
2 ICLK
0008 73F2h
ICU
Interrupt Source Priority Register 242
IPR242
8
8
2 ICLK
0008 73F3h
ICU
Interrupt Source Priority Register 243
IPR243
8
8
2 ICLK
0008 73F4h
ICU
Interrupt Source Priority Register 244
IPR244
8
8
2 ICLK
0008 73F5h
ICU
Interrupt Source Priority Register 245
IPR245
8
8
2 ICLK
0008 73F6h
ICU
Interrupt Source Priority Register 246
IPR246
8
8
2 ICLK
0008 73F7h
ICU
Interrupt Source Priority Register 247
IPR247
8
8
2 ICLK
0008 73F8h
ICU
Interrupt Source Priority Register 248
IPR248
8
8
2 ICLK
0008 73F9h
ICU
Interrupt Source Priority Register 249
IPR249
8
8
2 ICLK
0008 7500h
ICU
IRQ Control Register 0
IRQCR0
8
8
2 ICLK
0008 7501h
ICU
IRQ Control Register 1
IRQCR1
8
8
2 ICLK
0008 7502h
ICU
IRQ Control Register 2
IRQCR2
8
8
2 ICLK
0008 7503h
ICU
IRQ Control Register 3
IRQCR3
8
8
2 ICLK
0008 7504h
ICU
IRQ Control Register 4
IRQCR4
8
8
2 ICLK
0008 7505h
ICU
IRQ Control Register 5
IRQCR5
8
8
2 ICLK
0008 7506h
ICU
IRQ Control Register 6
IRQCR6
8
8
2 ICLK
0008 7507h
ICU
IRQ Control Register 7
IRQCR7
8
8
2 ICLK
0008 7510h
ICU
IRQ Pin Digital Filter Enable Register 0
IRQFLTE0
8
8
2 ICLK
0008 7514h
ICU
IRQ Pin Digital Filter Setting Register 0
IRQFLTC0
16
16
2 ICLK
0008 7580h
ICU
Non-Maskable Interrupt Status Register
NMISR
8
8
2 ICLK
0008 7581h
ICU
Non-Maskable Interrupt Enable Register
NMIER
8
8
2 ICLK
0008 7582h
ICU
Non-Maskable Interrupt Status Clear Register
NMICLR
8
8
2 ICLK
0008 7583h
ICU
NMI Pin Interrupt Control Register
NMICR
8
8
2 ICLK
0008 7590h
ICU
NMI Pin Digital Filter Enable Register
NMIFLTE
8
8
2 ICLK
0008 7594h
ICU
NMI Pin Digital Filter Setting Register
NMIFLTC
8
8
2 ICLK
0008 8000h
CMT
Compare Match Timer Start Register 0
CMSTR0
16
16
2 or 3 PCLKB
0008 8002h
CMT0
Compare Match Timer Control Register
CMCR
16
16
2 or 3 PCLKB
0008 8004h
CMT0
Compare Match Timer Counter
CMCNT
16
16
2 or 3 PCLKB
0008 8006h
CMT0
Compare Match Timer Constant Register
CMCOR
16
16
2 or 3 PCLKB
0008 8008h
CMT1
Compare Match Timer Control Register
CMCR
16
16
2 or 3 PCLKB
0008 800Ah
CMT1
Compare Match Timer Counter
CMCNT
16
16
2 or 3 PCLKB
0008 800Ch
CMT1
Compare Match Timer Constant Register
CMCOR
16
16
2 or 3 PCLKB
0008 8030h
IWDT
IWDT Refresh Register
IWDTRR
8
8
2 or 3 PCLKB
0008 8032h
IWDT
IWDT Control Register
IWDTCR
16
16
2 or 3 PCLKB
0008 8034h
IWDT
IWDT Status Register
IWDTSR
16
16
2 or 3 PCLKB
0008 8036h
IWDT
IWDT Reset Control Register
IWDTRCR
8
8
2 or 3 PCLKB
0008 8038h
IWDT
IWDT Count Stop Control Register
IWDTCSTPR
8
8
2 or 3 PCLKB
0008 8280h
CRC
CRC Control Register
CRCCR
8
8
2 or 3 PCLKB
0008 8281h
CRC
CRC Data Input Register
CRCDIR
8
8
2 or 3 PCLKB
0008 8282h
CRC
CRC Data Output Register
CRCDOR
16
16
2 or 3 PCLKB
0008 8300h
RIIC0
I2C Bus Control Register 1
ICCR1
8
8
2 or 3 PCLKB
0008 8301h
RIIC0
I2C Bus Control Register 2
ICCR2
8
8
2 or 3 PCLKB
0008 8302h
RIIC0
I2C Bus Mode Register 1
ICMR1
8
8
2 or 3 PCLKB
0008 8303h
RIIC0
I2C
Bus Mode Register 2
ICMR2
8
8
2 or 3 PCLKB
0008 8304h
RIIC0
I2C Bus Mode Register 3
ICMR3
8
8
2 or 3 PCLKB
0008 8305h
RIIC0
I2C Bus Function Enable Register
ICFER
8
8
2 or 3 PCLKB
0008 8306h
RIIC0
I2C Bus Status Enable Register
ICSER
8
8
2 or 3 PCLKB
0008 8307h
RIIC0
I2C Bus Interrupt Enable Register
ICIER
8
8
2 or 3 PCLKB
0008 8308h
RIIC0
I2C Bus Status Register 1
ICSR1
8
8
2 or 3 PCLKB
0008 8309h
RIIC0
I2C Bus Status Register 2
ICSR2
8
8
2 or 3 PCLKB
0008 830Ah
RIIC0
Slave Address Register L0
SARL0
8
8
2 or 3 PCLKB
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 36 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (6/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 830Ah
RIIC0
Timeout Internal Counter L
TMOCNTL
8
8
2 or 3 PCLKB
0008 830Bh
RIIC0
Slave Address Register U0
SARU0
8
8
2 or 3 PCLKB
0008 830Bh
RIIC0
Timeout Internal Counter U
TMOCNTU
8
8 *1
2 or 3 PCLKB
0008 830Ch
RIIC0
Slave Address Register L1
SARL1
8
8
2 or 3 PCLKB
0008 830Dh
RIIC0
Slave Address Register U1
SARU1
8
8
2 or 3 PCLKB
0008 830Eh
RIIC0
Slave Address Register L2
SARL2
8
8
2 or 3 PCLKB
0008 830Fh
RIIC0
Slave Address Register U2
SARU2
8
8
2 or 3 PCLKB
0008 8310h
RIIC0
I2C Bus Bit Rate Low-Level Register
ICBRL
8
8
2 or 3 PCLKB
0008 8311h
RIIC0
I2C Bus Bit Rate High-Level Register
ICBRH
8
8
2 or 3 PCLKB
0008 8312h
RIIC0
I2C Bus Transmit Data Register
ICDRT
8
8
2 or 3 PCLKB
0008 8313h
RIIC0
I2C Bus Receive Data Register
ICDRR
8
8
2 or 3 PCLKB
0008 8380h
RSPI0
RSPI Control Register
SPCR
8
8
2 or 3 PCLKB
0008 8381h
RSPI0
RSPI Slave Select Polarity Register
SSLP
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 8382h
RSPI0
RSPI Pin Control Register
SPPCR
8
8
0008 8383h
RSPI0
RSPI Status Register
SPSR
8
8
2 or 3 PCLKB
0008 8384h
RSPI0
RSPI Data Register
SPDR
32
16, 32
2 or 3 PCLKB/2ICLK
0008 8388h
RSPI0
RSPI Sequence Control Register
SPSCR
8
8
2 or 3 PCLKB
0008 8389h
RSPI0
RSPI Sequence Status Register
SPSSR
8
8
2 or 3 PCLKB
0008 838Ah
RSPI0
RSPI Bit Rate Register
SPBR
8
8
2 or 3 PCLKB
0008 838Bh
RSPI0
RSPI Data Control Register
SPDCR
8
8
2 or 3 PCLKB
0008 838Ch
RSPI0
RSPI Clock Delay Register
SPCKD
8
8
2 or 3 PCLKB
0008 838Dh
RSPI0
RSPI Slave Select Negation Delay Register
SSLND
8
8
2 or 3 PCLKB
0008 838Eh
RSPI0
RSPI Next-Access Delay Register
SPND
8
8
2 or 3 PCLKB
0008 838Fh
RSPI0
RSPI Control Register 2
SPCR2
8
8
2 or 3 PCLKB
0008 8390h
RSPI0
RSPI Command Register 0
SPCMD0
16
16
2 or 3 PCLKB
0008 8392h
RSPI0
RSPI Command Register 1
SPCMD1
16
16
2 or 3 PCLKB
0008 8394h
RSPI0
RSPI Command Register 2
SPCMD2
16
16
2 or 3 PCLKB
0008 8396h
RSPI0
RSPI Command Register 3
SPCMD3
16
16
2 or 3 PCLKB
0008 8398h
RSPI0
RSPI Command Register 4
SPCMD4
16
16
2 or 3 PCLKB
0008 839Ah
RSPI0
RSPI Command Register 5
SPCMD5
16
16
2 or 3 PCLKB
0008 839Ch
RSPI0
RSPI Command Register 6
SPCMD6
16
16
2 or 3 PCLKB
2 or 3 PCLKB
0008 839Eh
RSPI0
RSPI Command Register 7
SPCMD7
16
16
0008 8680h
MTU
Timer Start Register
TSTR
8
8, 16
2 or 3 PCLKB
0008 8681h
MTU
Timer Synchronous Register
TSYR
8
8, 16
2 or 3 PCLKB
0008 8690h
MTU0
Noise Filter Control Register
NFCR
8
8, 16
2 or 3 PCLKB
0008 8691h
MTU1
Noise Filter Control Register
NFCR
8
8, 16
2 or 3 PCLKB
0008 8692h
MTU2
Noise Filter Control Register
NFCR
8
8, 16
2 or 3 PCLKB
0008 8695h
MTU5
Noise Filter Control Register
NFCR
8
8, 16
2 or 3 PCLKB
2 or 3 PCLKB
0008 8700h
MTU0
Timer Control Register
TCR
8
8
0008 8701h
MTU0
Timer Mode Register
TMDR
8
8
2 or 3 PCLKB
0008 8702h
MTU0
Timer I/O Control Register H
TIORH
8
8
2 or 3 PCLKB
0008 8703h
MTU0
Timer I/O Control Register L
TIORL
8
8
2 or 3 PCLKB
0008 8704h
MTU0
Timer Interrupt Enable Register
TIER
8
8
2 or 3 PCLKB
0008 8705h
MTU0
Timer Status Register
TSR
8
8
2 or 3 PCLKB
0008 8706h
MTU0
Timer Counter
TCNT
16
16
2 or 3 PCLKB
0008 8708h
MTU0
Timer General Register A
TGRA
16
16
2 or 3 PCLKB
0008 870Ah
MTU0
Timer General Register B
TGRB
16
16
2 or 3 PCLKB
0008 870Ch
MTU0
Timer General Register C
TGRC
16
16
2 or 3 PCLKB
2 or 3 PCLKB
0008 870Eh
MTU0
Timer General Register D
TGRD
16
16
0008 8720h
MTU0
Timer General Register E
TGRE
16
16
2 or 3 PCLKB
0008 8722h
MTU0
Timer General Register F
TGRF
16
16
2 or 3 PCLKB
0008 8724h
MTU0
Timer Interrupt Enable Register 2
TIER2
8
8
2 or 3 PCLKB
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 37 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (7/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 8726h
MTU0
Timer Buffer Operation Transfer Mode Register
TBTM
8
8
2 or 3 PCLKB
0008 8780h
MTU1
Timer Control Register
TCR
8
8
2 or 3 PCLKB
0008 8781h
MTU1
Timer Mode Register
TMDR
8
8
2 or 3 PCLKB
0008 8782h
MTU1
Timer I/O Control Register
TIOR
8
8
2 or 3 PCLKB
0008 8784h
MTU1
Timer Interrupt Enable Register
TIER
8
8
2 or 3 PCLKB
0008 8785h
MTU1
Timer Status Register
TSR
8
8
2 or 3 PCLKB
0008 8786h
MTU1
Timer Counter
TCNT
16
16
2 or 3 PCLKB
0008 8788h
MTU1
Timer General Register A
TGRA
16
16
2 or 3 PCLKB
2 or 3 PCLKB
0008 878Ah
MTU1
Timer General Register B
TGRB
16
16
0008 8790h
MTU1
Timer Input Capture Control Register
TICCR
8
8
2 or 3 PCLKB
0008 8800h
MTU2
Timer Control Register
TCR
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 8801h
MTU2
Timer Mode Register
TMDR
8
8
0008 8802h
MTU2
Timer I/O Control Register
TIOR
8
8
2 or 3 PCLKB
0008 8804h
MTU2
Timer Interrupt Enable Register
TIER
8
8
2 or 3 PCLKB
0008 8805h
MTU2
Timer Status Register
TSR
8
8
2 or 3 PCLKB
0008 8806h
MTU2
Timer Counter
TCNT
16
16
2 or 3 PCLKB
0008 8808h
MTU2
Timer General Register A
TGRA
16
16
2 or 3 PCLKB
0008 880Ah
MTU2
Timer General Register B
TGRB
16
16
2 or 3 PCLKB
2 or 3 PCLKB
0008 8880h
MTU5
Timer Counter U
TCNTU
16
16
0008 8882h
MTU5
Timer General Register U
TGRU
16
16
2 or 3 PCLKB
0008 8884h
MTU5
Timer Control Register U
TCRU
8
8
2 or 3 PCLKB
0008 8886h
MTU5
Timer I/O Control Register U
TIORU
8
8
2 or 3 PCLKB
0008 8890h
MTU5
Timer Counter V
TCNTV
16
16
2 or 3 PCLKB
0008 8892h
MTU5
Timer General Register V
TGRV
16
16
2 or 3 PCLKB
2 or 3 PCLKB
0008 8894h
MTU5
Timer Control Register V
TCRV
8
8
0008 8896h
MTU5
Timer I/O Control Register V
TIORV
8
8
2 or 3 PCLKB
0008 88A0h
MTU5
Timer Counter W
TCNTW
16
16
2 or 3 PCLKB
0008 88A2h
MTU5
Timer General Register W
TGRW
16
16
2 or 3 PCLKB
0008 88A4h
MTU5
Timer Control Register W
TCRW
8
8
2 or 3 PCLKB
0008 88A6h
MTU5
Timer I/O Control Register W
TIORW
8
8
2 or 3 PCLKB
0008 88B2h
MTU5
Timer Interrupt Enable Register
TIER
8
8
2 or 3 PCLKB
0008 88B4h
MTU5
Timer Start Register
TSTR
8
8
2 or 3 PCLKB
0008 88B6h
MTU5
Timer Compare Match Clear Register
TCNTCMPCLR
8
8
2 or 3 PCLKB
0008 9000h
S12AD
A/D Control Register
ADCSR
16
16
2 or 3 PCLKB
0008 9004h
S12AD
A/D Channel Select Register A
ADANSA
16
16
2 or 3 PCLKB
0008 9008h
S12AD
A/D-Converted Value Addition Mode Select Register
ADADS
16
16
2 or 3 PCLKB
0008 900Ch
S12AD
A/D-Converted Value Addition Count Select Register
ADADC
8
8
2 or 3 PCLKB
0008 900Eh
S12AD
A/D Control Extended Register
ADCER
16
16
2 or 3 PCLKB
0008 9010h
S12AD
A/D Start Trigger Select Register
ADSTRGR
16
16
2 or 3 PCLKB
0008 9012h
S12AD
A/D Converted Extended Input Control Register
ADEXICR
16
16
2 or 3 PCLKB
0008 9014h
S12AD
A/D Channel Select Register B
ADANSB
16
16
2 or 3 PCLKB
0008 9018h
S12AD
A/D Data Duplication Register
ADDBLDR
16
16
2 or 3 PCLKB
0008 901Ah
S12AD
A/D Temperature Sensor Data Register
ADTSDR
16
16
2 or 3 PCLKB
0008 901Ch
S12AD
A/D Internal Reference Voltage Data Register
ADOCDR
16
16
2 or 3 PCLKB
0008 9020h
S12AD
A/D Data Register 0
ADDR0
16
16
2 or 3 PCLKB
0008 9022h
S12AD
A/D Data Register 1
ADDR1
16
16
2 or 3 PCLKB
0008 9024h
S12AD
A/D Data Register 2
ADDR2
16
16
2 or 3 PCLKB
0008 9026h
S12AD
A/D Data Register 3
ADDR3
16
16
2 or 3 PCLKB
2 or 3 PCLKB
0008 9028h
S12AD
A/D Data Register 4
ADDR4
16
16
0008 902Ch
S12AD
A/D Data Register 6
ADDR6
16
16
2 or 3 PCLKB
0008 9030h
S12AD
A/D Data Register 8
ADDR8
16
16
2 or 3 PCLKB
0008 9032h
S12AD
A/D Data Register 9
ADDR9
16
16
2 or 3 PCLKB
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 38 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (8/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 9034h
S12AD
A/D Data Register 10
ADDR10
16
16
2 or 3 PCLKB
0008 9036h
S12AD
A/D Data Register 11
ADDR11
16
16
2 or 3 PCLKB
0008 9038h
S12AD
A/D Data Register 12
ADDR12
16
16
2 or 3 PCLKB
0008 903Ah
S12AD
A/D Data Register 13
ADDR13
16
16
2 or 3 PCLKB
0008 903Ch
S12AD
A/D Data Register 14
ADDR14
16
16
2 or 3 PCLKB
0008 903Eh
S12AD
A/D Data Register 15
ADDR15
16
16
2 or 3 PCLKB
0008 9060h
S12AD
A/D Sampling State Register 0
ADSSTR0
8
8
2 or 3 PCLKB
0008 9061h
S12AD
A/D Sampling State Register L
ADSSTRL
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 9070h
S12AD
A/D Sampling State Register T
ADSSTRT
8
8
0008 9071h
S12AD
A/D Sampling State Register O
ADSSTRO
8
8
2 or 3 PCLKB
0008 9073h
S12AD
A/D Sampling State Register 1
ADSSTR1
8
8
2 or 3 PCLKB
0008 9074h
S12AD
A/D Sampling State Register 2
ADSSTR2
8
8
2 or 3 PCLKB
0008 9075h
S12AD
A/D Sampling State Register 3
ADSSTR3
8
8
2 or 3 PCLKB
0008 9076h
S12AD
A/D Sampling State Register 4
ADSSTR4
8
8
2 or 3 PCLKB
0008 9078h
S12AD
A/D Sampling State Register 6
ADSSTR6
8
8
2 or 3 PCLKB
0008 A020h
SCI1
Serial Mode Register
SMR
8
8
2 or 3 PCLKB
0008 A021h
SCI1
Bit Rate Register
BRR
8
8
2 or 3 PCLKB
0008 A022h
SCI1
Serial Control Register
SCR
8
8
2 or 3 PCLKB
0008 A023h
SCI1
Transmit Data Register
TDR
8
8
2 or 3 PCLKB
0008 A024h
SCI1
Serial Status Register
SSR
8
8
2 or 3 PCLKB
0008 A025h
SCI1
Receive Data Register
RDR
8
8
2 or 3 PCLKB
0008 A026h
SCI1
Smart Card Mode Register
SCMR
8
8
2 or 3 PCLKB
0008 A027h
SCI1
Serial Extended Mode Register
SEMR
8
8
2 or 3 PCLKB
0008 A028h
SCI1
Noise Filter Setting Register
SNFR
8
8
2 or 3 PCLKB
0008 A029h
SCI1
I2C
Mode Register 1
SIMR1
8
8
2 or 3 PCLKB
0008 A02Ah
SCI1
I2C Mode Register 2
SIMR2
8
8
2 or 3 PCLKB
0008 A02Bh
SCI1
I2C Mode Register 3
SIMR3
8
8
2 or 3 PCLKB
0008 A02Ch
SCI1
I2C Status Register
SISR
8
8
2 or 3 PCLKB
0008 A02Dh
SCI1
SPI Mode Register
SPMR
8
8
2 or 3 PCLKB
0008 A0A0h
SCI5
Serial Mode Register
SMR
8
8
2 or 3 PCLKB
0008 A0A1h
SCI5
Bit Rate Register
BRR
8
8
2 or 3 PCLKB
0008 A0A2h
SCI5
Serial Control Register
SCR
8
8
2 or 3 PCLKB
0008 A0A3h
SCI5
Transmit Data Register
TDR
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 A0A4h
SCI5
Serial Status Register
SSR
8
8
0008 A0A5h
SCI5
Receive Data Register
RDR
8
8
2 or 3 PCLKB
0008 A0A6h
SCI5
Smart Card Mode Register
SCMR
8
8
2 or 3 PCLKB
0008 A0A7h
SCI5
Serial Extended Mode Register
SEMR
8
8
2 or 3 PCLKB
0008 A0A8h
SCI5
Noise Filter Setting Register
SNFR
8
8
2 or 3 PCLKB
0008 A0A9h
SCI5
I2C
Mode Register 1
SIMR1
8
8
2 or 3 PCLKB
0008 A0AAh
SCI5
I2C Mode Register 2
SIMR2
8
8
2 or 3 PCLKB
0008 A0ABh
SCI5
I2C Mode Register 3
SIMR3
8
8
2 or 3 PCLKB
0008 A0ACh
SCI5
I2C Status Register
SISR
8
8
2 or 3 PCLKB
0008 A0ADh
SCI5
SPI Mode Register
SPMR
8
8
2 or 3 PCLKB
0008 B000h
CAC
CAC Control Register 0
CACR0
8
8
2 or 3 PCLKB
0008 B001h
CAC
CAC Control Register 1
CACR1
8
8
2 or 3 PCLKB
0008 B002h
CAC
CAC Control Register 2
CACR2
8
8
2 or 3 PCLKB
0008 B003h
CAC
CAC Interrupt Request Enable Register
CAICR
8
8
2 or 3 PCLKB
0008 B004h
CAC
CAC Status Register
CASTR
8
8
2 or 3 PCLKB
0008 B006h
CAC
CAC Upper-Limit Value Setting Register
CAULVR
16
16
2 or 3 PCLKB
0008 B008h
CAC
CAC Lower-Limit Value Setting Register
CALLVR
16
16
2 or 3 PCLKB
0008 B00Ah
CAC
CAC Counter Buffer Register
CACNTBR
16
16
2 or 3 PCLKB
0008 B080h
DOC
DOC Control Register
DOCR
8
8
2 or 3 PCLKB
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 39 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (9/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
2 or 3 PCLKB
0008 B082h
DOC
DOC Data Input Register
DODIR
16
16
0008 B084h
DOC
DOC Data Setting Register
DODSR
16
16
2 or 3 PCLKB
0008 B300h
SCI12
Serial Mode Register
SMR
8
8
2 or 3 PCLKB
0008 B301h
SCI12
Bit Rate Register
BRR
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 B302h
SCI12
Serial Control Register
SCR
8
8
0008 B303h
SCI12
Transmit Data Register
TDR
8
8
2 or 3 PCLKB
0008 B304h
SCI12
Serial Status Register
SSR
8
8
2 or 3 PCLKB
0008 B305h
SCI12
Receive Data Register
RDR
8
8
2 or 3 PCLKB
0008 B306h
SCI12
Smart Card Mode Register
SCMR
8
8
2 or 3 PCLKB
0008 B307h
SCI12
Serial Extended Mode Register
SEMR
8
8
2 or 3 PCLKB
0008 B308h
SCI12
Noise Filter Setting Register
SNFR
8
8
2 or 3 PCLKB
0008 B309h
SCI12
I2C
Mode Register 1
SIMR1
8
8
2 or 3 PCLKB
0008 B30Ah
SCI12
I2C Mode Register 2
SIMR2
8
8
2 or 3 PCLKB
0008 B30Bh
SCI12
I2C Mode Register 3
SIMR3
8
8
2 or 3 PCLKB
0008 B30Ch
SCI12
I2C Status Register
SISR
8
8
2 or 3 PCLKB
0008 B30Dh
SCI12
SPI Mode Register
SPMR
8
8
2 or 3 PCLKB
0008 B320h
SCI12
Extended Serial Mode Enable Register
ESMER
8
8
2 or 3 PCLKB
0008 B321h
SCI12
Control Register 0
CR0
8
8
2 or 3 PCLKB
0008 B322h
SCI12
Control Register 1
CR1
8
8
2 or 3 PCLKB
0008 B323h
SCI12
Control Register 2
CR2
8
8
2 or 3 PCLKB
0008 B324h
SCI12
Control Register 3
CR3
8
8
2 or 3 PCLKB
0008 B325h
SCI12
Port Control Register
PCR
8
8
2 or 3 PCLKB
0008 B326h
SCI12
Interrupt Control Register
ICR
8
8
2 or 3 PCLKB
0008 B327h
SCI12
Status Register
STR
8
8
2 or 3 PCLKB
0008 B328h
SCI12
Status Clear Register
STCR
8
8
2 or 3 PCLKB
0008 B329h
SCI12
Control Field 0 Data Register
CF0DR
8
8
2 or 3 PCLKB
0008 B32Ah
SCI12
Control Field 0 Compare Enable Register
CF0CR
8
8
2 or 3 PCLKB
0008 B32Bh
SCI12
Control Field 0 Receive Data Register
CF0RR
8
8
2 or 3 PCLKB
0008 B32Ch
SCI12
Primary Control Field 1 Data Register
PCF1DR
8
8
2 or 3 PCLKB
0008 B32Dh
SCI12
Secondary Control Field 1 Data Register
SCF1DR
8
8
2 or 3 PCLKB
0008 B32Eh
SCI12
Control Field 1 Compare Enable Register
CF1CR
8
8
2 or 3 PCLKB
0008 B32Fh
SCI12
Control Field 1 Receive Data Register
CF1RR
8
8
2 or 3 PCLKB
0008 B330h
SCI12
Timer Control Register
TCR
8
8
2 or 3 PCLKB
0008 B331h
SCI12
Timer Mode Register
TMR
8
8
2 or 3 PCLKB
0008 B332h
SCI12
Timer Prescaler Register
TPRE
8
8
2 or 3 PCLKB
0008 B333h
SCI12
Timer Count Register
TCNT
8
8
2 or 3 PCLKB
0008 C000h
PORT0
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C001h
PORT1
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C002h
PORT2
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C003h
PORT3
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C004h
PORT4
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C005h
PORT5
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C00Ah
PORTA
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C00Bh
PORTB
Port Direction Register
PDR
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 C00Ch
PORTC
Port Direction Register
PDR
8
8
0008 C00Eh
PORTE
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C011h
PORTH
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C012h
PORTJ
Port Direction Register
PDR
8
8
2 or 3 PCLKB
0008 C020h
PORT0
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C021h
PORT1
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C022h
PORT2
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C023h
PORT3
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 40 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (10/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 C024h
PORT4
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C025h
PORT5
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C02Ah
PORTA
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C02Bh
PORTB
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 C02Ch
PORTC
Port Output Data Register
PODR
8
8
0008 C02Eh
PORTE
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C031h
PORTH
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C032h
PORTJ
Port Output Data Register
PODR
8
8
2 or 3 PCLKB
0008 C040h
PORT0
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C041h
PORT1
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C042h
PORT2
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C043h
PORT3
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C044h
PORT4
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C045h
PORT5
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C04Ah
PORTA
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C04Bh
PORTB
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C04Ch
PORTC
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C04Eh
PORTE
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C051h
PORTH
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C052h
PORTJ
Port Input Data Register
PIDR
8
8
3 or 4 PCLKB cycles when reading,
2 or 3 PCLKB cycles when writing
0008 C060h
PORT0
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C061h
PORT1
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C062h
PORT2
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C063h
PORT3
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C064h
PORT4
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C065h
PORT5
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C06Ah
PORTA
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C06Bh
PORTB
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C06Ch
PORTC
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C06Eh
PORTE
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C071h
PORTH
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C072h
PORTJ
Port Mode Register
PMR
8
8
2 or 3 PCLKB
0008 C083h
PORT1
Open Drain Control Register 1
ODR1
8
8, 16
2 or 3 PCLKB
0008 C085h
PORT2
Open Drain Control Register 1
ODR1
8
8, 16
2 or 3 PCLKB
0008 C086h
PORT3
Open Drain Control Register 0
ODR0
8
8, 16
2 or 3 PCLKB
0008 C094h
PORTA
Open Drain Control Register 0
ODR0
8
8, 16
2 or 3 PCLKB
0008 C095h
PORTA
Open Drain Control Register 1
ODR1
8
8, 16
2 or 3 PCLKB
0008 C096h
PORTB
Open Drain Control Register 0
ODR0
8
8, 16
2 or 3 PCLKB
0008 C097h
PORTB
Open Drain Control Register 1
ODR1
8
8, 16
2 or 3 PCLKB
0008 C098h
PORTC
Open Drain Control Register 0
ODR0
8
8, 16
2 or 3 PCLKB
0008 C099h
PORTC
Open Drain Control Register 1
ODR1
8
8, 16
2 or 3 PCLKB
0008 C09Ch
PORTE
Open Drain Control Register 0
ODR0
8
8, 16
2 or 3 PCLKB
0008 C09Dh
PORTE
Open Drain Control Register 1
ODR1
8
8, 16
2 or 3 PCLKB
0008 C0C0h
PORT0
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0C1h
PORT1
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0C2h
PORT2
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 41 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (11/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 C0C3h
PORT3
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0C5h
PORT5
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0CAh
PORTA
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0CBh
PORTB
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0CCh
PORTC
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0CEh
PORTE
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C0D1h
PORTH
Pull-Up Control Register
PCR
8
8
2 or 3 PCLKB
0008 C11Fh
MPC
Write-Protect Register
PWPR
8
8
2 or 3 PCLKB
0008 C120h
PORT
Port Switching Register B
PSRB
8
8
2 or 3 PCLKB
0008 C121h
PORT
Port Switching Register A
PSRA
8
8
2 or 3 PCLKB
0008 C14Ch
MPC
P14 Pin Function Control Register
P14PFS
8
8
2 or 3 PCLKB
0008 C14Dh
MPC
P15 Pin Function Control Register
P15PFS
8
8
2 or 3 PCLKB
0008 C14Eh
MPC
P16 Pin Function Control Register
P16PFS
8
8
2 or 3 PCLKB
0008 C14Fh
MPC
P17 Pin Function Control Register
P17PFS
8
8
2 or 3 PCLKB
0008 C156h
MPC
P26 Pin Function Control Register
P26PFS
8
8
2 or 3 PCLKB
0008 C157h
MPC
P27 Pin Function Control Register
P27PFS
8
8
2 or 3 PCLKB
0008 C158h
MPC
P30 Pin Function Control Register
P30PFS
8
8
2 or 3 PCLKB
0008 C159h
MPC
P31 Pin Function Control Register
P31PFS
8
8
2 or 3 PCLKB
0008 C15Ah
MPC
P32 Pin Function Control Register
P32PFS
8
8
2 or 3 PCLKB
0008 C160h
MPC
P40 Pin Function Control Register
P40PFS
8
8
2 or 3 PCLKB
0008 C161h
MPC
P41 Pin Function Control Register
P41PFS
8
8
2 or 3 PCLKB
0008 C162h
MPC
P42 Pin Function Control Register
P42PFS
8
8
2 or 3 PCLKB
0008 C163h
MPC
P43 Pin Function Control Register
P43PFS
8
8
2 or 3 PCLKB
0008 C164h
MPC
P44 Pin Function Control Register
P44PFS
8
8
2 or 3 PCLKB
0008 C166h
MPC
P46 Pin Function Control Register
P46PFS
8
8
2 or 3 PCLKB
0008 C190h
MPC
PA0 Pin Function Control Register
PA0PFS
8
8
2 or 3 PCLKB
0008 C191h
MPC
PA1 Pin Function Control Register
PA1PFS
8
8
2 or 3 PCLKB
0008 C193h
MPC
PA3 Pin Function Control Register
PA3PFS
8
8
2 or 3 PCLKB
0008 C194h
MPC
PA4 Pin Function Control Register
PA4PFS
8
8
2 or 3 PCLKB
0008 C196h
MPC
PA6 Pin Function Control Register
PA6PFS
8
8
2 or 3 PCLKB
0008 C198h
MPC
PB0 Pin Function Control Register
PB0PFS
8
8
2 or 3 PCLKB
0008 C199h
MPC
PB1 Pin Function Control Register
PB1PFS
8
8
2 or 3 PCLKB
0008 C19Bh
MPC
PB3 Pin Function Control Register
PB3PFS
8
8
2 or 3 PCLKB
0008 C19Dh
MPC
PB5 Pin Function Control Register
PB5PFS
8
8
2 or 3 PCLKB
0008 C19Eh
MPC
PB6 Pin Function Control Register
PB6PFS
8
8
2 or 3 PCLKB
0008 C19Fh
MPC
PB7 Pin Function Control Register
PB7PFS
8
8
2 or 3 PCLKB
0008 C1A2h
MPC
PC2 Pin Function Control Register
PC2PFS
8
8
2 or 3 PCLKB
0008 C1A3h
MPC
PC3 Pin Function Control Register
PC3PFS
8
8
2 or 3 PCLKB
0008 C1A4h
MPC
PC4 Pin Function Control Register
PC4PFS
8
8
2 or 3 PCLKB
0008 C1A5h
MPC
PC5 Pin Function Control Register
PC5PFS
8
8
2 or 3 PCLKB
0008 C1A6h
MPC
PC6 Pin Function Control Register
PC6PFS
8
8
2 or 3 PCLKB
0008 C1A7h
MPC
PC7 Pin Function Control Register
PC7PFS
8
8
2 or 3 PCLKB
0008 C1B0h
MPC
PE0 Pin Function Control Register
PE0PFS
8
8
2 or 3 PCLKB
0008 C1B1h
MPC
PE1 Pin Function Control Register
PE1PFS
8
8
2 or 3 PCLKB
0008 C1B2h
MPC
PE2 Pin Function Control Register
PE2PFS
8
8
2 or 3 PCLKB
0008 C1B3h
MPC
PE3 Pin Function Control Register
PE3PFS
8
8
2 or 3 PCLKB
0008 C1B4h
MPC
PE4 Pin Function Control Register
PE4PFS
8
8
2 or 3 PCLKB
0008 C1B5h
MPC
PE5 Pin Function Control Register
PE5PFS
8
8
2 or 3 PCLKB
0008 C1B6h
MPC
PE6 Pin Function Control Register
PE6PFS
8
8
2 or 3 PCLKB
0008 C1B7h
MPC
PE7 Pin Function Control Register
PE7PFS
8
8
2 or 3 PCLKB
0008 C1C8h
MPC
PH0 Pin Function Control Register
PH0PFS
8
8
2 or 3 PCLKB
0008 C1C9h
MPC
PH1 Pin Function Control Register
PH1PFS
8
8
2 or 3 PCLKB
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Jul 29, 2016
Page 42 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (12/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
0008 C1CAh
MPC
PH2 Pin Function Control Register
PH2PFS
8
8
2 or 3 PCLKB
0008 C1CBh
MPC
PH3 Pin Function Control Register
PH3PFS
8
8
2 or 3 PCLKB
0008 C1D6h
MPC
PJ6 Pin Function Control Register
PJ6PFS
8
8
2 or 3 PCLKB
0008 C1D7h
MPC
PJ7 Pin Function Control Register
PJ7PFS
8
8
2 or 3 PCLKB
0008 C290h
SYSTEM
Reset Status Register 0
RSTSR0
8
8
4 or 5 PCLKB
0008 C291h
SYSTEM
Reset Status Register 1
RSTSR1
8
8
4 or 5 PCLKB
0008 C293h
SYSTEM
Main Clock Oscillator Forced Oscillation Control Register
MOFCR
8
8
4 or 5 PCLKB
0008 C297h
SYSTEM
Voltage Monitoring Circuit Control Register
LVCMPCR
8
8
4 or 5 PCLKB
0008 C298h
SYSTEM
Voltage Detection Level Select Register
LVDLVLR
8
8
4 or 5 PCLKB
0008 C29Ah
SYSTEM
Voltage Monitoring 1 Circuit Control Register 0
LVD1CR0
8
8
4 or 5 PCLKB
0008 C29Bh
SYSTEM
Voltage Monitoring 2 Circuit Control Register 0
LVD2CR0
8
8
4 or 5 PCLKB
0008 C400h
RTC
64-Hz Counter
R64CNT
8
8
2 or 3 PCLKB
0008 C402h
RTC
Second Counter
RSECCNT
8
8
2 or 3 PCLKB
0008 C402h
RTC
Binary Counter 0
BCNT0
8
8
2 or 3 PCLKB
0008 C404h
RTC
Minute Counter
RMINCNT
8
8
2 or 3 PCLKB
0008 C404h
RTC
Binary Counter 1
BCNT1
8
8
2 or 3 PCLKB
0008 C406h
RTC
Hour Counter
RHRCNT
8
8
2 or 3 PCLKB
0008 C406h
RTC
Binary Counter 2
BCNT2
8
8
2 or 3 PCLKB
0008 C408h
RTC
Day-Of-Week Counter
RWKCNT
8
8
2 or 3 PCLKB
0008 C408h
RTC
Binary Counter 3
BCNT3
8
8
2 or 3 PCLKB
0008 C40Ah
RTC
Date Counter
RDAYCNT
8
8
2 or 3 PCLKB
0008 C40Ch
RTC
Month Counter
RMONCNT
8
8
2 or 3 PCLKB
0008 C40Eh
RTC
Year Counter
RYRCNT
16
16
2 or 3 PCLKB
0008 C410h
RTC
Second Alarm Register
RSECAR
8
8
2 or 3 PCLKB
2 or 3 PCLKB
0008 C410h
RTC
Binary Counter 0 Alarm Register
BCNT0AR
8
8
0008 C412h
RTC
Minute Alarm Register
RMINAR
8
8
2 or 3 PCLKB
0008 C412h
RTC
Binary Counter 1 Alarm Register
BCNT1AR
8
8
2 or 3 PCLKB
0008 C414h
RTC
Hour Alarm Register
RHRAR
8
8
2 or 3 PCLKB
0008 C414h
RTC
Binary Counter 2 Alarm Register
BCNT2AR
8
8
2 or 3 PCLKB
0008 C416h
RTC
Day-of-Week Alarm Register
RWKAR
8
8
2 or 3 PCLKB
0008 C416h
RTC
Binary Counter 3 Alarm Register
BCNT3AR
8
8
2 or 3 PCLKB
0008 C418h
RTC
Date Alarm Register
RDAYAR
8
8
2 or 3 PCLKB
0008 C418h
RTC
Binary Counter 0 Alarm Enable Register
BCNT0AER
8
8
2 or 3 PCLKB
0008 C41Ah
RTC
Month Alarm Register
RMONAR
8
8
2 or 3 PCLKB
0008 C41Ah
RTC
Binary Counter 1 Alarm Enable Register
BCNT1AER
8
8
2 or 3 PCLKB
0008 C41Ch
RTC
Year Alarm Register
RYRAR
16
16
2 or 3 PCLKB
0008 C41Ch
RTC
Binary Counter 2 Alarm Enable Register
BCNT2AER
16
16
2 or 3 PCLKB
0008 C41Eh
RTC
Year Alarm Enable Register
RYRAREN
8
8
2 or 3 PCLKB
0008 C41Eh
RTC
Binary Counter 3 Alarm Enable Register
BCNT3AER
8
8
2 or 3 PCLKB
0008 C422h
RTC
RTC Control Register 1
RCR1
8
8
2 or 3 PCLKB
0008 C424h
RTC
RTC Control Register 2
RCR2
8
8
2 or 3 PCLKB
0008 C426h
RTC
RTC Control Register 3
RCR3
8
8
2 or 3 PCLKB
0008 C42Eh
RTC
Time Error Adjustment Register
RADJ
8
8
2 or 3 PCLKB
007F C0ACh
TEMPS
Temperature Sensor Calibration Data Register
TSCDRL
8
8
1 or 2 PCLKB
007F C0ADh
TEMPS
Temperature Sensor Calibration Data Register
TSCDRH
8
8
1 or 2 PCLKB
007F C0B0h
FLASH
Flash Start-Up Setting Monitor Register
FSCMR
16
16
2 or 3 FCLK
007F C0B2h
FLASH
Flash Access Window Start Address Monitor
FAWSMR
16
16
2 or 3 FCLK
007F C0B4h
FLASH
Flash Access Window End Address Monitor Register
FAWEMR
16
16
2 or 3 FCLK
007F C0B6h
FLASH
Flash Initial Setting Register
FISR
8
8
2 or 3 FCLK
007F C0B7h
FLASH
Flash Extra Area Control Register
FEXCR
8
8
2 or 3 FCLK
007F C0B8h
FLASH
Flash Error Address Monitor Register L
FEAML
16
16
2 or 3 FCLK
007F C0BAh
FLASH
Flash Error Address Monitor Register H
FEAMH
8
8
2 or 3 FCLK
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 43 of 108
RX110 Group
Table 4.1
Address
4. I/O Registers
List of I/O Registers (Address Order) (13/13)
Module
Symbol
Register Name
Register
Symbol
Number of
Bits
Access
Size
Number of Access States
2 or 3 FCLK
007F C0C0h
FLASH
Protection Unlock Register
FPR
8
8
007F C0C1h
FLASH
Protection Unlock Status Register
FPSR
8
8
2 or 3 FCLK
007F C0C2h
FLASH
Flash Read Buffer Register L
FRBL
16
16
2 or 3 FCLK
007F C0C4h
FLASH
Flash Read Buffer Register H
FRBH
16
16
2 or 3 FCLK
007F FF80h
FLASH
Flash P/E Mode Control Register
FPMCR
8
8
2 or 3 FCLK
007F FF81h
FLASH
Flash Area Select Register
FASR
8
8
2 or 3 FCLK
007F FF82h
FLASH
Flash Processing Start Address Register L
FSARL
16
16
2 or 3 FCLK
007F FF84h
FLASH
Flash Processing Start Address Register H
FSARH
8
8
2 or 3 FCLK
007F FF85h
FLASH
Flash Control Register
FCR
8
8
2 or 3 FCLK
007F FF86h
FLASH
Flash Processing End Address Register L
FEARL
16
16
2 or 3 FCLK
007F FF88h
FLASH
Flash Processing End Address Register H
FEARH
8
8
2 or 3 FCLK
007F FF89h
FLASH
Flash Reset Register
FRESETR
8
8
2 or 3 FCLK
007F FF8Ah
FLASH
Flash Status Register 0
FSTATR0
8
8
2 or 3 FCLK
007F FF8Bh
FLASH
Flash Status Register 1
FSTATR1
8
8
2 or 3 FCLK
007F FF8Ch
FLASH
Flash Write Buffer Register L
FWBL
16
16
2 or 3 FCLK
007F FF8Eh
FLASH
Flash Write Buffer Register H
FWBH
16
16
2 or 3 FCLK
007F FFB2h
FLASH
Flash P/E Mode Entry Register
FENTRYR
16
16
2 or 3 FCLK
Note 1. Odd addresses cannot be accessed in 16-bit units. When accessing a register in 16-bit units, access the address of the
TMOCNTL register. Table 24.6 lists register allocation for 16-bit access in the User’s Manual: Hardware.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 44 of 108
RX110 Group
5. Electrical Characteristics
5.
Electrical Characteristics
5.1
Absolute Maximum Ratings
Table 5.1
Conditions:
Absolute Maximum Ratings
VSS = AVSS0 = VREFL0 = 0 V
Item
Power supply voltage
Input voltage
Symbol
Value
Unit
VCC
–0.3 to +4.6
V
tolerant*1
Vin
–0.3 to +6.5
V
Ports P40 to P44, P46,
ports PJ6, PJ7
Vin
–0.3 to AVCC0 +0.3
V
Ports other than above
Vin
–0.3 to VCC +0.3
V
VREFH0
–0.3 to AVCC0 +0.3
V
Ports for 5 V
Reference power supply voltage
Analog power supply voltage
AVCC0
–0.3 to +4.6
V
Analog input voltage
VAN
–0.3 to AVCC0 + 0.3
(when AN000 to AN004 and
AN006 used)
–0.3 to VCC + 0.3
(when AN008 to AN015 used)
V
Operating temperature*2
Topr
–40 to +85
–40 to +105
°C
Storage temperature
Tstg
–55 to +125
°C
Caution: Permanent damage to the MCU may result if absolute maximum ratings are exceeded.
To preclude any malfunctions due to noise interference, insert capacitors of high frequency characteristics between the VCC and
VSS pins, between the AVCC0 and AVSS0 pins, and between the VREFH0 and VREFL0 pins. Place capacitors of about 0.1 μF
as close as possible to every power supply pin and use the shortest and heaviest possible traces. Also, connect capacitors as
stabilization capacitance.
Connect the VCL pin to a VSS pin via a 4.7 μF capacitor. The capacitor must be placed close to the pin, refer to section 5.9.1,
Connecting VCL Capacitor and Bypass Capacitors.
Do not input signals or an I/O pull-up power supply to ports other than 5-V tolerant ports while the device is not powered. The
current injection that results from input of such a signal or I/O pull-up may cause malfunction and the abnormal current that
passes in the device at this time may cause degradation of internal elements.
If input voltage (within the specified range from -0.3 to + 6.5V) is applied to 5-V tolerant ports, it will not cause problems such as
damage to the MCU.
Note 1. Ports P16, P17, PA6, and PB0 are 5 V tolerant.
Note 2. The upper limit of operating temperature is 85°C or 105°C, depending on the product. For details, refer to 1.2 List of Products.
Table 5.2
Recommended Operating Conditions
Item
Power supply voltages
Analog power supply voltages
Symbol
Min.
Typ.
Max.
Unit
VCC*1
1.8
—
3.6
V
VSS
—
0
—
V
AVCC0*1, *2
1.8
—
3.6
V
AVSS0
—
0
—
V
VREFH0
1.8
—
AVCC0
V
VREFL0
—
0
—
V
Note 1. Supply AVCC0 simultaneously with or after supplying VCC.
Note 2. Refer to section 27.6.10, Voltage Range of Analog Power Supply Pins in the User’s Manual: Hardware to determine the AVCC0
voltage.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 45 of 108
RX110 Group
5.2
5. Electrical Characteristics
DC Characteristics
Table 5.3
DC Characteristics (1)
Conditions: 2.7 V ≤ VCC ≤ 3.6 V, 2.7 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Schmitt trigger input
voltage
Symbol
Min.
Typ.
Max.
Unit
VIH
VCC × 0.7
—
5.8
V
Ports P16, P17,
port PA6, port PB0 (5 V tolerant)
VCC × 0.8
—
5.8
Ports P03, P05,
ports P14, P15,
ports P26, P27,
ports P30 to P32, P35,
ports P54, P55,
ports PA0, PA1, PA3, PA4,
ports PB1, PB3, PB5 to PB7,
ports PC0 to PC7,
ports PE0 to PE7,
ports PH0 to PH3, PH7,
RES#
VCC × 0.8
—
VCC + 0.3
–0.3
—
VCC × 0.3
–0.3
—
VCC × 0.2
VCC × 0.05
—
—
VCC × 0.1
—
—
VCC × 0.9
—
VCC + 0.3
VCC × 0.8
—
VCC + 0.3
AVCC0 × 0.7
—
AVCC0 + 0.3
2.1
—
VCC + 0.3
–0.3
—
VCC × 0.1
RIIC input pin
(except for SMBus, 5 V tolerant)
RIIC input pin
(except for SMBus)
VIL
Other than RIIC input pin
RIIC input pin
(except for SMBus)
∆VT
Other than RIIC input pin
Input voltage
(except for Schmitt
trigger input pins)
MD
VIH
XTAL (external clock input)
Ports P40 to P44, P46,
ports PJ6, PJ7
RIIC input pin (SMBus)
MD
VIL
XTAL (external clock input)
–0.3
—
VCC × 0.2
Ports P40 to P44, P46,
ports PJ6, PJ7
–0.3
—
AVCC0 × 0.3
RIIC input pin (SMBus)
–0.3
—
0.8
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Test
Conditions
V
Page 46 of 108
RX110 Group
Table 5.4
5. Electrical Characteristics
DC Characteristics (2)
Conditions: 1.8 V ≤ VCC < 2.7 V, 1.8 V ≤ AVCC0 < 2.7 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Schmitt trigger input
voltage
Ports P16, P17, port PA6, port PB0
(5 V tolerant)
Symbol
Min.
Typ.
Max.
Unit
VIH
VCC × 0.8
—
5.8
V
VCC × 0.8
—
VCC + 0.3
Ports P03, P05,
ports P14, P15,
ports P26, P27,
ports P30 to P32, P35,
ports P54, P55,
ports PA0, PA1, PA3, PA4,
ports PB1, PB3, PB5 to PB7,
ports PC0 to PC7,
ports PE0 to PE7,
ports PH0 to PH3, PH7,
RES#
All pins
Input voltage
(except for Schmitt
trigger input pins)
–0.3
—
VCC × 0.2
All pins
∆VT
VCC × 0.01
—
—
MD
VIH
VCC × 0.9
—
VCC + 0.3
VCC × 0.8
—
VCC + 0.3
AVCC0 × 0.7
—
AVCC0 + 0.3
–0.3
—
VCC × 0.1
XTAL (external clock input)
Ports P40 to P44, P46,
ports PJ6, PJ7
MD
Table 5.5
VIL
XTAL (external clock input)
–0.3
—
VCC × 0.2
Ports P40 to P44, P46,
ports PJ6, PJ7
–0.3
—
AVCC0 × 0.3
Test
Conditions
V
DC Characteristics (3)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Input leakage
current
RES#, MD, port P35, port PH7
Three-state
leakage current
(off-state)
Ports for 5 V tolerant
Input capacitance
Symbol
Min.
Typ.
Max.
Unit
Iin
—
—
1.0
µA
Vin = 0 V, VCC
ITSI
—
—
1.0
µA
Vin = 0 V, 5.8 V
—
—
1.0
—
—
15
—
—
30
Pins other than above
All input pins
(except for port P16, port P35)
Cin
Port P16, port P35
Table 5.6
Conditions:
Vin = 0 V, VCC
pF
Vin = 0 mV,
Frequency: 1 MHz,
Ta = 25°C
DC Characteristics (4)
1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Input pull-up
resistor
Test Conditions
All ports
(except for port P35, port PH7)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Symbol
Min.
Typ.
Max.
Unit
RU
10
20
100
kΩ
Test Conditions
Vin = 0 V
Page 47 of 108
RX110 Group
Table 5.7
Conditions:
5. Electrical Characteristics
DC Characteristics (5) (1/2)
1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Symbol
Typ
*4
Max
Unit
ICC
3.2
—
mA
ICLK = 16 MHz
2.1
—
ICLK = 8 MHz
1.5
—
ICLK = 32 MHz
9.6
—
ICLK = 16 MHz
5.6
—
Item
Supply
current*1
High-speed
operating mode
Normal
operating
mode
No peripheral operation*2
All peripheral operation:
Normal*3
Sleep mode
ICLK = 8 MHz
3.5
—
All peripheral operation:
Max.*3
ICLK = 32 MHz
—
21.6
No peripheral operation*2
ICLK = 32 MHz
1.5
—
ICLK = 16 MHz
1.2
—
ICLK = 8 MHz
1.0
—
ICLK = 32 MHz
5.1
—
ICLK = 16 MHz
3.1
—
All peripheral operation:
Normal*3
Deep sleep
mode
No peripheral operation*2
All peripheral operation:
Normal*3
Middle-speed
operating modes
Normal
operating
mode
No peripheral
operation*5
—
1.0
—
ICLK = 16 MHz
0.80
—
ICLK = 8 MHz
0.70
—
ICLK = 32 MHz
3.4
—
ICLK = 16 MHz
2.2
—
ICLK = 8 MHz
1.5
—
—
1.3
—
ICLK = 1 MHz
0.72
—
ICLK = 12 MHz
4.2
—
ICLK = 8 MHz
3.3
—
ICLK = 1 MHz
1.2
—
All peripheral
operation: Max.*6
ICLK = 12 MHz
—
10
No peripheral operation*5
ICLK = 12 MHz
1.0
—
ICLK = 8 MHz
0.82
—
ICLK = 1 MHz
0.65
—
ICLK = 12 MHz
2.3
—
ICLK = 8 MHz
1.9
—
ICLK = 1 MHz
1.0
—
ICLK = 12 MHz
0.8
—
ICLK = 8 MHz
0.66
—
ICLK = 1 MHz
0.58
—
ICLK = 12 MHz
1.6
—
No peripheral
operation*5
All peripheral operation:
Normal*6
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
2.0
ICLK = 32 MHz
1.7
All peripheral operation:
Normal*6
Deep sleep
mode
ICLK = 8 MHz
ICLK = 8 MHz
All peripheral operation:
Normal*6
Sleep mode
ICLK = 32 MHz
ICLK = 12 MHz
ICC
ICLK = 8 MHz
1.5
—
ICLK = 1 MHz
0.87
—
Test
Conditions
mA
Page 48 of 108
RX110 Group
Table 5.7
5. Electrical Characteristics
DC Characteristics (5) (2/2)
1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Conditions:
Item
Supply
current*1
Low-speed
operating mode
Normal
operating
mode
Sleep mode
Deep sleep
mode
Symbol
Typ
*4
Max
Unit
ICC
3.9
—
μA
No peripheral operation*7
ICLK = 32.768 kHz
All peripheral operation:
Normal*8, *9
ICLK = 32.768 kHz
10.4
—
All peripheral operation:
Max.*8, *9
ICLK = 32.768 kHz
—
36
No peripheral operation*7
ICLK = 32.768 kHz
2.1
—
All peripheral operation:
Normal*8
ICLK = 32.768 kHz
5.6
—
No peripheral operation*7
ICLK = 32.768 kHz
1.7
—
All peripheral operation:
Normal*8
ICLK = 32.768 kHz
3.9
—
Test
Conditions
Note 1. Supply current values do not include output charge/discharge current from all pins. The values apply when internal pull-up
MOSs are in the off state.
Note 2. Clock supply to the peripheral functions is stopped. The clock source is HOCO. FCLK and PCLK are set to divided by 64.
Note 3. Clocks are supplied to the peripheral functions. The clock source is HOCO. FCLK and PCLK are set to the same frequency as
ICLK.
Note 4. Values when VCC = 3.3 V.
Note 5. Clock supply to the peripheral functions is stopped. The clock source is the main oscillation circuit when ICLK = 12 MHz and
HOCO when ICLK = 8 or 1 MHz. FCLK and PCLK are set to divided by 64.
Note 6. Clocks are supplied to the peripheral functions. The clock source is the main oscillation circuit when ICLK = 12 MHz and HOCO
when ICLK = 8 or 1 MHz. FCLK and PCLK are set to the same frequency as ICLK.
Note 7. Clock supply to the peripheral functions is stopped. The clock source is the sub-clock oscillator. FCLK and PCLK are set to
divided by 64.
Note 8. Clocks are supplied to the peripheral functions. The clock source is the sub-clock oscillator. FCLK and PCLK are set to the
same frequency as ICLK.
Note 9. Values when the MSTPCRA.MSTPA17 bit (12-bit A/D converter module stop bit) is set to “transition to the module stop state is
made”.
18
16
Ta = 85/105°C, ICLK = 32 MHz*2
14
ICC (mA)
12
Ta = 25°C, ICLK = 32 MHz*1
10
Ta = 85/105°C, ICLK = 16 MHz*2
8
Ta = 85/105°C, ICLK = 8 MHz*2
6
Ta = 25°C, ICLK = 16 MHz*1
4
Ta = 25°C, ICLK = 8 MHz*1
2
0
1.5
2.0
2.5
3.0
3.5
4.0
VCC (V)
Note 1. All peripheral operation is normal. Average value of the tested middle samples during product evaluation.
Note 2. All peripheral operation is maximum. Average value of the tested upper-limit samples during product
evaluation.
Figure 5.1
Voltage Dependency in High-Speed Operating Mode (Reference Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 49 of 108
RX110 Group
5. Electrical Characteristics
8
7
Ta = 85/105°C, ICLK = 12 MHz*2
6
Ta = 85/105°C, ICLK = 8 MHz*2
ICC (mA)
5
Ta = 25°C, ICLK = 12 MHz*1
4
Ta = 25°C, ICLK = 8 MHz*1
3
Ta = 85/105°C, ICLK = 1 MHz*2
2
1
Ta = 25°C, ICLK = 1 MHz*1
0
1.5
2.0
2.5
3.0
3.5
4.0
VCC (V)
Note 1. All peripheral operation is normal. Average value of the tested middle samples during product evaluation.
Note 2. All peripheral operation is maximum. Average value of the tested upper-limit samples during product
evaluation.
Figure 5.2
Voltage Dependency in Middle-Speed Operating Mode (Reference Data)
30
25
Ta = 105°C, ICLK = 32KHz*2
ICC (µA)
20
Ta = 85°C, ICLK = 32KHz*2
15
10
Ta = 25°C, ICLK = 32KHz*1
5
0
1.5
2.0
2.5
3.0
3.5
4.0
VCC (V)
Note 1. All peripheral operation is normal. Average value of the tested middle samples during product evaluation.
Note 2. All peripheral operation is maximum. Average value of the tested upper-limit samples during product
evaluation.
Figure 5.3
Voltage Dependency in Low-Speed Operating Mode (Reference Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 50 of 108
RX110 Group
Table 5.8
5. Electrical Characteristics
DC Characteristics (6)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Symbol
Typ.*3
Max.
Unit
ICC
0.35
0.53
μA
Ta = 55°C
0.54
1.17
Ta = 85°C
1.38
5.2
Ta = 105°C
2.8
11.4
0.31
—
RCR3.RTCDV[2:0] = 010b
1.09
—
RCR3.RTCDV[2:0] = 100b
0.37
—
Item
Supply
current*1
Software standby
mode*2
Increment for RTC
Ta = 25°C
operation*4
Increment for IWDT operation
Note 1.
Note 2.
Note 3.
Note 4.
Test Conditions
Supply current values are with all output pins unloaded and all input pull-up MOSs in the off state.
The IWDT and LVD are stopped.
VCC = 3.3 V.
Includes the oscillation circuit.
100
Ta = 105°C*2
10
ICC (µA)
Ta = 85°C*2
Ta = 105°C*1
Ta = 85°C*1
Ta = 55°C*2
1
Ta = 55°C*1
Ta = 25°C*2
Ta = 25°C*1
0.1
1.5
2
2.5
3
3.5
4
VCC (V)
Note 1. Average value of the tested middle samples during product evaluation.
Note 2. Average value of the tested upper-limit samples during product evaluation.
Figure 5.4
Voltage Dependency in Software Standby Mode (Reference Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 51 of 108
RX110 Group
5. Electrical Characteristics
100
10
ICC (µA)
*2
*1
1
0.1
–40
–20
0
20
40
60
80
100
120
Ta (°C)
Note 1. Average value of the tested middle samples during product evaluation.
Note 2. Average value of the tested upper-limit samples during product evaluation.
Figure 5.5
Table 5.9
Temperature Dependency in Software Standby Mode (Reference Data)
DC Characteristics (7)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V
Item
Permissible total consumption
power*1
Symbol
Typ.
Max.
Unit
Pd
—
300
mW
—
105
Test Conditions
D version (Ta = -40 to 85°C)
G version (Ta = -40 to 105°C)*2
Note 1. Total power dissipated by the entire chip (including output currents).
Note 2. Please contact Renesas Electronics sales office for derating under Ta = +85°C to 105°C. Derating is the systematic reduction of
load for the sake of improved reliability.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 52 of 108
RX110 Group
Table 5.10
5. Electrical Characteristics
DC Characteristics (8)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Analog power
supply current
Symbol
During A/D conversion (at high-speed conversion)
Min.
Typ.*2
IAVCC
Waiting for A/D conversion (all units)
Reference power
supply current
During A/D conversion (at high-speed conversion)
LDV1, 2
Unit
—
0.7
1.2
mA
—
—
0.3
μA
—
25
52
μA
—
—
60
nA
ITEMP
—
75
—
μA
ILVD
—
0.15
—
μA
IREFH0
Waiting for A/D conversion (all units)
Temperature
sensor*1
Max.
Per channel
Test
Conditions
Note 1. Current consumed by the power supply (VCC).
Note 2. When VCC = AVCC0 = 3.3 V.
Table 5.11
DC Characteristics (9)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
RAM standby voltage
Table 5.12
Symbol
Min.
Typ.
Max.
Unit
VRAM
1.8
—
—
V
Test Conditions
DC Characteristics (10)
Conditions: 0 V ≤ VCC ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Power-on VCC rising
gradient
Note:
Note 1.
Note 2.
Note 3.
Note 4.
Symbol
Min.
Typ.
Max.
Unit
SrVCC
0.02
—
20
ms/V
During fast startup time*2
0.02
—
2
Voltage monitoring 1 reset
enabled at startup*3, *4
0.02
—
—
At normal startup*1
Test Conditions
When powering on AVCC0 and VCC, power them on at the same time or VCC first.
When OFS1.(STUPLVD1REN, FASTSTUP) = 11b.
When OFS1.(STUPLVD1REN, FASTSTUP) = 10b.
When OFS1.STUPLVD1REN = 0.
Turn on the power supply voltage according to the normal startup rising gradient because the register settings set by OFS1 are
not read in boot mode.
Table 5.13
DC Characteristics (11)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
The ripple voltage must meet the allowable ripple frequency fr(VCC) within the range between the VCC upper limit
(3.6 V) and lower limit (1.8 V).
When VCC change exceeds VCC ±10%, the allowable voltage change rising/falling gradient dt/dVCC must be met.
Item
Allowable ripple frequency
Allowable voltage change rising/
falling gradient
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Symbol
Min.
Typ.
Max.
Unit
Test Conditions
fr (VCC)
—
—
10
kHz
Figure 5.6
Vr (VCC) ≤ VCC × 0.2
—
—
1
MHz
Figure 5.6
Vr (VCC) ≤ VCC × 0.08
—
—
10
MHz
Figure 5.6
Vr (VCC) ≤ VCC × 0.06
1.0
—
—
ms/V
When VCC change exceeds VCC ±10%
dt/dVCC
Page 53 of 108
RX110 Group
5. Electrical Characteristics
1/fr(VCC)
VCC
Figure 5.6
Table 5.14
Vr(VCC)
Ripple Waveform
DC Characteristics (12)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Permissible error of VCL pin external
capacitance
Note:
Symbol
Min.
Typ.
Max.
Unit
CVCL
1.4
4.7
7.0
μF
Test Conditions
The recommended capacitance is 4.7 μF. Variations in connected capacitors should be within the above range.
Table 5.15
Permissible Output Currents (1)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V,
Ta = –40 to +85°C (D version)
Item
Permissible output low current
(average value per pin)
Permissible output low current
(maximum value per pin)
Permissible output low current
Ports P40 to P44, P46, ports PJ6, PJ7
Symbol
Max.
Unit
IOL
0.4
mA
Ports other than above
8.0
Ports P40 to P44, P46, ports PJ6, PJ7
0.4
Ports other than above
8.0
Total of ports P40 to P44, P46, ports PJ6, PJ7
IOL
30
Total of ports P14 to P17, port P32, ports P54, P55, ports PB0,
PB1, PB3, PB5 to PB7, ports PC2 to PC7, ports PH0 to PH3
30
Total of ports PA0, PA1, PA3, PA4, PA6, ports PE0 to PE7
30
Total of all output pins
Permissible output high current
(average value per pin)
2.4
Total of ports P03, P05, ports P26, P27, ports P30, P31
Ports P40 to P44, P46, ports PJ6, PJ7
60
IOH
Ports other than above
–0.1
–4.0
Permissible output high current
(maximum value per pin)
Ports P40 to P44, P46, ports PJ6, PJ7
–0.1
Ports other than above
–4.0
Permissible output high current
Total of ports P40 to P44, P46, ports PJ6, PJ7
Note:
IOH
–0.6
Total of ports P03, P05, ports P26, P27, ports P30, P31
–10
Total of ports P14 to P17, port P32, ports P54, P55, ports PB0,
PB1, PB3, PB5 to PB7, ports PC2 to PC7, ports PH0 to PH3
–15
Total of ports PA0, PA1, PA3, PA4, PA6, ports PE0 to PE7
–15
Total of all output pins
–40
Do not exceed the permissible total supply current.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 54 of 108
RX110 Group
Table 5.16
5. Electrical Characteristics
Permissible Output Currents (2)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V,
Ta = –40 to +105°C (G version)
Item
Symbol
Max.
Unit
IOL
0.4
mA
Permissible output low current
(average value per pin)
Ports P40 to P44, P46, ports PJ6, PJ7
Ports other than above
8.0
Permissible output low current
(maximum value per pin)
Ports P40 to P44, P46, ports PJ6, PJ7
0.4
Ports other than above
8.0
Permissible output low current
Total of ports P40 to P44, P46, ports PJ6, PJ7
IOL
1.6
Total of ports P03, P05, ports P26, P27, ports P30, P31
20
Total of ports P14 to P17, port P32, ports P54, P55, ports PB0,
PB1, PB3, PB5 to PB7, ports PC2 to PC7, ports PH0 to PH3
20
Total of ports PA0, PA1, PA3, PA4, PA6, ports PE0 to PE7
20
Total of all output pins
40
Ports P40 to P44, P46, ports PJ6, PJ7
Permissible output high current
(maximum value per pin)
Ports P40 to P44, P46, ports PJ6, PJ7
–0.1
Ports other than above
–4.0
Permissible output high current
Total of ports P40 to P44, P46, ports PJ6, PJ7
Note:
IOH
–0.1
Permissible output high current
(average value per pin)
Ports other than above
–4.0
IOH
–0.6
Total of ports P03, P05, ports P26, P27, ports P30, P31
–10
Total of ports P14 to P17, port P32, ports P54, P55, ports PB0,
PB1, PB3, PB5 to PB7, ports PC2 to PC7, ports PH0 to PH3
–15
Total of ports PA0, PA1, PA3, PA4, PA6, ports PE0 to PE7
–15
Total of all output pins
–40
Do not exceed the permissible total supply current.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 55 of 108
RX110 Group
Table 5.17
Conditions:
5. Electrical Characteristics
Output Voltage (1)
2.7 V ≤ VCC ≤ 3.6 V, 2.7 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +10°C
Item
Low-level
output voltage
All output ports
(except for RIIC, ports P40 to P44, P46,
ports PJ6, PJ7)
Symbol
Min.
Max.
Unit
VOL
—
0.6
V
—
0.4
—
0.4
IOL = 0.4 mA
RIIC pins
—
0.4
IOL = 3.0 mA
Standard mode
All output ports (except for ports P40 to P44,
P46, ports PJ6, PJ7)
VOH
Ports P40 to P44, P46, ports PJ6, PJ7
Table 5.18
Conditions:
0.6
—
AVCC0 – 0.5
—
IOL = 6.0 mA
V
IOH = –2.0 mA
IOH = –0.1 mA
Output Voltage (2)
All output ports
(except for ports P40 to P44, P46,
ports PJ6, PJ7)
Symbol
Min.
Max.
Unit
VOL
—
0.6
V
—
0.4
VOH
VCC – 0.5
—
AVCC0 – 0.5
—
Ports P40 to P44, P46, ports PJ6, PJ7
High-level
output voltage
—
VCC – 0.5
1.8 V ≤ VCC ≤ 2.7 V, 1.8 V ≤ AVCC0 ≤ 2.7 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Low-level
output voltage
IOL = 1.5 mA
Ports P40 to P44, P46, ports PJ6, PJ7
Fast mode
High-level
output voltage
Test Conditions
IOL = 3.0 mA
All output ports (except for ports P40 to P44,
P46, ports PJ6, PJ7)
Ports P40 to P44, P46, ports PJ6, PJ7
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Test Conditions
IOL = 1.5 mA
IOL = 0.4 mA
V
IOH = –1.0 mA
IOH = –0.1 mA
Page 56 of 108
RX110 Group
5. Electrical Characteristics
5.2.1
Standard I/O Pin Output Characteristics (1)
Figure 5.7 to Figure 5.10 show the characteristics of general ports (except for the RIIC output pin, ports P40 to P44,
P46, ports PJ6, PJ7).
IOH/IOL vs VOH/VOL
40
VCC = 3.3 V
30
VCC = 2.7 V
IOH/IOL [mA]
20
VCC = 1.8 V
10
0
0
0.5
1
1.5
2
2.5
3
3.5
VCC = 1.8 V
–10
VCC = 2.7 V
–20
VCC = 3.3 V
–30
VOH/VOL [V]
VOH/VOL and IOH/IOL Voltage Characteristics of General Ports (Except for the RIIC
Output Pin, Ports P40 to P44, P46, Ports PJ6, PJ7) at Ta = 25°C (Reference Data)
Figure 5.7
IOH/IOL vs VOH/VOL
10
Ta = –40°C
8
Ta = 25°C
Ta = 105°C
6
IOH/IOL [mA]
4
2
0
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
2
–2
Ta = 105°C
–4 Ta = 25°C
Ta = –40°C
–6
VOH/VOL [V]
Figure 5.8
VOH/VOL and IOH/IOL Temperature Characteristics of General Ports (Except for the RIIC
Output Pin, Ports P40 to P44, P46, Ports PJ6, PJ7) at VCC = 1.8 V (Reference Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 57 of 108
RX110 Group
5. Electrical Characteristics
IOH/IOL vs VOH/VOL
30
Ta = –40°C
25
Ta = 25°C
20
Ta = 105°C
IOH/IOL [mA]
15
10
5
0
0
0.5
1
1.5
2
2.5
3
–5
Ta = 105°C
–10
Ta = 25°C
–15
Ta = –40°C
–20
VOH/VOL [V]
Figure 5.9
VOH/VOL and IOH/IOL Temperature Characteristics of General Ports (Except for the RIIC
Output Pin, Ports P40 to P44, P46, Ports PJ6, PJ7) at VCC = 2.7 V (Reference Data)
IOH/IOL vs VOH/VOL
50
Ta = –40°C
40
Ta = 25°C
IOH/IOL [mA]
30
Ta = 105°C
20
10
0
0
–10
–20
0.5
1
1.5
2
2.5
3
3.5
4
Ta = 105°C
Ta = 25°C
Ta = –40°C
–30
VOH/VOL [V]
Figure 5.10
VOH/VOL and IOH/IOL Temperature Characteristics of General Ports (Except for the RIIC
Output Pin, Ports P40 to P44, P46, Ports PJ6, PJ7) at VCC = 3.3 V (Reference Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 58 of 108
RX110 Group
5. Electrical Characteristics
5.2.2
Standard I/O Pin Output Characteristics (2)
Figure 5.11 to Figure 5.13 show the characteristics of the RIIC output pin.
IOL vs VOL
40
VCC = 3.3 V
35
30
VCC = 2.7 V
IOL [mA]
25
20
15
10
5
0
0
0.5
1
1.5
2
2.5
3
3.5
VOH/VOL [V]
Figure 5.11
VOL and IOL Voltage Characteristics of RIIC Output Pin at Ta = 25°C (Reference Data)
IOL vs VOL
30
Ta = –40°C
25
Ta = 25°C
Ta = 105°C
IOL [mA]
20
15
10
5
0
0
0.5
1
1.5
2
2.5
3
VOL [V]
Figure 5.12
VOL and IOL Temperature Characteristics of RIIC Output Pin at VCC = 2.7 V (Reference
Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 59 of 108
RX110 Group
5. Electrical Characteristics
IOL vs VOL
50
45
Ta = –40°C
40
Ta = 25°C
35
Ta = 105°C
IOL [mA]
30
25
20
15
10
5
0
0
0.5
1
1.5
2
2.5
3
3.5
4
VOL [V]
Figure 5.13
VOL and IOL Temperature Characteristics of RIIC Output Pin at VCC = 3.3 V (Reference
Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 60 of 108
RX110 Group
5. Electrical Characteristics
5.2.3
Standard I/O Pin Output Characteristics (3)
Figure 5.14 to Figure 5.17 show the characteristics ports P40 to P44, P46, ports PJ6, PJ7.
IOH/IOL vs VOH/VOL
14
VCC = 3.3 V
12
10
VCC = 2.7 V
IOH/IOL [mA]
8
6
4
VCC = 1.8 V
2
0
0 VCC = 1.8 V 0.5
–2
1
1.5
2
2.5
3
3.5
VCC = 2.7 V
VCC = 3.3 V
–4
VOH/VOL [V]
VOH/VOL and IOH/IOL Voltage Characteristics of Ports P40 to P44, P46, Ports PJ6, PJ7 at
Ta = 25°C (Reference Data)
Figure 5.14
IOH/IOL vs VOH/VOL
4
3
Ta = –40°C
3
Ta = 25°C
Ta = 105°C
IOH/IOL [mA]
2
2
1
1
0
–1
–1
0
0.2
Ta = 105°C
Ta = 25°C
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
2
Ta = –40°C
VOH/VOL [V]
Figure 5.15
VOH/VOL and IOH/IOL Temperature Characteristics of Ports P40 to P44, P46, Ports PJ6,
PJ7 at VCC = 1.8 V (Reference Data)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 61 of 108
RX110 Group
5. Electrical Characteristics
IOH/IOL vs VOH/VOL
10
Ta = –40°C
8
Ta = 25°C
Ta = 105°C
IOH/IOL [mA]
6
4
2
0
0 Ta = 105°C
–2
0.5
1
1.5
2
2.5
3
Ta = 25°C
Ta = –40°C
–4
VOH/VOL [V]
Figure 5.16
VOH/VOL and IOH/IOL Temperature Characteristics of Ports P40 to P44, P46, Ports PJ6,
PJ7 at VCC = 2.7 V (Reference Data)
IOH/IOL vs VOH/VOL
16
14
Ta = –40°C
12
Ta = 25°C
Ta = 105°C
10
IOH/IOL [mA]
8
6
4
2
0
–2
0 Ta = 105°C 0.5
Ta = 25°C
–4
1
1.5
2
2.5
3
3.5
4
Ta = –40°C
VOH/VOL [V]
Figure 5.17
VOH/VOL and IOH/IOL Temperature Characteristics of Ports P40 to P44, P46, Ports PJ6,
PJ7 at VCC = 3.3 V (Reference Data)
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RX110 Group
5.3
5. Electrical Characteristics
AC Characteristics
5.3.1
Table 5.19
Conditions:
Clock Timing
Operation Frequency Value (High-Speed Operating Mode)
1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
VCC
Item
Maximum operating
frequency
Symbol
fmax
System clock (ICLK)
FlashIF clock
(FCLK)*1, *2
Unit
1.8 to 2.4 V
2.4 to 2.7 V
2.7 to 3.6 V
8
16
32
8
16
32
Peripheral module clock (PCLKB)
8
16
32
Peripheral module clock (PCLKD)*3
8
16
32
MHz
Note 1. The lower-limit frequency of FCLK is 1 MHz during programming or erasing of the flash memory. When using FCLK at below
4 MHz, the frequency can be set to 1 MHz, 2 MHz, or 3 MHz. A non-integer frequency such as 1.5 MHz cannot be set.
Note 2. The frequency accuracy of FCLK should be ±3.5%. Confirm the frequency accuracy of the clock source.
Note 3. The lower-limit frequency of PCLKD is 4 MHz at 2.4 V or above and 1 MHz at below 2.4 V when the A/D converter is in use.
Table 5.20
Operation Frequency Value (Middle-Speed Operating Mode)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
VCC
Item
Maximum operating
frequency
Symbol
System clock (ICLK)
2.4 to 2.7 V
2.7 to 3.6 V
8
12
12
FlashIF clock (FCLK)*1, *2
8
12
12
Peripheral module clock (PCLKB)
8
12
12
8
12
12
Peripheral module clock
fmax
Unit
1.8 to 2.4 V
(PCLKD)*3
MHz
Note 1. The lower-limit frequency of FCLK is 1 MHz during programming or erasing of the flash memory. When using FCLK at below
4 MHz, the frequency can be set to 1 MHz, 2 MHz, or 3 MHz. A non-integer frequency such as 1.5 MHz cannot be set.
Note 2. The frequency accuracy of FCLK should be ±3.5%.
Note 3. The lower-limit frequency of PCLKD is 4 MHz at 2.4 V or above and 1 MHz at below 2.4 V when the A/D converter is in use.
Table 5.21
Operation Frequency Value (Low-Speed Operating Mode)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Maximum operating
frequency
VCC
Symbol
System clock (ICLK)
Unit
1.8 to 2.4 V
fmax
2.4 to 2.7 V
32.768
FlashIF clock (FCLK)*1
32.768
Peripheral module clock (PCLKB)
32.768
Peripheral module clock (PCLKD)*2
32.768
2.7 to 3.6 V
kHz
Note 1. Programming and erasing the flash memory is impossible.
Note 2. The A/D converter cannot be used.
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RX110 Group
Table 5.22
5. Electrical Characteristics
Clock Timing
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Symbol
XTAL external clock input cycle time
tXcyc
Min.
Typ.
Max.
50
—
—
Unit
ns
—
ns
Test Conditions
Figure 5.18
XTAL external clock input high pulse width
tXH
20
—
XTAL external clock input low pulse width
tXL
20
—
—
ns
XTAL external clock rising time
tXr
—
—
5
ns
tXf
—
—
5
ns
tEXWT
0.5
—
—
µs
fMAIN
1
—
20
MHz
1
—
8
tMAINOSC
—
3
—
tMAINOSC
—
50
LOCO clock oscillation frequency
fLOCO
3.44
4.0
4.56
MHz
LOCO clock oscillation stabilization time
tLOCO
—
—
0.5
µs
IWDT-dedicated clock oscillation frequency
fILOCO
12.75
15
17.25
kHz
IWDT-dedicated clock oscillation stabilization time
tILOCO
—
—
50
μs
HOCO clock oscillation frequency
fHOCO
31.52
32
32.48
MHz
31.68
32
32.32
Ta = –20 to 85°C
31.36
32
32.64
Ta = –40 to 105°C
XTAL external clock falling time
XTAL external clock input wait time*1
2.4 ≤ VCC ≤ 3.6
Main clock oscillator oscillation frequency
1.8 ≤ VCC < 2.4
Main clock oscillation stabilization time (crystal)*2
Main clock oscillation stabilization time (ceramic
resonator)*2
HOCO clock oscillation stabilization time
Sub-clock oscillator oscillation
ms
µs
tHOCO2
—
—
56
µs
frequency*4
fSUB
—
32.768
—
kHz
time*3
tSUBOSC
—
0.5
—
s
Sub-clock oscillation stabilization
Figure 5.20
Figure 5.21
Figure 5.19
Ta = –40 to 85°C
Figure 5.23
Figure 5.24
Note 1. Time until the clock can be used after the main clock oscillator stop bit (MOSCCR.MOSTP) is set to 0 (operating) when the
external clock is stable.
Note 2. Reference values when an 8-MHz oscillator is used.
When specifying the main clock oscillator stabilization time, set the MOSCWTCR register with a stabilization time value that is
equal to or greater than the oscillator-manufacturer-recommended value.
After changing the setting of the MOSCCR.MOSTP bit so that the main clock oscillator operates, read the OSCOVFSR.MOOVF
flag to confirm that is has become 1, and then start using the main clock.
Note 3. After changing the setting of the SOSCCR.SOSTP bit or RCR3.RTCEN bit so that the sub-clock oscillator operates, only start
using the sub-clock after the sub-clock oscillation stabilization wait time that is equal to or greater than the oscillatormanufacturer-recommended value has elapsed.
Reference value when a 32.768-kHz resonator is used.
Note 4. Only 32.768 kHz can be used.
tEXcyc
tEXH
XTAL external clock input
VCC × 0.5
tEXr
Figure 5.18
tEXL
tEXf
XTAL External Clock Input Timing
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RX110 Group
5. Electrical Characteristics
ILOCOCR.ILCSTP
tILOCO
IWDT-dedicated clock oscillator output
Figure 5.19
IWDT-Dedicated Clock Oscillation Start Timing
MOSCCR.MOSTP
tMAINOSC
Main clock oscillator output
Figure 5.20
Main Clock Oscillation Start Timing
LOCOCR.LCSTP
tLOCO
LOCO clock oscillator output
Figure 5.21
LOCO Clock Oscillation Start Timing
RES#
Internal reset
tRESWT
OFS1.HOCOEN
HOCO clock
Figure 5.22
HOCO Clock Oscillation Start Timing (After Reset is Canceled by Setting
OFS1.HOCOEN Bit to 0)
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RX110 Group
5. Electrical Characteristics
HOCOCR.HCSTP
tHOCO
HOCO clock
Figure 5.23
HOCO Clock Oscillation Start Timing (Oscillation is Started by Setting HOCOCR.HCSTP
Bit)
SOSCCR.SOSTP
tSUBOSC
Sub-clock oscillator output
Figure 5.24
Sub-Clock Oscillation Start Timing
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RX110 Group
5. Electrical Characteristics
5.3.2
Reset Timing
Table 5.23
Reset Timing
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
RES# pulse width
Symbol
Min.
Typ.
Max.
Unit
tRESWP
3
—
—
ms
Figure 5.25
Other than above
tRESW
30
—
—
μs
Figure 5.26
At normal startup*1
tRESWT
—
8.5
—
ms
Figure 5.25
At power-on
Wait time after RES# cancellation
(at power-on)
Test Conditions
tRESWT
—
560
—
μs
Wait time after RES# cancellation
(during powered-on state)
tRESWT
—
114
—
μs
Figure 5.26
Independent watchdog timer reset period
tRESWIW
—
1
—
IWDT clock
cycle
Figure 5.27
tRESWSW
—
1
—
ICLK cycle
tRESW2
—
300
—
μs
tRESW2
—
168
—
μs
During fast startup
time*2
Software reset period
Wait time after independent watchdog timer reset
cancellation*3
Wait time after software reset cancellation
Note 1. When OFS1.(STUPLVD1REN, FASTSTUP) = 11b.
Note 2. When OFS1.(STUPLVD1REN, FASTSTUP) ≠ 11b.
Note 3. When IWDTCR.CKS[3:0] = 0000b.
VCC
RES#
tRESWP
Internal reset
tRESWT
Figure 5.25
Reset Input Timing at Power-On
tRESW
RES#
Internal reset
tRESWT
Figure 5.26
Reset Input Timing (1)
tRESWIW, tRESWSW
Independent watchdog timer reset
Software reset
Internal reset
tRESWT2
Figure 5.27
Reset Input Timing (2)
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RX110 Group
5. Electrical Characteristics
5.3.3
Timing of Recovery from Low Power Consumption Modes
Table 5.24
Timing of Recovery from Low Power Consumption Modes (1)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Recovery time
from software
standby mode*1
High-speed
mode
Symbol
Min.
Typ.
Max.
Unit
Test
Conditions
Figure 5.28
Crystal
connected to
main clock
oscillator
Main clock oscillator
operating*2
tSBYMC
—
2
3
ms
External clock
input to main
clock oscillator
Main clock oscillator
operating*3
tSBYEX
—
35
50
μs
Sub-clock oscillator operating
tSBYSC
—
650
800
μs
HOCO clock oscillator operating*4
tSBYHO
—
40
55
μs
LOCO clock oscillator operating
tSBYLO
—
40
55
μs
Note:
When the division ratios of PCLKB, PCLKD, FCLK, and ICLK are all set to 1.
Note 1. The recovery time varies depending on the state of each oscillator when the WAIT instruction is executed. The recovery time
when multiple oscillators are operating varies depending on the operating state of the oscillators that are not selected as the
system clock source. This applies when only the oscillator listed in each item is operating and the other oscillators are stopped.
Note 2. When the frequency of the crystal is 20 MHz.
When the main clock oscillator wait control register (MOSCWTCR) is set to 04h.
Note 3. When the frequency of the external clock is 20 MHz.
When the main clock oscillator wait control register (MOSCWTCR) is set to 00h.
Note 4. When the frequency of HOCO is 32 MHz.
When the high-speed clock oscillator wait control register (HOCOWTCR) is set to 05h.
Table 5.25
Timing of Recovery from Low Power Consumption Modes (2)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Recovery time
from software
standby mode*1
Middle-speed
mode
Symbol
Min.
Typ.
Max.
Unit
Test
Conditions
Figure 5.28
Crystal
connected to
main clock
oscillator
Main clock oscillator
operating*2
tSBYMC
—
2
3
ms
External clock
input to main
clock oscillator
Main clock oscillator
operating*3
tSBYEX
—
3
4
μs
tSBYSC
—
600
750
μs
tSBYHO
—
40
50
μs
tSBYLO
—
4.8
7
μs
Sub-clock oscillator operating
HOCO clock oscillator
operating*4
LOCO clock oscillator operating
Note: When the division ratios of PCLKB, PCLKD, FCLK, and ICLK are all set to 1.
Note 1. The recovery time varies depending on the state of each oscillator when the WAIT instruction is executed. The recovery time
when multiple oscillators are operating varies depending on the operating state of the oscillators that are not selected as the
system clock source. This applies when only the oscillator listed in each item is operating and the other oscillators are stopped.
Note 2. When the frequency of the crystal is 12 MHz.
When the main clock oscillator wait control register (MOSCWTCR) is set to 04h.
Note 3. When the frequency of the external clock is 12 MHz.
When the main clock oscillator wait control register (MOSCWTCR) is set to 00h.
Note 4. When the frequency of HOCO is 8 MHz.
When the high-speed clock oscillator wait control register (HOCOWTCR) is set to 05h.
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RX110 Group
Table 5.26
5. Electrical Characteristics
Timing of Recovery from Low Power Consumption Modes (3)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Recovery time
from software
standby mode*1
Low-speed
mode
Sub-clock oscillator operating
Symbol
Min.
Typ.
Max.
Unit
tSBYSC
—
600
750
μs
Test
Conditions
Figure 5.28
Note: When the division ratios of PCLKB, PCLKD, FCLK, and ICLK are all set to 1.
Note 1. The sub-clock continues oscillating in software standby mode during low-speed mode.
Oscillator
ICLK
IRQ
Software standby mode
tSBYMC, tSBYPC, tSBYEX,
tSBYPE, tSBYHO, tSBYLO
Oscillator
ICLK
IRQ
Software standby mode
tSBYSC
Figure 5.28
Software Standby Mode Cancellation Timing
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RX110 Group
Table 5.27
5. Electrical Characteristics
Timing of Recovery from Low Power Consumption Modes (4)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Recovery time from deep
sleep mode*1
Note:
Note 1.
Note 2.
Note 3.
Note 4.
Symbol
Min.
Typ.
Max.
Unit
High-speed mode*2
tDSLP
—
2
3.5
μs
Middle-speed mode*3
tDSLP
—
3
4
μs
Low-speed mode*4
tDSLP
—
400
500
μs
Test Conditions
When the division ratios of PCLKB, PCLKD, FCLK, and ICLK are all set to 1.
Oscillators continue oscillating in deep sleep mode.
When the frequency of the system clock is 32 MHz.
When the frequency of the system clock is 12 MHz.
When the frequency of the system clock is 32.768 kHz.
Oscillator
ICLK
IRQ
Deep sleep mode
tDSLP
Figure 5.29
Table 5.28
Deep Sleep Mode Cancellation Timing
Timing of Recovery from Low Power Consumption Modes (5)
Operating Mode Transition Time
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = -40 to +105°C
Mode before Transition
Mode after Transition
ICLK Frequency
Transition Time
Min.
Typ.
Max.
Unit
High-speed operating mode
Middle-speed operating mode
8 MHz
—
10
—
μs
Middle-speed operating mode
High-speed operating mode
8 MHz
—
37.5
—
μs
Low-speed operating mode
Middle-speed operating mode,
high-speed operating mode
32.768 kHz
—
213.62
—
μs
Middle-speed operating mode,
high-speed operating mode
Low-speed operating mode
32.768 kHz
—
183.11
—
μs
Note:
When the division ratios of PCLKB, PCLKD, FCLK, and ICLK are all set to 1.
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RX110 Group
5. Electrical Characteristics
5.3.4
Control Signal Timing
Table 5.29
Control Signal Timing
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
NMI pulse width
IRQ pulse width
Symbol
Min.
Typ.
Max.
Unit
tNMIW
200
—
—
ns
tPcyc × 2*1
—
—
200
—
—
tNMICK × 3.5*2
—
—
200
—
—
tIRQW
tPcyc × 2*1
—
—
200
—
—
tIRQCK × 3.5*3
—
—
Test Conditions
NMI digital filter disabled
(NMIFLTE.NFLTEN = 0)
NMI digital filter enabled
(NMIFLTE.NFLTEN = 1)
ns
IRQ digital filter disabled
(IRQFLTE0.FLTENi = 0)
IRQ digital filter enabled
(IRQFLTE0.FLTENi = 1)
tPcyc × 2 ≤ 200 ns
tPcyc × 2 > 200 ns
tNMICK × 3 ≤ 200 ns
tNMICK × 3 > 200 ns
tPcyc × 2 ≤ 200 ns
tPcyc × 2 > 200 ns
tIRQCK × 3 ≤ 200 ns
tIRQCK × 3 > 200 ns
Note:
200 ns minimum in software standby mode.
Note 1. tPcyc indicates the cycle of PCLKB.
Note 2. tNMICK indicates the cycle of the NMI digital filter sampling clock.
Note 3. tIRQCK indicates the cycle of the IRQi digital filter sampling clock (i = 0 to 7).
NMI
tNMIW
Figure 5.30
NMI Interrupt Input Timing
IRQ
tIRQW
Figure 5.31
IRQ Interrupt Input Timing
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RX110 Group
5. Electrical Characteristics
5.3.5
Timing of On-Chip Peripheral Modules
Table 5.30
Timing of On-Chip Peripheral Modules (1)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
I/O ports
Input data pulse width
MTU2
Input capture input pulse width
Single-edge setting
Min.
Max.
Unit*1
tPRW
1.5
—
tPcyc
Figure 5.32
1.5
—
tPcyc
Figure 5.33
2.5
—
tPcyc
Figure 5.34
tPcyc
Figure 5.35
tTICW
Both-edge setting
Timer clock pulse width
Single-edge setting
Both-edge setting
tTCKWH,
tTCKWL
Phase counting mode
SCI
—
—
2.5
—
4
—
6
—
Input clock pulse width
tSCKW
0.4
0.6
tScyc
Input clock rise time
tSCKr
—
20
ns
Input clock fall time
tSCKf
—
20
ns
tScyc
16
—
tPcyc
4
—
Asynchronous
Clock synchronous
Output clock cycle
Asynchronous
Clock synchronous
Output clock pulse width
tSCKW
0.4
0.6
tScyc
Output clock rise time
tSCKr
—
20
ns
tSCKf
—
20
ns
tTXD
—
40
ns
Output clock fall time
Transmit data delay time
(master)
Clock synchronous
Transmit data delay time
(slave)
Clock
synchronous
Receive data setup time
(master)
Clock
synchronous
Receive data setup time
(slave)
Clock synchronous
Receive data hold time
Clock synchronous
A/D
converter
Trigger input pulse width
CAC
CACREF input pulse width
2.7 V or above
—
65
ns
1.8 V or above
—
100
ns
2.7 V or above
65
—
ns
90
—
ns
40
—
ns
tRXH
40
—
ns
tTRGW
1.5
—
tPcyc
tCACREF
4.5 tcac + 3 tPcyc
—
ns
—
ns
—
ns
—
ns
15
ns
tRXS
1.8 V or above
tPcyc ≤ tcac*2
tPcyc > tcac*2
CLKOUT
1.5
2.5
tScyc
Input clock cycle
CLKOUT pin output cycle*4
VCC = 2.7 V or above
VCC = 2.7 V or above
tCcyc
VCC = 2.7 V or above
tCH
VCC = 2.7 V or above
125
35
70
tCL
VCC = 1.8 V or above
CLKOUT pin output rise time
35
70
tCr
—
VCC = 1.8 V or above
CLKOUT pin output fall time
VCC = 2.7 V or above
VCC = 1.8 V or above
Figure 5.37
250
VCC = 1.8 V or above
CLKOUT pin low pulse width*3
Figure 5.36
C = 30 pF
5 tcac + 6.5 tPcyc
VCC = 1.8 V or above
CLKOUT pin high pulse width*3
Test
Conditions
Symbol
30
tCf
—
15
ns
30
Note 1. tPcyc: PCLK cycle
Note 2. tcac: CAC count clock source cycle
Note 3. When the LOCO is selected as the clock output source (CKOCR.CKOSEL[2:0] bits = 000b), set the clock output division ratio
selection to divided by 2 (CKOCR.CKODIV[2:0] bits = 001b).
Note 4. When the XTAL external clock input or an oscillator is used with divided by 1 (CKOCR.CKOSEL[2:0] bits = 010b and
CKOCR.CKODIV[2:0] bits = 000b) to output from CLKOUT, the above should be satisfied with an input duty cycle of 45 to 55%.
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RX110 Group
Table 5.31
5. Electrical Characteristics
Timing of On-Chip Peripheral Modules (2)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C, C = 30 pF
Item
RSPI
RSPCK clock cycle Master
Symbol
Min.
Max.
Unit
Test Conditions
tSPcyc
2
4096
Figure 5.39
8
4096
tPcyc
*1
(tSPcyc – tSPCKr –
tSPCKf)/2 – 3
—
(tSPcyc – tSPCKr –
tSPCKf)/2
—
(tSPcyc – tSPCKr–
tSPCKf)/2 – 3
—
(tSPcyc – tSPCKr –
tSPCKf)/2
—
Slave
RSPCK clock
high pulse width
Master
tSPCKWH
Slave
RSPCK clock
low pulse width
Master
tSPCKWL
Slave
RSPCK clock
rise/fall time
Output
Master
tSPCKr,
tSPCKf
—
10
—
15
—
1
μs
2.7 V or above
tSU
10
—
ns
1.8 V or above
Slave
Data input hold
time
Master
Data output delay
time
Master
—
RSPCK set to PCLKB
divided by 2
tHF
0
—
tH
20 + 2 × tPcyc
—
Data output hold
time
Master
2.7 V or above
MOSI and MISO
rise/fall time
—
ns
tPcyc
tLAG
–30 + N*3 × tSPcyc
—
ns
2
—
tPcyc
tOD
—
14
ns
1.8 V or above
—
30
2.7 V or above
—
3 × tPcyc + 65
1.8 V or above
—
3 × tPcyc +105
0
—
–20
—
2.7 V or above
tOH
1.8 V or above
Master
tTD
Slave
Output
2.7 V or above
tDr, tDf
1.8 V or above
Output
Input
Slave access time
2.7 V or above
2.7 V or above
1.8 V or above
—
8 × tSPcyc + 2 × tPcyc
4 × tPcyc
—
—
10
—
20
ns
ns
1
μs
tSSLr,
tSSLf
—
20
ns
—
1
μs
tSA
—
6
tPcyc
—
7
—
5
—
6
1.8 V or above
Slave output release time
0
tSPcyc + 2 × tPcyc
ns
—
Input
SSL rise/fall time
× tSPcyc
tREL
Figure 5.40 to
Figure 5.45
ns
—
Slave
Successive
transmission delay
time
–30 +
N*2
ns
2
tLEAD
Slave
Slave
—
tPcyc
Master
Master
—
tH
Slave
SSL hold time
30
25 – tPcyc
RSPCK set to a division
ratio other than PCLKB
divided by 2
Slave
SSL setup time
ns
1.8 V or above
2.7 V or above
Input
Data input setup
time
ns
Figure 5.44,
Figure 5.45
tPcyc
Note 1. tPcyc: PCLK cycle
Note 2. N: An integer from 1 to 8 that can be set by the RSPI clock delay register (SPCKD)
Note 3. N: An integer from 1 to 8 that can be set by the RSPI slave select negation delay register (SSLND)
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RX110 Group
Table 5.32
5. Electrical Characteristics
Timing of On-Chip Peripheral Modules (3)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C, C = 30 pF
Item
Simple
SPI
SCK clock cycle output (master)
Symbol
Min.
Max.
Unit*1
tSPcyc
4
65536
tPcyc
6
65536
tSPCKWH
0.4
0.6
tSPcyc
tSPCKWL
0.4
0.6
tSPcyc
tSPCKr, tSPCKf
—
20
ns
ns
SCK clock cycle input (slave)
SCK clock high pulse width
SCK clock low pulse width
SCK clock rise/fall time
Data input setup time (master)
2.7 V or above
tSU
1.8 V or above
Data input setup time (slave)
65
—
95
—
40
—
Data input hold time
tH
40
—
ns
SS input setup time
tLEAD
3
—
tPcyc
SS input hold time
tLAG
3
—
tPcyc
Data output delay time (master)
tOD
—
40
ns
2.7 V or above
—
65
1.8 V or above
—
85
Data output delay time (slave)
Data output hold time (master)
2.7 V or above
tOH
1.8 V or above
Data output hold time (slave)
Data rise/fall time
SS input rise/fall time
–10
—
–20
—
–10
—
tDr, tDf
—
20
Test Conditions
Figure 5.39
Figure 5.40,
Figure 5.42
ns
ns
tSSLr, tSSLf
—
20
ns
Slave access time
tSA
—
6
tPcyc
Slave output release time
tREL
—
6
tPcyc
Figure 5.44,
Figure 5.45
Note 1. tPcyc: PCLK cycle
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RX110 Group
Table 5.33
5. Electrical Characteristics
Timing of On-Chip Peripheral Modules (4)
Conditions: 2.7 V ≤ VCC ≤ 3.6 V, 2.7 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, fPCLKB ≤ 32 MHz, Ta = –40 to +105°C
Symbol
Min.*1
Max.
SCL0 input cycle time
tSCL
6 (12) × tIICcyc + 1300
—
ns
SCL0 input high pulse width
tSCLH
3 (6) × tIICcyc + 300
—
ns
SCL0 input low pulse width
tSCLL
3 (6) × tIICcyc + 300
—
ns
SCL0, SDA0 input rise time
tSr
—
1000
ns
SCL0, SDA0 input fall time
tSf
—
300
ns
Item
RIIC
(Standard mode,
SMBus)
SCL0, SDA0 input spike pulse removal time
tSP
0
1 (4) × tIICcyc
ns
SDA0 input bus free time
tBUF
3 (6) × tIICcyc + 300
—
ns
START condition input hold time
tSTAH
tIICcyc + 300
—
ns
Repeated START condition input setup
time
tSTAS
1000
—
ns
STOP condition input setup time
tSTOS
1000
—
ns
Data input setup time
tSDAS
tIICcyc + 50
—
ns
Data input hold time
tSDAH
0
—
ns
SCL0, SDA0 capacitive load
RIIC
(Fast mode)
Unit Test Conditions
Cb
—
400
pF
SCL0 input cycle time
tSCL
6 (12) × tIICcyc + 600
—
ns
SCL0 input high pulse width
tSCLH
3 (6) × tIICcyc + 300
—
ns
SCL0 input low pulse width
tSCLL
3 (6) × tIICcyc + 300
—
ns
SCL0, SDA0 input rise time
tSr
—*2
300
ns
SCL0, SDA0 input fall time
tSf
—*2
300
ns
SCL0, SDA0 input spike pulse removal time
tSP
0
1 (4) × tIICcyc
ns
SDA0 input bus free time
tBUF
3 (6) × tIICcyc + 300
—
ns
START condition input hold time
tSTAH
tIICcyc + 300
—
ns
Repeated START condition input setup
time
tSTAS
300
—
ns
STOP condition input setup time
tSTOS
300
—
ns
Data input setup time
tSDAS
tIICcyc + 50
—
ns
Data input hold time
tSDAH
0
—
ns
Cb
—
400
pF
SCL0, SDA0 capacitive load
Figure 5.46
Figure 5.46
Note:
tIICcyc: RIIC internal reference count clock (IICφ) cycle
Note 1. The value in parentheses is used when the ICMR3.NF[1:0] bits are set to 11b while a digital filter is enabled with the ICFER.NFE
bit = 1.
Note 2. The minimum tsr and tsf specifications for fast mode are not set.
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RX110 Group
Table 5.34
5. Electrical Characteristics
Timing of On-Chip Peripheral Modules (5)
Conditions: 2.7 V ≤ VCC ≤ 3.6 V, 2.7 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, fPCLKB ≤ 32 MHz, Ta = –40 to +105°C
Item
Simple I2C
SDA0 input rise time
(Standard mode)
SDA0 input fall time
Min.
Max.
Unit
tSr
—
1000
ns
tSf
—
300
ns
tSP
0
4 × tpcyc*1
ns
Data input setup time
tSDAS
250
—
ns
Data input hold time
SDA0 input spike pulse removal time
Simple I2C
(Fast mode)
Symbol
tSDAH
0
—
ns
SCL0, SDA0 capacitive load
Cb
—
400
pF
SCL0, SDA0 input rise time
tSr
—
300
ns
SCL0, SDA0 input fall time
tSf
—
300
ns
SCL0, SDA0 input spike pulse removal time
tSP
0
4 × tpcyc*1
ns
Data input setup time
tSDAS
100
—
ns
Data input hold time
tSDAH
0
—
ns
Cb
—
400
pF
SCL0, SDA0 capacitive load
Test Conditions
Figure 5.46
Figure 5.46
Note:
tPcyc: PCLK cycle
Note 1. This applies when the SMR.CKS[1:0] bits = 00b and the SNFR.NFCS[2:0] bits = 010b while the SNFR.NFE bit = 1 and the
digital filter is enabled.
PCLK
Port
tPRW
Figure 5.32
I/O Port Input Timing
PCLK
Output
compare output
Input capture
input
Figure 5.33
tTICW
MTU2 Input/Output Timing
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5. Electrical Characteristics
PCLK
MTCLKA to
MTCLKH
tTCKWL
Figure 5.34
tTCKWH
MTU2 Clock Input Timing
tSCKW
tSCKr
tSCKf
SCKn
(n = 1, 5, 12)
tScyc
Figure 5.35
SCK Clock Input Timing
SCKn
tTXD
TXDn
tRXS tRXH
RXDn
(n = 1, 5, 12)
Figure 5.36
SCI Input/Output Timing: Clock Synchronous Mode
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RX110 Group
5. Electrical Characteristics
PCLK
ADTRG0#
tTRGW
Figure 5.37
A/D Converter External Trigger Input Timing
tCcyc
tCH
tCf
CLKOUT pin output
tCL
tCr
Test conditions: VOH = VCC × 0.7, VOL = VCC × 0.3, IOH = -1.0 mA, IOL = 1.0 mA, C = 30 pF
Figure 5.38
CLKOUT Output Timing
RSPI
Simple SPI
RSPCKA
Master select output
SCKn
Master select output
tSPCKr
tSPCKWH
VOH
VOH
VOL
tSPCKf
VOH
VOH
VOL
tSPCKWL
VOL
tSPcyc
tSPCKr
tSPCKWH
VIH
RSPCKA
Slave select input
SCKn
Slave select input
VIH
VIL
(n = 1, 5, 12)
tSPCKf
VIH
VIL
tSPCKWL
VIH
VIL
tSPcyc
VOH = 0.7 × VCC, VOL = 0.3 × VCC, VIH = 0.7 × VCC, VIL = 0.3 × VCC
Figure 5.39
RSPI Clock Timing and Simple SPI Clock Timing
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RX110 Group
RSPI
5. Electrical Characteristics
Simple SPI
tTD
SSLA0 to
SSLA3
output
tLEAD
RSPCKA
CPOL = 0
output
SCKn
CKPOL = 0
output
RSPCKA
CPOL = 1
output
SCKn
CKPOL = 1
output
tSSLr, tSSLf
tSU
MISOA
input
tLAG
SMISOn
input
tH
MSB IN
DATA
tDr, tDf
MOSIA
output
SMOSIn
output
LSB IN
tOH
MSB OUT
MSB IN
tOD
DATA
LSB OUT
IDLE
MSB OUT
(n = 1, 5, 12)
Figure 5.40
RSPI Timing (Master, CPHA = 0) (Bit Rate: PCLKB Set to Division Ratio Other Than
Divided by 2) and Simple SPI Timing (Master, CKPH = 1)
tTD
SSLA0 to
SSLA3
output
tLEAD
tLAG
tSSLr, tSSLf
RSPCKA
CPOL = 0
output
RSPCKA
CPOL = 1
output
tSU
MISOA
input
tHF
MSB IN
tDr, tDf
MOSIA
output
Figure 5.41
tHF
tOH
MSB OUT
LSB IN
DATA
MSB IN
tOD
DATA
LSB OUT
IDLE
MSB OUT
RSPI Timing (Master, CPHA = 0) (Bit Rate: PCLKB Set to Divided by 2)
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RX110 Group
RSPI
5. Electrical Characteristics
Simple SPI
tTD
SSLA0 to
SSLA3
output
tLEAD
RSPCKA
CPOL = 0
output
SCKn
CKPOL = 1
output
RSPCKA
CPOL = 1
output
SCKn
CKPOL = 0
output
tLAG
tSSLr, tSSLf
tSU
MISOA
input
SMISOn
input
tH
MSB IN
DATA
tOH
MOSIA
output
SMOSIn
output
LSB IN
tOD
MSB OUT
MSB IN
tDr, tDf
DATA
LSB OUT
IDLE
MSB OUT
(n = 1, 5, 12)
Figure 5.42
RSPI Timing (Master, CPHA = 1) (Bit Rate: PCLKB Set to Division Ratio Other Than
Divided by 2) and Simple SPI Timing (Master, CKPH = 0)
tTD
SSLA0 to
SSLA3
output
tLEAD
tLAG
tSSLr, tSSLf
RSPCKA
CPOL = 0
output
RSPCKA
CPOL = 1
output
tSU
MISOA
input
tHF
MSB IN
tOH
MOSIA
output
Figure 5.43
tH
DATA
LSB IN
tOD
MSB OUT
MSB IN
tDr, tDf
DATA
LSB OUT
IDLE
MSB OUT
RSPI Timing (Master, CPHA = 1) (Bit Rate: PCLKB Set to Divided by 2)
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5. Electrical Characteristics
RSPI
Simple SPI
SSLA0
input
SSn#
input
tTD
tLEAD
RSPCKA
CPOL = 0
input
SCKn
CKPOL = 0
input
RSPCKA
CPOL = 1
input
SCKn
CKPOL = 1
input
tLAG
tSA
MISOA
output
tOH
SMISOn
output
MSB OUT
tSU
MOSIA
input
tOD
SMOSIn
input
tREL
DATA
LSB OUT
tH
MSB IN
MSB OUT
tDr, tDf
MSB IN
DATA
LSB IN
MSB IN
(n = 1, 5, 12)
Figure 5.44
RSPI Timing (Slave, CPHA = 0) and Simple SPI Timing (Slave, CKPH = 1)
RSPI
Simple SPI
SSLA0
input
SSn#
input
tTD
tLEAD
RSPCKA
CPOL = 0
input
SCKn
CKPOL = 1
input
RSPCKA
CPOL = 1
input
SCKn
CKPOL = 0
input
MISOA
output
SMISOn
output
tSA
tLAG
tOH
tOD
LSB OUT
(Last data)
MSB OUT
tSU
MOSIA
input
SMOSIn
input
tREL
DATA
tH
MSB IN
LSB OUT
MSB OUT
tDr, tDf
DATA
LSB IN
MSB IN
(n = 1, 5, 12)
Figure 5.45
RSPI Timing (Slave, CPHA = 1) and Simple SPI Timing (Slave, CKPH = 0)
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RX110 Group
5. Electrical Characteristics
VIH
SDA0
VIL
tBUF
tSCLH
tSTAS
tSTAH
tSTOS
tSP
SCL0
P*1
tSCLL
tSr
tSf
tSCL
tSDAS
tSDAH
Note 1. S, P, and Sr indicate the following conditions, respectively.
S: START condition
P: STOP condition
Sr: Repeated START condition
Figure 5.46
P*1
Sr*1
S*1
Test conditions
VIH = VCC × 0.7, VIL = VCC × 0.3
RIIC Bus Interface Input/Output Timing and Simple I2C Bus Interface Input/Output
Timing
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RX110 Group
5.4
5. Electrical Characteristics
A/D Conversion Characteristics
Table 5.35
A/D Conversion Characteristics (1)
Conditions: 2.7 V ≤ VCC ≤ 3.6 V, 2.7 V ≤ AVCC0 ≤ 3.6 V, 2.7 V ≤ VREFH0 ≤ AVCC0, VSS = AVSS0 = VREFL0 = 0 V,
Ta = –40 to +105°C
Item
Min.
Typ.
Max.
Unit
Test Conditions
Frequency
4
—
32
MHz
Resolution
—
—
12
Bit
1.031
(0.313)*2
—
—
µs
1.375
(0.641)*2
—
—
Analog input effective range
0
—
VREFH0
V
Offset error
—
±0.5
±4.5
LSB
High-precision channel
PJ6PFS.ASEL bit = 1
PJ7PFS.ASEL bit = 1
±6.0
LSB
Other than above
Full-scale error
—
±0.75
±4.5
LSB
High-precision channel
PJ6PFS.ASEL bit = 1
PJ7PFS.ASEL bit = 1
±6.0
LSB
Other than above
time*1
Conversion
(Operation at
PCLKD = 32 MHz)
Permissible signal source
impedance (Max.) = 0.3 kΩ
High-precision channel
ADCSR.ADHSC bit = 1
ADSSTRn.SST[7:0] bits = 09h
Normal-precision channel
ADCSR.ADHSC bit = 1
ADSSTRn.SST[7:0] bits = 14h
Quantization error
—
±0.5
—
LSB
Absolute accuracy
—
±1.25
±5.0
LSB
High-precision channel
PJ6PFS.ASEL bit = 1
PJ7PFS.ASEL bit = 1
±8.0
LSB
Other than above
DNL differential nonlinearity error
—
±1.0
—
LSB
INL integral nonlinearity error
—
±1.0
±3.0
LSB
Note:
The characteristics apply when no pin functions other than A/D converter input are used. Absolute accuracy includes
quantization errors. Offset error, full-scale error, DNL differential nonlinearity error, and INL integral nonlinearity error do not
include quantization errors.
Note 1. The conversion time is the sum of the sampling time and the comparison time. As the test conditions, the number of sampling
states is indicated.
Note 2. The value in parentheses indicates the sampling time.
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5. Electrical Characteristics
AVREFH0
5.0
Characteristics listed in
Table 5.35
A/D Conversion
Characteristics (1)
4.0
3.6
Characteristics listed in
Table 5.36
A/D Conversion
Characteristics (2)
3.0
2.7
2.4
2.0
1.8
Characteristics listed in
Table 5.37
A/D Conversion
Characteristics (3)
1.0
1.0
Figure 5.47
1.8 2.4 2.7
2.0
3.0
3.6
4.0
5.0
AVCC0
AVCC0 to AVREFH Voltage Range
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RX110 Group
Table 5.36
5. Electrical Characteristics
A/D Conversion Characteristics (2)
Conditions: 2.4 V ≤ VCC ≤ 3.6 V, 2.4 V ≤ AVCC0 ≤ 3.6 V, 2.4 V ≤ VREFH0 ≤ AVCC0, VSS = AVSS0 = VREFL0 = 0 V,
Ta = –40 to +105°C
Item
Frequency
Resolution
Conversion time*1
(Operation at
PCLKD = 16 MHz)
Permissible signal source
impedance (Max.) = 1.0 kΩ
Min.
Typ.
Max.
Unit
4
—
16
MHz
Test Conditions
—
—
12
Bit
2.062
(0.625)*2
—
—
µs
High-precision channel
ADCSR.ADHSC bit = 1
ADSSTRn.SST[7:0] bits = 09h
2.750
(1.313)*2
—
—
µs
Normal-precision channel
ADCSR.ADHSC bit = 1
ADSSTRn.SST[7:0] bits = 14h
Analog input effective range
0
—
VREFH0
V
Offset error
—
±0.5
±6.0
LSB
Full-scale error
—
±1.25
±6.0
LSB
Quantization error
—
±0.5
—
LSB
Absolute accuracy
—
±3.0
±8.0
LSB
DNL differential nonlinearity error
—
±1.0
—
LSB
INL integral nonlinearity error
—
±1.5
±3.0
LSB
Note:
The characteristics apply when no pin functions other than A/D converter input are used. Absolute accuracy includes
quantization errors. Offset error, full-scale error, DNL differential nonlinearity error, and INL integral nonlinearity error do not
include quantization errors.
Note 1. The conversion time is the sum of the sampling time and the comparison time. As the test conditions, the number of sampling
states is indicated.
Note 2. The value in parentheses indicates the sampling time.
Table 5.37
A/D Conversion Characteristics (3)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, 1.8 V ≤ VREFH0 ≤ AVCC0, VSS = AVSS0 = VREFL0 = 0 V,
Ta = –40 to +105°C
Item
Min.
Typ.
Max.
Unit
Frequency
1
Resolution
—
—
8
MHz
—
12
Bit
4.875
(1.250)*2
—
—
µs
6.250
(2.625)*2
—
—
Analog input effective range
0
—
VREFH0
Offset error
—
±0.5
±24.0
LSB
Full-scale error
—
±1.25
±24.0
LSB
Quantization error
—
±0.5
—
LSB
Absolute accuracy
—
±2.75
±32.0
LSB
DNL differential nonlinearity error
—
±1.0
—
LSB
INL integral nonlinearity error
—
±1.25
±12.0
LSB
time*1
Conversion
(Operation at
PCLKD = 8 MHz)
Permissible signal source
impedance (Max.) = 5.0 kΩ
Test Conditions
High-precision channel
ADCSR.ADHSC bit = 0
ADSSTRn.SST[7:0] bits = 09h
Normal-precision channel
ADCSR.ADHSC bit = 0
ADSSTRn.SST[7:0] bits = 14h
V
Note:
The characteristics apply when no pin functions other than A/D converter input are used. Absolute accuracy includes
quantization errors. Offset error, full-scale error, DNL differential nonlinearity error, and INL integral nonlinearity error do not
include quantization errors.
Note 1. The conversion time is the sum of the sampling time and the comparison time. As the test conditions, the number of sampling
states is indicated.
Note 2. The value in parentheses indicates the sampling time.
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RX110 Group
Table 5.38
5. Electrical Characteristics
A/D Converter Channel Classification
Classification
Channel
Conditions
High-precision channel
AN000 to AN004, AN006
Normal-precision channel
AN008 to AN015
Internal reference voltage input
channel
Internal reference voltage
AVCC0 = 2.0 to 3.6 V
Temperature sensor input
channel
Temperature sensor output
AVCC0 = 2.0 to 3.6 V
Table 5.39
Remarks
AVCC0 = 1.8 to 3.6 V
Pins AN000 to AN004 and AN006
cannot be used as digital outputs when
the A/D converter is in use.
A/D Internal Reference Voltage Characteristics
Conditions: 2.0 V ≤ VCC ≤ 3.6 V, 2.0 V ≤ AVCC0 ≤ 3.6 V*1, VSS = AVSS0 = VREFL0 = 0 V, Ta = –40 to +105°C
Item
Internal reference voltage input
channel*2
Min.
Typ.
Max.
Unit
1.36
1.43
1.50
V
Test Conditions
Note 1. The internal reference voltage cannot be selected for input channels when AVCC0 < 2.0 V.
Note 2. The A/D internal reference voltage indicates the voltage when the internal reference voltage is input to the A/D converter.
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RX110 Group
5. Electrical Characteristics
FFFh
Full-scale error
Integral nonlinearity
error (INL)
A/D converter
output code
Ideal line of actual A/D
conversion characteristic
Actual A/D conversion
characteristic
Ideal A/D conversion
characteristic
Differential nonlinearity error (DNL)
1-LSB width for ideal A/D
conversion characteristic
Differential nonlinearity error (DNL)
1-LSB width for ideal A/D
conversion characteristic
Absolute accuracy
000h
Offset error
0
Figure 5.48
Analog input voltage
VREFH0
(full-scale)
Illustration of A/D Converter Characteristic Terms
Absolute accuracy
Absolute accuracy is the difference between output code based on the theoretical A/D conversion characteristics, and the
actual A/D conversion result. When measuring absolute accuracy, the voltage at the midpoint of the width of analog
input voltage (1-LSB width), that can meet the expectation of outputting an equal code based on the theoretical A/D
conversion characteristics, is used as an analog input voltage. For example, if 12-bit resolution is used and if reference
voltage (VREFH0 = 3.072 V), then 1-LSB width becomes 0.75 mV, and 0 mV, 0.75 mV, 1.5 mV, ... are used as analog
input voltages.
If analog input voltage is 6 mV, absolute accuracy = ±5 LSB means that the actual A/D conversion result is in the range
of 003h to 00Dh though an output code, 008h, can be expected from the theoretical A/D conversion characteristics.
Integral nonlinearity error (INL)
Integral nonlinearity error is the maximum deviation between the ideal line when the measured offset and full-scale
errors are zeroed, and the actual output code.
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5. Electrical Characteristics
Differential nonlinearity error (DNL)
Differential nonlinearity error is the difference between 1-LSB width based on the ideal A/D conversion characteristics
and the width of the actually output code.
Offset error
Offset error is the difference between a transition point of the ideal first output code and the actual first output code.
Full-scale error
Full-scale error is the difference between a transition point of the ideal last output code and the actual last output code.
5.5
Temperature Sensor Characteristics
Table 5.40
Temperature Sensor Characteristics
Conditions: 2.0 V ≤ VCC ≤ 3.6 V, 2.0 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Relative accuracy
Symbol
Min.
Typ.
Max.
Unit
―
―
±1.5
―
°C
―
±2.0
―
―
―
–3.65
―
mV/°C
Output voltage (at 25°C)
―
―
1.05
―
V
tSTART
―
―
5
μs
―
5
―
―
μs
Sampling time
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
2.4 V or above
Below 2.4 V
Temperature slope
Temperature sensor start time
Test Conditions
VCC = 3.3 V
Page 88 of 108
RX110 Group
5.6
5. Electrical Characteristics
Power-On Reset Circuit and Voltage Detection Circuit Characteristics
Table 5.41
Power-On Reset Circuit and Voltage Detection Circuit Characteristics (1)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Voltage detection level
Symbol
Min.
Typ.
Max.
Unit
Power-on reset (POR)
VPOR
1.35
1.50
1.65
V
Figure 5.49,
Figure 5.50
Test Conditions
Voltage detection circuit
(LVD1)*1
Vdet1_4
3.00
3.10
3.20
V
Figure 5.51
Vdet1_5
2.91
3.00
3.09
Vdet1_6
2.81
2.90
2.99
Vdet1_7
2.70
2.79
2.88
Vdet1_8
2.60
2.68
2.76
Vdet1_9
2.50
2.58
2.66
Vdet1_A
2.40
2.48
2.56
Vdet1_B
1.99
2.06
2.13
Vdet1_C
1.90
1.96
2.02
Vdet1_D
1.80
1.86
1.92
At falling edge VCC
Note:
These characteristics apply when noise is not superimposed on the power supply. When a setting is made so that the voltage
detection level overlaps with that of the voltage detection circuit (LVD2), it cannot be specified which of LVD1 and LVD2 is used
for voltage detection.
Note 1. n in the symbol Vdet1_n denotes the value of the LVDLVLR.LVD1LVL[3:0] bits.
Table 5.42
Power-On Reset Circuit and Voltage Detection Circuit Characteristics (2)
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Symbol
Min.
Typ.
Max.
Unit
Vdet2_0
2.71
2.90
3.09
V
Vdet2_1
2.43
2.60
2.77
Vdet2_2
1.87
2.00
2.13
Vdet2_3*2
1.69
1.80
1.91
tPOR
―
9.1
―
tPOR
―
1.6
―
tLVD1
―
568
―
―
100
―
tLVD2
―
100
―
μs
Figure 5.52
tdet
―
―
350
μs
Figure 5.49
Minimum VCC down time*5
tVOFF
350
―
―
μs
Figure 5.49,
VCC = 1.0 V or above
Power-on reset enable time
tW(POR)
1
―
―
ms
Figure 5.50,
VCC = below 1.0 V
LVD operation stabilization time (after LVD is enabled)
Td(E-A)
―
―
300
μs
Figure 5.51, Figure 5.52
VLVH
―
70
―
mV
―
60
―
Vdet1_5 to 9, LVD2 selected
―
50
―
When selection is from
among Vdet1_A to B.
―
40
―
When selection is from
among Vdet1_C to D.
Voltage detection level
Voltage detection circuit
(LVD2)*1
Wait time after power-on
reset cancellation
At normal startup*3
Wait time after voltage
monitoring 1 reset
cancellation
Power-on voltage monitoring
1 reset disabled*3
During fast startup
time*4
Power-on voltage monitoring
1 reset enabled*4
Wait time after voltage monitoring 2 reset cancellation
Response delay time
Hysteresis width (LVD1 and LVD2)
Note:
Note 1.
Note 2.
Note 3.
Note 4.
Note 5.
Test Conditions
Figure 5.52
At falling edge VCC
ms
Figure 5.50
μs
Figure 5.51
Vdet1_4 selected
These characteristics apply when noise is not superimposed on the power supply. When a setting is made so that the voltage
detection level overlaps with that of the voltage detection circuit (LVD1), it cannot be specified which of LVD1 and LVD2 is used
for voltage detection.
n in the symbol Vdet2_n denotes the value of the LVDLVLR.LVD2LVL[3:0] bits.
Vdet2_3 selection can be used only when the CMPA2 pin input voltage is selected and cannot be used when the power supply
voltage (VCC) is selected.
When OFS1.(STUPLVD1REN, FASTSTUP) = 11b.
When OFS1.(STUPLVD1REN, FASTSTUP) ≠ 11b.
The minimum VCC down time indicates the time when VCC is below the minimum value of voltage detection levels VPOR, Vdet0,
Vdet1, and Vdet2 for the POR/LVD.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 89 of 108
RX110 Group
5. Electrical Characteristics
tVOFF
VCC
VPOR
1.0 V
Internal reset signal
(active-low)
tdet
Figure 5.49
tdet
tPOR
Voltage Detection Reset Timing
VPOR
VCC
1.0 V
tw(POR)
Internal reset signal
(active-low)
*1
tdet
tPOR
Note 1. tw(por) is the time required for a power-on reset to be enabled while the external power VCC is being held below the
valid voltage (1.0 V).
When VCC turns on, maintain tw(por) for 1.0 ms or more.
Figure 5.50
Power-On Reset Timing
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 90 of 108
RX110 Group
5. Electrical Characteristics
tVOFF
VCC
VLVH
Vdet1
LVD1E
Td(E-A)
LVD1
Comparator output
LVD1CMPE
LVD1MON
Internal reset signal
(active-low)
When LVD1RN = L
tdet
tdet
tLVD1
When LVD1RN = H
tLVD1
Figure 5.51
Voltage Detection Circuit Timing (Vdet1)
tVOFF
VCC
VLVH
Vdet2
LVD2E
Td(E-A)
LVD2
Comparator output
LVD2CMPE
LVD2MON
Internal reset signal
(active-low)
When LVD2RN = L
tdet
tdet
tLVD2
When LVD2RN = H
tLVD2
Figure 5.52
Voltage Detection Circuit Timing (Vdet2)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 91 of 108
RX110 Group
5.7
5. Electrical Characteristics
Oscillation Stop Detection Timing
Table 5.43
Oscillation Stop Detection Circuit Characteristics
Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V, Ta = –40 to +105°C
Item
Detection time
Symbol
Min.
Typ.
Max.
Unit
tdr
—
—
1
ms
Test
Conditions
Figure 5.53
Main clock
tdr
OSTDSR.OSTDF
LOCO clock
ICLK
Figure 5.53
Oscillation Stop Detection Timing
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 92 of 108
RX110 Group
5.8
5. Electrical Characteristics
ROM (Flash Memory for Code Storage) Characteristics
Table 5.44
ROM (Flash Memory for Code Storage) Characteristics (1)
Item
Reprogramming/erasure
Data hold time
Symbol
cycle*1
Min.
Typ.
Max.
Unit
NPEC
1000
—
—
Times
tDRP
20*2, *3
—
—
Year
After 1000 times of NPEC
Conditions
Ta = +85°C
Note 1. Definition of reprogram/erase cycle: The reprogram/erase cycle is the number of erasing for each block. When the reprogram/
erase cycle is n times (n = 1000), erasing can be performed n times for each block. For instance, when 4-byte programming is
performed 256 times for different addresses in 1-Kbyte block and then the entire block is erased, the reprogram/erase cycle is
counted as one. However, programming the same address for several times as one erasing is not enabled (overwriting is
prohibited).
Note 2. Characteristic when using the flash memory programmer and the self-programming library provided from Renesas Electronics.
Note 3. This result is obtained from reliability testing.
Table 5.45
ROM (Flash Memory for Code Storage) Characteristics (2)
High-speed operating mode Conditions: 2.7 V ≤ VCC ≤ 3.6 V, 2.7 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V
Temperature range for the programming/erasure operation: Ta = –40 to +105°C
Item
Symbol
FCLK = 1 MHz
Min.
FCLK = 32 MHz
Typ.
Max.
Min.
Typ.
Max.
Unit
Programming time
4-byte
tP4
—
103
931
—
52
489
μs
Erasure time
1-Kbyte
tE1K
—
8.23
267
—
5.48
214
ms
tE128K
—
203
463
—
20
228
ms
4-byte
tBC4
—
—
48
—
—
15.9
μs
1-Kbyte
tBC1K
—
—
1.58
—
—
0.127
ms
tSED
—
—
21.6
—
—
12.8
μs
Start-up area switching setting time
tSAS
—
12.6
543
—
6.16
432
ms
Access window time
tAWS
—
12.6
543
—
6.16
432
ms
ROM mode transition wait time 1
tDIS
2
—
—
2
—
—
μs
ROM mode transition wait time 2
tMS
5
—
—
5
—
—
μs
128-Kbyte
Blank check time
Erase operation forcible stop time
Note:
Note:
Note:
Does not include the time until each operation of the flash memory is started after instructions are executed by software.
The lower-limit frequency of FCLK is 1 MHz during programming or erasing of the flash memory. When using FCLK at below
4 MHz, the frequency can be set to 1 MHz, 2 MHz, or 3 MHz. A non-integer frequency such as 1.5 MHz cannot be set.
The frequency accuracy of FCLK should be ±3.5%. Confirm the frequency accuracy of the clock source.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 93 of 108
RX110 Group
Table 5.46
5. Electrical Characteristics
ROM (Flash Memory for Code Storage) Characteristics (3)
Middle-speed operating mode Conditions: 1.8 V ≤ VCC ≤ 3.6 V, 1.8 V ≤ AVCC0 ≤ 3.6 V, VSS = AVSS0 = 0 V
Temperature range for the programming/erasure operation: Ta = –40 to +85°C
Item
Symbol
FCLK = 1 MHz
FCLK = 8 MHz
Min.
Typ.
Max.
Min.
Typ.
Max.
Unit
Programming time
4-byte
tP4
—
143
1330
—
96.8
932
μs
Erasure time
1-Kbyte
tE1K
—
8.3
269
—
5.85
219
ms
128-Kbyte
tE128K
—
203
464
—
40
260
ms
4-byte
tBC4
—
—
78
—
—
50
μs
1-Kbyte
tBC1K
—
—
1.61
—
—
0.369
ms
Erase operation forcible stop time
tSED
—
—
33.6
—
—
25.6
μs
Start-up area switching setting time
tSAS
—
13.2
549
—
7.6
445
ms
Access window time
tAWS
—
13.2
549
—
7.6
445
ms
ROM mode transition wait time 1
tDIS
2
—
—
2
—
—
μs
ROM mode transition wait time 2
tMS
3
—
—
3
—
—
μs
Blank check time
Note:
Note:
Note:
Does not include the time until each operation of the flash memory is started after instructions are executed by software.
The lower-limit frequency of FCLK is 1 MHz during programming or erasing of the flash memory. When using FCLK at below
4 MHz, the frequency can be set to 1 MHz, 2 MHz, or 3 MHz. A non-integer frequency such as 1.5 MHz cannot be set.
The frequency accuracy of FCLK should be ±3.5%. Confirm the frequency accuracy of the clock source.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 94 of 108
RX110 Group
5.9
5. Electrical Characteristics
Usage Notes
5.9.1
Connecting VCL Capacitor and Bypass Capacitors
This MCU integrates an internal voltage-down circuit, which is used for lowering the power supply voltage in the
internal MCU to adjust automatically to the optimum level. A 4.7-μF capacitor needs to be connected between this
internal voltage-down power supply (VCL pin) and VSS pin. Figure 5.54 to Figure 5.55 shows how to connect
external capacitors. Place an external capacitor close to the pins. Do not apply the power supply voltage to the VCL pin.
Insert a multilayer ceramic capacitor as a bypass capacitor between each pair of the power supply pins. Implement a
bypass capacitor to the MCU power supply pins as close as possible. Use a recommended value of 0.1 μF as the
capacitance of the capacitors. For the capacitors related to crystal oscillation, see section 9, Clock Generation Circuit
in the User’s Manual: Hardware. For the capacitors related to analog modules, also see section 27, 12-Bit A/D
Converter (S12ADb) in the User’s Manual: Hardware.
For notes on designing the printed circuit board, see the descriptions of the application note "Hardware Design Guide"
(R01AN1411EJ). The latest version can be downloaded from Renesas Electronics Website.
33
34
35
36
32
31
51
30
52
29
53
28
54
27
RX110 Group
PLQP0064KB-A
PLQP0064GA-A
(64-pin LFQFP/LQFP)
(Top view)
55
56
57
58
59
26
25
24
23
22
20
62 AVSS0
19
63 AVCC0
18
17
16
12
11
10
9
8
7
6
5
4
3
2
1
64
15 VCC
21
61
14 VSS
60
13 VCL
Bypass
capacitor
0.1 µF
37
39
50
VCC 38
41
49
VSS 40
42
43
44
45
46
47
48
Bypass
capacitor
0.1 µF
Bypass
Bypass
capacitor capacitor
4.7 µF
0.1 µF
Note. Do not apply the power supply voltage to the VCL pin.
Use a 4.7-µF multilayer ceramic for the VCL pin and place it close to the pin.
A recommended value is shown for the capacitance of the bypass capacitors.
Figure 5.54
Connecting Capacitors (64 Pins)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 95 of 108
RX110 Group
5. Electrical Characteristics
25
26
29
27
24
38
23
39
22
40
21
41
RX110 Group
42
PLQP0048KB-A
(48-pin LFQFP)
(Top view)
43
44
20
19
18
17
Bypass
capacitor
4.7 µF
12 VCC
11 VSS
10 VCL
9
13
8
48 AVCC0
7
14
6
47 AVSS0
5
15
4
46
3
16
2
45
1
Bypass
capacitor
0.1 µF
VCC 28
37
VSS 30
31
32
33
34
35
36
Bypass
capacitor
0.1 µF
Bypass
capacitor
0.1 µF
Note. Do not apply the power supply voltage to the VCL pin.
Use a 4.7-µF multilayer ceramic for the VCL pin and place it close to the pin.
A recommended value is shown for the capacitance of the bypass capacitors.
Figure 5.55
Connecting Capacitors (48-pin LFQFP)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 96 of 108
RX110 Group
Appendix 1. Package Dimensions
Appendix 1. Package Dimensions
Information on the latest version of the package dimensions or mountings has been displayed in “Packages” on Renesas
Electronics Corporation website.
JEITA Package Code
P-LFQFP64-10x10-0.50
RENESAS Code
PLQP0064KB-A
Previous Code
64P6Q-A / FP-64K / FP-64KV
MASS[Typ.]
0.3g
HD
*1
D
48
33
49
NOTE)
1. DIMENSIONS "*1" AND "*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION "*3" DOES NOT
INCLUDE TRIM OFFSET.
32
bp
64
1
c1
Terminal cross section
ZE
17
Reference
Symbol
c
E
*2
HE
b1
16
Index mark
ZD
c
A
*3
A1
y S
e
A2
F
S
bp
L
x
L1
Detail F
Figure A
D
E
A2
HD
HE
A
A1
bp
b1
c
c1
e
x
y
ZD
ZE
L
L1
Dimension in Millimeters
Min Nom Max
9.9 10.0 10.1
9.9 10.0 10.1
1.4
11.8 12.0 12.2
11.8 12.0 12.2
1.7
0.05 0.1 0.15
0.15 0.20 0.25
0.18
0.09 0.145 0.20
0.125
0°
8°
0.5
0.08
0.08
1.25
1.25
0.35 0.5 0.65
1.0
64-Pin LFQFP (PLQP0064KB-A)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 97 of 108
RX110 Group
Appendix 1. Package Dimensions
JEITA Package Code
P-LQFP64-14x14-0.80
RENESAS Code
PLQP0064GA-A
Previous Code
64P6U-A/ ⎯
MASS[Typ.]
0.7g
HD
*1
D
33
48
49
NOTE)
1. DIMENSIONS "*1" AND "*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION "*3" DOES NOT
INCLUDE TRIM OFFSET.
32
bp
c
Reference
Symbol
*2
E
HE
c1
b1
ZE
Terminal cross section
64
17
c
Index mark
A2
16
ZD
A
1
F
A1
S
L
D
E
A2
HD
HE
A
A1
bp
b1
c
c1
L1
y S
e
Figure B
Detail F
*3
bp
x
e
x
y
ZD
ZE
L
L1
Dimension in Millimeters
Min Nom Max
13.9 14.0 14.1
13.9 14.0 14.1
1.4
15.8 16.0 16.2
15.8 16.0 16.2
1.7
0.1 0.2
0
0.32 0.37 0.42
0.35
0.09 0.145 0.20
0.125
0°
8°
0.8
0.20
0.10
1.0
1.0
0.3 0.5 0.7
1.0
64-Pin LQFP (PLQP0064GA-A)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 98 of 108
RX110 Group
Appendix 1. Package Dimensions
64-PIN PLASTIC FLGA (5x5)
60x b
x M
S AB
A
D
w S A
ZD
e
8
ZE
7
6
B
5
E
4
3.90
3
2
C
D
INDEX MARK
w S B
1
H
G
F E
D C
B
E
A
3.90
y1
A
S
S
y
S
DETAIL C
DETAIL E
DETAIL D
R0.17o0.015
0.70o0.03
0.55o0.04 R0.125o 0.02
0.75
0.55
R0.17o0.015 0.70o0.03
R0.125o0.02 0.55o0.04
0.75
0.55
b
(LAND PAD)
0.34o0.03
(APERTURE OF
SOLDER RESIST)
0.55
0.75
0.55o0.04
0.70o0.03
0.55
0.75
0.55o0.04
0.70o0.03
R0.275o0.02
R0.35o0.015
(UNIT:mm)
ITEM
D
DIMENSIONS
5.00o0.10
E
5.00o0.10
w
0.20
e
A
0.50
0.69o0.07
b
0.25o0.04
x
0.05
y
0.08
y1
0.20
ZD
0.75
ZE
0.75
P64FC-50-AN5
2011 Renesas Electronics Corporation. All rights reserved.
Figure C
64-Pin WFLGA (PWLG0064KA-A)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 99 of 108
RX110 Group
Appendix 1. Package Dimensions
JEITA Package Code
P-LFQFP48-7x7-0.50
RENESAS Code
PLQP0048KB-A
Previous Code
48P6Q-A
MASS[Typ.]
0.2g
HD
*1
D
36
25
37
NOTE)
1. DIMENSIONS "*1" AND "*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION "*3" DOES NOT
INCLUDE TRIM OFFSET.
24
bp
c
c1
HE
*2
E
b1
Reference
Symbol
48
13
1
ZE
Terminal cross section
12
c
A
F
A2
Index mark
ZD
S
A1
L
D
E
A2
HD
HE
A
A1
bp
b1
c
c1
y S
Figure D
*3
bp
Detail F
x
Min
6.9
6.9
8.8
8.8
0
0.17
0.09
0°
L1
e
Dimension in Millimeters
e
x
y
ZD
ZE
L
L1
0.35
Nom Max
7.0 7.1
7.0 7.1
1.4
9.0 9.2
9.0 9.2
1.7
0.1 0.2
0.22 0.27
0.20
0.145 0.20
0.125
8°
0.5
0.08
0.10
0.75
0.75
0.5 0.65
1.0
48-Pin LFQFP (PLQP0048KB-A)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 100 of 108
RX110 Group
Appendix 1. Package Dimensions
JEITA Package Code
RENESAS Code
Previous Code
MASS (TYP.) [g]
P-HWQFN48-7x7-0.50
PWQN0048KB-A
48PJN-A
P48K8-50-5B4-5
0.13
D
DETAIL OF
E
S
A
PART
A
A
S
y
S
Referance
Symbol
D2
A
EXPOSED DIE PAD
1
12
Min
Nom
Max
D
6.95
7.00
7.05
E
6.95
7.00
7.05
A
0.70
0.75
0.80
b
0.18
0.25
0.30
e
13
48
Dimension in Millimeters
Lp
B
0.50
0.30
0.40
0.50
x
0.05
y
0.05
E2
ITEM
37
24
36
25
Lp
EXPOSED
DIE PAD
VARIATIONS
D2
E2
MIN NOM MAX MIN NOM MAX
A 5.45 5.50 5.55 5.45 5.50 5.55
e
b
x
M
S AB
2012 Renesas Electronics Corporation. All rights reserved.
Figure E
48-Pin HWQFN (PWQN0048KB-A)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 101 of 108
RX110 Group
Appendix 1. Package Dimensions
JEITA Package Code
RENESAS Code
Previous Code
MASS (TYP.) [g]
P-HWQFN40-6x6-0.50
PWQN0040KC-A
P40K8-50-4B4-4
0.09
D
DETAIL OF A
PART
E
S
A
A
S
y
Referance
Symbol
S
D2
A
1
EXPOSED DIE PAD
10
Min
Nom
Max
D
5.95
6.00
6.05
E
5.95
6.00
6.05
A
0.70
0.75
0.80
b
0.18
0.25
0.30
e
Lp
11
40
Dimension in Millimeters
0.50
0.30
0.40
0.50
x
0.05
y
0.05
B
E2
ITEM
31
20
21
30
Lp
E2
A 4.45 4.50 4.55 4.45 4.50 4.55
e
b
Figure F
EXPOSED
DIE PAD
VARIATIONS
D2
MIN NOM MAX MIN NOM MAX
x
M
S AB
2012 Renesas Electronics Corporation. All rights reserved.
40-Pin HWQFN (PWQN0040KC-A)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 102 of 108
RX110 Group
Appendix 1. Package Dimensions
JEITA Package Code
RENESAS Code
Previous Code
MASS (TYP.) [g]
P-WFLGA36-4x4-0.50
PWLG0036KA-A
P36FC-50-AA4-2
0.023
32x b
S AB
e
ZE
w S A
M
A
ZD
D
x
6
5
B
4
E
3
2.90
2
C
INDEX MARK
y1
D
w S B
S
1
F
E D C B A
E
2.90
A
S
y
S
DETAIL C
DETAIL E
DETAIL D
R0.17± 0.05
0.70 ±0.05
0.55 ±0.05 R0.12 ±0.05
0.75
0.55
(UNIT:mm)
R0.17 ±0.05
0.70 ±0.05
R0.12 ±0.05 0.55 ±0.05
0.75
0.55
φb
(LAND PAD)
φ 0.34±0.05
(APERTURE OF
SOLDER RESIST)
0.55
0.75
0.55±0.05
0.70± 0.05
0.55
0.75
0.55±0.05
R0.275±0.05
R0.35±0.05
ITEM
D
DIMENSIONS
E
4.00±0.10
w
0.20
4.00±0.10
e
0.50
A
0.69±0.07
b
0.24±0.05
x
0.05
y
0.08
y1
0.20
ZD
0.75
ZE
0.75
0.70±0.05
2012 Renesas Electronics Corporation. All rights reserved.
Figure G
36-Pin WFLGA (PWLG0036KA-A)
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 103 of 108
REVISION HISTORY
RX110 Group
REVISION HISTORY
REVISION HISTORY
Rev.
Date
0.51
1.00
Jul 03, 2013
Dec , 2013
RX110 Group Datasheet
Description
Page
Summary
—
First edition, issued
1. Overview
6, 7
Table 1.3 List of Products changed
8
Figure 1.1 How to Read the Product Part No., Memory Capacity, and Package Type changed
9
Figure 1.2 Block Diagram changed
4. I/O Registers
44
Table 4.1 List of I/O Registers (Address Order) changed
5. Electrical Characteristics
45 to 91 Changed
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 104 of 108
RX110 Group
REVISION HISTORY
Classifications
- Items with Technical Update document number: Changes according to the corresponding issued Technical Update
- Items without Technical Update document number: Minor changes that do not require Technical Update to be issued
Rev.
Date
1.20
Jul 29, 2016
Page
1. Overview
18 to 25
Description
Summary
Table 1.5 to 1.9 Note 1 regarding I/O power source is AVCC0 for the ports
(P4, PJ6, and PJ7), added
5. Electrical Characteristics
45
Table 5.1 Absolute Maximum Ratings, Analog power supply voltage added
45
Table 5.2 Recommended Operating Conditions, VREFH0 / VREFL0 added
51
Table 5.8 DC Characteristics (6), Increment for IWDT operation added
52
Table 5.9 DC Characteristics (7) Permissible total consumption power
added
53
Table 5.10 DC Characteristics (8), LDV1,2 added
54, 55
Table 5.15 Permissible Output Currents is divided into D version and G
version
93
Table 5.45 ROM (Flash Memory for Code Storage) Characteristics (2),
Erasure time - 128-Kbyte added
94
Table 5.46 ROM (Flash Memory for Code Storage) Characteristics (3),
Temperature range for the programming/erasure operation changed
and Erasure time - 128-Kbyte added
95, 96
5.9 Usage Notes added
Classification
TN-RX*-A135A/E
TN-RX*-A132A/E
TN-RX*-A132A/E
All trademarks and registered trademarks are the property of their respective owners.
R01DS0202EJ0120 Rev.1.20
Jul 29, 2016
Page 105 of 108
NOTES FOR CMOS DEVICES
(1) VOLTAGE APPLICATION WAVEFORM AT INPUT PIN: Waveform distortion due to input noise or a
reflected wave may cause malfunction. If the input of the CMOS device stays in the area between VIL
(MAX) and VIH (MIN) due to noise, etc., the device may malfunction. Take care to prevent chattering noise
from entering the device when the input level is fixed, and also in the transition period when the input level
passes through the area between VIL (MAX) and VIH (MIN).
(2) HANDLING OF UNUSED INPUT PINS: Unconnected CMOS device inputs can be cause of malfunction.
If an input pin is unconnected, it is possible that an internal input level may be generated due to noise, etc.,
causing malfunction. CMOS devices behave differently than Bipolar or NMOS devices. Input levels of
CMOS devices must be fixed high or low by using pull-up or pull-down circuitry. Each unused pin should be
connected to VDD or GND via a resistor if there is a possibility that it will be an output pin. All handling
related to unused pins must be judged separately for each device and according to related specifications
governing the device.
(3) PRECAUTION AGAINST ESD: A strong electric field, when exposed to a MOS device, can cause
destruction of the gate oxide and ultimately degrade the device operation. Steps must be taken to stop
generation of static electricity as much as possible, and quickly dissipate it when it has occurred.
Environmental control must be adequate. When it is dry, a humidifier should be used. It is recommended
to avoid using insulators that easily build up static electricity. Semiconductor devices must be stored and
transported in an anti-static container, static shielding bag or conductive material. All test and measurement
tools including work benches and floors should be grounded. The operator should be grounded using a
wrist strap. Semiconductor devices must not be touched with bare hands. Similar precautions need to be
taken for PW boards with mounted semiconductor devices.
(4) STATUS BEFORE INITIALIZATION: Power-on does not necessarily define the initial status of a MOS
device. Immediately after the power source is turned ON, devices with reset functions have not yet been
initialized. Hence, power-on does not guarantee output pin levels, I/O settings or contents of registers. A
device is not initialized until the reset signal is received. A reset operation must be executed immediately
after power-on for devices with reset functions.
(5) POWER ON/OFF SEQUENCE: In the case of a device that uses different power supplies for the internal
operation and external interface, as a rule, switch on the external power supply after switching on the internal
power supply. When switching the power supply off, as a rule, switch off the external power supply and then
the internal power supply. Use of the reverse power on/off sequences may result in the application of an
overvoltage to the internal elements of the device, causing malfunction and degradation of internal elements
due to the passage of an abnormal current. The correct power on/off sequence must be judged separately
for each device and according to related specifications governing the device.
(6) INPUT OF SIGNAL DURING POWER OFF STATE : Do not input signals or an I/O pull-up power supply
while the device is not powered. The current injection that results from input of such a signal or I/O pull-up
power supply may cause malfunction and the abnormal current that passes in the device at this time may
cause degradation of internal elements. Input of signals during the power off state must be judged
separately for each device and according to related specifications governing the device.
General Precautions in the Handling of Microprocessing Unit and Microcontroller Unit Products
The following usage notes are applicable to all Microprocessing unit and Microcontroller unit products from Renesas.
For detailed usage notes on the products covered by this document, refer to the relevant sections of the document as well
as any technical updates that have been issued for the products.
1. Handling of Unused Pins
Handle unused pins in accordance with the directions given under Handling of Unused Pins in the
manual.
¾ The input pins of CMOS products are generally in the high-impedance state. In operation with an
unused pin in the open-circuit state, extra electromagnetic noise is induced in the vicinity of LSI, an
associated shoot-through current flows internally, and malfunctions occur due to the false
recognition of the pin state as an input signal become possible. Unused pins should be handled as
described under Handling of Unused Pins in the manual.
2. Processing at Power-on
The state of the product is undefined at the moment when power is supplied.
¾ The states of internal circuits in the LSI are indeterminate and the states of register settings and
pins are undefined at the moment when power is supplied.
In a finished product where the reset signal is applied to the external reset pin, the states of pins
are not guaranteed from the moment when power is supplied until the reset process is completed.
In a similar way, the states of pins in a product that is reset by an on-chip power-on reset function
are not guaranteed from the moment when power is supplied until the power reaches the level at
which resetting has been specified.
3. Prohibition of Access to Reserved Addresses
Access to reserved addresses is prohibited.
¾ The reserved addresses are provided for the possible future expansion of functions. Do not access
these addresses; the correct operation of LSI is not guaranteed if they are accessed.
4. Clock Signals
After applying a reset, only release the reset line after the operating clock signal has become stable.
When switching the clock signal during program execution, wait until the target clock signal has
stabilized.
¾ When the clock signal is generated with an external resonator (or from an external oscillator)
during a reset, ensure that the reset line is only released after full stabilization of the clock signal.
Moreover, when switching to a clock signal produced with an external resonator (or by an external
oscillator) while program execution is in progress, wait until the target clock signal is stable.
5. Differences between Products
Before changing from one product to another, i.e. to a product with a different part number, confirm
that the change will not lead to problems.
¾ The characteristics of Microprocessing unit or Microcontroller unit products in the same group but
having a different part number may differ in terms of the internal memory capacity, layout pattern,
and other factors, which can affect the ranges of electrical characteristics, such as characteristic
values, operating margins, immunity to noise, and amount of radiated noise. When changing to a
product with a different part number, implement a system-evaluation test for the given product.
Notice
1.
Descriptions of circuits, software and other related information in this document are provided only to illustrate the operation of semiconductor products and application examples. You are fully responsible for
the incorporation of these circuits, software, and information in the design of your equipment. Renesas Electronics assumes no responsibility for any losses incurred by you or third parties arising from the
use of these circuits, software, or information.
2.
Renesas Electronics has used reasonable care in preparing the information included in this document, but Renesas Electronics does not warrant that such information is error free. Renesas Electronics
3.
Renesas Electronics does not assume any liability for infringement of patents, copyrights, or other intellectual property rights of third parties by or arising from the use of Renesas Electronics products or
assumes no liability whatsoever for any damages incurred by you resulting from errors in or omissions from the information included herein.
technical information described in this document. No license, express, implied or otherwise, is granted hereby under any patents, copyrights or other intellectual property rights of Renesas Electronics or
others.
4.
You should not alter, modify, copy, or otherwise misappropriate any Renesas Electronics product, whether in whole or in part. Renesas Electronics assumes no responsibility for any losses incurred by you or
5.
Renesas Electronics products are classified according to the following two quality grades: "Standard" and "High Quality". The recommended applications for each Renesas Electronics product depends on
third parties arising from such alteration, modification, copy or otherwise misappropriation of Renesas Electronics product.
the product's quality grade, as indicated below.
"Standard": Computers; office equipment; communications equipment; test and measurement equipment; audio and visual equipment; home electronic appliances; machine tools; personal electronic
equipment; and industrial robots etc.
"High Quality": Transportation equipment (automobiles, trains, ships, etc.); traffic control systems; anti-disaster systems; anti-crime systems; and safety equipment etc.
Renesas Electronics products are neither intended nor authorized for use in products or systems that may pose a direct threat to human life or bodily injury (artificial life support devices or systems, surgical
implantations etc.), or may cause serious property damages (nuclear reactor control systems, military equipment etc.). You must check the quality grade of each Renesas Electronics product before using it
in a particular application. You may not use any Renesas Electronics product for any application for which it is not intended. Renesas Electronics shall not be in any way liable for any damages or losses
incurred by you or third parties arising from the use of any Renesas Electronics product for which the product is not intended by Renesas Electronics.
6.
You should use the Renesas Electronics products described in this document within the range specified by Renesas Electronics, especially with respect to the maximum rating, operating supply voltage
range, movement power voltage range, heat radiation characteristics, installation and other product characteristics. Renesas Electronics shall have no liability for malfunctions or damages arising out of the
use of Renesas Electronics products beyond such specified ranges.
7.
Although Renesas Electronics endeavors to improve the quality and reliability of its products, semiconductor products have specific characteristics such as the occurrence of failure at a certain rate and
malfunctions under certain use conditions. Further, Renesas Electronics products are not subject to radiation resistance design. Please be sure to implement safety measures to guard them against the
possibility of physical injury, and injury or damage caused by fire in the event of the failure of a Renesas Electronics product, such as safety design for hardware and software including but not limited to
redundancy, fire control and malfunction prevention, appropriate treatment for aging degradation or any other appropriate measures. Because the evaluation of microcomputer software alone is very difficult,
please evaluate the safety of the final products or systems manufactured by you.
8.
Please contact a Renesas Electronics sales office for details as to environmental matters such as the environmental compatibility of each Renesas Electronics product. Please use Renesas Electronics
products in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled substances, including without limitation, the EU RoHS Directive. Renesas Electronics assumes
no liability for damages or losses occurring as a result of your noncompliance with applicable laws and regulations.
9.
Renesas Electronics products and technology may not be used for or incorporated into any products or systems whose manufacture, use, or sale is prohibited under any applicable domestic or foreign laws or
regulations. You should not use Renesas Electronics products or technology described in this document for any purpose relating to military applications or use by the military, including but not limited to the
development of weapons of mass destruction. When exporting the Renesas Electronics products or technology described in this document, you should comply with the applicable export control laws and
regulations and follow the procedures required by such laws and regulations.
10. It is the responsibility of the buyer or distributor of Renesas Electronics products, who distributes, disposes of, or otherwise places the product with a third party, to notify such third party in advance of the
contents and conditions set forth in this document, Renesas Electronics assumes no responsibility for any losses incurred by you or third parties as a result of unauthorized use of Renesas Electronics
products.
11. This document may not be reproduced or duplicated in any form, in whole or in part, without prior written consent of Renesas Electronics.
12. Please contact a Renesas Electronics sales office if you have any questions regarding the information contained in this document or Renesas Electronics products, or if you have any other inquiries.
(Note 1)
"Renesas Electronics" as used in this document means Renesas Electronics Corporation and also includes its majority-owned subsidiaries.
(Note 2)
"Renesas Electronics product(s)" means any product developed or manufactured by or for Renesas Electronics.
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Tel: +60-3-7955-9390, Fax: +60-3-7955-9510
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Tel: +91-80-67208700, Fax: +91-80-67208777
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12F., 234 Teheran-ro, Gangnam-Gu, Seoul, 135-080, Korea
Tel: +82-2-558-3737, Fax: +82-2-558-5141
© 2016 Renesas Electronics Corporation. All rights reserved.
Colophon 5.0