Please note that Cypress is an Infineon Technologies Company.
The document following this cover page is marked as “Cypress” document as this is the
company that originally developed the product. Please note that Infineon will continue
to offer the product to new and existing customers as part of the Infineon product
portfolio.
Continuity of document content
The fact that Infineon offers the following product as part of the Infineon product
portfolio does not lead to any changes to this document. Future revisions will occur
when appropriate, and any changes will be set out on the document history page.
Continuity of ordering part numbers
Infineon continues to support existing part numbers. Please continue to use the
ordering part numbers listed in the datasheet for ordering.
www.infineon.com
�PSoC® 5LP: CY8C58LP Family
Datasheet
®
Programmable System-on-Chip (PSoC )
General Description
PSoC® 5LP is a true programmable embedded system-on-chip, integrating configurable analog and digital peripherals, memory, and
a microcontroller on a single chip. The PSoC 5LP architecture boosts performance through:
32-bit Arm Cortex-M3 core plus DMA controller and digital filter processor, at up to 80 MHz
Ultra low power with industry's widest voltage range
Programmable digital and analog peripherals enable custom functions
Flexible routing of any analog or digital peripheral function to any pin
PSoC devices employ a highly configurable system-on-chip architecture for embedded control design. They integrate configurable
analog and digital circuits, controlled by an on-chip microcontroller. A single PSoC device can integrate as many as 100 digital and
analog peripheral functions, reducing design time, board space, power consumption, and system cost while improving system quality.
Features
Operating characteristics
Analog peripherals
Voltage range: 1.71 to 5.5 V, up to 6 power domains
[1]
Temperature range (ambient): –40 to 85 °C
Extended temperature parts: –40 to 105 °C
DC to 80-MHz operation
Power modes
• Active mode 3.1 mA at 6 MHz, and 15.4 mA at 48 MHz
• 2-µA sleep mode
• 300-nA hibernate mode with RAM retention
Boost regulator from 0.5-V input up to 5-V output
Performance
32-bit Arm Cortex-M3 CPU, 32 interrupt inputs
24-channel direct memory access (DMA) controller
24-bit 64-tap fixed-point digital filter processor (DFB)
Memories
Up to 256 KB program flash, with cache and security features
Up to 32 KB additional flash for error correcting code (ECC)
Up to 64 KB RAM
2 KB EEPROM
Digital peripherals
Four 16-bit timer, counter, and PWM (TCPWM) blocks
2
I C, 1 Mbps bus speed
USB 2.0 certified Full-Speed (FS) 12 Mbps peripheral interface (TID#10840032) using internal oscillator[2]
Full CAN 2.0b, 16 Rx, 8 Tx buffers
20 to 24 universal digital blocks (UDB), programmable to
create any number of functions:
• 8-, 16-, 24-, and 32-bit timers, counters, and PWMs
• I2C, UART, SPI, I2S, LIN 2.0 interfaces
• Cyclic redundancy check (CRC)
• Pseudo random sequence (PRS) generators
• Quadrature decoders
• Gate-level logic functions
Configurable 8- to 20-bit delta-sigma ADC
Up to two 12-bit SAR ADCs
Four 8-bit DACs
Four comparators
Four opamps
Four programmable analog blocks, to create:
• Programmable gain amplifier (PGA)
• Transimpedance amplifier (TIA)
• Mixer
• Sample and hold circuit
®
CapSense support, up to 62 sensors
1.024 V ±0.1% internal voltage reference
Versatile I/O system
46 to 72 I/O pins – up to 62 general-purpose I/Os (GPIOs)
Up to eight performance I/O (SIO) pins
• 25 mA current sink
• Programmable input threshold and output high voltages
• Can act as a general-purpose comparator
• Hot swap capability and overvoltage tolerance
Two USBIO pins that can be used as GPIOs
Route any digital or analog peripheral to any GPIO
LCD direct drive from any GPIO, up to 46 × 16 segments
CapSense support from any GPIO
1.2-V to 5.5-V interface voltages, up to four power domains
Programming, debug, and trace
JTAG (4-wire), serial wire debug (SWD) (2-wire), single wire
viewer (SWV), and Traceport (5-wire) interfaces
Arm debug and trace modules embedded in the CPU core
2
Bootloader programming through I C, SPI, UART, USB, and
other interfaces
Package options: 68-pin QFN, 100-pin TQFP, and 99-pin CSP
Development support with free PSoC Creator™ tool
Programmable clocking
3- to 74-MHz internal oscillator, 1% accuracy at 3 MHz
4- to 25-MHz external crystal oscillator
Internal PLL clock generation up to 80 MHz
Low-power internal oscillator at 1, 33, and 100 kHz
32.768-kHz external watch crystal oscillator
12 clock dividers routable to any peripheral or I/O
Schematic and firmware design support
Over 100 PSoC Components™ integrate multiple ICs and
system interfaces into one PSoC. Components are free
embedded ICs represented by icons. Drag and drop
component icons to design systems in PSoC Creator.
Includes free GCC compiler, supports Keil/Arm MDK
compiler
Supports device programming and debugging
Notes
1. The maximum storage temperature is 150 °C in compliance with JEDEC Standard JESD22-A103, High Temperature Storage Life.
2. This feature on select devices only. See Ordering Information on page 127 for details.
Cypress Semiconductor Corporation
Document Number: 001-84932 Rev. *N
•
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised November 27, 2019
�PSoC® 5LP: CY8C58LP Family
Datasheet
More Information
Cypress provides a wealth of data at www.cypress.com to help you to select the right PSoC device for your design, and to help you
to quickly and effectively integrate the device into your design. For a comprehensive list of resources, see the knowledge base article
KBA86521, How to Design with PSoC 3, PSoC 4, and PSoC 5LP. Following is an abbreviated list for PSoC 5LP:
Overview: PSoC Portfolio, PSoC Roadmap
Development Kits:
Product Selectors: PSoC 1, PSoC 3, PSoC 4, PSoC 5LP
In addition, PSoC Creator includes a device selection tool.
Application notes: Cypress offers a large number of PSoC
application notes and code examples covering a broad range
of topics, from basic to advanced level. Recommended application notes for getting started with PSoC 5LP are:
AN77759: Getting Started With PSoC 5LP
AN77835: PSoC 3 to PSoC 5LP Migration Guide
AN61290: Hardware Design Considerations
AN57821: Mixed Signal Circuit Board Layout
AN58304: Pin Selection for Analog Designs
AN81623: Digital Design Best Practices
AN73854: Introduction To Bootloaders
CY8CKIT-059 is a low-cost platform for prototyping, with a
unique snap-away programmer and debugger on the USB
connector.
CY8CKIT-050 is designed for analog performance, for developing high-precision analog, low-power, and low-voltage applications.
CY8CKIT-001 provides a common development platform for
any one of the PSoC 1, PSoC 3, PSoC 4, or PSoC 5LP
families of devices.
The MiniProg3 device provides an interface for flash programming and debug.
Technical Reference Manuals (TRM)
Architecture TRM
Registers TRM
Programming Specification
PSoC Creator
PSoC Creator is a free Windows-based Integrated Design Environment (IDE). It enables concurrent hardware and firmware design
of PSoC 3, PSoC 4, and PSoC 5LP based systems. Create designs using classic, familiar schematic capture supported by over 100
pre-verified, production-ready PSoC Components; see the list of component datasheets. With PSoC Creator, you can:
3. Configure components using the configuration tools
1. Drag and drop component icons to build your hardware
system design in the main design workspace
4. Explore the library of 100+ components
2. Codesign your application firmware with the PSoC hardware,
5. Review component datasheets
using the PSoC Creator IDE C compiler
Figure 1. Multiple-Sensor Example Project in PSoC Creator
1
2
3
4
5
Document Number: 001-84932 Rev. *N
Page 2 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Contents
1. Architectural Overview ................................................ 4
2. Pinouts .......................................................................... 6
3. Pin Descriptions ......................................................... 12
4. CPU .............................................................................. 13
4.1 Arm Cortex-M3 CPU ........................................... 13
4.2 Cache Controller ................................................. 14
4.3 DMA and PHUB .................................................. 14
4.4 Interrupt Controller .............................................. 17
5. Memory ........................................................................ 19
5.1 Static RAM .......................................................... 19
5.2 Flash Program Memory ....................................... 19
5.3 Flash Security ...................................................... 19
5.4 EEPROM ............................................................. 19
5.5 Nonvolatile Latches (NVLs) ................................. 20
5.6 External Memory Interface .................................. 21
5.7 Memory Map ....................................................... 22
6. System Integration ..................................................... 23
6.1 Clocking System .................................................. 23
6.2 Power System ..................................................... 26
6.3 Reset ................................................................... 31
6.4 I/O System and Routing ...................................... 33
7. Digital Subsystem ...................................................... 40
7.1 Example Peripherals ........................................... 40
7.2 Universal Digital Block ......................................... 42
7.3 UDB Array Description ........................................ 45
7.4 DSI Routing Interface Description ....................... 45
7.5 CAN ..................................................................... 47
7.6 USB ..................................................................... 48
7.7 Timers, Counters, and PWMs ............................. 49
7.8 I2C ....................................................................... 49
7.9 Digital Filter Block ................................................ 51
8. Analog Subsystem ..................................................... 51
8.1 Analog Routing .................................................... 52
8.2 Delta-sigma ADC ................................................. 54
8.3 Successive Approximation ADC .......................... 55
8.4 Comparators ........................................................ 55
8.5 Opamps ............................................................... 57
8.6 Programmable SC/CT Blocks ............................. 57
8.7 LCD Direct Drive ................................................. 58
8.8 CapSense ............................................................ 59
8.9 Temp Sensor ....................................................... 59
8.10 DAC ................................................................... 59
8.11 Up/Down Mixer .................................................. 60
8.12 Sample and Hold ............................................... 60
Document Number: 001-84932 Rev. *N
9. Programming, Debug Interfaces, Resources ........... 61
9.1 JTAG Interface .................................................... 61
9.2 SWD Interface ..................................................... 63
9.3 Debug Features ................................................... 64
9.4 Trace Features .................................................... 64
9.5 SWV and TRACEPORT Interfaces ..................... 64
9.6 Programming Features ........................................ 64
9.7 Device Security ................................................... 64
9.8 CSP Package Bootloader .................................... 65
10. Development Support .............................................. 66
10.1 Documentation .................................................. 66
10.2 Online ................................................................ 66
10.3 Tools .................................................................. 66
11. Electrical Specifications .......................................... 67
11.1 Absolute Maximum Ratings ............................... 67
11.2 Device Level Specifications ............................... 68
11.3 Power Regulators .............................................. 71
11.4 Inputs and Outputs ............................................ 76
11.5 Analog Peripherals ............................................ 85
11.6 Digital Peripherals ........................................... 111
11.7 Memory ........................................................... 116
11.8 PSoC System Resources ................................ 120
11.9 Clocking ........................................................... 123
12. Ordering Information .............................................. 127
12.1 Part Numbering Conventions .......................... 128
13. Packaging ................................................................ 129
14. Acronyms ................................................................ 132
15. Document Conventions ......................................... 134
15.1 Units of Measure ............................................. 134
Document History Page ............................................... 135
Sales, Solutions, and Legal Information .................... 139
Worldwide Sales and Design Support ..................... 139
Products .................................................................. 139
PSoC® Solutions .................................................... 139
Cypress Developer Community ............................... 139
Technical Support ................................................... 139
Page 3 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
1. Architectural Overview
Introducing the CY8C58LP family of ultra low power, flash Programmable System-on-Chip (PSoC) devices, part of a scalable 8-bit
PSoC 3 and 32-bit PSoC 5LP platform. The CY8C58LP family provides configurable blocks of analog, digital, and interconnect circuitry
around a CPU subsystem. The combination of a CPU with a flexible analog subsystem, digital subsystem, routing, and I/O enables
a high level of integration in a wide variety of consumer, industrial, and medical applications.
Figure 1-1. Simplified Block Diagram
Analog Interconnect
Clock Tree
IMO
Digital System
Quadrature Decoder
UDB
UDB
UDB
UDB
I 2C Slave
Sequencer
Universal Digital Block Array (24 x UDB)
8- Bit
Timer
16- Bit
PWM
UDB
UDB
8- Bit SPI
UDB
12- Bit SPI
UDB
UDB
I2C
Master/
Slave
CAN 2.0
16- Bit PRS
UDB
UDB
UDB
UDB
UDB
UDB
UDB
UDB
UDB
22 Ω
UDB
8- Bit
Timer
Logic
UDB
FS USB
2.0
4x
Timer
Counter
PWM
Logic
UDB
UDB
UART
UDB
UDB
USB
PHY
GPIOs
32.768 KHz
( Optional)
GPIOs
Xtal
Osc
SIO
System Wide
Resources
Usage Example for UDB
4- 25 MHz
( Optional)
GPIOs
Digital Interconnect
12- Bit PWM
RTC
Timer
WDT
and
Wake
EEPROM
SRAM
CPU System
Interrupt
Controller
Cortex M3CPU
Program &
Debug
GPIOs
System Bus
Memory System
Program
GPIOs
Debug &
Trace
EMIF
FLASH
ILO
Cache
Controller
PHUB
DMA
Boundary
Scan
LCD Direct
Drive
Digital
Filter
Block
POR and
LVD
1.71 to
5.5 V
Sleep
Power
1.8 V LDO
SMP
4 x SC / CT Blocks
(TIA, PGA, Mixer etc)
Temperature
Sensor
GPIOs
Power Management
System
Analog System
ADCs
2x
SAR
ADC
+
4x
Opamp
-
+
4x DAC
CapSense
1x
Del Sig
ADC
4x
CMP
-
3 per
Opamp
GPIOs
SIOs
Clocking System
0. 5 to 5.5 V
( Optional)
Figure 1-1 illustrates the major components of the CY8C58LP
family. They are:
Arm Cortex-M3 CPU subsystem
Nonvolatile subsystem
Programming, debug, and test subsystem
Inputs and outputs
Clocking
Power
Digital subsystem
PSoC’s digital subsystem provides half of its unique
configurability. It connects a digital signal from any peripheral to
any pin through the digital system interconnect (DSI). It also
provides functional flexibility through an array of small, fast, low
power UDBs. PSoC Creator provides a library of pre-built and
tested standard digital peripherals (UART, SPI, LIN, PRS, CRC,
timer, counter, PWM, AND, OR, and so on) that are mapped to
the UDB array. You can also easily create a digital circuit using
boolean primitives by means of graphical design entry. Each
UDB contains programmable array logic (PAL)/programmable
logic device (PLD) functionality, together with a small state
machine engine to support a wide variety of peripherals.
Analog subsystem
Document Number: 001-84932 Rev. *N
Page 4 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
In addition to the flexibility of the UDB array, PSoC also provides
configurable digital blocks targeted at specific functions. For the
CY8C58LP family, these blocks can include four 16-bit timers,
counters, and PWM blocks; I2C slave, master, and multimaster;
Full-Speed USB; and Full CAN 2.0.
For more details on the peripherals see the Example Peripherals
on page 40 of this datasheet. For information on UDBs, DSI, and
other digital blocks, see the Digital Subsystem on page 40 of this
datasheet.
PSoC’s analog subsystem is the second half of its unique
configurability. All analog performance is based on a highly
accurate absolute voltage reference with less than 0.1% error
over temperature and voltage. The configurable analog
subsystem includes:
Analog muxes
Comparators
Analog mixers
Voltage references
ADCs
DACs
Digital filter block (DFB)
All GPIO pins can route analog signals into and out of the device
using the internal analog bus. This allows the device to interface
up to 62 discrete analog signals. One of the ADCs in the analog
subsystem is a fast, accurate, configurable delta-sigma ADC
with these features:
Less than 100-µV offset
A gain error of 0.2%
Integral non linearity (INL) less than ±2 LSB
Differential non linearity (DNL) less than ±1 LSB
SINAD better than 84 dB in 16-bit mode
This converter addresses a wide variety of precision analog
applications including some of the most demanding sensors.
The CY8C58LP family also offers up to two SAR ADCs.
Featuring 12-bit conversions at up to 1 M samples per second,
they also offer low nonlinearity and offset errors and SNR better
than 70 dB. They are well-suited for a variety of higher speed
analog applications.
The output of any of the ADCs can optionally feed the
programmable DFB via DMA without CPU intervention. You can
configure the DFB to perform IIR and FIR digital filters and
several user defined custom functions. The DFB can implement
filters with up to 64 taps. It can perform a 48-bit
multiply-accumulate (MAC) operation in one clock cycle.
Four high-speed voltage or current DACs support 8-bit output
signals at an update rate of up to 8 Msps. They can be routed
out of any GPIO pin. You can create higher resolution voltage
PWM DAC outputs using the UDB array. This can be used to
create a pulse width modulated (PWM) DAC of up to 10 bits, at
up to 48 kHz. The digital DACs in each UDB support PWM, PRS,
or delta-sigma algorithms with programmable widths.
Document Number: 001-84932 Rev. *N
In addition to the ADCs, DACs, and DFB, the analog subsystem
provides multiple:
Comparators
Uncommitted opamps
Configurable switched capacitor/continuous time (SC/CT)
blocks. These support:
Transimpedance amplifiers
Programmable gain amplifiers
Mixers
Other similar analog components
See the “Analog Subsystem” section on page 51 of this
datasheet for more details.
PSoC’s CPU subsystem is built around a 32-bit three-stage
pipelined Arm Cortex-M3 processor running at up to 80 MHz.
The Cortex-M3 includes a tightly integrated nested vectored
interrupt controller (NVIC) and various debug and trace modules.
The overall CPU subsystem includes a DMA controller, flash
cache, and RAM. The NVIC provides low latency, nested
interrupts, and tail-chaining of interrupts and other features to
increase the efficiency of interrupt handling. The DMA controller
enables peripherals to exchange data without CPU involvement.
This allows the CPU to run slower (saving power) or use those
CPU cycles to improve the performance of firmware algorithms.
The flash cache also reduces system power consumption by
allowing less frequent flash access.
PSoC’s nonvolatile subsystem consists of flash, byte-writeable
EEPROM, and nonvolatile configuration options. It provides up
to 256 KB of on-chip flash. The CPU can reprogram individual
blocks of flash, enabling boot loaders. You can enable an ECC
for high reliability applications. A powerful and flexible protection
model secures the user's sensitive information, allowing
selective memory block locking for read and write protection.
Two KB of byte-writable EEPROM is available on-chip to store
application data. Additionally, selected configuration options
such as boot speed and pin drive mode are stored in nonvolatile
memory. This allows settings to activate immediately after POR.
The three types of PSoC I/O are extremely flexible. All I/Os have
many drive modes that are set at POR. PSoC also provides up
to four I/O voltage domains through the VDDIO pins. Every GPIO
has analog I/O, LCD drive, CapSense, flexible interrupt
generation, slew rate control, and digital I/O capability. The SIOs
on PSoC allow VOH to be set independently of VDDIO when used
as outputs. When SIOs are in input mode they are high
impedance. This is true even when the device is not powered or
when the pin voltage goes above the supply voltage. This makes
the SIO ideally suited for use on an I2C bus where the PSoC may
not be powered when other devices on the bus are. The SIO pins
also have high current sink capability for applications such as
LED drives. The programmable input threshold feature of the
SIO can be used to make the SIO function as a general purpose
analog comparator. For devices with FS USB, the USB physical
interface is also provided (USBIO). When not using USB, these
pins may also be used for limited digital functionality and device
programming. All the features of the PSoC I/Os are covered in
detail in the I/O System and Routing on page 33 of this
datasheet.
Page 5 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
The PSoC device incorporates flexible internal clock generators,
designed for high stability and factory trimmed for high accuracy.
The internal main oscillator (IMO) is the master clock base for
the system, and has one-percent accuracy at 3 MHz. The IMO
can be configured to run from 3 MHz up to 74 MHz. Multiple clock
derivatives can be generated from the main clock frequency to
meet application needs. The device provides a PLL to generate
system clock frequencies up to 80 MHz from the IMO, external
crystal, or external reference clock. It also contains a separate,
very low-power internal low-speed oscillator (ILO) for the sleep
and watchdog timers. A 32.768-kHz external watch crystal is
also supported for use in RTC applications. The clocks, together
with programmable clock dividers, provide the flexibility to
integrate most timing requirements.
The CY8C58LP family supports a wide supply operating range
from 1.71 to 5.5 V. This allows operation from regulated supplies
such as 1.8 ± 5%, 2.5 V ±10%, 3.3 V ± 10%, or 5.0 V ± 10%, or
directly from a wide range of battery types. In addition, it provides
an integrated high efficiency synchronous boost converter that
can power the device from supply voltages as low as 0.5 V. This
enables the device to be powered directly from a single battery.
In addition, you can use the boost converter to generate other
voltages required by the device, such as a 3.3 V supply for LCD
glass drive. The boost’s output is available on the VBOOST pin,
allowing other devices in the application to be powered from the
PSoC.
PSoC supports a wide range of low power modes. These include
a 300-nA hibernate mode with RAM retention and a 2-µA sleep
mode with RTC. In the second mode, the optional 32.768-kHz
watch crystal runs continuously and maintains an accurate RTC.
Power to all major functional blocks, including the programmable
digital and analog peripherals, can be controlled independently
by firmware. This allows low power background processing
when some peripherals are not in use. This, in turn, provides a
total device current of only 3.1 mA when the CPU is running at
6 MHz.
The details of the PSoC power modes are covered in the Power
System on page 26 of this datasheet.
PSoC uses JTAG (4 wire) or SWD (2 wire) interfaces for
programming, debug, and test. Using these standard interfaces
you can debug or program the PSoC with a variety of hardware
solutions from Cypress or third party vendors. The Cortex-M3
debug and trace modules include FPB, DWT, ETM, and ITM.
These modules have many features to help solve difficult debug
and trace problems. Details of the programming, test, and
debugging interfaces are discussed in the Programming, Debug
Interfaces, Resources on page 61 of this datasheet.
Document Number: 001-84932 Rev. *N
2. Pinouts
Each VDDIO pin powers a specific set of I/O pins. (The USBIOs
are powered from VDDD.) Using the VDDIO pins, a single PSoC
can support multiple voltage levels, reducing the need for
off-chip level shifters. The black lines drawn on the pinout
diagrams in Figure 2-3 and Figure 2-4, as well as Table 2-1,
show the pins that are powered by each VDDIO.
Each VDDIO may source up to 100 mA total to its associated I/O
pins, as shown in Figure 2-1.
Figure 2-1. VDDIO Current Limit
IDDIO X
mA
VDDIO X
I/O Pins
PSoC
Conversely, for the 100-pin and 68-pin devices, the set of I/O
pins associated with any VDDIO may sink up to 100 mA total, as
shown in Figure 2-2.
Figure 2-2. I/O Pins Current Limit
Ipins
VDDIO X
mA
I/O Pins
PSoC
VSSD
Page 6 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
P2[5] (GPIO, TRACEDATA[1])
VDDIO2
P2[4] (GPIO, TRACEDATA[0])
P2[3] (GPIO, TRACECLK)
P2[2] (GPIO)
P2[1] (GPIO)
P2[0] (GPIO)
P15[5] (GPOI)
P15[4] (GPIO)
VDDD
VSSD
VCCD
P0[7] (GPIO, IDAC2)
P0[6] (GPIO, IDAC0)
P0[5] (GPIO, OPAMP2-)
P0[4] (GPIO, OPAMP2+, SAR0 EXTREF)
VDDIO0
Figure 2-3. 68-pin QFN Part Pinout [3]
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
51
50
Lines show VDDIO
to I/O supply
association
QFN
(TOP VIEW)
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
P0[3] (GPIO, OPAMP0-, EXTREF0)
P0[2] (GPIO, OPAMP0+, SAR1 EXTREF)
P0[1] (GPIO, OPAMP0OUT)
P0[0] (GPIO, OPAMP2OUT)
P12[3] (SIO)
P12[2] (SIO)
VSSD
VDDA
VSSA
VCCA
P15[3] (GPIO, KHZ XTAL: XI)
P15[2] (GPIO, KHZ XTAL: XO)
P12[1] (SIO, I2C1: SDA)
P12[0] (SIO, 12C1: SCL)
P3[7] (GPIO, OPAMP3OUT)
P3[6] (GPIO, OPAMP1OUT)
VDDIO3
(GPIO) P1[6]
(GPIO) P1[7]
(SIO) P12[6]
(SIO) P12[7]
[4]
(USBIO, D+, SWDIO) P15[6]
[4] (USBIO, D-, SWDCK) P15[7]
VDDD
VSSD
VCCD
(MHZ XTAL: XO, GPIO) P15[0]
(MHZ XTAL: XI, GPIO) P15[1]
(IDAC1, GPIO) P3[0]
(IDAC3, GPIO) P3[1]
(OPAMP3-, EXTREF1, GPIO) P3[2]
(OPAMP3+, GPIO) P3[3]
(OPAMP1-, GPIO) P3[4]
(OPAMP1+, GPIO) P3[5]
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
(TRACEDATA[2], GPIO) P2[6]
(TRACEDATA[3], GPIO) P2[7]
(I2C0: SCL, SIO) P12[4]
(I2C0: SDA, SIO) P12[5]
VSSB
IND
VBOOST
VBAT
VSSD
XRES
(TMS, SWDIO, GPIO) P1[0]
(TCK, SWDCK, GPIO) P1[1]
(Configurable XRES, GPIO) P1[2]
(TDO, SWV, GPIO) P1[3]
(TDI, GPIO) P1[4]
(NTRST, GPIO) P1[5]
VDDIO1
Notes
3. The center pad on the QFN package should be connected to digital ground (VSSD) for best mechanical, thermal, and electrical performance. If not connected to
ground, it should be electrically floated and not connected to any other signal. For more information, see AN72845, Design Guidelines for QFN Devices.
4. Pins are Do Not Use (DNU) on devices without USB. The pin must be left floating.
Document Number: 001-84932 Rev. *N
Page 7 of 139
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Datasheet
P4[5] (GPIO)
P4[4] (GPIO)
P4[3] (GPIO)
P4[2] (GPIO)
P0[7] (GPIO, IDAC2)
P0[6] (GPIO, IDAC0)
P0[5] (GPIO, OPAMP2-)
P0[4] (GPIO, OPAMP2+, SAR0 EXTREF)
P15[4] (GPIO)
P6[3] (GPIO)
P6[2] (GPIO)
P6[1] (GPIO)
P6[0] (GPIO)
VDDD
VSSD
VCCD
P4[7] (GPIO)
P4[6] (GPIO)
75
74
Lines show VDDIO
to I/O supply
association
TQFP
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
VDDIO0
P0[3] (GPIO, OPAMP0-, EXTREF0)
P0[2] (GPIO, OPAMP0+, SAR1 EXTREF)
P0[1] (GPIO, OPAMP0OUT)
P0[0] (GPIO, OPAMP2OUT)
P4[1] (GPIO)
P4[0] (GPIO)
P12[3] (SIO)
P12[2] (SIO)
VSSD
VDDA
VSSA
(OPAMP1+, GPIO) P3[5]
VDDIO3
VCCA
NC
NC
NC
NC
NC
NC
P15[3] (GPIO, KHZ XTAL: XI)
P15[2] (GPIO, KHZ XTAL: XO)
P12[1] (SIO, I2C1: SDA)
P12[0] (SIO, I2C1: SCL)
P3[7] (GPIO, OPAMP3OUT)
P3[6] (GPIO, OPAMP1OUT)
[6]
[6]
(USBIO, D-, SWDCK) P15[7]
VDDD
VSSD
VCCD
NC
NC
(MHZ XTAL: XO, GPIO) P15[0]
(MHZ XTAL: XI, GPIO) P15[1]
(IDAC1, GPIO) P3[0]
(IDAC3, GPIO) P3[1]
(OPAMP3-, EXTREF1, GPIO) P3[2]
(OPAMP3+, GPIO) P3[3]
(OPAMP1-, GPIO) P3[4]
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
VDDIO1
(GPIO) P1[6]
(GPIO) P1[7]
(SIO) P12[6]
(SIO) P12[7]
(GPIO) P5[4]
(GPIO) P5[5]
(GPIO) P5[6]
(GPIO) P5[7]
(USBIO, D+, SWDIO) P15[6]
(TRACEDATA[1], GPIO) P2[5]
(TRACEDATA[2], GPIO) P2[6]
(TRACEDATA[3], GPIO) P2[7]
(I2C0: SCL, SIO) P12[4]
(I2C0: SDA, SIO) P12[5]
(GPIO) P6[4]
(GPIO) P6[5]
(GPIO) P6[6]
(GPIO) P6[7]
VSSB
IND
VBOOST
VBAT
VSSD
XRES
(GPIO) P5[0]
(GPIO) P5[1]
(GPIO) P5[2]
(GPIO) P5[3]
(TMS, SWDIO, GPIO) P1[0]
(TCK, SWDCK, GPIO) P1[1]
(Configurable XRES, GPIO) P1[2]
(TDO, SWV, GPIO) P1[3]
(TDI, GPIO) P1[4]
(NTRST, GPIO) P1[5]
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
VDDIO2
P2[4] (GPIO, TRACEDATA[0])
P2[3] (GPIO, TRACECLK)
P2[2] (GPIO)
P2[1] (GPIO)
P2[0] (GPIO)
P15[5] (GPIO)
Figure 2-4. 100-pin TQFP Part Pinout
Table 2-1. VDDIO and Port Pin Associations
VDDIO
Port Pins
VDDIO0
P0[7:0], P4[7:0], P12[3:2]
VDDIO1
P1[7:0], P5[7:0], P12[7:6]
VDDIO2
P2[7:0], P6[7:0], P12[5:4], P15[5:4]
VDDIO3
P3[7:0], P12[1:0], P15[3:0]
VDDD
P15[7:6] (USB D+, D-)
Note
5. Pins are Do Not Use (DNU) on devices without USB. The pin must be left floating.
Document Number: 001-84932 Rev. *N
Page 8 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Table 2-2 shows the pinout for the 99-pin CSP package. Since there are four VDDIO pins, the set of I/O pins associated with any VDDIO
may sink up to 100 mA total, same as for the 100-pin and 68-pin devices.
Table 2-2. CSP Pinout
Ball
Name
Ball
Name
Ball
Name
Ball
Name
E5
P2[5]
L2
VIO1
B2
P3[6]
C8
VIO0
G6
P2[6]
K2
P1[6]
B3
P3[7]
D7
P0[4]
G5
P2[7]
C9
P4[2]
C3
P12[0]
E7
P0[5]
H6
P12[4]
E8
P4[3]
C4
P12[1]
B9
P0[6]
K7
P12[5]
K1
P1[7]
E3
P15[2]
D8
P0[7]
L8
P6[4]
H2
P12[6]
E4
P15[3]
D9
P4[4]
J6
P6[5]
F4
P12[7]
A1
NC
F8
P4[5]
H5
P6[6]
J1
P5[4]
A9
NC
F7
P4[6]
J5
P6[7]
H1
P5[5]
L1
NC
E6
P4[7]
L7
VSSB
F3
P5[6]
L9
NC
E9
VCCD
K6
Ind
G1
P5[7]
A3
VCCA
F9
VSSD
L6
VBOOST
G2
P15[6][6]
A4
VSSA
G9
VDDD
K5
VBAT
F2
P15[7][6]
B7
VSSA
H9
P6[0]
L5
VSSD
E2
VDDD
B8
VSSA
G8
P6[1]
L4
XRES
F1
VSSD
C7
VSSA
H8
P6[2]
J4
P5[0]
E1
VCCD
A5
VDDA
J9
P6[3]
K4
P5[1]
D1
P15[0]
A6
VSSD
G7
P15[4]
K3
P5[2]
D2
P15[1]
B5
P12[2]
F6
P15[5]
L3
P5[3]
C1
P3[0]
A7
P12[3]
F5
P2[0]
H4
P1[0]
C2
P3[1]
C5
P4[0]
J7
P2[1]
J3
P1[1]
D3
P3[2]
D5
P4[1]
J8
P2[2]
H3
P1[2]
D4
P3[3]
B6
P0[0]
K9
P2[3]
J2
P1[3]
B4
P3[4]
C6
P0[1]
H7
P2[4]
G4
P1[4]
A2
P3[5]
A8
P0[2]
K8
VIO2
G3
P1[5]
B1
VIO3
D6
P0[3]
Figure 2-5 on page 10 and Figure 2-6 on page 11 show an example schematic and an example PCB layout, for the 100-pin TQFP
part, for optimal analog performance on a two-layer board.
The two pins labeled VDDD must be connected together.
The two pins labeled VCCD must be connected together, with capacitance added, as shown in Figure 2-5 and Power System on
page 26. The trace between the two VCCD pins should be as short as possible.
The two pins labeled VSSD must be connected together.
For information on circuit board layout issues for mixed signals, refer to the application note, AN57821 - Mixed Signal Circuit Board
Layout Considerations for PSoC® 3 and PSoC 5.
Note
6. Pins are Do Not Use (DNU) on devices without USB. The pin must be left floating.
Document Number: 001-84932 Rev. *N
Page 9 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Figure 2-5. Example Schematic for 100-pin TQFP Part with Power Connections
VDDD
VDDD
C1
1 UF
VDDD
C2
0.1 UF
VSSD
VDDIO0
OA0-, REF0, P0[3]
OA0+, SAR1REF, P0[2]
OA0OUT, P0[1]
OA2OUT, P0[0]
P4[1]
P4[0]
SIO, P12[3]
SIO, P12[2]
VSSD
VDDA
VSSA
VCCA
NC
NC
NC
NC
NC
NC
KHZXIN, P15[3]
KHZXOUT, P15[2]
SIO, P12[1]
SIO, P12[0]
OA3OUT, P3[7]
VSSD
VSSD
VDDD
C12
0.1 UF
C15
1 UF
C16
0.1 UF
VDDA
VDDD
C8
0.1 UF
C17
1 UF
VSSD
VSSD
VDDA
VSSA
VCCA
VSSD
VSSA
VDDA
C9
1 UF
C10
0.1 UF
VSSA
VDDIO3
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
VDDD
C11
0.1 UF
VCCD
VDDD
OA1OUT, P3[6]
P3[5], OA1+
VDDIO1
P1[6]
P1[7]
P12[6], SIO
P12[7], SIO
P5[4]
P5[5]
P5[6]
P5[7]
USB D+, P15[6]
USB D-, P15[7]
VDDD
VSSD
VCCD
NC
NC
P15[0], MHZXOUT
P15[1], MHZXIN
P3[0], IDAC1
P3[1], IDAC3
P3[2], OA3-, REF1
P3[3], OA3+
P3[4], OA1-
P2[5]
P2[6]
P2[7]
P12[4], SIO
P12[5], SIO
P6[4]
P6[5]
P6[6]
P6[7]
VSSB
IND
VBOOST
VBAT
VSSD
XRES
P5[0]
P5[1]
P5[2]
P5[3]
P1[0], SWDIO, TMS
P1[1], SWDCK, TCK
P1[2]
P1[3], SWV, TDO
P1[4], TDI
P1[5], NTRST
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
VSSD
1
2
3
4
5
6
7
8
9
10
11
12
13
VSSD 14
15
16
17
18
19
20
21
22
23
24
25
VSSD
VDDIO2
P2[4]
P2[3]
P2[2]
P2[1]
P2[0]
P15[5]
P15[4]
P6[3]
P6[2]
P6[1]
P6[0]
VDDD
VSSD
VCCD
P4[7]
P4[6]
P4[5]
P4[4]
P4[3]
P4[2]
IDAC2, P0[7]
IDAC0, P0[6]
OA2-, P0[5]
OA2+,
SAR0REF,
P0[4]
VSSD
VDDD
100
99
98
97
96
95
94
93
92
91
90
89
88 VDDD
VSSD
87
86
85
84
83
82
81
80
79
78
77
76
VCCD
C6
0.1 UF
VSSD
VSSD
Note The two VCCD pins must be connected together with as short a trace as possible. A trace under the device is recommended, as
shown in Figure 2-6.
For more information on pad layout, refer to http://www.cypress.com/cad-resources/psoc-5lp-cad-libraries.
Document Number: 001-84932 Rev. *N
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Datasheet
Figure 2-6. Example PCB Layout for 100-pin TQFP Part for Optimal Analog Performance
VSSA
VDD D
VSSD
Plane
Document Number: 001-84932 Rev. *N
VSSD
VD DA
VSSA
Plane
Page 11 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
3. Pin Descriptions
TRACEDATA[3:0]. Cortex-M3
output data.
IDAC0, IDAC1, IDAC2, IDAC3. Low-resistance output pin for
high-current DACs (IDAC).
SWV. SWV output.
Opamp0out, Opamp1out, Opamp2out, Opamp3out. High
current output of uncommitted opamp.[7]
Extref0, Extref1. External reference input to the analog system.
SAR0 EXTREF, SAR1 EXTREF. External references for SAR
ADCs
Opamp0-, Opamp1-, Opamp2-, Opamp3-. Inverting input to
uncommitted opamp.
TRACEPORT
connections,
USBIO, D+. Provides D+ connection directly to a USB 2.0 bus.
May be used as a digital I/O pin; it is powered from VDDD instead
of from a VDDIO. Pins are Do Not Use (DNU) on devices without
USB.
USBIO, D-. Provides D- connection directly to a USB 2.0 bus.
May be used as a digital I/O pin; it is powered from VDDD instead
of from a VDDIO. Pins are Do Not Use (DNU) on devices without
USB.
VBOOST. Power sense connection to boost pump.
Opamp0+, Opamp1+, Opamp2+, Opamp3+. Noninverting
input to uncommitted opamp.
VBAT. Battery supply to boost pump.
GPIO. Provides interfaces to the CPU, digital peripherals,
analog peripherals, interrupts, LCD segment drive, and
CapSense.[7]
I2C0: SCL, I2C1: SCL. I2C SCL line providing wake from sleep
on an address match. Any I/O pin can be used for I2C SCL if
wake from sleep is not required.
I2C0: SDA, I2C1: SDA. I2C SDA line providing wake from sleep
on an address match. Any I/O pin can be used for I2C SDA if
wake from sleep is not required.
Ind. Inductor connection to boost pump.
kHz XTAL: Xo, kHz XTAL: Xi. 32.768-kHz crystal oscillator pin.
MHz XTAL: Xo, MHz XTAL: Xi. 4 to 25-MHz crystal oscillator
pin.
nTRST. Optional JTAG Test Reset programming and debug port
connection to reset the JTAG connection.
SIO. Provides interfaces to the CPU, digital peripherals and
interrupts with a programmable high threshold voltage, analog
comparator, high sink current, and high impedance state when
the device is unpowered.
VCCA. Output of the analog core regulator or the input to
the analog core. Requires a 1uF capacitor to VSSA. The
regulator output is not designed to drive external circuits. Note
that if you use the device with an external core regulator
(externally regulated mode), the voltage applied to this pin
must not exceed the allowable range of 1.71 V to 1.89 V.
When using the internal core regulator, (internally regulated
mode, the default), do not tie any power to this pin. For details
see Power System on page 26.
VCCD. Output of the digital core regulator or the input to the
digital core. The two VCCD pins must be shorted together, with
the trace between them as short as possible, and a 1uF capacitor
to VSSD. The regulator output is not designed to drive external
circuits. Note that if you use the device with an external core
regulator (externally regulated mode), the voltage applied to
this pin must not exceed the allowable range of 1.71 V to
1.89 V. When using the internal core regulator (internally
regulated mode, the default), do not tie any power to this pin. For
details see Power System on page 26.
SWDCK. SWD Clock programming and debug port connection.
VDDA. Supply for all analog peripherals and analog core
regulator. VDDA must be the highest voltage present on the
device. All other supply pins must be less than or equal to
VDDA.
SWDIO. SWD Input and Output programming and debug port
connection.
VDDD. Supply for all digital peripherals and digital core
regulator. VDDD must be less than or equal to VDDA.
TCK. JTAG
connection.
VSSA. Ground for all analog peripherals.
Test
Clock
programming
and
debug
port
VSSB. Ground connection for boost pump.
TDI. JTAG Test Data In programming and debug port
connection.
VSSD. Ground for all digital logic and I/O pins.
TDO. JTAG Test Data Out programming and debug port
connection.
VDDIO0, VDDIO1, VDDIO2, VDDIO3. Supply for I/O pins. Each
VDDIO must be tied to a valid operating voltage (1.71 V to 5.5 V),
and must be less than or equal to VDDA.
TMS. JTAG Test Mode Select programming and debug port
connection.
XRES. External reset pin. Active low with internal pull-up.
TRACECLK. Cortex-M3
TRACEDATA pins.
TRACEPORT
connection,
clocks
Note
7. GPIOs with opamp outputs are not recommended for use with CapSense.
Document Number: 001-84932 Rev. *N
Page 12 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
4. CPU
4.1 Arm Cortex-M3 CPU
The CY8C58LP family of devices has an Arm Cortex-M3 CPU core. The Cortex-M3 is a low-power 32-bit three-stage pipelined
Harvard-architecture CPU that delivers 1.25 DMIPS/MHz. It is intended for deeply embedded applications that require fast interrupt
handling features.
Figure 4-1. Arm Cortex-M3 Block Diagram
Interrupt Inputs
Nested
Vectored
Interrupt
Controller
(NVIC)
I- Bus
JTAG/SWD
D-Bus
Embedded
Trace Module
(ETM)
Instrumentation
Trace Module
(ITM)
S- Bus
Trace Pins:
Debug Block
(Serial and
JTAG)
Flash Patch
and Breakpoint
(FPB)
Trace Port
5 for TRACEPORT or
Interface Unit 1 for SWV mode
(TPIU)
Cortex M3 Wrapper
C-Bus
AHB
32 KB
SRAM
Data
Watchpoint and
Trace (DWT)
Cortex M3 CPU Core
AHB
Bus
Matrix
Bus
Matrix
1 KB
Cache
256 KB
ECC
Flash
AHB
32 KB
SRAM
Bus
Matrix
AHB Bridge & Bus Matrix
DMA
PHUB
AHB Spokes
GPIO &
EMIF
Prog.
Digital
Prog.
Analog
Special
Functions
Peripherals
The Cortex-M3 CPU subsystem includes these features:
4.1.1 Cortex-M3 Features
Arm Cortex-M3 CPU
The Cortex-M3 CPU features include:
Programmable nested vectored interrupt controller (NVIC),
tightly integrated with the CPU core
Full featured debug and trace modules, tightly integrated with
the CPU core
Up to 256 KB of flash memory, 2 KB of EEPROM, and 64 KB
of SRAM
Cache controller
Peripheral HUB (PHUB)
DMA controller
External memory interface (EMIF)
Document Number: 001-84932 Rev. *N
4 GB address space. Predefined address regions for code,
data, and peripherals. Multiple buses for efficient and
simultaneous accesses of instructions, data, and peripherals.
The Thumb®-2 instruction set, which offers Arm-level
performance at Thumb-level code density. This includes 16-bit
and 32-bit instructions. Advanced instructions include:
Bit-field control
Hardware multiply and divide
Saturation
If-Then
Wait for events and interrupts
Exclusive access and barrier
Special register access
Page 13 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
The Cortex-M3 does not support Arm instructions for SRAM
addresses.
Bit-band support for the SRAM region. Atomic bit-level write
and read operations for SRAM addresses.
Unaligned data storage and access. Contiguous storage of
Table 4-2. Cortex M3 CPU Registers (continued)
Register
R14
R15
data of different byte lengths.
Operation at two privilege levels (privileged and user) and in
xPSR
two modes (thread and handler). Some instructions can only
be executed at the privileged level. There are also two stack
pointers: Main (MSP) and Process (PSP). These features
support a multitasking operating system running one or more
user-level processes.
Description
R14 is the link register (LR). The LR stores the return
address when a subroutine is called.
R15 is the program counter (PC). Bit 0 of the PC is
ignored and considered to be 0, so instructions are
always aligned to a half word (2 byte) boundary.
The program status registers are divided into three
status registers, which are accessed either together
or separately:
Application program status register (APSR) holds
program execution status bits such as zero, carry,
negative, in bits[27:31].
Extensive interrupt and system exception support.
Interrupt program status register (IPSR) holds the
4.1.2 Cortex-M3 Operating Modes
Execution program status register (EPSR) holds
current exception number in bits[0:8].
4.1.3 CPU Registers
control bits for interrupt continuable and IF-THEN
instructions in bits[10:15] and [25:26]. Bit 24 is
always set to 1 to indicate Thumb mode. Trying to
clear it causes a fault exception.
PRIMASK
A 1-bit interrupt mask register. When set, it allows
only the nonmaskable interrupt (NMI) and hard fault
exception. All other exceptions and interrupts are
masked.
FAULTMASK A 1-bit interrupt mask register. When set, it allows
only the NMI. All other exceptions and interrupts are
masked.
BASEPRI
A register of up to nine bits that define the masking
priority level. When set, it disables all interrupts of
the same or higher priority value. If set to 0 then the
masking function is disabled.
CONTROL
A 2-bit register for controlling the operating mode.
Bit 0: 0 = privileged level in thread mode,
1 = user level in thread mode.
Bit 1: 0 = default stack (MSP) is used,
1 = alternate stack is used. If in thread mode or user
level then the alternate stack is the PSP. There is no
alternate stack for handler mode; the bit must be 0
while in handler mode.
The Cortex-M3 CPU registers are listed in Table 4-2. Registers
R0-R15 are all 32 bits wide.
4.2 Cache Controller
The Cortex-M3 operates at either the privileged level or the user
level, and in either the thread mode or the handler mode.
Because the handler mode is only enabled at the privileged level,
there are actually only three states, as shown in Table 4-1.
Table 4-1. Operational Level
Condition
Privileged
User
Running an exception Handler mode
Not used
Running main program Thread mode
Thread mode
At the user level, access to certain instructions, special registers,
configuration registers, and debugging components is blocked.
Attempts to access them cause a fault exception. At the
privileged level, access to all instructions and registers is
allowed.
The processor runs in the handler mode (always at the privileged
level) when handling an exception, and in the thread mode when
not.
Table 4-2. Cortex M3 CPU Registers
Register
R0-R12
Description
General purpose registers R0-R12 have no special
architecturally defined uses. Most instructions that
specify a general purpose register specify R0-R12.
Low registers: Registers R0-R7 are accessible by
all instructions that specify a general purpose
register.
High registers: Registers R8-R12 are accessible
R13
by all 32-bit instructions that specify a general
purpose register; they are not accessible by all
16-bit instructions.
R13 is the stack pointer register. It is a banked
register that switches between two 32-bit stack
pointers: the main stack pointer (MSP) and the
process stack pointer (PSP). The PSP is used only
when the CPU operates at the user level in thread
mode. The MSP is used in all other privilege levels
and modes. Bits[0:1] of the SP are ignored and
considered to be 0, so the SP is always aligned to a
word (4 byte) boundary.
Document Number: 001-84932 Rev. *N
The CY8C58LP family has a 1 KB, 4-way set-associative
instruction cache between the CPU and the flash memory. This
improves instruction execution rate and reduces system power
consumption by requiring less frequent flash access.
4.3 DMA and PHUB
The PHUB and the DMA controller are responsible for data
transfer between the CPU and peripherals, and also data
transfers between peripherals. The PHUB and DMA also control
device configuration during boot. The PHUB consists of:
A central hub that includes the DMA controller, arbiter, and
router
Multiple spokes that radiate outward from the hub to most
peripherals
There are two PHUB masters: the CPU and the DMA controller.
Both masters may initiate transactions on the bus. The DMA
channels can handle peripheral communication without CPU
intervention. The arbiter in the central hub determines which
DMA channel is the highest priority if there are multiple requests.
Page 14 of 139
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4.3.1 PHUB Features
4.3.3 Priority Levels
CPU and DMA controller are both bus masters to the PHUB
The CPU always has higher priority than the DMA controller
when their accesses require the same bus resources. Due to the
system architecture, the CPU can never starve the DMA. DMA
channels of higher priority (lower priority number) may interrupt
current DMA transfers. In the case of an interrupt, the current
transfer is allowed to complete its current transaction. To ensure
latency limits when multiple DMA accesses are requested
simultaneously, a fairness algorithm guarantees an interleaved
minimum percentage of bus bandwidth for priority levels 2
through 7. Priority levels 0 and 1 do not take part in the fairness
algorithm and may use 100% of the bus bandwidth. If a tie occurs
on two DMA requests of the same priority level, a simple round
robin method is used to evenly share the allocated bandwidth.
The round robin allocation can be disabled for each DMA
channel, allowing it to always be at the head of the line. Priority
levels 2 to 7 are guaranteed the minimum bus bandwidth shown
in Table 4-4 after the CPU and DMA priority levels 0 and 1 have
satisfied their requirements.
Eight multi-layer AHB bus parallel access paths (spokes) for
peripheral access
Simultaneous CPU and DMA access to peripherals located on
different spokes
Simultaneous DMA source and destination burst transactions
on different spokes
Supports 8-, 16-, 24-, and 32-bit addressing and data
Table 4-3. PHUB Spokes and Peripherals
PHUB Spokes
0
Peripherals
SRAM
1
IOs, PICU, EMIF
2
PHUB local configuration, Power manager,
Clocks, IC, SWV, EEPROM, Flash
programming interface
3
Analog interface and trim, Decimator
4
USB, CAN, I2C, Timers, Counters, and PWMs
5
DFB
6
UDBs group 1
7
UDBs group 2
Table 4-4. Priority Levels
Priority Level
% Bus Bandwidth
0
100.0
1
100.0
2
50.0
3
25.0
4.3.2 DMA Features
4
12.5
24 DMA channels
5
6.2
6
3.1
7
1.5
Each channel has one or more transaction descriptors (TDs)
to configure channel behavior. Up to 128 total TDs can be
defined
TDs can be dynamically updated
Eight levels of priority per channel
Any digitally routable signal, the CPU, or another DMA channel,
can trigger a transaction
Each channel can generate up to two interrupts per transfer
Transactions can be stalled or canceled
Supports transaction size of infinite or 1 to 64k bytes
Large transactions may be broken into smaller bursts of 1 to
127 bytes
TDs may be nested and/or chained for complex transactions
Document Number: 001-84932 Rev. *N
When the fairness algorithm is disabled, DMA access is granted
based solely on the priority level; no bus bandwidth guarantees
are made.
4.3.4 Transaction Modes Supported
The flexible configuration of each DMA channel and the ability to
chain multiple channels allow the creation of both simple and
complex use cases. General use cases include, but are not
limited to:
4.3.4.1 Simple DMA
In a simple DMA case, a single TD transfers data between a
source and sink (peripherals or memory location). The basic
timing diagrams of DMA read and write cycles are shown in
Figure 4-2. For more description on other transfer modes, refer
to the Technical Reference Manual.
Page 15 of 139
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Figure 4-2. DMA Timing Diagram
ADDRESS Phase
DATA Phase
ADDRESS Phase
CLK
DATA Phase
CLK
ADDR 16/32
A
ADDR 16/32
B
WRITE
A
B
WRITE
DATA (A)
DATA
READY
DATA (A)
DATA
READY
Basic DMA Write Transfer without wait states
Basic DMA Read Transfer without wait states
4.3.4.2 Auto Repeat DMA
Auto repeat DMA is typically used when a static pattern is
repetitively read from system memory and written to a peripheral.
This is done with a single TD that chains to itself.
4.3.4.3 Ping Pong DMA
A ping pong DMA case uses double buffering to allow one buffer
to be filled by one client while another client is consuming the
data previously received in the other buffer. In its simplest form,
this is done by chaining two TDs together so that each TD calls
the opposite TD when complete.
4.3.4.4 Circular DMA
Circular DMA is similar to ping pong DMA except it contains more
than two buffers. In this case there are multiple TDs; after the last
TD is complete it chains back to the first TD.
4.3.4.5 Indexed DMA
In an indexed DMA case, an external master requires access to
locations on the system bus as if those locations were shared
memory. As an example, a peripheral may be configured as an
SPI or I2C slave where an address is received by the external
master. That address becomes an index or offset into the internal
system bus memory space. This is accomplished with an initial
“address fetch” TD that reads the target address location from
the peripheral and writes that value into a subsequent TD in the
chain. This modifies the TD chain on the fly. When the “address
fetch” TD completes it moves on to the next TD, which has the
new address information embedded in it. This TD then carries
out the data transfer with the address location required by the
external master.
4.3.4.6 Scatter Gather DMA
In the case of scatter gather DMA, there are multiple
noncontiguous sources or destinations that are required to
effectively carry out an overall DMA transaction. For example, a
packet may need to be transmitted off of the device and the
packet elements, including the header, payload, and trailer, exist
Document Number: 001-84932 Rev. *N
in various noncontiguous locations in memory. Scatter gather
DMA allows the segments to be concatenated together by using
multiple TDs in a chain. The chain gathers the data from the
multiple locations. A similar concept applies for the reception of
data onto the device. Certain parts of the received data may
need to be scattered to various locations in memory for software
processing convenience. Each TD in the chain specifies the
location for each discrete element in the chain.
4.3.4.7 Packet Queuing DMA
Packet queuing DMA is similar to scatter gather DMA but
specifically refers to packet protocols. With these protocols,
there may be separate configuration, data, and status phases
associated with sending or receiving a packet.
For instance, to transmit a packet, a memory mapped
configuration register can be written inside a peripheral,
specifying the overall length of the ensuing data phase. The CPU
can set up this configuration information anywhere in system
memory and copy it with a simple TD to the peripheral. After the
configuration phase, a data phase TD (or a series of data phase
TDs) can begin (potentially using scatter gather). When the data
phase TD(s) finish, a status phase TD can be invoked that reads
some memory mapped status information from the peripheral
and copies it to a location in system memory specified by the
CPU for later inspection. Multiple sets of configuration, data, and
status phase “subchains” can be strung together to create larger
chains that transmit multiple packets in this way. A similar
concept exists in the opposite direction to receive the packets.
4.3.4.8 Nested DMA
One TD may modify another TD, as the TD configuration space
is memory mapped similar to any other peripheral. For example,
a first TD loads a second TD’s configuration and then calls the
second TD. The second TD moves data as required by the
application. When complete, the second TD calls the first TD,
which again updates the second TD’s configuration. This
process repeats as often as necessary.
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4.4 Interrupt Controller
The Cortex-M3 NVIC supports 16 system exceptions and 32 interrupts from peripherals, as shown in Table 4-5.
Table 4-5. Cortex-M3 Exceptions and Interrupts
Exception
Number
Exception Type
Priority
Exception Table
Address Offset
Function
0x00
Starting value of R13 / MSP
1
Reset
-3 (highest)
0x04
Reset
2
NMI
-2
0x08
Non maskable interrupt
3
Hard fault
-1
0x0C
All classes of fault, when the corresponding fault handler
cannot be activated because it is currently disabled or
masked
4
MemManage
Programmable
0x10
Memory management fault, for example, instruction
fetch from a nonexecutable region
5
Bus fault
Programmable
0x14
Error response received from the bus system; caused
by an instruction prefetch abort or data access error
6
Usage fault
Programmable
0x18
Typically caused by invalid instructions or trying to
switch to Arm mode
7–10
-
-
0x1C–0x28
Reserved
11
SVC
Programmable
0x2C
System service call via SVC instruction
12
Debug monitor
Programmable
0x30
Debug monitor
13
-
-
0x34
Reserved
14
PendSV
Programmable
0x38
Deferred request for system service
15
SYSTICK
Programmable
0x3C
System tick timer
16–47
IRQ
Programmable
0x40–0x3FC
Peripheral interrupt request #0 - #31
Bit 0 of each exception vector indicates whether the exception is
executed using Arm or Thumb instructions. Because the
Cortex-M3 only supports Thumb instructions, this bit must
always be 1. The Cortex-M3 non maskable interrupt (NMI) input
can be routed to any pin, via the DSI, or disconnected from all
pins. See DSI Routing Interface Description on page 45.
The Nested Vectored Interrupt Controller (NVIC) handles
interrupts from the peripherals, and passes the interrupt vectors
to the CPU. It is closely integrated with the CPU for low latency
interrupt handling. Features include:
32 interrupts. Multiple sources for each interrupt.
Eight priority levels, with dynamic priority control.
Priority grouping. This allows selection of preempting and non
preempting interrupt levels.
Document Number: 001-84932 Rev. *N
Support for tail-chaining, and late arrival, of interrupts. This
enables back-to-back interrupt processing without the
overhead of state saving and restoration between interrupts.
Processor state automatically saved on interrupt entry, and
restored on interrupt exit, with no instruction overhead.
If the same priority level is assigned to two or more interrupts,
the interrupt with the lower vector number is executed first. Each
interrupt vector may choose from three interrupt sources: Fixed
Function, DMA, and UDB. The fixed function interrupts are direct
connections to the most common interrupt sources and provide
the lowest resource cost connection. The DMA interrupt sources
provide direct connections to the two DMA interrupt sources
provided per DMA channel. The third interrupt source for vectors
is from the UDB digital routing array. This allows any digital signal
available to the UDB array to be used as an interrupt source. All
interrupt sources may be routed to any interrupt vector using the
UDB interrupt source connections.
Page 17 of 139
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Table 4-6. Interrupt Vector Table
Interrupt #
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
Cortex-M3 Exception #
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
Document Number: 001-84932 Rev. *N
Fixed Function
Low voltage detect (LVD)
Cache/ECC
Reserved
Sleep (Pwr Mgr)
PICU[0]
PICU[1]
PICU[2]
PICU[3]
PICU[4]
PICU[5]
PICU[6]
PICU[12]
PICU[15]
Comparators Combined
Switched Caps Combined
I2C
CAN
Timer/Counter0
Timer/Counter1
Timer/Counter2
Timer/Counter3
USB SOF Int
USB Arb Int
USB Bus Int
USB Endpoint[0]
USB Endpoint Data
Reserved
LCD
DFB Int
Decimator Int
phub_err_int
eeprom_fault_int
DMA
phub_termout0[0]
phub_termout0[1]
phub_termout0[2]
phub_termout0[3]
phub_termout0[4]
phub_termout0[5]
phub_termout0[6]
phub_termout0[7]
phub_termout0[8]
phub_termout0[9]
phub_termout0[10]
phub_termout0[11]
phub_termout0[12]
phub_termout0[13]
phub_termout0[14]
phub_termout0[15]
phub_termout1[0]
phub_termout1[1]
phub_termout1[2]
phub_termout1[3]
phub_termout1[4]
phub_termout1[5]
phub_termout1[6]
phub_termout1[7]
phub_termout1[8]
phub_termout1[9]
phub_termout1[10]
phub_termout1[11]
phub_termout1[12]
phub_termout1[13]
phub_termout1[14]
phub_termout1[15]
UDB
udb_intr[0]
udb_intr[1]
udb_intr[2]
udb_intr[3]
udb_intr[4]
udb_intr[5]
udb_intr[6]
udb_intr[7]
udb_intr[8]
udb_intr[9]
udb_intr[10]
udb_intr[11]
udb_intr[12]
udb_intr[13]
udb_intr[14]
udb_intr[15]
udb_intr[16]
udb_intr[17]
udb_intr[18]
udb_intr[19]
udb_intr[20]
udb_intr[21]
udb_intr[22]
udb_intr[23]
udb_intr[24]
udb_intr[25]
udb_intr[26]
udb_intr[27]
udb_intr[28]
udb_intr[29]
udb_intr[30]
udb_intr[31]
Page 18 of 139
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5. Memory
5.1 Static RAM
CY8C58LP static RAM (SRAM) is used for temporary data
storage. Code can be executed at full speed from the portion of
SRAM that is located in the code space. This process is slower
from SRAM above 0x20000000. The device provides up to 64
KB of SRAM. The CPU or the DMA controller can access all of
SRAM. The SRAM can be accessed simultaneously by the
Cortex-M3 CPU and the DMA controller if accessing different
32-KB blocks.
“Device Security” section on page 64). For more information on
how to take full advantage of the security features in PSoC, see
the PSoC 5 TRM.
Table 5-1. Flash Protection
Protection
Setting
Allowed
Not Allowed
Unprotected
External read and write –
+ internal read and write
Factory
Upgrade
External write + internal
read and write
External read
5.2 Flash Program Memory
Field Upgrade Internal read and write
Flash memory in PSoC devices provides nonvolatile storage for
user firmware, user configuration data, bulk data storage, and
optional ECC data. The main flash memory area contains up to
256 KB of user program space.
External read and
write
Full Protection Internal read
External read and
write + internal write
Up to an additional 32 KB of flash space is available for Error
Correcting Codes (ECC). If ECC is not used this space can store
device configuration data and bulk user data. User code may not
be run out of the ECC flash memory section. ECC can correct
one bit error and detect two bit errors per 8 bytes of firmware
memory; an interrupt can be generated when an error is
detected. The flash output is 9 bytes wide with 8 bytes of data
and 1 byte of ECC data.
The CPU or DMA controller read both user code and bulk data
located in flash through the cache controller. This provides
higher CPU performance. If ECC is enabled, the cache controller
also performs error checking and correction.
Flash programming is performed through a special interface and
preempts code execution out of flash. Code execution may be
done out of SRAM during flash programming.
The flash 24programming interface performs flash erasing,
programming and setting code protection levels. Flash in-system
serial programming (ISSP), typically used for production
programming, is possible through both the SWD and JTAG
interfaces. In-system programming, typically used for
bootloaders, is also possible using serial interfaces such as I2C,
USB, UART, and SPI, or any communications protocol.
5.3 Flash Security
All PSoC devices include a flexible flash protection model that
prevents access and visibility to on-chip flash memory. This
prevents duplication or reverse engineering of proprietary code.
Flash memory is organized in blocks, where each block contains
256 bytes of program or data and 32 bytes of ECC or
configuration data.
The device offers the ability to assign one of four protection
levels to each row of flash. Table 5-1 lists the protection modes
available. Flash protection levels can only be changed by
performing a complete flash erase. The Full Protection and Field
Upgrade settings disable external access (through a debugging
tool such as PSoC Creator, for example). If your application
requires code update through a boot loader, then use the Field
Upgrade setting. Use the Unprotected setting only when no
security is needed in your application. The PSoC device also
offers an advanced security feature called Device Security which
permanently disables all test, programming, and debug ports,
protecting your application from external access (see the
Document Number: 001-84932 Rev. *N
Disclaimer
Note the following details of the flash code protection features on
Cypress devices.
Cypress products meet the specifications contained in their
particular Cypress datasheets. Cypress believes that its family
of products is one of the most secure families of its kind on the
market today, regardless of how they are used. There may be
methods, unknown to Cypress, that can breach the code
protection features. Any of these methods, to our knowledge,
would be dishonest and possibly illegal. Neither Cypress nor any
other semiconductor manufacturer can guarantee the security of
their code. Code protection does not mean that we are
guaranteeing the product as “unbreakable.”
Cypress is willing to work with the customer who is concerned
about the integrity of their code. Code protection is constantly
evolving. We at Cypress are committed to continuously
improving the code protection features of our products.
5.4 EEPROM
PSoC EEPROM memory is a byte addressable nonvolatile
memory. The CY8C58LP has 2 KB of EEPROM memory to store
user data. Reads from EEPROM are random access at the byte
level. Reads are done directly; writes are done by sending write
commands to an EEPROM programming interface. CPU code
execution can continue from flash during EEPROM writes.
EEPROM is erasable and writeable at the row level. The
EEPROM is divided into 128 rows of 16 bytes each. The factory
default values of all EEPROM bytes are 0.
Because the EEPROM is mapped to the Cortex-M3 Peripheral
region, the CPU cannot execute out of EEPROM. There is no
ECC hardware associated with EEPROM. If ECC is required it
must be handled in firmware.
It can take as much as 20 milliseconds to write to EEPROM or
flash. During this time the device should not be reset, or
unexpected changes may be made to portions of EEPROM or
flash. Reset sources (see Reset Sources on page 32) include
XRES pin, software reset, and watchdog; care should be taken
to make sure that these are not inadvertently activated. In
addition, the low voltage detect circuits should be configured to
generate an interrupt instead of a reset.
Page 19 of 139
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5.5 Nonvolatile Latches (NVLs)
PSoC has a 4-byte array of nonvolatile latches (NVLs) that are used to configure the device at reset. The NVL register map is shown
in Table 5-3.
Table 5-2. Device Configuration NVL Register Map
Register Address
7
6
5
4
3
2
1
0
0x00
PRT3RDM[1:0]
PRT2RDM[1:0]
PRT1RDM[1:0]
PRT0RDM[1:0]
0x01
PRT12RDM[1:0]
PRT6RDM[1:0]
PRT5RDM[1:0]
PRT4RDM[1:0]
0x02
XRESMEN
0x03
DBGEN
DIG_PHS_DLY[3:0]
PRT15RDM[1:0]
ECCEN
DPS[1:0]
CFGSPEED
The details for individual fields and their factory default settings are shown in Table 5-3:.
Table 5-3. Fields and Factory Default Settings
Field
Description
Settings
PRTxRDM[1:0]
Controls reset drive mode of the corresponding IO port. 00b (default) - high impedance analog
See “Reset Configuration” on page 39. All pins of the port 01b - high impedance digital
are set to the same mode.
10b - resistive pull up
11b - resistive pull down
XRESMEN
0 (default) - GPIO
Controls whether pin P1[2] is used as a GPIO or as an
external reset. P1[2] is generally used as a GPIO, and not 1 - external reset
as an external reset.
DBGEN
Debug Enable allows access to the debug system, for
third-party programmers.
0 - access disabled
1 (default) - access enabled
CFGSPEED
Controls the speed of the IMO-based clock during the
device boot process, for faster boot or low-power
operation
0 (default) - 12 MHz IMO
1 - 48 MHz IMO
DPS[1:0]
Controls the usage of various P1 pins as a debug port.
See “Programming, Debug Interfaces, Resources” on
page 61.
00b - 5-wire JTAG
01b (default) - 4-wire JTAG
10b - SWD
11b - debug ports disabled
ECCEN
Controls whether ECC flash is used for ECC or for general 0 - ECC disabled
configuration and data storage. See “Flash Program
1 (default) - ECC enabled
Memory” on page 19.
DIG_PHS_DLY[3:0]
Selects the digital clock phase delay.
See the TRM for details.
Although PSoC Creator provides support for modifying the device configuration NVLs, the number of NVL erase/write cycles is limited
– see “Nonvolatile Latches (NVL)” on page 117.
Document Number: 001-84932 Rev. *N
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5.6 External Memory Interface
CY8C58LP provides an external memory interface (EMIF) for
connecting to external memory devices. The connection allows
read and write accesses to external memories. The EMIF
operates in conjunction with UDBs, I/O ports, and other
hardware to generate external memory address and control
signals. At 33 MHz, each memory access cycle takes four bus
clock cycles.
Figure 5-1 is the EMIF block diagram. The EMIF supports
synchronous and asynchronous memories. The CY8C58LP only
supports one type of external memory device at a time.
External memory is located in the Cortex-M3 external RAM
space; it can use up to 24 address bits. See Memory Map on
page 22. The memory can be 8 or 16 bits wide.
Cortex-M3 instructions can be fetched from external memory if it
is 16-bit. Other limitations apply; for details, see application note
AN89610, PSoC® 4 and PSoC 5LP Arm Cortex Code
Optimization. There is no provision for code security in external
memory. If code must be kept secure, then it should be placed in
internal flash. See Flash Security on page 19 and Device
Security on page 64.
Figure 5-1. EMIF Block Diagram
Address Signals
External_ MEM_ ADDR[23:0]
I/O
PORTs
Data Signals
External_ MEM_ DATA[15:0]
I/O
PORTs
Control Signals
I/O
PORTs
Data,
Address,
and Control
Signals
IO IF
PHUB
Data,
Address,
and Control
Signals
Control
DSI Dynamic Output
Control
UDB
DSI to Port
Data,
Address,
and Control
Signals
EM Control
Signals
Other
Control
Signals
EMIF
Document Number: 001-84932 Rev. *N
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5.7 Memory Map
Table 5-5. Peripheral Data Address Map (continued)
The Cortex-M3 has a fixed address map, which allows
peripherals to be accessed by simple memory access
instructions.
5.7.1 Address Map
The 4-GB address space is divided into the ranges shown in
Table 5-4:
Table 5-4. Address Map
Address Range
0x00000000–
0x1FFFFFFF
0x20000000–
0x3FFFFFFF
Address Range
Purpose
0x40004F00–0x40004FFF
Fixed timer/counter/PWMs
0x40005000–0x400051FF
I/O ports control
0x40005400–0x400054FF
External Memory Interface
(EMIF) control registers
0x40005800–0x40005FFF
Analog Subsystem Interface
0x40006000–0x400060FF
USB Controller
Size
Use
0x40006400–0x40006FFF
UDB Working Registers
0.5 GB
Program code. This includes
the exception vector table at
power up, which starts at
address 0.
0x40007000–0x40007FFF
PHUB Configuration
0x40008000–0x400087FF
EEPROM
0x4000A000–0x4000A400
CAN
Static RAM. This includes a 1
MByte bit-band region
starting at 0x20000000 and a
32 Mbyte bit-band alias
region starting at
0x22000000.
0x4000C000–0x4000C800
Digital Filter Block
0x40010000–0x4001FFFF
Digital Interconnect Configuration
0x48000000–0x48007FFF
Flash ECC Bytes
0x60000000–0x60FFFFFF
External Memory Interface
(EMIF)
0xE0000000–0xE00FFFFF
Cortex-M3 PPB Registers,
including NVIC, debug, and trace
0.5 GB
0x40000000–
0x5FFFFFFF
0.5 GB
Peripherals.
0x60000000–
0x9FFFFFFF
1 GB
External RAM.
0xA0000000–
0xDFFFFFFF
1 GB
External peripherals.
0xE0000000–
0xFFFFFFFF
0.5 GB
Internal peripherals, including
the NVIC and debug and
trace modules.
Table 5-5. Peripheral Data Address Map
Address Range
0x00000000–0x0003FFFF
Purpose
256 KB flash
The bit-band feature allows individual bits in SRAM to be read or
written as atomic operations. This is done by reading or writing
bit 0 of corresponding words in the bit-band alias region. For
example, to set bit 3 in the word at address 0x20000000, write a
1 to address 0x2200000C. To test the value of that bit, read
address 0x2200000C and the result is either 0 or 1 depending
on the value of the bit.
Most memory accesses done by the Cortex-M3 are aligned, that
is, done on word (4-byte) boundary addresses. Unaligned
accesses of words and 16-bit half-words on nonword boundary
addresses can also be done, although they are less efficient.
0x1FFF8000–0x1FFFFFFF 32 KB SRAM in Code region
5.7.2 Address Map and Cortex-M3 Buses
0x20000000–0x20007FFF
32 KB SRAM in SRAM region
0x40004000–0x400042FF
Clocking, PLLs, and oscillators
The ICode and DCode buses are used only for accesses within
the Code address range, 0–0x1FFFFFFF.
0x40004300–0x400043FF
Power management
0x40004500–0x400045FF
Ports interrupt control
0x40004700–0x400047FF
Flash programming interface
0x40004800–0x400048FF
Cache controller
0x40004900–0x400049FF
I2C controller
0x40004E00–0x40004EFF
Decimator
Document Number: 001-84932 Rev. *N
The System bus is used for data accesses and debug accesses
within
the
ranges
0x20000000–0xDFFFFFFF
and
0xE0100000–0xFFFFFFFF. Instruction fetches can also be
done within the range 0x20000000–0x3FFFFFFF, although
these can be slower than instruction fetches via the ICode bus.
The private peripheral bus (PPB) is used within the Cortex-M3 to
access system control registers and debug and trace module
registers.
Page 22 of 139
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Datasheet
6. System Integration
DSI signal from an external I/O pin or other logic
24- to 80-MHz fractional phase-locked loop (PLL) sourced
from IMO, MHzECO, or DSI
1-kHz, 33-kHz, 100-kHz ILO for watchdog timer (WDT) and
Sleep Timer
32.768-kHz external crystal oscillator (ECO) for RTC
6.1 Clocking System
The clocking system generates, divides, and distributes clocks
throughout the PSoC system. For the majority of systems, no
external crystal is required. The IMO and PLL together can
generate up to a 80 MHz clock, accurate to ±1% over voltage and
temperature. Additional internal and external clock sources allow
each design to optimize accuracy, power, and cost. All of the
system clock sources can be used to generate other clock
frequencies in the 16-bit clock dividers and UDBs for anything
you want, for example a UART baud rate generator.
Clock generation and distribution is automatically configured
through the PSoC Creator IDE graphical interface. This is based
on the complete system’s requirements. It greatly speeds the
design process. PSoC Creator allows designers to build clocking
systems with minimal input. The designer can specify desired
clock frequencies and accuracies, and the software locates or
builds a clock that meets the required specifications. This is
possible because of the programmability inherent in PSoC.
IMO has a USB mode that auto-locks to the USB bus clock
requiring no external crystal for USB. (USB equipped parts
only)
Independently sourced clock in all clock dividers
Eight 16-bit clock dividers for the digital system
Four 16-bit clock dividers for the analog system
Dedicated 16-bit divider for the CPU bus and CPU clock
Automatic clock configuration in PSoC Creator
Key features of the clocking system include:
Seven general purpose clock sources
3- to 74-MHz IMO, ±1% at 3 MHz
4- to 25-MHz external crystal oscillator (MHzECO)
Clock doubler provides a doubled clock frequency output for
the USB block, see USB Clock Domain on page 26.
Table 6-1. Oscillator Summary
Source
Fmin
Tolerance at Fmin
Fmax
Tolerance at Fmax
Startup Time
IMO
3 MHz
±1% over voltage and temperature
74 MHz
±7%
13 µs max
MHzECO
4 MHz
Crystal dependent
25 MHz
Crystal dependent
5 ms typ, max is
crystal dependent
DSI
0 MHz
Input dependent
33 MHz
Input dependent
Input dependent
PLL
24 MHz
Input dependent
80 MHz
Input dependent
250 µs max
Doubler
48 MHz
Input dependent
48 MHz
Input dependent
1 µs max
ILO
1 kHz
–50%, +100%
100 kHz
–55%, +100%
15 ms max in lowest
power mode
kHzECO
32 kHz
Crystal dependent
32 kHz
Crystal dependent
500 ms typ, max is
crystal dependent
Document Number: 001-84932 Rev. *N
Page 23 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Figure 6-1. Clocking Subsystem
3-74 MHz
IMO
4-25 MHz
ECO
External IO
or DSI
0-33 MHz
32 kHz ECO
1,33,100 kHz
ILO
CPU
Clock
48 MHz
Doubler for
USB
24-80 MHz
PLL
System
Clock Mux
Bus
Clock
Bus Clock Divider
16 bit
7
Digital Clock
Divider 16 bit
Digital Clock
Divider 16 bit
Analog Clock
Divider 16 bit
s
k
e
w
Digital Clock
Divider 16 bit
Digital Clock
Divider 16 bit
Analog Clock
Divider 16 bit
s
k
e
w
7
Digital Clock
Divider 16 bit
Digital Clock
Divider 16 bit
Analog Clock
Divider 16 bit
s
k
e
w
Digital Clock
Divider 16 bit
Digital Clock
Divider 16 bit
Analog Clock
Divider 16 bit
s
k
e
w
Document Number: 001-84932 Rev. *N
Page 24 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
6.1.1 Internal Oscillators
Figure 6-1 shows that there are two internal oscillators. They can
be routed directly or divided. The direct routes may not have a
50% duty cycle. Divided clocks have a 50% duty cycle.
6.1.1.1 Internal Main Oscillator
In most designs the IMO is the only clock source required, due
to its ±1% accuracy. The IMO operates with no external
components and outputs a stable clock. A factory trim for each
frequency range is stored in the device. With the factory trim,
tolerance varies from ±1% at 3 MHz, up to ±7% at 74 MHz. The
IMO, in conjunction with the PLL, allows generation of CPU and
system clocks up to the device's maximum frequency (see USB
Clock Domain on page 26). The IMO provides clock outputs at
3, 6, 12, 24, 48, and 74 MHz.
6.1.1.2 Clock Doubler
The clock doubler outputs a clock at twice the frequency of the
input clock. The doubler works at input frequency of 24 MHz,
providing 48 MHz for the USB. It can be configured to use a clock
from the IMO, MHzECO, or the DSI (external pin).
6.1.1.3 Phase-Locked Loop
The PLL allows low frequency, high accuracy clocks to be
multiplied to higher frequencies. This is a tradeoff between
higher clock frequency and accuracy and, higher power
consumption and increased startup time.
The PLL block provides a mechanism for generating clock
frequencies based upon a variety of input sources. The PLL
outputs clock frequencies in the range of 24 to 80 MHz. Its input
and feedback dividers supply 4032 discrete ratios to create
almost any desired system clock frequency. The accuracy of the
PLL output depends on the accuracy of the PLL input source.
The most common PLL use is to multiply the IMO clock at 3 MHz,
where it is most accurate, to generate the CPU and system
clocks up to the device’s maximum frequency.
The central timewheel can be programmed to wake the system
periodically and optionally issue an interrupt. This enables
flexible, periodic wakeups from low power modes or coarse
timing applications. Systems that require accurate timing should
use the RTC capability instead of the central timewheel.
The 100-kHz clock (CLK100K) can be used as a low power
system clock to run the CPU. It can also generate time intervals
using the fast timewheel.
The fast timewheel is a 5-bit counter, clocked by the 100-kHz
clock. It features programmable settings and automatically
resets when the terminal count is reached. An optional interrupt
can be generated each time the terminal count is reached. This
enables flexible, periodic interrupts of the CPU at a higher rate
than is allowed using the central timewheel.
The 33-kHz clock (CLK33K) comes from a divide-by-3 operation
on CLK100K. This output can be used as a reduced accuracy
version of the 32.768-kHz ECO clock with no need for a crystal.
6.1.2 External Oscillators
Figure 6-1 shows that there are two external oscillators. They
can be routed directly or divided. The direct routes may not have
a 50% duty cycle. Divided clocks have a 50% duty cycle.
6.1.2.1 MHz External Crystal Oscillator
The MHzECO provides high frequency, high precision clocking
using an external crystal (see Figure 6-2). It supports a wide
variety of crystal types, in the range of 4 to 25 MHz. When used
in conjunction with the PLL, it can generate CPU and system
clocks up to the device's maximum frequency (see
Phase-Locked Loop on page 25). The GPIO pins connecting to
the external crystal and capacitors are fixed. MHzECO accuracy
depends on the crystal chosen.
Figure 6-2. MHzECO Block Diagram
The PLL achieves phase lock within 250 µs (verified by bit
setting). It can be configured to use a clock from the IMO,
MHzECO, or DSI (external pin). The PLL clock source can be
used until lock is complete and signaled with a lock bit. The lock
signal can be routed through the DSI to generate an interrupt.
Disable the PLL before entering low power modes.
4 - 25 MHz
Crystal Osc
XCLK_MHZ
6.1.1.4 Internal Low-Speed Oscillator
The ILO provides clock frequencies for low power consumption,
including the watchdog timer, and sleep timer. The ILO
generates up to three different clocks: 1 kHz, 33 kHz, and
100 kHz.
The 1-kHz clock (CLK1K) is typically used for a background
‘heartbeat’ timer. This clock inherently lends itself to low power
supervisory operations such as the watchdog timer and long
sleep intervals using the central timewheel (CTW).
The central timewheel is a 1 kHz, free running, 13-bit counter
clocked by the ILO. The central timewheel is always enabled
except in hibernate mode and when the CPU is stopped during
debug on chip mode. It can be used to generate periodic
interrupts for timing purposes or to wake the system from a low
power mode. Firmware can reset the central timewheel.
Document Number: 001-84932 Rev. *N
Xi
(Pin P15[1])
External
Components
Xo
(Pin P15[0])
4 – 25 MHz
crystal
Capacitors
Page 25 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
6.1.2.2 32.768 kHz ECO
The system clock is used to select and supply the fastest clock
The 32.768-kHz external crystal oscillator (32kHzECO) provides
precision timing with minimal power consumption using an
external 32.768-kHz watch crystal (see Figure 6-3). The
32kHzECO also connects directly to the sleep timer and provides
the source for the RTC. The RTC uses a 1 second interrupt to
implement the RTC functionality in firmware.
Bus clock 16-bit divider uses the system clock to generate the
The oscillator works in two distinct power modes. This allows
users to trade off power consumption with noise immunity from
neighboring circuits. The GPIO pins connected to the external
crystal and capacitors are fixed.
Figure 6-3. 32kHzECO Block Diagram
XCLK32K
32 kHz
Crystal Osc
in the system for general system clock requirements and clock
synchronization of the PSoC device.
system’s bus clock used for data transfers and the CPU. The
CPU clock is directly derived from the bus clock.
Eight fully programmable 16-bit clock dividers generate digital
system clocks for general use in the digital system, as
configured by the design’s requirements. Digital system clocks
can generate custom clocks derived from any of the seven
clock sources for any purpose. Examples include baud rate
generators, accurate PWM periods, and timer clocks, and
many others. If more than eight digital clock dividers are
required, the UDBs and fixed function timer/counter/PWMs can
also generate clocks.
Four 16-bit clock dividers generate clocks for the analog system
components that require clocking, such as ADCs and mixers.
The analog clock dividers include skew control to ensure that
critical analog events do not occur simultaneously with digital
switching events. This is done to reduce analog system noise.
Xi
(Pin P15[3])
External
Components
Xo
(Pin P15[2])
32 kHz
crystal
Capacitors
Each clock divider consists of an 8-input multiplexer, a 16-bit
clock divider (divide by 2 and higher) that generates ~50% duty
cycle clocks, system clock resynchronization logic, and deglitch
logic. The outputs from each digital clock tree can be routed into
the digital system interconnect and then brought back into the
clock system as an input, allowing clock chaining of up to 32 bits.
6.1.4 USB Clock Domain
It is recommended that the external 32.768-kHz watch crystal
have a load capacitance (CL) of 6 pF or 12.5 pF. Check the
crystal manufacturer's datasheet. The two external capacitors,
CL1 and CL2, are typically of the same value, and their total
capacitance, CL1CL2 / (CL1 + CL2), including pin and trace
capacitance, should equal the crystal CL value. For more information, refer to application note AN54439: PSoC 3 and PSoC 5
External Oscillators. See also pin capacitance specifications in
the “GPIO” section on page 76.
6.1.2.3 Digital System Interconnect
The DSI provides routing for clocks taken from external clock
oscillators connected to I/O. The oscillators can also be
generated within the device in the digital system and UDBs.
While the primary DSI clock input provides access to all clocking
resources, up to eight other DSI clocks (internally or externally
generated) may be routed directly to the eight digital clock
dividers. This is only possible if there are multiple precision clock
sources.
The USB clock domain is unique in that it operates largely
asynchronously from the main clock network. The USB logic
contains a synchronous bus interface to the chip, while running
on an asynchronous clock to process USB data. The USB logic
requires a 48-MHz frequency. This frequency can be generated
from different sources, including DSI clock at 48 MHz or doubled
value of 24 MHz from internal oscillator, DSI signal, or crystal
oscillator.
6.2 Power System
The power system consists of separate analog, digital, and I/O
supply pins, labeled VDDA, VDDD, and VDDIOX, respectively. It
also includes two internal 1.8 V regulators that provide the digital
(VCCD) and analog (VCCA) supplies for the internal core logic.
The output pins of the regulators (VCCD and VCCA) and the
VDDIO pins must have capacitors connected as shown in
Figure 6-4. The two VCCD pins must be shorted together, with as
short a trace as possible, and connected to a 1 µF ±10% X5R
capacitor. The power system also contains a sleep regulator, an
I2C regulator, and a hibernate regulator.
6.1.3 Clock Distribution
All seven clock sources are inputs to the central clock distribution
system. The distribution system is designed to create multiple
high precision clocks. These clocks are customized for the
design’s requirements and eliminate the common problems
found with limited resolution prescalers attached to peripherals.
The clock distribution system generates several types of clock
trees.
Document Number: 001-84932 Rev. *N
Page 26 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Figure 6-4. PSoC Power System
VDDD
1 µF
VDDIO2
VDDD
I/O Supply
VSSD
VCCD
VDDIO 2
VDDIO0
0.1 µF
0.1 µF
I/O Supply
VDDIO0
0.1 µF
I2C
Regulator
Sleep
Regulator
Digital
Domain
VDDA
VDDA
Digital
Regulators
VSSB
VCCA
Analog
Regulator
0.1 µF
1 µF
.
VSSA
Analog
Domain
0.1 µF
I/O Supply
VDDIO3
VDDD
VSSD
I/O Supply
VCCD
VDDIO1
Hibernate
Regulator
0.1 µF
0.1 µF
VDDIO1
VDDD
VDDIO3
Notes
The two VCCD pins must be connected together with as short a trace as possible. A trace under the device is recommended, as
shown in Figure 2-6.
You can power the device in internally regulated mode, where the voltage applied to the VDDx pins is as high as 5.5 V, and the
internal regulators provide the core voltages. In this mode, do not apply power to the VCCx pins, and do not tie the VDDx pins
to the VCCx pins.
You can also power the device in externally regulated mode, that is, by directly powering the VCCD and VCCA pins. In this configuration,
the VDDD pins should be shorted to the VCCD pins and the VDDA pin should be shorted to the VCCA pin. The allowed supply range
in this configuration is 1.71 V to 1.89 V. After power up in this configuration, the internal regulators are on by default, and should be
disabled to reduce power consumption.
It is good practice to check the datasheets for your bypass capacitors, specifically the working voltage and the DC bias specifications.
With some capacitors, the actual capacitance can decrease considerably when the DC bias (VDDX or VCCX in Figure 6-4) is a
significant percentage of the rated working voltage.
Document Number: 001-84932 Rev. *N
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�PSoC® 5LP: CY8C58LP Family
Datasheet
6.2.1 Power Modes
Active is the main processing mode. Its functionality is
configurable. Each power controllable subsystem is enabled or
disabled by using separate power configuration template
registers. In alternate active mode, fewer subsystems are
enabled, reducing power. In sleep mode most resources are
disabled regardless of the template settings. Sleep mode is
optimized to provide timed sleep intervals and RTC functionality.
The lowest power mode is hibernate, which retains register and
SRAM state, but no clocks, and allows wakeup only from I/O
pins. Figure 6-5 illustrates the allowable transitions between
power modes. Sleep and hibernate modes should not be entered
until all VDDIO supplies are at valid voltage levels.
PSoC 5LP devices have four different power modes, as shown
in Table 6-2 and Table 6-3. The power modes allow a design to
easily provide required functionality and processing power while
simultaneously minimizing power consumption and maximizing
battery life in low power and portable devices.
PSoC 5LP power modes, in order of decreasing power
consumption are:
Active
Alternate active
Sleep
Hibernate
Table 6-2. Power Modes
Power Modes
Description
Entry Condition Wakeup Source
Active Clocks
Regulator
Active
Primary mode of operation, all Wakeup, reset,
peripherals available (program- manual register
mable)
entry
Any interrupt
Any (programmable)
All regulators available.
Digital and analog
regulators can be disabled
if external regulation used.
Alternate
Active
Manual register
Similar to Active mode, and is
entry
typically configured to have
fewer peripherals active to
reduce power. One possible
configuration is to use the UDBs
for processing, with the CPU
turned off
Any interrupt
Any (programmable)
All regulators available.
Digital and analog
regulators can be disabled
if external regulation used.
Sleep
All subsystems automatically
disabled
Comparator,
ILO/kHzECO
PICU, I2C, RTC,
CTW, LVD
Both digital and analog
regulators buzzed.
Digital and analog
regulators can be disabled
if external regulation used.
Hibernate
Manual register
All subsystems automatically
entry
disabled
Lowest power consuming mode
with all peripherals and internal
regulators disabled, except
hibernate regulator is enabled
Configuration and memory
contents retained
PICU
Only hibernate regulator
active.
Manual register
entry
Table 6-3. Power Modes Wakeup Time and Power Consumption
Sleep
Modes
Wakeup
Time
Current
(Typ)
Code
Execution
Digital
Resources
Analog
Resources
Clock Sources
Available
Wakeup Sources
Reset
Sources
Active
–
3.1 mA[8]
Yes
All
All
All
–
All
Alternate
Active
–
–
User
defined
All
All
All
–
All
3.6 V
Current consumption while device programming. Sum of
digital, analog, and I/Os: IDDD + IDDA + IDDIOX.
Figure 11-1. Active Mode Current vs FCPU, VDD = 3.3 V,
Temperature = 25 °C
mA
mA
mA
mA
mA
Figure 11-2. IDD vs Frequency at 25 °C
0.7
25
0.6
0.5
IDD, mA
A/MHz
20
Curren
nt, mA
Typ
T = –40 °C
T = 25 °C
T = 85 °C
T = 105 °C
T = –40 °C
T = 25 °C
T = 85 °C
T = 105 °C
T = –40 °C
T = 25 °C
T = 85 °C
T = 105 °C
Hibernate mode current
VDD = VDDIO =
All regulators and oscillators off.
2.7–3.6 V
SRAM retention
GPIO interrupts are active
Boost = OFF
SIO pins in single ended input, unregulated output mode
VDD = VDDIO =
1.71–1.95 V
IDDAR[27]
Min
15
10
0.4
0.3
0.2
0.1
Ϯϰ�D,nj�ŶŽŶͲh^��ŵŽĚĞ
5
0
0
0
0
20
40
60
20
80
40
60
80
Bus Clock, MHz
CPU Frequency, MHz
Figure 11-3. Active Mode Current vs Temperature and FCPU,
VDD = 3.3 V
Figure 11-4. Active Mode Current vs VDD and Temperature,
FCPU = 24 MHz
10
25
8
20
105 °C
Current, mA
Current, mA
80 MHz
24 MHz
15
6 MHz
MH
10
5
6
25 °C
-40 °C
4
2
0
0
-40
-20
0
20
40
60
Temperature, °C
80
100
1.5
2
2.5
3
3.5
4
4.5
5
5.5
VDD, V
Notes
26. The current consumption of additional peripherals that are implemented only in programmed logic blocks can be found in their respective datasheets, available in
PSoC Creator, the integrated design environment. To estimate total current, find CPU current at frequency of interest and add peripheral currents for your particular
system from the device datasheet and component datasheets.
27. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 70 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Table 11-3. AC Specifications
Parameter
Description
Conditions
1.71 V ≤ VDDD ≤ 5.5 V
1.71 V ≤ VDDD ≤ 5.5 V
FCPU
FBUSCLK
SVDD[28]
TIO_INIT[28]
CPU frequency
Bus frequency
VDD ramp rate
Time from VDDD/VDDA/VCCD/VCCA ≥ IPOR to
I/O ports set to their reset states
TSTARTUP[28]
Time from VDDD/VDDA/VCCD/VCCA ≥ PRES VCCA/VDDA = regulated from
to CPU executing code at reset vector
VDDA/VDDD, no PLL used, fast IMO
boot mode (48 MHz typ.)
VCCA/VCCD = regulated from
VDDA/VDDD, no PLL used, slow IMO
boot mode (12 MHz typ.)
[28]
Wakeup from sleep mode –
TSLEEP
Application of non-LVD interrupt to beginning
of execution of next CPU instruction
THIBERNATE[28] Wakeup from hibernate mode – Application
of external interrupt to beginning of
execution of next CPU instruction
Min
DC
DC
–
–
Typ
–
–
–
–
Max
80.01
80.01
0.066
10
Units
MHz
MHz
V/µs
µs
–
–
33
µs
–
–
66
µs
–
–
25
µs
–
–
150
µs
11.3 Power Regulators
Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except where noted. Specifications are valid for 1.71 V to 5.5 V,
except where noted.
11.3.1 Digital Core Regulator
Table 11-4. Digital Core Regulator DC Specifications
Parameter
Description
Input voltage
VDDD
Output voltage
VCCD
Regulator output capacitor
Conditions
±10%, X5R ceramic or better. The two VCCD
pins must be shorted together, with as short
a trace as possible, see “Power System”
section on page 26
Figure 11-5. Analog and Digital Regulators, VCC vs VDD,
10 mA Load
Min
1.8
–
0.9
Typ
–
1.80
1
Max
5.5
–
1.1
Units
V
V
µF
Figure 11-6. Digital Regulator PSRR vs Frequency and VDD
100
PSRR
R, dB
80
60
Vdd=4.5V
40
Vdd=3.6V
20
Vdd=2.7V
0
0.1
1
10
100
1000
Frequency, kHz
Note
28. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 71 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
11.3.2 Analog Core Regulator
Table 11-5. Analog Core Regulator DC Specifications
Parameter
Description
Input voltage
VDDA
VCCA
Output voltage
Regulator output capacitor
Conditions
Min
1.8
–
0.9
±10%, X5R ceramic or better
Typ
–
1.80
1
Max
5.5
–
1.1
Units
V
V
µF
Figure 11-7. Analog Regulator PSRR vs Frequency and VDD
100
PSRR
R, dB
80
60
40
Vdd=4.5V
Vdd=3.6V
20
Vdd=2.7V
0
0.1
1
10
100
1000
Frequency, KHz
11.3.3 Inductive Boost Regulator
Unless otherwise specified, operating conditions are: VBAT = 0.5 V–3.6 V, VOUT = 1.8 V–5.0 V, IOUT = 0 mA–50 mA,
LBOOST = 4.7 µH–22 µH, CBOOST = 22 µF || 3 × 1.0 µF || 3 × 0.1 µF, CBAT = 22 µF, IF = 1.0 A. Unless otherwise specified, all charts
and graphs show typical values.
Table 11-6. Inductive Boost Regulator DC Specifications
Parameter
Description
voltage[29]
VOUT
Boost output
VBAT
Input voltage to boost[30]
Document Number: 001-84932 Rev. *N
Conditions
Min
Typ
Max
Units
vsel = 1.8 V in register BOOST_CR0
vsel = 1.9 V in register BOOST_CR0
vsel = 2.0 V in register BOOST_CR0
vsel = 2.4 V in register BOOST_CR0
vsel = 2.7 V in register BOOST_CR0
vsel = 3.0 V in register BOOST_CR0
vsel = 3.3 V in register BOOST_CR0
vsel = 3.6 V in register BOOST_CR0
vsel = 5.0 V in register BOOST_CR0
IOUT = 0 mA–5 mA vsel = 1.8 V–2.0 V,
TA = 0 °C–70 °C
1.71
1.81
1.90
2.16
2.43
2.70
2.97
3.24
4.50
0.5
1.8
1.90
2.00
2.40
2.70
3.00
3.30
3.60
5.00
–
1.89
2.00
2.10
2.64
2.97
3.30
3.63
3.96
5.50
0.8
V
V
V
V
V
V
V
V
V
V
IOUT = 0 mA–15 mA vsel = 1.8 V–5.0 V[31],
TA = –10 °C–85 °C
1.6
–
3.6
V
IOUT = 0 mA–25 mA vsel = 1.8 V–2.7 V,
TA = –10 °C–85 °C
0.8
–
1.6
V
IOUT = 0 mA–50 mA vsel = 1.8 V–3.3 V[31],
TA = –40 °C–85 °C
1.8
–
2.5
V
vsel = 1.8 V–3.3 V[31],
TA = –10 °C–85 °C
1.3
–
2.5
V
vsel = 2.5 V–5.0 V[31],
TA = –10 °C–85 °C
2.5
–
3.6
V
Page 72 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Table 11-6. Inductive Boost Regulator DC Specifications (continued)
Parameter
IOUT
Description
Output current
Conditions
Min
Typ
Max
Units
TA = 0 °C–70 °C
VBAT = 0.5 V–0.8 V
0
–
5
mA
TA = –10 °C–85 °C
VBAT = 1.6 V–3.6 V
0
–
15
mA
VBAT = 0.8 V–1.6 V
0
–
25
mA
VBAT = 1.3 V–2.5 V
0
–
50
mA
VBAT = 2.5 V–3.6 V
0
–
50
mA
TA = –40 °C–85 °C
0
–
50
mA
–
–
700
mA
–
–
250
25
–
–
µA
µA
Load regulation
–
–
10
%
Line regulation
–
–
10
%
ILPK
Inductor peak current
IQ
Quiescent current
RegLOAD
RegLINE
VBAT = 1.8 V–2.5 V
Boost active mode
Boost sleep mode, IOUT < 1 µA
Notes
29. Listed vsel options are characterized. Additional VSEL options are valid and guaranteed by design.
30. The boost will start at all valid VBAT conditions including down to VBAT = 0.5 V.
31. If VBAT is greater than or equal to VOUT boost setting, then VOUT will be less than VBAT due to resistive losses in the boost circuit.
Document Number: 001-84932 Rev. *N
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�PSoC® 5LP: CY8C58LP Family
Datasheet
Table 11-7. Recommended External Components for Boost Circuit
Parameter
LBOOST
Description
Conditions
Boost inductor
Min
Typ
Max
Units
4.7 µH nominal
3.7
4.7
5.7
µH
10 µH nominal
8.0
10.0
12.0
µH
17.0
22.0
27.0
µH
CBOOST
Total capacitance sum of
VDDD, VDDA, VDDIO[32]
22 µH nominal
17.0
26.0
31.0
µF
CBAT
Battery filter capacitor
17.0
22.0
27.0
µF
IF
Schottky diode average
forward current
1.0
–
–
A
VR
Schottky reverse voltage
20.0
–
–
V
Figure 11-8. TA range over VBAT and VOUT
Figure 11-9. IOUT range over VBAT and VOUT
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Figure 11-10. LBOOST values over VBAT and VOUT
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����+
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,287 � ����P$������+�����+�
,287 � ����P$������+�
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����+
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Note
32. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
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�PSoC® 5LP: CY8C58LP Family
Datasheet
Figure 11-11. Efficiency vs VBAT, LBOOST = 4.7 µH [33]
Figure 11-12. Efficiency vs VBAT, LBOOST = 10 µH [33]
100%
95%
Vout = 1.8 V
95%
90%
Vout = 2.4 V
90%
85%
Vout = 3.3 V
85%
80%
% Efficiency
% Efficiency
100%
Vout = 5.0 V
80%
75%
Vout = 1.8 V
70%
Vout = 2.4 V
65%
65%
Vout = 3
3.3
3V
60%
60%
Vout = 5.0 V
55%
55%
75%
70%
50%
50%
0
0.5
1
1.5
2
2.5
3
3.5
0
4
0.5
1
1.5
2
2.5
3
3.5
4
VBAT, V
VBAT, V
Figure 11-13. Efficiency vs VBAT, LBOOST = 22 µH [33]
Figure 11-14. VRIPPLE vs VBAT [33]
100%
300
95%
250
90%
200
VRIPPLE, mV
% Efficiency
85%
80%
Vout = 1.8 V
75%
Vout = 2.4 V
70%
150
Lboost = 4.7 uH
100
Lboost = 10 uH
Vout = 3.3 V
65%
Lboost = 22 uH
50
60%
55%
0
0
50%
0
0.5
1
1.5
2
2.5
3
3.5
4
0.5
1
1.5
2
2.5
3
3.5
4
VBAT, V
VBAT, V
Note
33. Typical example. Actual values may vary depending on external component selection, PCB layout, and other design parameters.
Document Number: 001-84932 Rev. *N
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�PSoC® 5LP: CY8C58LP Family
Datasheet
11.4 Inputs and Outputs
Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except where noted. Specifications are valid for 1.71 V to 5.5 V,
except where noted. Unless otherwise specified, all charts and graphs show typical values.
When the power supplies ramp up, the pin voltages are indeterminate until both VDDIO and VDDA reach the IPOR voltage, which can
be as high as 1.45 V. At that point, the pins change to their normal NVL settings.
11.4.1 GPIO
Table 11-8. GPIO DC Specifications
Min
Typ
Max
Units
VIH
Parameter
Input voltage high threshold
CMOS Input, PRT[x]CTL = 0
0.7 × VDDIO
–
–
V
VIL
Input voltage low threshold
CMOS Input, PRT[x]CTL = 0
–
–
0.3 ×
VDDIO
V
VIH
Input voltage high threshold
LVTTL Input, PRT[x]CTL = 1, VDDIO < 2.7 V 0.7 x VDDIO
–
–
V
VIH
Input voltage high threshold
LVTTL Input, PRT[x]CTL = 1, VDDIO ≥ 2.7 V
2.0
–
–
V
VIL
Input voltage low threshold
LVTTL Input, PRT[x]CTL = 1, VDDIO < 2.7 V
–
–
0.3 x
VDDIO
V
VIL
Input voltage low threshold
LVTTL Input, PRT[x]CTL = 1, VDDIO ≥ 2.7 V
–
–
0.8
V
VOH
Output voltage high
IOH = 4 mA at 3.3 VDDIO
VDDIO – 0.6
–
–
V
IOH = 1 mA at 1.8 VDDIO
VDDIO – 0.5
–
–
V
VOL
Output voltage low
IOL = 8 mA at 3.3 VDDIO
–
–
0.6
V
IOL = 3 mA at 3.3 VDDIO
–
–
0.4
V
IOL = 4 mA at 1.8 VDDIO
–
–
0.6
V
3.5
5.6
8.5
kΩ
3.5
5.6
8.5
kΩ
Rpullup
Description
Conditions
Pull-up resistor
Rpulldown Pull-down resistor
IIL
Input leakage current (absolute
value)[34]
25 °C, VDDIO = 3.0 V
–
–
2
nA
CIN
Input capacitance[34]
P0.0, P0.1, P0.2, P3.6, P3.7
–
17
20
pF
P0.3, P0.4, P3.0, P3.1, P3.2
–
10
15
pF
P0.6, P0.7, P15.0, P15.6,
All other GPIOs
P15.7[35]
–
7
12
pF
–
5
9
pF
VH
Input voltage hysteresis
(Schmitt-Trigger)[34]
–
40
–
mV
Idiode
Current through protection diode
to VDDIO and VSSIO
–
–
100
µA
Rglobal
Resistance pin to analog global 25 °C, VDDIO = 3.0 V
bus
–
320
–
Ω
Rmux
Resistance pin to analog mux bus 25 °C, VDDIO = 3.0 V
–
220
–
Ω
Notes
34. Based on device characterization (Not production tested).
35. For information on designing with PSoC oscillators, refer to the application note, AN54439 - PSoC® 3 and PSoC 5 External Oscillator.
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Datasheet
Figure 11-15. GPIO Output High Voltage and Current
Figure 11-16. GPIO Output Low Voltage and Current
Table 11-9. GPIO AC Specifications[36]
Parameter
Description
Conditions
Min
Typ
Max
Units
TriseF
Rise time in Fast Strong Mode
3.3 V VDDIO Cload = 25 pF
–
–
6
ns
TfallF
Fall time in Fast Strong Mode
3.3 V VDDIO Cload = 25 pF
–
–
6
ns
TriseS
Rise time in Slow Strong Mode
3.3 V VDDIO Cload = 25 pF
–
–
60
ns
TfallS
Fall time in Slow Strong Mode
3.3 V VDDIO Cload = 25 pF
–
–
60
ns
90/10% VDDIO into 25 pF
–
–
33
MHz
1.71 V < VDDIO < 2.7 V, fast strong drive mode
90/10% VDDIO into 25 pF
–
–
20
MHz
3.3 V < VDDIO < 5.5 V, slow strong drive mode
90/10% VDDIO into 25 pF
–
–
7
MHz
1.71 V < VDDIO < 3.3 V, slow strong drive mode 90/10% VDDIO into 25 pF
–
–
3.5
MHz
GPIO input operating frequency
–
–
33
MHz
GPIO output operating frequency
2.7 V < VDDIO < 5.5 V, fast strong drive mode
Fgpioout
Fgpioin
90/10% VDDIO
Note
36. Based on device characterization (Not production tested).
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�PSoC® 5LP: CY8C58LP Family
Datasheet
11.4.2 SIO
Table 11-10. SIO DC Specifications
Parameter
Description
Vinmax
Maximum input voltage
Vinref
Input voltage reference (differential
input mode)
Conditions
Min
Typ
Max
Units
–
–
5.5
V
0.5
–
0.52 × VDDIO
V
VDDIO > 3.7
1
–
VDDIO – 1
V
VDDIO < 3.7
1
–
VDDIO – 0.5
V
CMOS input
0.7 × VDDIO
–
–
V
SIO_ref + 0.2
–
–
V
All allowed values of Vddio and
VDDD, see Absolute Maximum
Ratings on page 67
Output voltage reference (regulated output mode)
Voutref
Input voltage high threshold
VIH
GPIO mode
Differential input
mode[37]
Hysteresis disabled
Input voltage low threshold
VIL
GPIO mode
CMOS input
–
–
0.3 × VDDIO
V
Differential input mode[37]
Hysteresis disabled
–
–
SIO_ref – 0.2
V
VDDIO – 0.4
–
–
V
IOH = 1 mA
SIO_ref – 0.65
–
SIO_ref + 0.2
V
IOH = 0.1 mA
SIO_ref – 0.3
–
SIO_ref + 0.2
V
no load, IOH = 0
SIO_ref – 0.1
–
SIO_ref + 0.1
V
–
–
0.8
V
Output voltage high
Unregulated mode
VOH
VOL
Regulated
mode[37]
Output voltage low
IOH = 4 mA, VDDIO = 3.3 V
VDDIO = 3.30 V, IOL = 25 mA
VDDIO = 3.30 V, IOL = 20 mA
–
–
0.4
V
VDDIO = 1.80 V, IOL = 4 mA
–
–
0.4
V
Rpullup
Pull-up resistor
3.5
5.6
8.5
kΩ
Rpulldown
Pull-down resistor
3.5
5.6
8.5
kΩ
IIL
Input leakage current (absolute
value)[38]
VIH < Vddsio
25 °C, Vddsio = 3.0 V, VIH = 3.0 V
–
–
14
nA
VIH > Vddsio
25 °C, Vddsio = 0 V, VIH = 3.0 V
–
–
10
µA
–
–
9
pF
Single ended mode (GPIO mode)
–
115
–
mV
Differential mode
–
50
–
mV
–
–
100
µA
CIN
Input Capacitance[38]
VH
Input voltage hysteresis
(Schmitt-Trigger)[38]
Idiode
Current through protection diode to
VSSIO
Notes
37. See Figure 6-9 on page 35 and Figure 6-12 on page 38 for more information on SIO reference.
38. Based on device characterization (Not production tested).
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Datasheet
Figure 11-17. SIO Output High Voltage and Current,
Unregulated Mode
Figure 11-18. SIO Output Low Voltage and Current,
Unregulated Mode
Figure 11-19. SIO Output High Voltage and Current,
Regulated Mode
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Datasheet
Table 11-11 SIO AC Specifications[39]
Parameter
Description
Conditions
Min
Typ
Max
Units
TriseF
Rise time in fast strong mode
(90/10%)
Cload = 25 pF, VDDIO = 3.3 V
–
–
12
ns
TfallF
Fall time in fast strong mode
(90/10%)
Cload = 25 pF, VDDIO = 3.3 V
–
–
12
ns
TriseS
Rise time in slow strong mode
(90/10%)
Cload = 25 pF, VDDIO = 3.0 V
–
–
75
ns
TfallS
Fall time in slow strong mode
(90/10%)
Cload = 25 pF, VDDIO = 3.0 V
–
–
60
ns
2.7 V < VDDIO < 5.5 V, Unregulated output (GPIO) mode, fast
strong drive mode
90/10% VDDIO into 25 pF
–
–
33
MHz
1.71 V < VDDIO < 2.7 V, Unregulated output (GPIO) mode, fast
strong drive mode
90/10% VDDIO into 25 pF
–
–
16
MHz
3.3 V < VDDIO < 5.5 V, Unregulated output (GPIO) mode, slow
strong drive mode
90/10% VDDIO into 25 pF
–
–
5
MHz
1.71 V < VDDIO < 3.3 V, Unregulated output (GPIO) mode, slow
strong drive mode
90/10% VDDIO into 25 pF
–
–
4
MHz
2.7 V < VDDIO < 5.5 V, Regulated Output continuously switching into
25 pF
output mode, fast strong drive
mode
–
–
20
MHz
1.71 V < VDDIO < 2.7 V, Regulated Output continuously switching into
output mode, fast strong drive
25 pF
mode
–
–
10
MHz
1.71 V < VDDIO < 5.5 V, Regulated Output continuously switching into
output mode, slow strong drive
25 pF
mode
–
–
2.5
MHz
–
–
33
MHz
SIO output operating frequency
Fsioout
Fsioin
SIO input operating frequency
1.71 V < VDDIO < 5.5 V
90/10% VDDIO
Note
39. Based on device characterization (Not production tested).
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�PSoC® 5LP: CY8C58LP Family
Datasheet
Figure 11-20. SIO Output Rise and Fall Times, Fast Strong
Mode, VDDIO = 3.3 V, 25 pF Load
Figure 11-21. SIO Output Rise and Fall Times, Slow Strong
Mode, VDDIO = 3.3 V, 25 pF Load
Table 11-12. SIO Comparator Specifications[40]
Parameter
Vos
Description
Offset voltage
TCVos
Offset voltage drift with temp
CMRR
Common mode rejection ratio
Tresp
Response time
Document Number: 001-84932 Rev. *N
Conditions
Min
Typ
Max
Units
mV
VDDIO = 2 V
–
–
68
VDDIO = 2.7 V
–
–
72
VDDIO = 5.5 V
–
–
82
–
–
250
μV/°C
VDDIO = 2 V
30
–
–
dB
VDDIO = 2.7 V
35
–
–
VDDIO = 5.5 V
40
–
–
–
–
30
ns
Page 81 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
11.4.3 USBIO
For operation in GPIO mode, the standard range for VDDD applies, see Device Level Specifications on page 68.
Table 11-13. USBIO DC Specifications
Min
Typ
Max
Units
Rusbi
Parameter
USB D+ pull-up resistance[40]
With idle bus
0.900
–
1.575
kΩ
Rusba
USB D+ pull-up resistance[40]
While receiving traffic
1.425
–
3.090
kΩ
Vohusb
Static output high[40]
15 kΩ ±5% to Vss, internal pull-up
enabled
2.8
–
3.6
V
Volusb
Static output low[40]
15 kΩ ±5% to Vss, internal pull-up
enabled
–
–
0.3
V
Vihgpio
Input voltage high, GPIO mode[40]
VDDD = 1.8 V
1.5
–
–
V
VDDD = 3.3 V
2
–
–
V
Vilgpio
Vohgpio
Volgpio
Vdi
Description
Input voltage low, GPIO mode[40]
Output voltage high, GPIO mode[40]
Output voltage low, GPIO mode[40]
Differential input sensitivity
Conditions
VDDD = 5.0 V
2
–
–
V
VDDD = 1.8 V
–
–
0.8
V
VDDD = 3.3 V
–
–
0.8
V
VDDD = 5.0 V
–
–
0.8
V
IOH = 4 mA, VDDD = 1.8 V
1.6
–
–
V
IOH = 4 mA, VDDD = 3.3 V
3.1
–
–
V
IOH = 4 mA, VDDD = 5.0 V
4.2
–
–
V
IOL = 4 mA, VDDD = 1.8 V
–
–
0.3
V
IOL = 4 mA, VDDD = 3.3 V
–
–
0.3
V
IOL = 4 mA, VDDD = 5.0 V
–
–
0.3
V
|(D+)–(D–)|
–
–
0.2
V
Vcm
Differential input common mode range
0.8
–
2.5
V
Vse
Single ended receiver threshold
0.8
–
2
V
Rps2
PS/2 pull-up resistance[40]
In PS/2 mode, with PS/2 pull-up
enabled
3
–
7
kΩ
Rext
External USB series resistor[40]
In series with each USB pin
21.78
(–1%)
22
22.22
(+1%)
Ω
Zo
USB driver output impedance[40]
Including Rext
28
–
44
Ω
CIN
USB transceiver input capacitance
–
–
20
pF
–
–
2
nA
IIL[40]
Input leakage current (absolute value)[40]
25 °C, VDDD = 3.0 V
Note
40. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 82 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Figure 11-22. USBIO Output High Voltage and Current,
GPIO Mode
Figure 11-23. USBIO Output Rise and Fall Times, GPIO Mode,
VDDD = 3.3 V, 25 pF Load
Table 11-14. USBIO AC Specifications[41]
Parameter
Description
Conditions
Min
Typ
Max
Units
Tdrate
Full-speed data rate average bit rate
12 – 0.25%
12
12 +
0.25%
MHz
Tjr1
Receiver data jitter tolerance to next
transition
–8
–
8
ns
Tjr2
Receiver data jitter tolerance to pair
transition
–5
–
5
ns
Tdj1
Driver differential jitter to next transition
–3.5
–
3.5
ns
Tdj2
Driver differential jitter to pair transition
–4
–
4
ns
Tfdeop
Source jitter for differential transition to
SE0 transition
–2
–
5
ns
Tfeopt
Source SE0 interval of EOP
160
–
175
ns
Tfeopr
Receiver SE0 interval of EOP
82
–
–
ns
Tfst
Width of SE0 interval during differential
transition
–
–
14
ns
Fgpio_out
GPIO mode output operating frequency 3 V ≤ VDDD ≤ 5.5 V
–
–
20
MHz
–
–
6
MHz
VDDD = 1.71 V
Tr_gpio
Rise time, GPIO mode, 10%/90% VDDD VDDD > 3 V, 25 pF load
VDDD = 1.71 V, 25 pF load
Tf_gpio
Fall time, GPIO mode, 90%/10% VDDD VDDD > 3 V, 25 pF load
VDDD = 1.71 V, 25 pF load
–
–
12
ns
–
–
40
ns
–
–
12
ns
–
–
40
ns
Note
41. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
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Datasheet
Figure 11-24. USBIO Output Low Voltage and Current,
GPIO Mode
Table 11-15. USB Driver AC Specifications[42]
Parameter
Description
Conditions
Min
Typ
Max
Units
Tr
Transition rise time
–
–
20
ns
Tf
Transition fall time
–
–
20
ns
TR
Rise/fall time matching
90%
–
111%
Vcrs
Output signal crossover voltage
1.3
–
2
V
Min
Typ
Max
Units
VUSB_5, VUSB_3.3, see USB DC
Specifications on page 114
11.4.4 XRES
Table 11-16. XRES DC Specifications
Parameter
Description
Conditions
VIH
Input voltage high threshold
0.7 × VDDIO
–
–
V
VIL
Input voltage low threshold
–
–
0.3 × VDDIO
V
8.5
kΩ
Rpullup
Pull-up resistor
3.5
5.6
CIN
Input capacitance[42]
–
3
VH
Input voltage hysteresis
(Schmitt-Trigger)[42]
–
100
–
mV
Idiode
Current through protection diode to
VDDIO and VSSIO
–
–
100
µA
Min
Typ
Max
Units
1
–
–
µs
pF
Table 11-17. XRES AC Specifications[42]
Parameter
TRESET
Description
Reset pulse width
Conditions
Note
42. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 84 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
11.5 Analog Peripherals
Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except where noted. Specifications are valid for 1.71 V to 5.5 V,
except where noted.
11.5.1 Opamp
Table 11-18. Opamp DC Specifications
Parameter
Description
VI
Input voltage range
Vos
Input offset voltage
TCVos
Conditions
Input offset voltage drift with temperature
Min
Typ
Max
Units
VSSA
–
VDDA
V
–
–
2.5
mV
Operating temperature –40 °C to
70 °C
–
–
2
mV
Power mode = high
–
–
±30
µV / °C
Ge1
Gain error, unity gain buffer mode
Rload = 1 kΩ
–
–
±0.1
%
Cin
Input capacitance
Routing from pin
–
–
18
pF
Vo
Output voltage range
1 mA, source or sink, power mode VSSA + 0.05
= high
Iout
Output current capability, source or sink VSSA + 500 mV ≤ VOUT ≤ VDDA
–500 mV, VDDA > 2.7 V
25
–
–
mA
VSSA + 500 mV ≤ VOUT ≤ VDDA
–500 mV, 1.7 V = VDDA ≤ 2.7 V
16
–
–
mA
Power mode = min
–
250
400
uA
Power mode = low
–
250
400
uA
Power mode = med
–
330
950
uA
Quiescent current[43]
Idd
Power mode = high
Common mode rejection ratio[43]
CMRR
PSRR
Power supply rejection
IIB
Input bias
ratio[43]
current[43]
–
VDDA –
0.05
V
–
1000
2500
uA
80
–
–
dB
VDDA ≥ 2.7 V
85
–
–
dB
VDDA < 2.7 V
70
–
–
dB
25 °C
–
10
–
pA
Figure 11-25. Opamp Vos Histogram, 7020 samples/1755
parts, 30 °C, VDDA = 3.3 V
Figure 11-26. Opamp Vos vs Temperature, VDDA = 5 V
0.2
20
18
0.1
16
Vos, mV
14
%
12
10
8
0
-0.1
6
-0.2
4
2
-0.3
0.5
0.4
0.3
0.2
0.1
0
-0.1
-0.2
-0.3
-0.4
-0.5
0
-40
-20
0
20
40
60
80
100
Temperature, °C
Vos, mV
Note
43. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 85 of 139
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Datasheet
Figure 11-27. Opamp Vos vs Vcommon and VDDA, 25 °C
Figure 11-28. Opamp Output Voltage vs Load Current and
Temperature, High Power Mode, 25 °C, Vdda = 2.7 V
3
0.3
2.5
0.25
2
Vdda = 5
5.5
5V
0 15
0.15
Vdda = 2.7 V
0.1
Vdda = 1.7 V
0.05
Vo
out, V
Vos, mV
0.2
Vin = 2.7 V
1.5
Vin = 0 V
1
0.5
0
0
1
2
3
4
5
6
Vcommon, V
0
0
5
10
15
Iload, Source / Sink, mA
20
25
Figure 11-29. Opamp Operating Current vs Vdda and Power
Mode
1
Current, mA
0.8
0.6
0.4
0.2
0
1
2
High Power Mode
3
VDDA, V
Medium
Document Number: 001-84932 Rev. *N
4
5
Low, Minimum
Page 86 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Table 11-19. Opamp AC Specifications[44]
Parameter
Description
GBW
Gain-bandwidth product
SR
Slew rate, 20% - 80%
en
Input noise density
Conditions
Power mode = minimum, 15 pF load
Power mode = low, 15 pF load
Power mode = medium, 200 pF load
Power mode = high, 200 pF load
Power mode = minimum, 15 pF load
Power mode = low, 15 pF load
Power mode = medium, 200 pF load
Power mode = high, 200 pF load
Power mode = high, Vdda = 5 V, at
100 kHz
Figure 11-30. Opamp Noise vs Frequency, Power Mode =
High, Vdda = 5V
Typ
–
–
–
–
–
–
–
–
45
Max
–
–
–
–
–
–
–
–
–
Units
MHz
MHz
MHz
MHz
V/µs
V/µs
V/µs
V/µs
nV/sqrtHz
Figure 11-31. Opamp Step Response, Rising
1.2
Input and Outp
put Signals, V
1000
nV/sq
qrtHz
Min
1
2
1
3
1.1
1.1
0.9
3
–
100
1
0.8
06
0.6
Input
0.4
Output
0.2
0
10
0.01
0.1
1
10
100
1000
Frequency, kHz
-1
-0.5
0
Time, μs
0.5
1
Figure 11-32. Opamp Step Response, Falling
Input and Outpu
ut Signals, V
1.2
1
0.8
Input
p
06
0.6
Output
0.4
0.2
0
-1
-0.5
0
Time, μs
0.5
1
Note
44. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 87 of 139
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Datasheet
11.5.2 Delta-Sigma ADC
Unless otherwise specified, operating conditions are:
Operation in continuous sample mode
fclk = 3.072 MHz for resolution = 16 to 20 bits; fclk = 6.144 MHz for resolution = 8 to 15 bits
Reference = 1.024 V internal reference bypassed on P3.2 or P0.3
Unless otherwise specified, all charts and graphs show typical values
Table 11-20. 20-bit Delta-sigma ADC DC Specifications
Parameter
Description
Conditions
Resolution
Number of channels, single ended
Min
Typ
Max
Units
8
–
20
bits
–
–
No. of
GPIO
–
Number of channels, differential
Differential pair is formed using a
pair of GPIOs.
–
–
No. of
GPIO/2
–
Monotonic
Yes
–
–
–
–
Ge
Gain error
Buffered, buffer gain = 1, Range =
±1.024 V, 16-bit mode, 25 °C
–
–
±0.4
%
Gd
Gain drift
Buffered, buffer gain = 1, Range =
±1.024 V, 16-bit mode
–
–
50
ppm/°
C
Buffered, 16-bit mode, full voltage
range
–
–
±0.2
mV
Buffered, 16-bit mode,
VDDA = 1.8 V ±5%, 25 °C
–
–
±0.1
mV
Buffer gain = 1, 16-bit,
Range = ±1.024 V
–
–
1
µV/°C
VSSA
–
VDDA
V
Input voltage range, differential unbuffered[45]
VSSA
–
VDDA
V
Input voltage range, differential,
buffered[45]
VSSA
–
VDDA – 1
V
90
–
–
dB
85
–
–
80
–
–
Vos
TCVos
Input offset voltage
Temperature coefficient, input offset
voltage
Input voltage range, single
ended[45]
Buffer gain = 1, 16-bit,
Range = ±1.024 V
PSRRb
Power supply rejection ratio, buffered[45]
CMRRb
Buffer gain = 1, 16 bit,
Common mode rejection ratio, buffered[45] Range = ±1.024 V
TA ≤ 105 °C
dB
INL20
Integral non linearity[45]
Range = ±1.024 V, unbuffered
–
–
±32
LSB
DNL20
Differential non linearity[45]
Range = ±1.024 V, unbuffered
–
–
±1
LSB
Range = ±1.024 V, unbuffered
–
–
±2
LSB
Range = ±1.024 V, unbuffered
–
–
±1
LSB
linearity[45]
INL16
Integral non
DNL16
Differential non linearity[45]
linearity[45]
INL12
Integral non
Range = ±1.024 V, unbuffered
–
–
±1
LSB
DNL12
Differential non linearity[45]
Range = ±1.024 V, unbuffered
–
–
±1
LSB
INL8
Integral non linearity[45]
Range = ±1.024 V, unbuffered
–
–
±1
LSB
Range = ±1.024 V, unbuffered
–
–
±1
LSB
DNL8
Differential non
linearity[45]
Note
45. Based on device characterization (not production tested).
Document Number: 001-84932 Rev. *N
Page 88 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Table 11-20. 20-bit Delta-sigma ADC DC Specifications (continued)
Parameter
Rin_Buff
Description
Conditions
ADC input resistance
Min
Typ
Max
Units
Input buffer used
10
–
–
MΩ
Rin_ADC16 ADC input resistance
Input buffer bypassed, 16-bit,
Range = ±1.024 V
–
74[46]
–
kΩ
Rin_ADC12 ADC input resistance
Input buffer bypassed, 12 bit,
Range = ±1.024 V
–
148[46]
–
kΩ
–
70[46, 47]
–
kΩ
0.9
–
1.3
V
1.5
mA
Rin_ExtRef ADC external reference input resistance
Vextref
ADC external reference input voltage, see
also internal reference in Voltage
Pins P0[3], P3[2]
Reference on page 93
Current Consumption
IDD_20
IDDA + IDDD Current consumption, 20 bit[48] 187 sps, unbuffered
–
–
IDD_16
IDDA + IDDD
–
–
1.5
mA
–
–
1.95
mA
–
–
1.95
mA
–
–
2.5
mA
IDD_12
IDD_8
IBUFF
Current consumption, 16 bit[48]
48 ksps, unbuffered
IDDA + IDDD Current consumption, 12 bit[48] 192 ksps, unbuffered
IDDA + IDDD Current consumption, 8 bit[48] 384 ksps, unbuffered
Buffer current consumption[48]
Table 11-21. Delta-sigma ADC AC Specifications
Parameter
Description
Conditions
Startup time
THD
Total harmonic distortion[48]
Buffer gain = 1, 16 bit,
Range = ±1.024 V
Min
Typ
Max
Units
–
–
4
Samples
–
–
0.0032
%
20-Bit Resolution Mode
SR20
Sample rate[48]
Range = ±1.024 V, unbuffered
7.8
–
187
sps
BW20
Input bandwidth at max sample rate[48]
Range = ±1.024 V, unbuffered
–
40
–
Hz
Range = ±1.024 V, unbuffered
2
–
48
ksps
16-Bit Resolution Mode
SR16
BW16
Sample rate[48]
Input bandwidth at max sample
rate[48]
Range = ±1.024 V, unbuffered
–
11
–
kHz
SINAD16int Signal to noise ratio, 16-bit, internal
reference[48]
Range = ±1.024V, unbuffered
81
–
–
dB
TA ≤ 105 °C
77
–
–
SINAD16ext Signal to noise ratio, 16-bit, external
reference[48]
Range = ±1.024 V, unbuffered
84
–
–
dB
12-Bit Resolution Mode
SR12
Sample rate, continuous, high power[48]
Range = ±1.024 V, unbuffered
4
–
192
ksps
BW12
Input bandwidth at max sample rate[48]
Range = ±1.024 V, unbuffered
–
44
–
kHz
Range = ±1.024 V, unbuffered
66
–
–
dB
Range = ±1.024 V, unbuffered
8
–
384
ksps
Range = ±1.024 V, unbuffered
–
88
–
kHz
Range = ±1.024 V, unbuffered
43
–
–
dB
SINAD12int Signal to noise ratio, 12-bit, internal
reference[48]
8-Bit Resolution Mode
SR8
Sample rate, continuous, high power[48]
rate[48]
BW8
Input bandwidth at max sample
SINAD8int
Signal to noise ratio, 8-bit, internal
reference[48]
Notes
46. By using switched capacitors at the ADC input an effective input resistance is created. Holding the gain and number of bits constant, the resistance is proportional
to the inverse of the clock frequency. This value is calculated, not measured. For more information see the Technical Reference Manual.
47. Recommend an external reference device with an output impedance 2.7 V,
Vin ≥ 0.5 V
Input offset voltage in slow mode
Factory trim, Vin ≥ 0.5 V
VOS
Min
Typ
–
Max
Units
10
mV
–
9
mV
–
4
mV
–
–
4
mV
–
±12
–
mV
–
63
85
µV/°C
Input offset voltage in fast mode[59] Custom trim
–
Input offset voltage in slow mode[59] Custom trim
VOS
Input offset voltage in ultra low
power mode
TCVos
Temperature coefficient, input
offset voltage
VCM = VDDA / 2, fast mode
VCM = VDDA / 2, slow mode
–
15
20
VHYST
Hysteresis
Hysteresis enable mode
–
10
32
mV
VICM
Input common mode voltage
VOS
High current / fast mode
VSSA
–
VDDA
V
Low current / slow mode
VSSA
–
VDDA
V
Ultra low power mode
VSSA
–
VDDA – 1.15
V
–
50
–
dB
CMRR
Common mode rejection ratio
ICMP
High current mode/fast mode
–
–
400
µA
Low current mode/slow mode
–
–
100
µA
Ultra low power mode
–
6
–
µA
Min
Typ
Max
Units
Table 11-33. Comparator AC Specifications[58]
Parameter
TRESP
Description
Conditions
Response time, high current
mode[59]
50 mV overdrive, measured
pin-to-pin
–
75
110
ns
Response time, low current
mode[59]
50 mV overdrive, measured
pin-to-pin
–
155
200
ns
Response time, ultra low power
mode[59]
50 mV overdrive, measured
pin-to-pin
–
55
–
µs
Notes
58. The recommended procedure for using a custom trim value for the on-chip comparators can be found in the TRM.
59. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 98 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
11.5.7 Current Digital-to-analog Converter (IDAC)
All specifications are based on use of the low-resistance IDAC output pins (see Pin Descriptions on page 12 for details). See the
IDAC component data sheet in PSoC Creator for full electrical specifications and APIs.
Unless otherwise specified, all charts and graphs show typical values.
Table 11-34. IDAC DC Specifications
Parameter
Description
Conditions
Min
Typ
Max
Units
–
–
8
bits
Range = 2.04 mA, code = 255,
VDDA ≥ 2.7 V, Rload = 600 Ω
–
2.04
–
mA
Range = 2.04 mA, High mode,
code = 255, VDDA ≤ 2.7 V,
Rload = 300 Ω
–
2.04
–
mA
Range = 255 µA, code = 255,
Rload = 600 Ω
–
255
–
µA
Range = 31.875 µA, code = 255,
Rload = 600 Ω
–
31.875
–
µA
–
–
Yes
Resolution
IOUT
Output current at code = 255
Monotonicity
Ezs
Zero scale error
Eg
Gain error
TC_Eg
INL
Temperature coefficient of gain
error
Integral nonlinearity
Range = 2.04 mA
–
0
±1
LSB
–
–
±2.5
%
Range = 255 µA
–
–
±2.5
%
Range = 31.875 µA
–
–
±3.5
%
Range = 2.04 mA
–
–
0.045
% / °C
Range = 255 µA
–
–
0.045
% / °C
Range = 31.875 µA
–
–
0.05
% / °C
Sink mode, range = 255 µA, Codes
8–255, Rload = 2.4 kΩ,
Cload = 15 pF
–
±0.9
±1
LSB
Source mode, range = 255 µA,
Codes 8–255, Rload = 2.4 kΩ,
Cload = 15 pF
–
±1.2
±1.6
LSB
Source mode, range = 31.875 µA,
Codes 8–255, Rload = 20 kΩ,
Cload = 15 pF[60]
–
±0.9
±2
LSB
Sink mode, range = 31.875 µA,
Codes 8–255, Rload = 20 kΩ,
Cload = 15 pF[60]
–
±0.9
±2
LSB
Source mode, range = 2.04 mA,
Codes 8–255, Rload = 600 Ω,
Cload = 15 pF[60]
–
±0.9
±2
LSB
Sink mode, range = 2.04 mA,
Codes 8–255, Rload = 600 Ω,
Cload = 15 pF[60]
–
±0.6
±1
LSB
Notes
60. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 99 of 139
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Datasheet
Table 11-34. IDAC DC Specifications (continued)
Parameter
DNL
Description
Differential nonlinearity
Conditions
Min
Typ
Max
Units
Sink mode, range = 255 µA,
Rload = 2.4 kΩ, Cload = 15 pF
–
±0.3
±1
LSB
Source mode, range = 255 µA,
Rload = 2.4 kΩ, Cload = 15 pF
–
±0.3
±1
LSB
Source mode, range = 31.875 µA,
Rload = 20 kΩ, Cload = 15 pF[61]
–
±0.2
±1
LSB
Sink mode, range = 31.875 µA,
Rload = 20 kΩ, Cload = 15 pF[61]
–
±0.2
±1
LSB
Source mode, range = 2.0 4 mA,
Rload = 600 Ω, Cload = 15 pF[61]
–
±0.2
±1
LSB
Sink mode, range = 2.0 4 mA,
Rload = 600 Ω, Cload = 15 pF[61]
–
±0.2
±1
LSB
Vcompliance
Dropout voltage, source or sink
mode
Voltage headroom at max current,
Rload to VDDA or Rload to VSSA,
VDIFF from VDDA
1
–
–
V
IDD
Operating current, code = 0
Slow mode, source mode, range =
31.875 µA
–
44
100
µA
Slow mode, source mode, range =
255 µA,
–
33
100
µA
Slow mode, source mode, range =
2.04 mA
–
33
100
µA
Slow mode, sink mode, range =
31.875 µA
–
36
100
µA
Slow mode, sink mode, range =
255 µA
–
33
100
µA
Slow mode, sink mode, range =
2.04 mA
–
33
100
µA
Fast mode, source mode, range =
31.875 µA
–
310
500
µA
Fast mode, source mode, range =
255 µA
–
305
500
µA
Fast mode, source mode, range =
2.04 mA
–
305
500
µA
Fast mode, sink mode, range =
31.875 µA
–
310
500
µA
Fast mode, sink mode, range =
255 µA
–
300
500
µA
Fast mode, sink mode, range =
2.04 mA
–
300
500
µA
Note
61. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 100 of 139
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Datasheet
Figure 11-48. IDAC INL vs Input Code, Range = 255 µA, Sink
Mode
1
1
0.5
0.5
INL, L
LSB
INL, L
LSB
Figure 11-47. IDAC INL vs Input Code, Range = 255 µA,
Source Mode
0
0
-0.5
-0.5
-1
-1
0
32
64
96
128
160
192
224
256
0
32
64
96
Code, 8-bit
Figure 11-49. IDAC DNL vs Input Code, Range = 255 µA,
Source Mode
0.25
DNL, LSB
0.25
DNL, LSB
0.5
0
-0.25
-0.5
-0.5
64
96
128
160
192
224
0
256
32
64
224
256
96
128
160
192
224
256
Code, 8-bit
Code, 8-bit
Figure 11-51. IDAC INL vs Temperature, Range = 255 µA, Fast
Mode
Figure 11-52. IDAC DNL vs Temperature, Range = 255 µA,
Fast Mode
1
0.5
Source mode
0.75
Source mode
0.4
Sink mode
Sink mode
DNL, LSB
INL, L
LSB
192
0
-0.25
32
160
Figure 11-50. IDAC DNL vs Input Code, Range = 255 µA, Sink
Mode
0.5
0
128
Code, 8-bit
05
0.5
0.3
0.2
0.25
0.1
0
0
-40
-20
0
20
40
Temperature, °C
Document Number: 001-84932 Rev. *N
60
80
100
-40
-20
0
20
40
60
80
100
Temperature, °C
Page 101 of 139
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Datasheet
Figure 11-54. IDAC Full Scale Error vs Temperature, Range
= 255 µA, Sink Mode
1.5
1.5
1
1
Full Scale Error, %
Full Scale Error, %
Figure 11-53. IDAC Full Scale Error vs Temperature, Range
= 255 µA, Source Mode
0.5
0
-0.5
0.5
0
-0.5
-1
-1
-1.5
-1.5
-40
-20
0
20
40
60
80
-40
100
-20
0
Figure 11-55. IDAC Operating Current vs Temperature,
Range = 255 µA, Code = 0, Source Mode
40
60
80
100
Figure 11-56. IDAC Operating Current vs Temperature,
Range = 255 µA, Code = 0, Sink Mode
350
350
300
300
Operating C
Current, μA
Operating C
Current, μA
20
Temperature, °C
Temperature, °C
250
Fast Mode
200
Slow Mode
150
100
50
250
Fast Mode
200
Slow Mode
150
100
50
0
0
-40
-20
0
20
40
Temperature, °C
Document Number: 001-84932 Rev. *N
60
80
100
-40
-20
0
20
40
60
80
100
Temperature, °C
Page 102 of 139
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Datasheet
Table 11-35. IDAC AC Specifications[62]
Parameter
FDAC
TSETTLE
Description
Update rate
Settling time to 0.5 LSB
Conditions
Range = 31.875 µA, full scale
transition, fast mode, 600 Ω 15-pF
load
Range = 255 µA, full scale
transition, fast mode, 600 Ω 15-pF
load
Range = 255 µA, source mode, fast
mode, Vdda = 5 V, 10 kHz
Current noise
Figure 11-57. IDAC Step Response, Codes 0x40 - 0xC0,
255-µA Mode, Source Mode, Fast Mode, VDDAa = 5 V
Min
–
–
Typ
–
–
Max
8
125
Units
Msps
ns
–
–
125
ns
–
340
–
pA/sqrtHz
Figure 11-58. IDAC Glitch Response, Codes 0x7F - 0x80,
255 µA Mode, Source Mode, Fast Mode, VDDA = 5 V
134
250
132
200
Iout, μA
Iout, μA
130
150
100
128
126
124
50
122
120
0
0
0.5
1
1.5
0
2
0.5
1
1.5
2
Time, μs
Time, μs
Figure 11-59. IDAC PSRR vs Frequency
Figure 11-60. IDAC Current Noise, 255 µA Mode,
Source Mode, Fast Mode, VDDA = 5 V
60
10000
40
1000
30
pA / sq
qrtHz
PSRR, dB
P
50
20
10
100
10
0
0.1
1
10
100
1000
10000
Frequency, kHz
255 ȝA, code 0x7F
1
255 ȝA, code 0xFF
0.01
0.1
1
Frequency, kHz
10
100
Note
62. Based on device characterization (Not production tested).
Document Number: 001-84932 Rev. *N
Page 103 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
11.5.8 Voltage Digital to Analog Converter (VDAC)
See the VDAC component datasheet in PSoC Creator for full electrical specifications and APIs.
Unless otherwise specified, all charts and graphs show typical values.
Table 11-36. VDAC DC Specifications
Parameter
Description
Conditions
Min
Resolution
Max
Units
–
8
–
bits
–
±2.1
±2.5
LSB
–
±2.1
±2.5
LSB
–
±0.3
±1
LSB
–
±0.3
±1
LSB
–
4
–
kΩ
16
–
kΩ
1.02
–
V
4.08
–
V
–
Yes
–
INL1
Integral nonlinearity
1 V scale
INL4
Integral nonlinearity[63]
4 V scale
DNL1
Differential nonlinearity
1 V scale
DNL4
Differential nonlinearity[63]
4 V scale
Rout
Output resistance
1 V scale
4 V scale
–
VOUT
Output voltage range, code = 255
1 V scale
–
4 V scale, Vdda = 5 V
–
–
Monotonicity
Typ
VOS
Zero scale error
Eg
Gain error
4 V scale
–
–
±2.5
%
TC_Eg
Temperature coefficient, gain error 1 V scale
–
–
0.03
%FSR / °C
IDD
Operating current[63]
1 V scale
0
±0.9
LSB
–
±2.5
%
4 V scale
–
–
0.03
%FSR / °C
Slow mode
–
–
100
µA
Fast mode
–
–
500
µA
Figure 11-61. VDAC INL vs Input Code, 1 V Mode
Figure 11-62. VDAC DNL vs Input Code, 1 V Mode
1
0.5
0.5
0.25
DNL, LSB
INL, L
LSB
–
–
0
-0.5
0
-0.25
-1
-0.5
0
32
64
96
128
160
192
Code, 8-bit
224
256
0
32
64
96
128
160
192
224
256
Code, 8-bit
Note
63. Based on device characterization (Not production tested).
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Figure 11-63. VDAC INL vs Temperature, 1 V Mode
Figure 11-64. VDAC DNL vs Temperature, 1 V Mode
1
0.5
0.4
DNL, LSB
INL, L
LSB
0.75
05
0.5
0.3
0.2
0.25
0.1
0
0
-40
-20
0
20
40
60
80
100
-40
-20
0
20
Temperature, °C
60
80
100
Figure 11-66. VDAC Full Scale Error vs Temperature, 4 V
Mode
1
2
0.75
1.5
Full Scale Error, %
Full Scale Error, %
Figure 11-65. VDAC Full Scale Error vs Temperature, 1 V
Mode
05
0.5
0.25
1
0.5
0
0
-40
-20
0
20
40
60
80
-40
100
-20
0
20
40
60
80
100
Temperature, °C
Temperature, °C
Figure 11-67. VDAC Operating Current vs Temperature, 1V
Mode, Slow Mode
Figure 11-68. VDAC Operating Current vs Temperature, 1 V
Mode, Fast Mode
50
400
40
Operating C
Current, μA
Operating C
Current, μA
40
Temperature, °C
30
20
10
0
300
200
100
0
-40
-20
0
20
40
Temperature, °C
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60
80
100
-40
-20
0
20
40
60
80
100
Temperature, °C
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Table 11-37. VDAC AC Specifications[64]
Parameter
FDAC
Description
Conditions
Update rate
Min
Typ
Max
Units
1 V scale
–
–
1000
ksps
4 V scale
–
–
250
ksps
–
0.45
1
µs
TsettleP
Settling time to 0.1%, step 25% to 1 V scale, Cload = 15 pF
75%
4 V scale, Cload = 15 pF
–
0.8
3.2
µs
TsettleN
Settling time to 0.1%, step 75% to 1 V scale, Cload = 15 pF
25%
–
0.45
1
µs
4 V scale, Cload = 15 pF
–
0.7
3
µs
Range = 1 V, fast mode, Vdda =
5 V, 10 kHz
–
750
–
nV/sqrtHz
Voltage noise
Figure 11-69. VDAC Step Response, Codes 0x40 - 0xC0, 1 V
Mode, Fast Mode, Vdda = 5 V
Figure 11-70. VDAC Glitch Response, Codes 0x7F - 0x80, 1 V
Mode, Fast Mode, Vdda = 5 V
0.54
1
0.75
Voutt, V
Voutt, V
0.52
05
0.5
0.5
0.25
0.48
0
0
0.5
1
1.5
0
2
0.5
1
1.5
2
Time, μs
Time, μs
Figure 11-71. VDAC PSRR vs Frequency
Figure 11-72. VDAC Voltage Noise, 1 V Mode, Fast Mode,
Vdda = 5 V
50
100000
10000
30
nV/sq
qrtHz
PSRR, dB
P
40
20
10
0
1000
100
0.1
1
10
Frequency, kHz
4 V, code 0x7F
100
4 V, code 0xFF
1000
10
0.01
0.1
1
10
100
Frequency, kHz
Note
64. Based on device characterization (Not production tested).
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11.5.9 Mixer
The mixer is created using a SC/CT analog block; see the Mixer component datasheet in PSoC Creator for full electrical specifications
and APIs.
Table 11-38. Mixer DC Specifications
Parameter
VOS
G
Description
Min
Typ
Max
Units
–
–
15
mV
Quiescent current
–
0.9
2
mA
Gain
–
0
–
dB
Input offset voltage
Conditions
High power mode, VIN = 1.024 V,
VREF = 1.024 V
Table 11-39. Mixer AC Specifications[65]
Min
Typ
Max
Units
fLO
Parameter
Local oscillator frequency
Description
Down mixer mode
Conditions
–
–
4
MHz
fin
Input signal frequency
Down mixer mode
–
–
14
MHz
fLO
Local oscillator frequency
Up mixer mode
–
–
1
MHz
fin
Input signal frequency
Up mixer mode
–
–
1
MHz
SR
Slew rate
3
–
–
V/µs
11.5.10 Transimpedance Amplifier
The TIA is created using a SC/CT analog block; see the TIA component datasheet in PSoC Creator for full electrical specifications
and APIs.
Table 11-40. Transimpedance Amplifier (TIA) DC Specifications
Parameter
VIOFF
Rconv
Description
Conditions
Min
Typ
Max
Units
–
–
10
mV
R = 20K; 40 pF load
–25
–
+35
%
R = 30K; 40 pF load
–25
–
+35
%
R = 40K; 40 pF load
–25
–
+35
%
R = 80K; 40 pF load
–25
–
+35
%
R = 120K; 40 pF load
–25
–
+35
%
R = 250K; 40 pF load
–25
–
+35
%
Input offset voltage
Conversion
resistance[66]
R= 500K; 40 pF load
–25
–
+35
%
R = 1M; 40 pF load
–25
–
+35
%
–
1.1
2
mA
Min
Typ
Max
Units
R = 20K; –40 pF load
1200
–
–
kHz
R = 120K; –40 pF load
240
–
–
kHz
R = 1M; –40 pF load
25
–
–
kHz
Quiescent current[65]
Table 11-41. Transimpedance Amplifier (TIA) AC Specifications[65]
Parameter
BW
Description
Input bandwidth (–3 dB)
Conditions
Notes
65. Based on device characterization (Not production tested).
66. Conversion resistance values are not calibrated. Calibrated values and details about calibration are provided in PSoC Creator component datasheets. External precision
resistors can also be used.
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11.5.11 Programmable Gain Amplifier
The PGA is created using a SC/CT analog block; see the PGA component datasheet in PSoC Creator for full electrical specifications
and APIs.
Unless otherwise specified, operating conditions are:
Operating temperature = 25 °C for typical values
Unless otherwise specified, all charts and graphs show typical values.
Table 11-42. PGA DC Specifications
Parameter
Description
Conditions
Min
Typ
Max
Units
Vssa
–
Vdda
V
Power mode = high,
gain = 1
–
–
10
mV
Input offset voltage drift with Power mode = high,
temperature
gain = 1
–
–
±30
µV/°C
Vin
Input voltage range
Power mode = minimum
Vos
Input offset voltage
TCVos
Ge1
Gain error, gain = 1
–
–
±0.15
%
Ge16
Gain error, gain = 16
–
–
±2.5
%
–
–
±5
%
–
–
±0.01
% of FSR
Ge50
Gain error, gain = 50
Vonl
DC output nonlinearity
Gain = 1
Cin
Input capacitance
–
–
7
pF
Voh
Output voltage swing
Power mode = high,
gain = 1, Rload = 100 kΩ to
VDDA / 2
VDDA – 0.15
–
–
V
Vol
Output voltage swing
Power mode = high,
gain = 1, Rload = 100 kΩ to
VDDA / 2
–
–
VSSA + 0.15
V
Vsrc
Output voltage under load
Iload = 250 µA, Vdda ≥ 2.7V,
power mode = high
–
–
300
mV
Idd
Operating current[67]
Power mode = high
–
1.5
1.65
mA
PSRR
Power supply rejection ratio
48
–
–
dB
Figure 11-73. PGA Voffset Histogram, 4096 samples/
1024 parts
Note
67. Based on device characterization (Not production tested).
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Table 11-43. PGA AC Specifications[68]
Parameter
BW1
Description
Conditions
–3 dB bandwidth
Min
Typ
Max
Units
6.7
8
–
MHz
TA ≤ 105 °C
6
8
–
Power mode = high,
gain = 1, input = 100 mV
peak-to-peak
SR1
Slew rate
Power mode = high,
gain = 1, 20% to 80%
3
–
–
V/µs
en
Input noise density
Power mode = high,
Vdda = 5 V, at 100 kHz
–
43
–
nV/sqrtHz
Figure 11-74. Bandwidth vs. Temperature, at Different Gain
Settings, Power Mode = High
Figure 11-75. Noise vs. Frequency, Vdda = 5 V,
Power Mode = High
1000
nV/sq
qrtHz
BW,, MHz
10
1
100
0.1
-40
-20
0
20
40
60
80
100
Temperature, °C
Gain = 1
Gain = 24
10
0.01
Gain = 48
0.1
1
10
Frequency, kHz
100
1000
Note
68. Based on device characterization (Not production tested).
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11.5.12 Temperature Sensor
Table 11-44. Temperature Sensor Specifications
Parameter
Description
Temp sensor accuracy
Conditions
Min
Typ
Max
Units
–
±5
–
°C
Conditions
Min
Typ
Max
Units
Range: –40 °C to +105 °C
11.5.13 LCD Direct Drive
Table 11-45. LCD Direct Drive DC Specifications[69]
Parameter
Description
ICC
LCD Block (no glass)
Device sleep mode with wakeup at
400Hz rate to refresh LCD, bus, clock =
3MHz, Vddio = Vdda = 3V, 8 commons,
16 segments, 1/5 duty cycle, 40 Hz
frame rate, no glass connected
–
81
–
μA
ICC_SEG
Current per segment driver
Strong drive mode
–
260
–
µA
VBIAS
LCD bias range (VBIAS refers to the VDDA ≥ 3 V and VDDA ≥ VBIAS
main output voltage(V0) of LCD DAC)
2
–
5
V
LCD bias step size
VDDA ≥ 3 V and VDDA ≥ VBIAS
–
9.1 × VDDA
–
mV
LCD capacitance per segment/
common driver
Drivers may be combined
–
500
5000
pF
Maximum segment DC offset
VDDA ≥ 3 V and VDDA ≥ VBIAS
–
–
20
mV
Output drive current per segment
driver)
VDDIO = 5.5 V, strong drive mode
355
–
710
µA
IOUT
Table 11-46. LCD Direct Drive AC Specifications[69]
Parameter
Description
LCD frame rate
fLCD
Conditions
Min
10
Typ
50
Max
150
Units
Hz
Note
69. Based on device characterization (Not production tested).
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11.6 Digital Peripherals
Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except where noted. Specifications are valid for 1.71 V to 5.5 V,
except where noted.
11.6.1 Timer
The following specifications apply to the Timer/Counter/PWM peripheral in timer mode. Timers can also be implemented in UDBs; for
more information, see the Timer component datasheet in PSoC Creator.
Table 11-47. Timer DC Specifications[70]
Parameter
Description
Block current consumption
Conditions
16-bit timer, at listed input clock
frequency
3 MHz
12 MHz
48 MHz
80 MHz
Min
–
Typ
–
Max
–
Units
µA
–
–
–
–
15
60
260
360
–
–
–
–
µA
µA
µA
µA
Min
DC
15
30
15
15
30
15
30
Typ
–
–
–
–
–
–
–
–
Max
80.01
–
–
–
–
–
–
–
Units
MHz
ns
ns
ns
ns
ns
ns
ns
Table 11-48. Timer AC Specifications[70]
Parameter
Description
Operating frequency
Capture pulse width (Internal)[71]
Capture pulse width (external)
Timer resolution[71]
Enable pulse width[71]
Enable pulse width (external)
Reset pulse width[71]
Reset pulse width (external)
Conditions
Notes
70. Based on device characterization (Not production tested).
71. For correct operation, the minimum Timer/Counter/PWM input pulse width is the period of bus clock.
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11.6.2 Counter
The following specifications apply to the Timer/Counter/PWM peripheral, in counter mode. Counters can also be implemented in
UDBs; for more information, see the Counter component datasheet in PSoC Creator.
Table 11-49. Counter DC Specifications[72]
Parameter
Description
Block current consumption
Conditions
Min
Typ
Max
Units
16-bit counter, at listed input clock
frequency
–
–
–
µA
3 MHz
–
15
–
µA
12 MHz
–
60
–
µA
48 MHz
–
260
–
µA
80 MHz
–
360
–
µA
Min
DC
15
15
15
30
15
30
15
30
Typ
–
–
–
–
Max
80.01
–
–
–
–
–
–
–
–
–
–
–
Units
MHz
ns
ns
ns
ns
ns
ns
ns
ns
Table 11-50. Counter AC Specifications[72]
Parameter
Description
Operating frequency
Capture pulse[73]
Resolution[73]
Pulse width[73]
Pulse width (external)
Enable pulse width[73]
Enable pulse width (external)
Reset pulse width[73]
Reset pulse width (external)
Conditions
Notes
72. Based on device characterization (Not production tested).
73. For correct operation, the minimum Timer/Counter/PWM input pulse width is the period of bus clock.
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11.6.3 Pulse Width Modulation
The following specifications apply to the Timer/Counter/PWM peripheral, in PWM mode. PWM components can also be implemented
in UDBs; for more information, see the PWM component datasheet in PSoC Creator.
Table 11-51. PWM DC Specifications[74]
Parameter
Description
Block current consumption
Conditions
Min
16-bit PWM, at listed input clock frequency
Typ
Max
Units
–
–
–
µA
3 MHz
–
15
–
µA
12 MHz
–
60
–
µA
48 MHz
–
260
–
µA
80 MHz
–
360
–
µA
Table 11-52. PWM AC Specifications[74]
Parameter
Description
Conditions
Min
Typ
Max
Units
Operating frequency
DC
–
80.01
MHz
Pulse width[75]
15
–
–
ns
Pulse width (external)
30
–
–
ns
Kill pulse width[75]
15
–
–
ns
Kill pulse width (external)
30
–
–
ns
Enable pulse width[75]
15
–
–
ns
Enable pulse width (external)
30
–
–
ns
Reset pulse width[75]
15
–
–
ns
Reset pulse width (external)
30
–
–
ns
Conditions
Enabled, configured for 100 kbps
Enabled, configured for 400 kbps
Min
–
–
Typ
–
–
Max
250
260
Units
µA
µA
Conditions
Min
–
Typ
–
Max
1
Units
Mbps
Conditions
Min
Typ
Max
Units
–
–
200
µA
11.6.4 I2C
Table 11-53. Fixed I2C DC Specifications[74]
Parameter
Description
Block current consumption
Table 11-54. Fixed I2C AC Specifications[76]
Parameter
Description
Bit rate
11.6.5 Controller Area Network
Table 11-55. CAN DC Specifications[74, 77]
Parameter
IDD
Description
Block current consumption
Table 11-56. CAN AC Specifications[74, 77]
Parameter
Description
Bit rate
Conditions
Minimum 8 MHz clock
Min
–
Typ
–
Max
1
Units
Mbit
Notes
74. Based on device characterization (Not production tested).
75. For correct operation, the minimum Timer/Counter/PWM input pulse width is the period of bus clock.
76. Rise/fall time matching (TR) not guaranteed, see Table 11-15 on page 84.
77. Refer to ISO 11898 specification for details.
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11.6.6 Digital Filter Block
Table 11-57. DFB DC Specifications[78]
Parameter
Description
DFB operating current
Conditions
Min
Typ
Max
Units
–
0.16
0.27
mA
1 MHz (13.4 ksps)
–
0.33
0.53
mA
10 MHz (134 ksps)
–
3.3
5.3
mA
64-tap FIR at FDFB
500 kHz (6.7 ksps)
48 MHz (644 ksps)
–
15.7
25.5
mA
80 MHz (1.07 Msps)
–
26.0
42.5
mA
Min
Typ
Max
Units
DC
–
80.01
MHz
Table 11-58. DFB AC Specifications[78]
Parameter
FDFB
Description
Conditions
DFB operating frequency
11.6.7 USB
Table 11-59. USB DC Specifications
Parameter
Min
Typ
Max
Units
USB configured, USB regulator
enabled
4.35
–
5.25
V
VUSB_3.3
USB configured, USB regulator
bypassed
3.15
–
3.6
V
VUSB_3
USB configured, USB regulator
bypassed[78]
2.85
–
3.6
V
–
10
–
mA
–
8
–
mA
–
0.5
–
mA
VDDD = 5 V, disconnected from
USB host
–
0.3
–
mA
VDDD = 3.3 V, connected to USB
host, PICU configured to wake on
USB resume signal
–
0.5
–
mA
VDDD = 3.3 V, disconnected from
USB host
–
0.3
–
mA
VUSB_5
Description
Device supply (VDDD) for USB
operation
Conditions
IUSB_Configured Device supply current in device active VDDD = 5 V, FCPU = 1.5 MHz
mode, bus clock and IMO = 24 MHz V
DDD = 3.3 V, FCPU = 1.5 MHz
IUSB_Suspended Device supply current in device sleep VDDD = 5 V, connected to USB
mode
host, PICU configured to wake on
USB resume signal
Note
78. Rise/fall time matching (TR) not guaranteed, see Table 11-15 on page 84.
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11.6.8 Universal Digital Blocks (UDBs)
PSoC Creator provides a library of pre-built and tested standard digital peripherals (UART, SPI, LIN, PRS, CRC, timer, counter, PWM,
AND, OR, and so on) that are mapped to the UDB array. See the component datasheets in PSoC Creator for full AC/DC specifications,
APIs, and example code.
Table 11-60. UDB AC Specifications[79]
Parameter
Description
Conditions
Min
Typ
Max
Units
FMAX_TIMER Maximum frequency of 16-bit timer in
a UDB pair
–
–
67.01
MHz
FMAX_ADDER Maximum frequency of 16-bit adder in
a UDB pair
–
–
67.01
MHz
–
–
67.01
MHz
–
–
67.01
MHz
Datapath Performance
FMAX_CRC
Maximum frequency of 16-bit
CRC/PRS in a UDB pair
PLD Performance
FMAX_PLD
Maximum frequency of a two-pass
PLD function in a UDB pair
Clock to Output Performance
tCLK_OUT
Propagation delay for clock in to data 25 °C, VDDD ≥ 2.7 V
out, see Figure 11-76.
–
20
25
ns
tCLK_OUT
Propagation delay for clock in to data Worst-case placement, routing,
out, see Figure 11-76.
and pin selection
–
–
55
ns
Figure 11-76. Clock to Output Performance
Note
79. Based on device characterization (Not production tested).
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11.7 Memory
Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except where noted. Specifications are valid for 1.71 V to 5.5 V,
except where noted.
11.7.1 Flash
Table 11-61. Flash DC Specifications
Parameter
Description
Erase and program voltage
Conditions
VDDD pin
Min
Typ
Max
Units
1.71
–
5.5
V
Min
Typ
Max
Units
Table 11-62. Flash AC Specifications
Parameter
Description
Conditions
TWRITE
Row write time (erase + program)
–
15
20
ms
TERASE
Row erase time
–
10
13
ms
Row program time
–
5
7
ms
Bulk erase time (256 KB)
–
–
140
ms
–
–
15
ms
–
5
7.5
seconds
20
–
–
years
Ambient temp. TA ≤ 85 °C,
10 K erase/program cycles
10
–
–
Ambient temp. TA ≤ 105 °C,
10 K erase/program cycles,
≤ one year at TA ≥ 75 °C [80]
10
–
–
Min
Typ
Max
Units
1.71
–
5.5
V
Min
Typ
Max
Units
Single row erase/write cycle time
–
10
20
ms
EEPROM data retention time, retention Ambient temp, TA ≤ 25 °C,
period measured from last erase cycle 1M erase/program cycles
20
–
–
years
Ambient temp, TA ≤ 55 °C,
100K erase/program cycles
20
–
–
Ambient temp. TA ≤ 85 °C,
10K erase/program cycles
10
–
–
Ambient temp. TA ≤ 105 °C,
10K erase/program cycles,
≤ one year at TA ≥75 °C
10
–
–
TBULK
Sector erase time (16 KB)
TPROG
Total device programming time
No overhead[80]
Flash data retention time, retention
Ambient temp. TA ≤ 55 °C,
period measured from last erase cycle 100 K erase/program cycles
11.7.2 EEPROM
Table 11-63. EEPROM DC Specifications
Parameter
Description
Conditions
Erase and program voltage
Table 11-64. EEPROM AC Specifications
Parameter
TWRITE
Description
Conditions
Note
80. See PSoC 5 Device Programming Specifications for a description of a low-overhead method of programming PSoC 5 flash.
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11.7.3 Nonvolatile Latches (NVL)
Table 11-65. NVL DC Specifications
Parameter
Description
Erase and program voltage
Conditions
Min
Typ
Max
Units
1.71
–
5.5
V
Min
Typ
Max
Units
Programmed at 25 °C
1K
–
–
program/
erase
cycles
Programmed at 0 °C to 70 °C
100
–
–
program/
erase
cycles
years
VDDD pin
Table 11-66. NVL AC Specifications
Parameter
Description
NVL endurance
NVL data retention time
Conditions
Ambient temp. TA ≤ 55 °C
20
–
–
Ambient temp. TA ≤ 85 °C
10
–
–
Ambient temp. TA ≤ 105 °C,
≤ one year at TA ≥ 75 °C [81]
10
–
–
Min
Typ
Max
Units
1.2
–
–
V
Min
Typ
Max
Units
DC
–
80.01
MHz
11.7.4 SRAM
Table 11-67. SRAM DC Specifications
Parameter
VSRAM
Description
Conditions
SRAM retention voltage[82]
Table 11-68. SRAM AC Specifications
Parameter
FSRAM
Description
SRAM operating frequency
Conditions
Notes
81. Cypress provides a retention calculator to calculate the retention lifetime based on customers' individual temperature profiles for operation over the –40 °C to +105 °C
ambient temperature range. Contact customercare@cypress.com.
82. Based on device characterization (Not production tested).
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Datasheet
11.7.5 External Memory Interface
Figure 11-77. Asynchronous Write and Read Cycle Timing, No Wait States
Tbus_clock
Bus Clock
EM_Addr
EM_CE
EM_WE
EM_OE
Twr_setup
Trd_hold
Trd_setup
EM_Data
Write Cycle
Read Cycle
Minimum of 4 bus clock cycles between successive EMIF accesses
Table 11-69. Asynchronous Write and Read Timing Specifications[83]
Parameter
Fbus_clock
Description
Bus clock frequency[84]
period[85]
Tbus_clock
Bus clock
Twr_Setup
Time from EM_data valid to rising edge of
EM_WE and EM_CE
Trd_setup
Trd_hold
Conditions
Min
Typ
Max
Units
–
–
33
MHz
30.3
–
–
ns
Tbus_clock – 10
–
–
ns
Time that EM_data must be valid before rising
edge of EM_OE
5
–
–
ns
Time that EM_data must be valid after rising
edge of EM_OE
5
–
–
ns
Notes
83. Based on device characterization (Not production tested).
84. EMIF signal timings are limited by GPIO frequency limitations. See “GPIO” section on page 76.
85. EMIF output signals are generally synchronized to bus clock, so EMIF signal timings are dependent on bus clock frequency.
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Datasheet
Figure 11-78. Synchronous Write and Read Cycle Timing, No Wait States
Tbus_clock
Bus Clock
EM_Clock
EM_Addr
EM_CE
EM_ADSC
EM_WE
EM_OE
Twr_setup
Trd_hold
Trd_setup
EM_Data
Write Cycle
Read Cycle
Minimum of 4 bus clock cycles between successive EMIF accesses
Table 11-70. Synchronous Write and Read Timing Specifications[86]
Parameter
Fbus_clock
Description
Bus clock frequency[87]
period[88]
Tbus_clock
Bus clock
Twr_Setup
Time from EM_data valid to rising edge of
EM_Clock
Trd_setup
Trd_hold
Conditions
Min
Typ
Max
Units
–
–
33
MHz
30.3
–
–
ns
Tbus_clock – 10
–
–
ns
Time that EM_data must be valid before rising
edge of EM_OE
5
–
–
ns
Time that EM_data must be valid after rising
edge of EM_OE
5
–
–
ns
Notes
86. Based on device characterization (Not production tested).
87. EMIF signal timings are limited by GPIO frequency limitations. See “GPIO” section on page 76.
88. EMIF output signals are generally synchronized to bus clock, so EMIF signal timings are dependent on bus clock frequency.
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Datasheet
11.8 PSoC System Resources
Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except where noted. Specifications are valid for 1.71 V to 5.5 V,
except where noted.
11.8.1 POR with Brown Out
For brown out detect in regulated mode, VDDD and VDDA must be ≥ 2.0 V. Brown out detect is not available in externally regulated
mode.
Table 11-71. Precise Low-Voltage Reset (PRES) with Brown Out DC Specifications
Parameter
Description
Min
Typ
Max
Units
1.64
–
1.68
V
1.62
–
1.66
V
Min
Typ
Max
Units
–
–
0.5
µs
–
5
–
V/sec
Min
Typ
Max
Units
LVI_A/D_SEL[3:0] = 0000b
1.68
1.73
1.77
V
LVI_A/D_SEL[3:0] = 0001b
1.89
1.95
2.01
V
LVI_A/D_SEL[3:0] = 0010b
2.14
2.20
2.27
V
PRESR
Rising trip voltage
PRESF
Falling trip voltage
Conditions
Factory trim
Table 11-72. Power-On-Reset (POR) with Brown Out AC Specifications[89]
Parameter
Description
Conditions
PRES_TR[90] Response time
VDDD/VDDA droop rate
Sleep mode
11.8.2 Voltage Monitors
Table 11-73. Voltage Monitors DC Specifications
Parameter
LVI
HVI
Description
Conditions
Trip voltage
LVI_A/D_SEL[3:0] = 0011b
2.38
2.45
2.53
V
LVI_A/D_SEL[3:0] = 0100b
2.62
2.71
2.79
V
LVI_A/D_SEL[3:0] = 0101b
2.87
2.95
3.04
V
LVI_A/D_SEL[3:0] = 0110b
3.11
3.21
3.31
V
LVI_A/D_SEL[3:0] = 0111b
3.35
3.46
3.56
V
LVI_A/D_SEL[3:0] = 1000b
3.59
3.70
3.81
V
LVI_A/D_SEL[3:0] = 1001b
3.84
3.95
4.07
V
LVI_A/D_SEL[3:0] = 1010b
4.08
4.20
4.33
V
LVI_A/D_SEL[3:0] = 1011b
4.32
4.45
4.59
V
LVI_A/D_SEL[3:0] = 1100b
4.56
4.70
4.84
V
LVI_A/D_SEL[3:0] = 1101b
4.83
4.98
5.13
V
LVI_A/D_SEL[3:0] = 1110b
5.05
5.21
5.37
V
LVI_A/D_SEL[3:0] = 1111b
5.30
5.47
5.63
V
5.57
5.75
5.92
V
Min
Typ
Max
Units
–
–
1
µs
Trip voltage
Table 11-74. Voltage Monitors AC Specifications
Parameter
LVI_tr[90]
Description
Response time
Conditions
Notes
89. Based on device characterization (Not production tested).
90. This value is calculated, not measured.
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Datasheet
11.8.3 Interrupt Controller
Table 11-75. Interrupt Controller AC Specifications
Parameter
Description
Conditions
Min
Typ
Max
Units
Delay from interrupt signal input to ISR
code execution from main line code[91]
–
–
12
Tcy CPU
Delay from interrupt signal input to ISR
code execution from ISR code
(tail-chaining)[91]
–
–
6
Tcy CPU
11.8.4 JTAG Interface
Figure 11-79. JTAG Interface Timing
(1/f_TCK)
TCK
T_TDI_setup
T_TDI_hold
TDI
T_TDO_valid
T_TDO_hold
TDO
T_TMS_setup
T_TMS_hold
TMS
Table 11-76. JTAG Interface AC Specifications[92]
Parameter
f_TCK
Description
TCK frequency
Conditions
3.3 V ≤ VDDD ≤ 5 V
1.71 V ≤ VDDD < 3.3 V
T_TDI_setup
TDI setup before TCK high
Min
Typ
Max
Units
–
–
12[93]
MHz
–
–
7[93]
MHz
(T/10) – 5
–
–
ns
T_TMS_setup
TMS setup before TCK high
T_TDI_hold
TDI, TMS hold after TCK high
T = 1/f_TCK max
T/4
–
–
T/4
–
–
T_TDO_valid
TCK low to TDO valid
T = 1/f_TCK max
T_TDO_hold
TDO hold after TCK high
T = 1/f_TCK max
–
–
2T/5
T/4
–
–
T_nTRST
Minimum nTRST pulse width
f_TCK = 2 MHz
8
–
–
ns
Notes
91. Arm Cortex-M3 NVIC spec. Visit www.arm.com for detailed documentation about the Cortex-M3 CPU.
92. Based on device characterization (Not production tested).
93. f_TCK must also be no more than 1/3 CPU clock frequency.
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Datasheet
11.8.5 SWD Interface
Figure 11-80. SWD Interface Timing
(1/f_SW DCK)
SW DCK
T_SW DI_setup T_SW DI_hold
SW DIO
(PSoC input)
T_SW DO _hold
T_SW DO _valid
SW DIO
(PSoC output)
Table 11-77. SWD Interface AC Specifications[94]
Parameter
f_SWDCK
Description
SWDCLK frequency
Conditions
3.3 V ≤ VDDD ≤ 5 V
Min
Typ
Max
Units
–
–
12[95]
MHz
MHz
MHz
1.71 V ≤ VDDD < 3.3 V
–
–
7[95]
1.71 V ≤ VDDD < 3.3 V, SWD over
USBIO pins
–
–
5.5[95]
T_SWDI_setup SWDIO input setup before SWDCK high T = 1/f_SWDCK max
T/4
–
–
T_SWDI_hold
SWDIO input hold after SWDCK high
T = 1/f_SWDCK max
T/4
–
–
T = 1/f_SWDCK max
–
–
T/2
T_SWDO_hold SWDIO output hold after SWDCK high T = 1/f_SWDCK max
1
–
–
ns
Min
Typ
Max
Units
MHz
Mbit
T_SWDO_valid SWDCK high to SWDIO output
11.8.6 TPIU Interface
Table 11-78. TPIU Interface AC Specifications[94]
Parameter
Description
Conditions
TRACEPORT (TRACECLK) frequency
–
–
33[96]
SWV bit rate
–
–
33[96]
Notes
94. Based on device characterization (Not production tested).
95. f_SWDCK must also be no more than 1/3 CPU clock frequency.
96. TRACEPORT signal frequency and bit rate are limited by GPIO output frequency, see Table 11-9 on page 77.
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Datasheet
11.9 Clocking
Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except where noted. Specifications are valid for 1.71 V to 5.5 V,
except where noted. Unless otherwise specified, all charts and graphs show typical values
11.9.1 Internal Main Oscillator
Table 11-79. IMO DC Specifications[97]
Parameter
Description
Conditions
Min
Typ
Max
Units
74.7 MHz
–
–
730
µA
62.6 MHz
–
–
600
µA
Supply current
48 MHz
Icc_imo
–
–
500
µA
–
–
500
µA
24 MHz – non-USB mode
–
–
300
µA
12 MHz
–
–
200
µA
6 MHz
–
–
180
µA
3 MHz
–
–
150
µA
24 MHz – USB mode
With oscillator locking to USB bus
Figure 11-81. IMO Current vs. Frequency
700
600
Cu e t, μ
500
400
300
200
100
0
0
10
20
30
40
50
Frequency, MHz
60
70
80
Table 11-80. IMO AC Specifications
Parameter
FIMO[98]
Description
Conditions
Min
IMO frequency stability (with factory trim)
74.7 MHz
–7
62.6 MHz
–7
48 MHz
–5
24 MHz – non-USB mode
–4
24 MHz – USB mode
With oscillator locking to USB bus
–0.25
12 MHz
–3
6 MHz
–2
3 MHz
0 °C to 70 °C
–1
–40 °C to 105 °C
–1.5
3-MHz frequency stability after typical Typical (non-optimized) board layout and
–
PCB assembly post-reflow
250 °C solder reflow. Device may be calibrated
after assembly to improve performance.
Typ
Max
Units
–
–
–
–
–
–
–
–
–
±2%
7
7
5
4
0.25
3
2
1
1.5
–
%
%
%
%
%
%
%
%
%
%
Note
97. Based on device characterization (Not production tested).
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Datasheet
Table 11-80. IMO AC Specifications (continued)
Parameter
Description
[99]
Tstart_imo Startup time
Jitter (peak to peak)[99]
Jp-p
F = 24 MHz
F = 3 MHz
Jitter (long term)[100]
Jperiod
F = 24 MHz
F = 3 MHz
Conditions
From enable (during normal system operation)
Figure 11-82. IMO Frequency Variation vs. Temperature
Min
–
Typ
–
Max
13
Units
µs
–
–
0.9
1.6
–
–
ns
ns
–
–
0.9
12
–
–
ns
ns
Figure 11-83. IMO Frequency Variation vs. VCC
0.5
62.6 MHz
24 MHz
3 MHz
% Variation
0.25
0
-0.25
-0.5
-40
-20
0
20
40
60
Temperature, °C
80
100
Notes
98. FIMO is measured after packaging, and thus accounts for substrate and die attach stresses.
99. Based on device characterization (Not production tested).
100.Based on device characterization (Not production tested). USBIO pins tied to ground (VSSD).
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Datasheet
11.9.2 Internal Low-Speed Oscillator
Table 11-81. ILO DC Specifications
Parameter
Description
Operating
Conditions
current[101]
ICC
Min
Typ
Max
Units
FOUT = 1 kHz
–
–
1.7
µA
FOUT = 33 kHz
–
–
2.6
µA
FOUT = 100 kHz
–
–
2.6
µA
Power down mode
–
–
15
nA
Min
Typ
Max
Units
–
–
2
ms
100 kHz
45
100
200
kHz
1 kHz
0.5
1
2
kHz
Leakage current[101]
Table 11-82. ILO AC Specifications[102]
Parameter
Tstart_ilo
Description
Conditions
Startup time, all frequencies
Turbo mode
ILO frequencies
FILO
Figure 11-84. ILO Frequency Variation vs. Temperature
Figure 11-85. ILO Frequency Variation vs. VDD
20
50
10
% Variiation
% Variation
25
0
100 kHz
-25
0
100 kHz
-10
1 kHz
1 kHz
-20
-50
-40
-20
0
20
40
60
80
Temperature, °C
100
1.5
2.5
3.5
4.5
5.5
VDDD, V
Notes
101.This value is calculated, not measured.
102.Based on device characterization (Not production tested).
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Datasheet
11.9.3 MHz External Crystal Oscillator
For more information on crystal or ceramic resonator selection for the MHzECO, refer to application note AN54439: PSoC 3 and
PSoC 5 External Oscillators.
Table 11-83. MHzECO DC Specifications
Parameter
ICC
Description
Operating
current[103]
Conditions
Min
Typ
Max
Units
–
3.8
–
mA
Min
Typ
Max
Units
4
–
25
MHz
Min
–
–
Typ
0.25
–
Max
1.0
1
Units
µA
µW
Min
Typ
Max
Units
–
32.768
–
kHz
–
1
–
s
Measured at VDDIO/2
VIL to VIH
Min
0
30
0.5
Typ
–
50
–
Max
33
70
–
Units
MHz
%
V/ns
Conditions
In = 3 MHz, Out = 80 MHz
In = 3 MHz, Out = 67 MHz
In = 3 MHz, Out = 24 MHz
Min
–
–
–
Typ
650
400
200
Max
–
–
–
Units
µA
µA
µA
Min
1
1
24
–
–
Typ
–
–
–
–
–
Max
48
3
80
250
250
Units
MHz
MHz
MHz
µs
ps
13.56 MHz crystal
Table 11-84. MHzECO AC Specifications
Parameter
F
Description
Conditions
Crystal frequency range
11.9.4 kHz External Crystal Oscillator
Table 11-85. kHzECO DC Specifications[103]
Parameter
Description
Operating current
ICC
DL
Drive level
Conditions
Low power mode; CL = 6 pF
Table 11-86. kHzECO AC Specifications[103]
Parameter
Description
F
Frequency
TON
Startup time
Conditions
High power mode
11.9.5 External Clock Reference
Table 11-87. External Clock Reference AC Specifications[103]
Parameter
Description
External frequency range
Input duty cycle range
Input edge rate
Conditions
11.9.6 Phase-Locked Loop
Table 11-88. PLL DC Specifications
Parameter
Description
PLL operating current
IDD
Table 11-89. PLL AC Specifications
Parameter
Description
Fpllin
PLL input frequency[104]
PLL intermediate frequency[105]
Fpllout
PLL output frequency[104]
Lock time at startup
Jperiod-rms Jitter (rms)[103]
Conditions
Output of prescaler
Notes
103.Based on device characterization (Not production tested).
104.This specification is guaranteed by testing the PLL across the specified range using the IMO as the source for the PLL.
105.PLL input divider, Q, must be set so that the input frequency is divided down to the intermediate frequency range. Value for Q ranges from 1 to 16.
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�PSoC® 5LP: CY8C58LP Family
Datasheet
12. Ordering Information
In addition to the features listed in Table 12-1, every CY8C58LP device includes: up to 256 KB flash, 64 KB SRAM, 2 KB EEPROM,
a precision on-chip voltage reference, precision oscillators, flash, ECC, DMA, a fixed function I2C, JTAG/SWD programming and
debug, external memory interface, boost, and more. In addition to these features, the flexible UDBs and analog subsection support
a wide range of peripherals. To assist you in selecting the ideal part, PSoC Creator makes a part recommendation after you choose
the components required by your application. All CY8C58LP derivatives incorporate device and flash security in user-selectable
security levels; see the TRM for details.
Table 12-1. CY8C58LP Family with Arm Cortex-M3 CPU
I/O[108]
16-BIT TIMER/PWM
FS USB
CAN 2.0B
GPIO
SIO
USBIO
4
4
4
✔ ✔ 24 4
–
–
70 62
8
0
100-TQFP
0x2E11F069
CY8C5868AXI-LP032
67 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
–
72 62
8
2
100-TQFP
0x2E120069
CY8C5868AXI-LP035
67 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
✔ 72 62
8
2
100-TQFP
0x2E123069
CY8C5868LTI-LP036
67 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
–
–
46 38
8
0
68-QFN
0x2E124069
CY8C5868LTI-LP038
67 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
–
48 38
8
2
68-QFN
0x2E126069
CY8C5868LTI-LP039
67 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
✔ 48 38
8
2
68-QFN
0x2E127069
CY8C5867AXI-LP023
67 128 32
2
✔
1x20-bit Del-Sig
1x12-bit SAR
4
4
4
4
✔ ✔ 24 4
–
–
70 62
8
0
100-TQFP
0x2E117069
CY8C5867AXI-LP024
67 128 32
2
✔
1x20-bit Del-Sig
1x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
–
72 62
8
2
100-TQFP
0x2E118069
CY8C5867LTI-LP025
67 128 32
2
✔
1x20-bit Del-Sig
1x12-bit SAR
4
4
4
4
✔ ✔ 24 4
–
–
46 38
8
0
68-QFN
0x2E119069
CY8C5867LTI-LP028
67 128 32
2
✔
1x20-bit Del-Sig
1x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
–
48 38
8
2
68-QFN
0x2E11C069
CY8C5866AXI-LP020
67
64
16
2
✔
1x20-bit Del-Sig
1x12-bit SAR
4
4
4
4
✔ ✔ 20 4
✔
✔ 72 62
8
2
100-TQFP
0x2E114069
CY8C5866AXI-LP021
67
64
16
2
✔
1x20-bit Del-Sig
1x12-bit SAR
4
4
4
4
✔ ✔ 20 4
✔
–
72 62
8
2
100-TQFP
0x2E115069
CY8C5866LTI-LP022
67
64
16
2
✔
1x20-bit Del-Sig
1x12-bit SAR
4
4
4
4
✔ ✔ 20 4
✔
–
48 38
8
2
68-QFN
0x2E116069
CY8C5888AXI-LP096
80 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
✔ 72 62
8
2
100-TQFP
0x2E160069
CY8C5888AXQ-LP096
80 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
✔ 72 62
8
2
100-TQFP
0x2E160069
CY8C5888LTI-LP097
80 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
✔ 48 38
8
2
68-QFN
0x2E161069
CY8C5888LTQ-LP097
80 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
✔ 48 38
8
2
68-QFN
0x2E161069
CY8C5888FNI-LP210
80 256 64
2
✔
4
4
4
4
✔ ✔ 24 4
✔
✔ 72 62
8
2
99-WLCSP
0x2E1D2069
CY8C5888FNI-LP214
80 256 64
2
✔
1x20-bit Del-Sig
2x12-bit SAR
1x20-bit Del-Sig
2x12-bit SAR
4
4
4
4
✔ ✔ 24 4
✔
–
8
2
99-WLCSP
0x2E1D6069
TOTAL I/O
OPAMPS
4
UDBS[107]
SC/CT
ANALOG BLOCKS[106]
1x20-bit Del-Sig
2x12-bit SAR
CAPSENSE
COMPARATORS
✔
DFB
DAC
2
ADCS
67 256 64
FLASH (KB)
CY8C5868AXI-LP031
Part Number
CPU SPEED (MHZ)
LCD SEGMENT DRIVE
Digital
EEPROM (KB)
Analog
SRAM (KB)
MCU Core
72 62
Package
JTAG ID[109]
Notes
106.Analog blocks support a wide variety of functionality including TIA, PGA, and mixers. See Example Peripherals on page 40 for more information on how analog blocks
can be used.
107.UDBs support a wide variety of functionality including SPI, LIN, UART, timer, counter, PWM, PRS, and others. Individual functions may use a fraction of a UDB or
multiple UDBs. Multiple functions can share a single UDB. See Example Peripherals on page 40 for more information on how UDBs can be used.
108.The I/O Count includes all types of digital I/O: GPIO, SIO, and the two USB I/O. See “I/O System and Routing” section on page 33 for details on the functionality of
each of these types of I/O.
109.The JTAG ID has three major fields. The most significant nibble (left digit) is the version, followed by a 2 byte part number and a 3 nibble manufacturer ID.
Document Number: 001-84932 Rev. *N
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Datasheet
12.1 Part Numbering Conventions
PSoC 5LP devices follow the part numbering convention described here. All fields are single character alphanumeric (0, 1, 2, …, 9,
A, B, …, Z) unless stated otherwise.
CY8Cabcdefg-LPxxx
a: Architecture
ef: Package code
3: PSoC 3
5: PSoC 5
Two character alphanumeric
AX: TQFP
LT: QFN
PV: SSOP
FN: CSP
b: Family group within architecture
2: CY8C52LP family
4: CY8C54LP family
6: CY8C56LP family
8: CY8C58LP family
g: Temperature Range
C: Commercial
I: Industrial
Q: Extended
A: Automotive
c: Speed grade
6: 67 MHz
8: 80 MHz
xxx: Peripheral set
d: Flash capacity
5: 32 KB
6: 64 KB
7: 128 KB
8: 256 KB
Examples
Three character numeric
No meaning is associated with these three characters
CY8C
5 8 8 8 AX/PV I - LPx x x
Cypress Prefix
5: PSoC 5
8: CY8C58LP Family
Architecture
Family Group within Architecture
8: 80 MHz
Speed Grade
8: 256 KB
Flash Capacity
AX: TQFP, PV: SSOP
Package Code
I: Industrial
Temperature Range
Peripheral Set
Tape and reel versions of these devices are available and are marked with a “T” at the end of the part number.
All devices in the PSoC 5LP CY8C58LP family comply to RoHS-6 specifications, demonstrating the commitment by Cypress to
lead-free products. Lead (Pb) is an alloying element in solders that has resulted in environmental concerns due to potential toxicity.
Cypress uses nickel-palladium-gold (NiPdAu) technology for the majority of leadframe-based packages.
A high level review of the Cypress Pb-free position is available on our website. Specific package information is also available. Package
Material Declaration Datasheets (PMDDs) identify all substances contained within Cypress packages. PMDDs also confirm the
absence of many banned substances. The information in the PMDDs will help Cypress customers plan for recycling or other “end of
life” requirements.
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Datasheet
13. Packaging
Table 13-1. Package Characteristics
Min
Typ
Max
Units
TA
Parameter
Operating ambient temperature
Description
Conditions
–40
25
105
°C
TJ
Operating junction temperature
–40
–
120
°C
TJA
Package θJA (68-pin QFN)
–
15
–
°C/Watt
TJA
Package θJA (100-pin TQFP)
–
34
–
°C/Watt
TJC
Package θJC (68-pin QFN)
–
13
–
°C/Watt
TJC
Package θJC (100-pin TQFP)
–
10
–
°C/Watt
TA
Operating ambient temperature
For CSP parts
–40
25
85
°C
TJ
Operating junction temperature
For CSP parts
–40
–
100
TJA
Package θJA (99-ball CSP)
TJc
Package θJC (99-ball CSP)
16.5
–
0.1
°C
°C/Watt
–
°C/Watt
Table 13-2. Solder Reflow Peak Temperature
Package
Maximum Peak
Temperature
Maximum Time at
Peak Temperature
68-pin QFN
260 °C
30 seconds
100-pin TQFP
260 °C
30 seconds
99-ball WLCSP
255 °C
30 seconds
Table 13-3. Package Moisture Sensitivity Level (MSL), IPC/JEDEC J-STD-2
Package
MSL
68-pin QFN
MSL 3
100-pin TQFP
MSL 3
99-ball WLCSP
MSL1
Document Number: 001-84932 Rev. *N
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�PSoC® 5LP: CY8C58LP Family
Datasheet
Figure 13-1. 68-pin QFN 8x8 with 0.4 mm Pitch Package Outline (Sawn Version)
001-09618 *E
Figure 13-2. 100-pin TQFP (14 x 14 x 1.4 mm) Package Outline
51-85048 *K
Document Number: 001-84932 Rev. *N
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Datasheet
Figure 13-3. WLCSP Package (5.192 × 5.940 × 0.6 mm) Package Outline
001-88034 *B
Document Number: 001-84932 Rev. *N
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Datasheet
14. Acronyms
Table 14-1. Acronyms Used in this Document (continued)
Table 14-1. Acronyms Used in this Document
Acronym
Description
Acronym
Description
FIR
finite impulse response, see also IIR
FPB
flash patch and breakpoint
FS
full-speed
GPIO
general-purpose input/output, applies to a PSoC
pin
HVI
high-voltage interrupt, see also LVI, LVD
abus
analog local bus
ADC
analog-to-digital converter
AG
analog global
AHB
AMBA (advanced microcontroller bus architecture) high-performance bus, an Arm data
transfer bus
IC
integrated circuit
ALU
arithmetic logic unit
IDAC
current DAC, see also DAC, VDAC
AMUXBUS
analog multiplexer bus
IDE
integrated development environment
application programming interface
I2C,
API
APSR
application program status register
Arm®
advanced RISC machine, a CPU architecture
ATM
automatic thump mode
BW
bandwidth
CAN
Controller Area Network, a communications
protocol
CMRR
or IIC
Inter-Integrated Circuit, a communications
protocol
IIR
infinite impulse response, see also FIR
ILO
internal low-speed oscillator, see also IMO
IMO
internal main oscillator, see also ILO
INL
integral nonlinearity, see also DNL
I/O
input/output, see also GPIO, DIO, SIO, USBIO
common-mode rejection ratio
IPOR
initial power-on reset
CPU
central processing unit
IPSR
interrupt program status register
CRC
cyclic redundancy check, an error-checking
protocol
IRQ
interrupt request
DAC
digital-to-analog converter, see also IDAC, VDAC
ITM
instrumentation trace macrocell
DFB
digital filter block
LCD
liquid crystal display
DIO
digital input/output, GPIO with only digital
capabilities, no analog. See GPIO.
LIN
Local Interconnect Network, a communications
protocol.
DMA
direct memory access, see also TD
LR
link register
DNL
differential nonlinearity, see also INL
LUT
lookup table
DNU
do not use
LVD
low-voltage detect, see also LVI
DR
port write data registers
LVI
low-voltage interrupt, see also HVI
DSI
digital system interconnect
LVTTL
low-voltage transistor-transistor logic
DWT
data watchpoint and trace
MAC
multiply-accumulate
ECC
error correcting code
MCU
microcontroller unit
ECO
external crystal oscillator
MISO
master-in slave-out
EEPROM
electrically erasable programmable read-only
memory
NC
no connect
NMI
nonmaskable interrupt
NRZ
non-return-to-zero
NVIC
nested vectored interrupt controller
NVL
nonvolatile latch, see also WOL
EMI
electromagnetic interference
EMIF
external memory interface
EOC
end of conversion
EOF
end of frame
EPSR
execution program status register
ESD
electrostatic discharge
ETM
embedded trace macrocell
Document Number: 001-84932 Rev. *N
opamp
operational amplifier
PAL
programmable array logic, see also PLD
PC
program counter
PCB
printed circuit board
PGA
programmable gain amplifier
Page 132 of 139
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Datasheet
Table 14-1. Acronyms Used in this Document (continued)
Acronym
Description
Table 14-1. Acronyms Used in this Document (continued)
Acronym
Description
PHUB
peripheral hub
TIA
transimpedance amplifier
PHY
physical layer
TRM
technical reference manual
PICU
port interrupt control unit
TTL
transistor-transistor logic
PLA
programmable logic array
TX
transmit
PLD
programmable logic device, see also PAL
UART
PLL
phase-locked loop
Universal Asynchronous Transmitter Receiver, a
communications protocol
PMDD
package material declaration datasheet
POR
power-on reset
PRES
precise low-voltage reset
PRS
pseudo random sequence
PS
port read data register
PSoC®
Programmable System-on-Chip™
PSRR
power supply rejection ratio
PWM
pulse-width modulator
RAM
random-access memory
RISC
reduced-instruction-set computing
RMS
root-mean-square
RTC
real-time clock
RTL
register transfer language
RTR
remote transmission request
RX
receive
SAR
successive approximation register
SC/CT
switched capacitor/continuous time
SCL
I2C serial clock
SDA
I2C serial data
S/H
sample and hold
SINAD
signal to noise and distortion ratio
SIO
special input/output, GPIO with advanced
features. See GPIO.
SOC
start of conversion
SOF
start of frame
SPI
Serial Peripheral Interface, a communications
protocol
SR
slew rate
SRAM
static random access memory
SRES
software reset
SWD
serial wire debug, a test protocol
SWV
single-wire viewer
TD
transaction descriptor, see also DMA
THD
total harmonic distortion
Document Number: 001-84932 Rev. *N
UDB
universal digital block
USB
Universal Serial Bus
USBIO
USB input/output, PSoC pins used to connect to
a USB port
VDAC
voltage DAC, see also DAC, IDAC
WDT
watchdog timer
WOL
write once latch, see also NVL
WRES
watchdog timer reset
XRES
external reset pin
XTAL
crystal
Page 133 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
15. Document Conventions
15.1 Units of Measure
Table 15-1. Units of Measure
Symbol
Unit of Measure
°C
degrees Celsius
dB
decibels
fF
femtofarads
Hz
hertz
KB
1024 bytes
kbps
kilobits per second
Khr
kilohours
kHz
kilohertz
kΩ
kilohms
ksps
kilosamples per second
LSB
least significant bit
Mbps
megabits per second
MHz
megahertz
MΩ
megaohms
Msps
megasamples per second
µA
microamperes
µF
microfarads
µH
microhenrys
µs
microseconds
µV
microvolts
µW
microwatts
mA
milliamperes
ms
milliseconds
mV
millivolts
nA
nanoamperes
ns
nanoseconds
nV
nanovolts
Ω
ohms
pF
picofarads
ppm
parts per million
ps
picoseconds
s
seconds
sps
samples per second
sqrtHz
square root of hertz
V
volts
Document Number: 001-84932 Rev. *N
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�PSoC® 5LP: CY8C58LP Family
Datasheet
Document History Page
Description Title: PSoC® 5LP: CY8C58LP Family Datasheet Programmable System-on-Chip (PSoC®)
Document Number: 001-84932
Revision
ECN
Submission
Date
**
3825653
12/07/2012
Datasheet for new CY8C58LP family
*A
3897878
02/07/2013
Updated characterization footnotes in Electrical Specifications.
Updated conditions for SAR ADC INL and DNL specifications in Table 11-28
Changed number of opamps in Ordering Information
Removed Preliminary status
Removed references to CAN.
Updated INL VIDAC spec.
Description of Change
*B
3902085
02/12/2013
Changed Hibernate wakeup time from 125 µs to 200 µs in Table 6-3 and Table 11-3.
*C
3917994
01/03/2013
Added Controller Area Network (CAN) content.
*D
4114902
09/30/2013
Added information about 1 KB cache in Features.
Added warning on reset devices in the EEPROM section.
Added DBGEN field in Table 5-3.
Deleted statement about repeat start from the I2C section.
Removed TSTG spec from Table 11-1 and added a note clarifying the maximum storage
temperature range.
Updated chip Idd, regulator, opamp, delta-sigma ADC, SAR ADC, IDAC, and VDAC graphs.
Added min and max values for the Regulator Output Capacitor parameter.
Updated CIN specs in GPIO DC Specifications and SIO DC Specifications.
Updated rise and fall time specs in Fast Strong mode in Table 11-9, and deleted related
graphs.
Added IIB parameter in Opamp DC Specifications
Updated Vos spec conditions and changed TCVos max value from 0.55 to 1 in Table 11-20.
Updated Voltage Reference Specifications and IMO AC Specifications.
Updated FIMO spec (3 MHz).
Updated 100-TQFP package diagram.
Added Appendix for CSP package (preliminary).
*E
4225729
12/20/2013
Added SIO Comparator Specifications.
Changed THIBERNATE wakeup spec from 200 to 150 µs.
Updated CSP package details and ordering information.
Added 80 MHz parts in Table 12-1.
*F
4386988
05/22/2014
Updated General Description and Features.
Added More Information and PSoC Creator sections.
Updated JTAG IDs in Ordering Information.
Updated 100-TQFP package diagram.
*G
4587100
12/08/2014
Added link to AN72845 in Note 3.
Updated interrupt priority numbers in Section 4.4.
Updated Section 5.4 to clarify the factory default values of EEPROM.
Corrected ECCEN settings in Table 5-3.
Updated Section 6.1.1 and Section 6.1.2.
Added a note below Figure 6-4.
Updated Figure 6-11.
Changed ‘Control Store RAM’ to ‘Dynamic Configuration RAM’ in Figure 7-4 and changed
Section 7.2.2.2 heading to ‘Dynamic Configuration RAM’.
Updated Section 7.8.
Document Number: 001-84932 Rev. *N
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�PSoC® 5LP: CY8C58LP Family
Datasheet
Document History Page (continued)
Description Title: PSoC® 5LP: CY8C58LP Family Datasheet Programmable System-on-Chip (PSoC®)
Document Number: 001-84932
Revision
ECN
Submission
Date
Description of Change
*H
4698847
03/24/2015
Updated Features:
Added “Extended temperature parts: –40 to 105 °C” as indented under “Temperature range
(ambient)” under “Operating characteristics”.
Updated System Integration:
Updated Power System:
Updated Boost Converter:
Updated entire section.
Updated Electrical Specifications:
Replaced “Specifications are valid for –40 °C ≤ TA ≤ 85 °C and TJ ≤ 100 °C, except where
noted.” with “Specifications are valid for –40 °C ≤ TA ≤ 105 °C and TJ ≤ 120 °C, except
where noted.” in all instances.
Updated Device Level Specifications:
Updated Table 11-2:
Added details of IDD parameter corresponding to “T = 105 °C”.
Updated Figure 11-3 and Figure 11-4.
Updated Power Regulators:
Updated Inductive Boost Regulator:
Updated Table 11-6:
Updated details of VBAT, IOUT, VOUT, RegLOAD, RegLINE parameters.
Removed VOUT: VBAT parameter and its details.
Removed Table “Inductive Boost Regulator AC Specifications”.
Updated Table 11-7:
Updated details of LBOOST, CBOOST parameters.
Added CBAT parameter and its details.
Added Figure 11-8, Figure 11-9, Figure 11-10, Figure 11-11, Figure 11-12, Figure 11-13,
Figure 11-14.
Removed Figure “Efficiency vs IOUT VBOOST = 3.3 V, LBOOST = 10 μH”.
Removed Figure “Efficiency vs IOUT VBOOST = 3.3 V, LBOOST = 22 μH”.
Updated Analog Peripherals:
Updated Opamp:
Updated Figure 11-26.
Updated Delta-Sigma ADC:
Updated Table 11-20:
Added details of CMRRb parameter corresponding to condition “TA ≤ 105 °C”.
Updated Table 11-21:
Added details of SINAD16int parameter corresponding to condition
“TA ≤ 105 °C”.
Updated Voltage Reference:
Updated Table 11-27:
Added details of VREF parameter corresponding to condition “105 °C”.
Updated Figure 11-39.
Updated Current Digital-to-analog Converter (IDAC):
Updated Figure 11-51, Figure 11-52, Figure 11-53, Figure 11-54, Figure 11-55,
Figure 11-56.
Updated Voltage Digital to Analog Converter (VDAC):
Updated Figure 11-63, Figure 11-64, Figure 11-65, Figure 11-66, Figure 11-67,
Figure 11-68.
Updated Programmable Gain Amplifier:
Updated Table 11-43:
Added details of BW1 parameter corresponding to condition “TA ≤ 105 °C”.
Updated Figure 11-74.
Updated Temperature Sensor:
Updated Table 11-44:
Replaced 85 °C with 105 °C.
Document Number: 001-84932 Rev. *N
Page 136 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Document History Page (continued)
Description Title: PSoC® 5LP: CY8C58LP Family Datasheet Programmable System-on-Chip (PSoC®)
Document Number: 001-84932
Revision
ECN
Submission
Date
Description of Change
*H (cont.)
4698847
03/24/2015
Updated Electrical Specifications:
Updated Memory:
Updated Flash:
Updated Table 11-62:
Updated details in “Conditions” column corresponding to “Flash data retention time”
parameter.
Added Note 80 and referred the same note in last condition corresponding to “Flash data
retention time” parameter.
Updated EEPROM:
Updated Table 11-64:
Updated details in “Conditions” column corresponding to “EEPROM data retention time”
parameter.
Added Note 80 and referred the same note in last condition corresponding to “EEPROM
data retention time” parameter.
Updated Nonvolatile Latches (NVL):
Updated Table 11-66:
Updated details in “Conditions” column corresponding to “NVL data retention time”
parameter.
Added Note 81 and referred the same note in last condition corresponding to “NVL data
retention time” parameter.
Updated Clocking:
Updated Internal Main Oscillator:
Updated Table 11-80:
Replaced 85 °C with 105 °C.
Updated Figure 11-83.
Updated Ordering Information:
Updated Table 12-1:
Updated part numbers.
Updated Part Numbering Conventions:
Added “Q: Extended” as sub bullet under “g: Temperature Range”.
Updated Packaging:
Updated Table 13-1:
Changed maximum value of TA parameter from 85 °C to 105 °C.
Changed maximum value of TJ parameter from 100 °C to 120 °C.
Updated :
Updated :
spec 001-88034 – Changed revision from ** to *A.
*I
4839323
07/15/2015
Document Number: 001-84932 Rev. *N
Added reference to code examples in More Information.
Updated typ value of TWRITE from 2 to 10 in EEPROM AC specs table.
Changed “Device supply for USB operation" to "Device supply (VDDD) for USB operation"
in USB DC Specifications.
Clarified power supply sequencing and margin for VDDA and VDDD.
Updated Serial Wire Debug Interface with limitations of debugging on Port 15.
Updated Delta-sigma ADC DC Specifications
Page 137 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Document History Page (continued)
Description Title: PSoC® 5LP: CY8C58LP Family Datasheet Programmable System-on-Chip (PSoC®)
Document Number: 001-84932
Revision
ECN
Submission
Date
Description of Change
*J
5030641
11/30/2015
Added Table 2-1.
Removed the configurable XRES information.
Updated Section 5.6
Updated Section 6.3.1.1.
Updated values for DSI Fmax, Fgpioin max, and Fsioin max.
Corrected the web link for the PSoC 5 Device Programming Specifications in Section 9.
Updated CSP Package Bootloader section.
Added MHzECO DC Specifications.
Updated 99-WLCSP and 100-pin TQFP package drawings.
Added a footnote reference for the “CY8C5287AXI-LP095” part in Table 12-1 clarifying that
it has 256 KB flash.
Added the CY8C5667AXQ-LP040 part in Table 12-1.
*K
5478402
10/25/2016
Updated More Information.
Add Links to CAD Libraries in Section 2.
Corrected typos in External Electrical Connections.
*L
5703770
04/20/2017
Updated the Cypress logo and copyright information.
*M
6385319
11/15/2018
Added a footnote on DNU pins for the WLCSP pinout table.
Updated the links in Sales, Solutions, and Legal Information.
*N
6739970
11/27/2019
Updated the paragraph in section Inputs and Outputs.
Completing Sunset review.
Document Number: 001-84932 Rev. *N
Page 138 of 139
�PSoC® 5LP: CY8C58LP Family
Datasheet
Sales, Solutions, and Legal Information
Worldwide Sales and Design Support
Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office
closest to you, visit us at Cypress Locations.
PSoC® Solutions
Products
Arm® Cortex® Microcontrollers
Automotive
cypress.com/arm
cypress.com/automotive
Clocks & Buffers
Interface
cypress.com/clocks
cypress.com/interface
Internet of Things
Memory
cypress.com/iot
cypress.com/memory
Microcontrollers
cypress.com/mcu
PSoC
cypress.com/psoc
Power Management ICs
Cypress Developer Community
Community | Projects | Video | Blogs | Training | Components
Technical Support
cypress.com/support
cypress.com/pmic
Touch Sensing
cypress.com/touch
USB Controllers
Wireless Connectivity
PSoC 1 | PSoC 3 | PSoC 4 | PSoC 5LP | PSoC 6 MCU
cypress.com/usb
cypress.com/wireless
© Cypress Semiconductor Corporation, 2012-2019. This document is the property of Cypress Semiconductor Corporation and its subsidiaries (“Cypress”). This document, including any software or
firmware included or referenced in this document (“Software”), is owned by Cypress under the intellectual property laws and treaties of the United States and other countries worldwide. Cypress reserves
all rights under such laws and treaties and does not, except as specifically stated in this paragraph, grant any license under its patents, copyrights, trademarks, or other intellectual property rights. If
the Software is not accompanied by a license agreement and you do not otherwise have a written agreement with Cypress governing the use of the Software, then Cypress hereby grants you a
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indirectly through resellers and distributors), solely for use on Cypress hardware product units, and (2) under those claims of Cypress's patents that are infringed by the Software (as provided by
Cypress, unmodified) to make, use, distribute, and import the Software solely for use with Cypress hardware products. Any other use, reproduction, modification, translation, or compilation of the
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TO THE EXTENT PERMITTED BY APPLICABLE LAW, CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS DOCUMENT OR ANY SOFTWARE
OR ACCOMPANYING HARDWARE, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. No computing
device can be absolutely secure. Therefore, despite security measures implemented in Cypress hardware or software products, Cypress shall have no liability arising out of any security breach, such
as unauthorized access to or use of a Cypress product. CYPRESS DOES NOT REPRESENT, WARRANT, OR GUARANTEE THAT CYPRESS PRODUCTS, OR SYSTEMS CREATED USING
CYPRESS PRODUCTS, WILL BE FREE FROM CORRUPTION, ATTACK, VIRUSES, INTERFERENCE, HACKING, DATA LOSS OR THEFT, OR OTHER SECURITY INTRUSION (collectively,
“Security Breach”). Cypress disclaims any liability relating to any Security Breach, and you shall and hereby do release Cypress from any claim, damage, or other liability arising from any Security
Breach. In addition, the products described in these materials may contain design defects or errors known as errata which may cause the product to deviate from published specifications. To the extent
permitted by applicable law, Cypress reserves the right to make changes to this document without further notice. Cypress does not assume any liability arising out of the application or use of any
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the responsibility of the user of this document to properly design, program, and test the functionality and safety of any application made of this information and any resulting product. “High-Risk Device”
means any device or system whose failure could cause personal injury, death, or property damage. Examples of High-Risk Devices are weapons, nuclear installations, surgical implants, and other
medical devices. “Critical Component” means any component of a High-Risk Device whose failure to perform can be reasonably expected to cause, directly or indirectly, the failure of the High-Risk
Device, or to affect its safety or effectiveness. Cypress is not liable, in whole or in part, and you shall and hereby do release Cypress from any claim, damage, or other liability arising from any use of
a Cypress product as a Critical Component in a High-Risk Device. You shall indemnify and hold Cypress, its directors, officers, employees, agents, affiliates, distributors, and assigns harmless from
and against all claims, costs, damages, and expenses, arising out of any claim, including claims for product liability, personal injury or death, or property damage arising from any use of a Cypress
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use the product as a Critical Component in the specific High-Risk Device and you have signed a separate indemnification agreement.
Cypress, the Cypress logo, Spansion, the Spansion logo, and combinations thereof, WICED, PSoC, CapSense, EZ-USB, F-RAM, and Traveo are trademarks or registered trademarks of Cypress in
the United States and other countries. For a more complete list of Cypress trademarks, visit cypress.com. Other names and brands may be claimed as property of their respective owners.
Document Number: 001-84932 Rev. *N
Revised November 27, 2019
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