Cypress CYRF89135 8-bit flash based mcu function and 2.4-ghz wirelessusb nl radio transceiver function in a single device Datasheet

CYRF89135
PRoC™ - Embedded
PRoC™ - Embedded
Internal low-speed oscillator (ILO) at 32 kHz for watchdog
and sleep timers
❐ Precision 32 kHz oscillator for optional external crystal
PRoC™ – Embedded Features
■
■
❐
Single Device, two functions
❐ 8-bit flash based MCU function and 2.4-GHz WirelessUSB™
NL radio transceiver function in a single device
RF Attributes
❐ Wide operating range: 1.9 V to 3.6 V
❐ 2.4-GHz WirelessUSB NL Transceiver function
❐ Operates in the 2.4-GHz ISM Band (2.402 GHz–2.479 GHz)
❐ 1-Mbps over-the-air data rate
❐ Receive sensitivity typical: –87 dBm
❐ 1 μA typical current consumption in sleep state
❐ Closed-loop frequency synthesis
❐ Supports frequency-hopping spread spectrum
❐ On-chip packet framer with 64-byte first in first out (FIFO)
data buffer
❐ Built-in auto-retry-acknowledge protocol simplifies usage
❐ Built-in cyclic redundancy check (CRC), forward error
correction (FEC), data whitening
❐ Additional outputs for interrupt request (IRQ) generation
❐ Digital readout of received signal strength indication (RSSI)
■
MCU Attributes
❐ Powerful Harvard-architecture processor
❐ M8C CPU – Up to 4 MIPS with 24 MHz Internal clock, external
crystal resonator or clock signal
❐ Low power at high speed
■
Temperature range: 0 °C to +70 °C
■
Flexible on-chip memory
❐ 32 KB Flash/2 KB SRAM
❐ 50,000 flash erase/write cycles
❐ Partial flash updates
❐ Flexible protection modes
❐ In-system serial programming (ISSP)
■
Precision, programmable clocking
❐ Internal main oscillator (IMO): 6/12/24 MHz ± 5%
Cypress Semiconductor Corporation
Document Number: 001-86331 Rev. **
•
■
Programmable pin configurations
❐ Up to 35 general-purpose I/Os (GPIOs)
❐ Dual mode GPIO: All GPIOs support digital I/O and analog
inputs
❐ 25-mA sink current on each GPIO
• 120 mA total sink current on all GPIOs
❐ Pull-up, high Z, open-drain modes on all GPIOs
❐ CMOS drive mode –5 mA source current on ports 0 and 1
and 1 mA on port 2
❐ 20 mA total source current on port 1.
❐ Configurable input threshold for Port 1.
■
Versatile analog system
❐ Low-dropout voltage regulator for all analog resources
❐ High power supply rejection ratio (PSRR) comparator
❐ 8 to 10-bit incremental analog-to-digital converter (ADC)
■
Additional system resources
2
❐ I C slave:
• Selectable to 50 kHz, 100 kHz, or 400 kHz
❐ SPI master and slave: Configurable 46.9 kHz to 12 MHz
❐ Three 16-bit timers
❐ Watchdog and sleep timers
❐ Integrated supervisory circuit
❐ Emulated E2PROM using flash memory
■
Complete development tools
❐ Free development tool (PSoC Designer™)
❐ Full-featured, in-circuit emulator (ICE) and programmer
❐ Full-speed emulation
❐ Complex breakpoint structure
❐ 128 KB trace memory
■
Package option
❐ 68-pin 8mm × 8mm × 1.0 mm QFN
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised April 3, 2013
CYRF89135
Logical Block Diagram
Port 4
Port 3
Port 2
Port 1
Port 0
Prog. LDO
PSoC Core
PWR Sys
(Regulator)
System Bus
SRAM
2048 Bytes
Interrupt
Controller
SROM
32K Flash
Sleep and
Watchdog
CPU Core (M8C)
6/12/24 MHz Internal Main Oscillator
Internal Low Speed Oscillator (ILO
Multiple Clock Sources
VIN
VOUT
WIRELESSUSB-NL
SYSTEM
VDD_IO
LDO Linear
Regulator
GFSK
Modulator
PKT
FIFO
RST_n
Framer
SPI Registers
PA
Synthesizer
ANT
ANTb
VCO
Pwr/ Reset
BRCLK
Xtal Osc
GFSK
Demodulator
X
Image
Rej . Mxr.
XTALi
I2C Slave
LNA + BPF
XTALo
Internal Voltage
References
System
Resets
SPI
Master/
Slave
Three 16 bit
Timers
POR
and
LVD
Digital
Clocks
SYSTEM RESOURCES
Document Number: 001-86331 Rev. **
Page 2 of 41
CYRF89135
Contents
PSoC® Functional Overview ............................................ 4
PSoC Core .................................................................. 4
10 bit ADC ................................................................... 4
SPI ............................................................................... 5
I2C Slave ..................................................................... 5
WirelessUSB NL System ............................................. 5
Transmit Power Control ............................................... 6
Power-on and Register Initialization Sequence ........... 6
Getting Started .................................................................. 7
Development Kits ........................................................ 7
Training ....................................................................... 7
CYPros Consultants .................................................... 7
Solutions Library .......................................................... 7
Technical Support ....................................................... 7
Development Tools .......................................................... 8
PSoC Designer Software Subsystems ........................ 8
Designing with PSoC Designer ....................................... 9
Select User Modules ................................................... 9
Configure User Modules .............................................. 9
Organize and Connect ................................................ 9
Generate, Verify, and Debug ....................................... 9
Pinouts ............................................................................ 10
Pin Definitions ................................................................ 10
Absolute Maximum Ratings .......................................... 13
Operating Temperature .................................................. 13
Electrical Specifications – PSoC Core ......................... 14
DC Chip-Level Specifications .................................... 15
DC GPIO Specifications ............................................ 16
Analog DC Mux Bus Specifications ........................... 18
DC Low Power Comparator Specifications ............... 18
Comparator User Module Electrical Specifications ... 18
ADC Electrical Specifications .................................... 19
DC POR and LVD Specifications .............................. 20
Document Number: 001-86331 Rev. **
DC Programming Specifications ............................... 21
DC I2C Specifications ............................................... 22
DC Reference Buffer Specifications .......................... 22
AC Chip-Level Specifications .................................... 23
AC GPIO Specifications ............................................ 24
AC Comparator Specifications .................................. 25
AC External Clock Specifications .............................. 25
AC Programming Specifications ................................ 26
AC I2C Specifications ................................................ 27
Electrical Specifications – RF Section ......................... 30
Packaging Information ................................................... 34
Thermal Impedances ................................................. 35
Capacitance on Crystal Pins ..................................... 35
Solder Reflow Specifications ..................................... 35
Development Tool Selection ......................................... 36
Software .................................................................... 36
Development Kits ...................................................... 36
Evaluation Tools ........................................................ 36
Device Programmers ................................................. 36
Ordering Information ...................................................... 37
Ordering Code Definitions ......................................... 37
Acronyms ........................................................................ 38
Reference Documents .................................................... 38
Document Conventions ................................................. 38
Units of Measure ....................................................... 38
Numeric Naming ........................................................ 39
Glossary .......................................................................... 39
Document History Page ................................................. 40
Sales, Solutions, and Legal Information ...................... 41
Worldwide Sales and Design Support ....................... 41
Products .................................................................... 41
PSoC Solutions ......................................................... 41
Page 3 of 41
CYRF89135
PSoC® Functional Overview
The PSoC family consists of on-chip controller devices, which
are designed to replace multiple traditional microcontroller unit
(MCU)-based components with one, low cost single-chip
programmable component. A PSoC device includes
configurable analog and digital blocks, and programmable
interconnect. This architecture allows the user to create
customized peripheral configurations, to match the requirements
of each individual application. Additionally, a fast CPU, flash
program memory, SRAM data memory, and configurable I/O are
included in a range of convenient pinouts.
The architecture for this device family, as shown in the Logical
Block Diagram on page 2, consists of three main areas:
■
The Core
■
WirelessUSB NL System
■
System Resources.
VIN
TEMP SENSOR/ ADC
TEMP
DIODES
ADC
SYSTEM BUS
A common, versatile bus allows connection between I/O and the
analog system.
PSoC Core
The PSoC Core is a powerful engine that supports a rich
instruction set. It encompasses SRAM for data storage, an
interrupt controller, sleep and watchdog timers, and IMO and
ILO. The CPU core, called the M8C, is a powerful processor with
speeds up to 24 MHz. The M8C is a 4-MIPS, 8-bit
Harvard-architecture microprocessor.
System Resources provide additional capability, such as a
configurable I2C slave and SPI master-slave communication
interface and various system resets supported by the M8C.
10 bit ADC
The ADC on PRoC-EMB is an independent block with a state
machine interface to control accesses to the block. The ADC is
housed together with the temperature sensor core and can be
connected to this or the Analog Mux Bus. As a default operation,
the ADC is connected to the temperature sensor diodes to give
digital values of the temperature.
Document Number: 001-86331 Rev. **
INTERFACE BLOCK
COMMAND/ STATUS
Interface to the M8 C
( Processor ) Core
The ADC User Module contains an integrator block and one
comparator with positive and negative input set by the MUXes.
The input to the integrator stage comes from the Analog Global
Input Mux or the temperature sensor with an input voltage range
of 0 V to 1.3 V, where 1.3 V is 72% of full scale.
Page 4 of 41
CYRF89135
Figure 2. I2C Block Diagram
SPI
The serial peripheral interconnect (SPI) 3-wire protocol uses
both edges of the clock to enable synchronous communication
without the need for stringent setup and hold requirements.
I2C Core
SDA_IN
To/From
GPIO
Pins
SCL_IN
Buffer Module
CPU Port
I2C Basic
Configuration
I2C_BUF
I2C_CFG
SDA_OUT
SCL_OUT
I2C_EN
I2C_SCR
32 Byte RAM
I2C_DR
HW Addr Cmp
I2C_ADDR
Buffer Ctl
Plus Features
MOSI
System Bus
Figure 1. Basic SPI Configuration
Data is output by
Data is registered at the
both the Master
input of both devices on the
and Slave on
opposite edge of the clock.
one edge of the
clock.
SCLK
I2C Plus
Slave
SYSCLK
I2C_BP
I2C_CP
I2C_XCFG
MCU_BP
I2C_XSTAT
MCU_CP
STANDBY
MISO
A device can be a master or slave. A master outputs clock and
data to the slave device and inputs slave data. A slave device
inputs clock and data from the master device and outputs data
for input to the master. Together, the master and slave are
essentially a circular Shift register, where the master generates
the clocking and initiates data transfers.
A basic data transfer occurs when the master sends eight bits of
data, along with eight clocks. In any transfer, both master and
slave transmit and receive simultaneously. If the master only
sends data, the received data from the slave is ignored. If the
master wishes to receive data from the slave, the master must
send dummy bytes to generate the clocking for the slave to send
data back.
The basic I2C features include
■
Slave, transmitter, and receiver operation
■
Byte processing for low CPU overhead
■
Interrupt or polling CPU interface
■
Support for clock rates of up to 400 kHz
■
7- or 10-bit addressing (through firmware support)
■
SMBus operation (through firmware support)
Enhanced features of the I2C Slave Enhanced Module include:
■
Support for 7-bit hardware address compare
MOSI,
MISO
■
Flexible data buffering schemes
SCLK
■
A ‘no bus stalling’ operating mode
SPI Block
MOSI,
MISO
SCLK
DATA_IN DATA_OUT
CLK_IN
CLK_OUT
INT
SYSCLK
SS_
Registers
CONFIGURATION[7:0]
CONTROL[7:0]
TRANSMIT[7:0]
RECEIVE[7:0]
I2C Slave
The I2C slave enhanced communications block is a
serial-to-parallel processor, designed to interface the
PRoC-EMB device to a two-wire I2C serial communications bus.
To eliminate the need for excessive CPU intervention and
overhead, the block provides I2C-specific support for status
detection and generation of framing bits. By default, the I2C
Slave Enhanced module is firmware compatible with the
previous generation of I2C slave functionality. However, this
module provides new features that are configurable to
implement significant flexibility for both internal and external
interfacing.
Document Number: 001-86331 Rev. **
A low power bus monitoring modeThe I2C block controls the data
(SDA) and the clock (SCL) to the external I2C interface through
direct connections to two dedicated GPIO pins. When I2C is
enabled, these GPIO pins are not available for general purpose
use. The enCoRe V LV CPU firmware interacts with the block
through I/O register reads and writes, and firmware
synchronization is implemented through polling and/or
interrupts.
WirelessUSB NL System
WirelessUSB NL, optimized to operate in the 2.4-GHz ISM band,
is Cypress's third generation of 2.4-GHz low-power RF
technology. WirelessUSB NL implements a Gaussian
frequency-shift keying (GFSK) radio using a differentiated
single-mixer, closed-loop modulation design that optimizes
power efficiency and interference immunity. Closed-loop
modulation effectively eliminates the problem of frequency drift,
enabling WirelessUSB NL to transmit up to 255-byte payloads
without repeatedly having to pay power penalties for re-locking
the phase-locked loop (PLL) as in open-loop designs
Among the advantages of WirelessUSB NL are its fast lock times
and channel switching, along with the ability to transmit larger
payloads. Use of longer payload packets, compared to multiple
short payload packets, can reduce overhead, improve overall
power efficiency, and help alleviate spectrum crowding.
Page 5 of 41
CYRF89135
Combined with Cypress’s controller, WirelessUSB NL also
provides the lowest bill of materials (BOM) cost solution for
sophisticated PC peripheral applications such as wireless
keyboards and mice, as well as best-in-class wireless performance in other demanding applications. such as toys, remote
controls, fitness, automation, presenter tools, and gaming.
With PRoC-EMB 68-pin QFN, the WirelessUSB NL transceiver
can add wireless capability to a wide variety of applications.
The WirelessUSB NL is a fully-integrated CMOS RF transceiver,
GFSK data modem, and packet framer, optimized for use in the
2.4-GHz ISM band. It contains transmit, receive, RF synthesizer,
and digital modem functions, with few external components. The
transmitter supports digital power control. The receiver uses
extensive digital processing for excellent overall performance,
even in the presence of interference and transmitter
impairments.
The product transmits GFSK data at approximately 0-dBm
output power. Sigma-Delta PLL delivers high-quality DC-coupled
transmit data path.
The low-IF receiver architecture produces good selectivity and
image rejection, with typical sensitivity of –87 dBm or better on
most channels. Sensitivity on channels that are integer multiples
of the crystal reference oscillator frequency (12 MHz) may show
approximately 5 dB degradation. Digital RSSI values are
available to monitor channel quality.
On-chip transmit and receive FIFO registers are available to
buffer the data transfer with MCU. Over-the-air data rate is
always 1 Mbps even when connected to a slow, low-cost MCU.
Built-in CRC, FEC, data whitening, and automatic
retry/acknowledge are all available to simplify and optimize
performance for individual applications.
For more details on the radio’s implementation details and timing
requriements, please go through the WirelessUSB NL datasheet
in www.cypress.com.
Figure 3. WirelessUSB NL logic Block Diagram
VDD1 ...VDD7
VOUT
VIN
VDD_IO
LDO Linear
Regulator
GFSK
Modulator
PKT
MISO
MOSI
RST_n
Framer
CLK
SPI Registers
SPI_SS
PA
Synthesizer
ANT
ANTb
VCO
Pwr/ Reset
BRCLK
Xtal Osc
GFSK
Demodulator
X
Image
Rej. Mxr.
XTALi
XTALo
Document Number: 001-86331 Rev. **
LNA + BPF
GND GND
Page 6 of 41
CYRF89135
■
Transmit Power Control
The following table lists recommended settings for register 9 for
short-range applications, where reduced transmit RF power is a
desirable trade off for lower current.
Table 1. Transmit Power Control
Power Setting
Description
Typical Transmit
Power (dBm)
Register 9
PA0 - Highest power
+1
0x1820
PA2 - High power
0
0x1920
PA4 - High power
–3
0x1A20
PA8 - Low power
–7.5
0x1C20
PA12 - Lower power
–11.2
0x1E20
A register-controlled bypass mode allows the user to disable
the LDO regulator.
Getting Started
The quickest way to understand the PRoC-EMB silicon is to read
this datasheet and then use the PSoC Designer Integrated
Development Environment (IDE). This datasheet is an overview
of the PSoC integrated circuit and presents specific pin, register,
and electrical specifications.
For in depth information, along with detailed programming
details, see the Technical Reference Manual for the enCoRe-V
LV.
For up-to-date ordering, packaging, and electrical specification
information, see the latest PSoC device datasheets on the web
at www.cypress.com/psoc.
Power-on and Register Initialization Sequence
Development Kits
For proper initialization at power up, VIN must ramp up at the
minimum overall ramp rate no slower than shown by TVIN
specification in the following figure. During this time, the RST_n
line must track the VIN voltage ramp-up profile to within
approximately 0.2 V. Since most MCU GPIO pins automatically
default to a high-Z condition at power up, it only requires a pull-up
resistor. When power is stable and the MCU POR releases, and
MCU begins to execute instructions, RST_n must then be pulsed
low as shown in Figure 13, followed by writing Reg[27 = 0x4200.
During or after this SPI transaction, the State Machine status can
be read to confirm FRAMER_ST = 1, indicating a proper
initialization.
PSoC Development Kits are available online from and through a
growing number of regional and global distributors, which
include Arrow, Avnet, Digi-Key, Farnell, Future Electronics, and
Newark.
Additional System Resources
System Resources, some of which have been previously listed,
provide additional capability useful to complete systems.
Additional resources include low voltage detection and power on
reset. The following statements describe the merits of each
system resource:
■
Low-voltage detection (LVD) interrupts can signal the
application of falling voltage levels, while the advanced
power-on reset (POR) circuit eliminates the need for a system
supervisor.
■
The 3.6 V maximum input, 1.8, 2.5, or 3 V selectable output,
low dropout regulator (LDO) provides regulation for I/Os. A
register controlled bypass mode enables the user to disable
the LDO.
Document Number: 001-86331 Rev. **
Training
Free PSoC technical training (on demand, webinars, and
workshops), which is available online via www.cypress.com,
covers a wide variety of topics and skill levels to assist you in
your designs.
CYPros Consultants
Certified PSoC consultants offer everything from technical
assistance to completed PSoC designs. To contact or become a
PSoC consultant go to the CYPros Consultants web site.
Solutions Library
Visit our growing library of solution focused designs. Here you
can find various application designs that include firmware and
hardware design files that enable you to complete your designs
quickly.
Technical Support
Technical support – including a searchable Knowledge Base
articles and technical forums – is also available online. If you
cannot find an answer to your question, call our Technical
Support hotline at 1-800-541-4736.
Page 7 of 41
CYRF89135
Development Tools
PSoC Designer™ is the revolutionary integrated design
environment (IDE) that you can use to customize PSoC to meet
your specific application requirements. PSoC Designer software
accelerates system design and time to market. Develop your
applications using a library of precharacterized analog and digital
peripherals (called user modules) in a drag-and-drop design
environment. Then, customize your design by leveraging the
dynamically generated application programming interface (API)
libraries of code. Finally, debug and test your designs with the
integrated debug environment, including in-circuit emulation and
standard software debug features. PSoC Designer includes:
Code Generation Tools
The code generation tools work seamlessly within the
PSoC Designer interface and have been tested with a full range
of debugging tools. You can develop your design in C, assembly,
or a combination of the two.
Assemblers. The assemblers allow you to merge assembly
code seamlessly with C code. Link libraries automatically use
absolute addressing or are compiled in relative mode, and linked
with other software modules to get absolute addressing.
■
Application editor graphical user interface (GUI) for device and
user module configuration and dynamic reconfiguration
■
Extensive user module catalog
C Language Compilers. C language compilers are available
that support the PSoC family of devices. The products allow you
to create complete C programs for the PSoC family devices. The
optimizing C compilers provide all of the features of C, tailored
to the PSoC architecture. They come complete with embedded
libraries providing port and bus operations, standard keypad and
display support, and extended math functionality.
■
Integrated source-code editor (C and assembly)
Debugger
■
Free C compiler with no size restrictions or time limits
■
Built-in debugger
■
In-circuit emulation
PSoC Designer has a debug environment that provides
hardware in-circuit emulation, allowing you to test the program in
a physical system while providing an internal view of the PSoC
device. Debugger commands allow you to read and program and
read and write data memory, and read and write I/O registers.
You can read and write CPU registers, set and clear breakpoints,
and provide program run, halt, and step control. The debugger
also lets you to create a trace buffer of registers and memory
locations of interest.
Built-in support for communication interfaces:
2
❐ Hardware and software I C slaves and masters
❐ SPI master and slave, and wireless
PSoC Designer supports the entire library of PSoC 1 devices and
runs on Windows XP, Windows Vista, and Windows 7.
■
PSoC Designer Software Subsystems
Design Entry
In the chip-level view, choose a base device to work with. Then
select different onboard analog and digital components that use
the PSoC blocks, which are called user modules. Examples of
user modules are analog-to-digital converters (ADCs),
digital-to-analog converters (DACs), amplifiers, and filters.
Configure the user modules for your chosen application and
connect them to each other and to the proper pins. Then
generate your project. This prepopulates your project with APIs
and libraries that you can use to program your application.
The tool also supports easy development of multiple
configurations and dynamic reconfiguration. Dynamic
reconfiguration makes it possible to change configurations at run
time. In essence, this lets you to use more than 100 percent of
PSoC’s resources for an application.
Document Number: 001-86331 Rev. **
Online Help System
The online help system displays online, context-sensitive help.
Designed for procedural and quick reference, each functional
subsystem has its own context-sensitive help. This system also
provides tutorials and links to FAQs and an Online Support
Forum to aid the designer.
In-Circuit Emulator
A low-cost, high-functionality in-circuit emulator (ICE) is
available for development support. This hardware can program
single devices.
The emulator consists of a base unit that connects to the PC
using a USB port. The base unit is universal and operates with
all PSoC devices. Emulation pods for each device family are
available separately. The emulation pod takes the place of the
PSoC device in the target board and performs full-speed
(24 MHz) operation.
Page 8 of 41
CYRF89135
Designing with PSoC Designer
The development process for the PSoC device differs from that
of a traditional fixed-function microprocessor. The configurable
analog and digital hardware blocks give the PSoC architecture a
unique flexibility that pays dividends in managing specification
change during development and lowering inventory costs. These
configurable resources, called PSoC blocks, have the ability to
implement a wide variety of user-selectable functions. The PSoC
development process is:
1. Select user modules.
2. Configure user modules.
3. Organize and connect.
4. Generate, verify, and debug.
Select User Modules
PSoC Designer provides a library of prebuilt, pretested hardware
peripheral components called “user modules”. User modules
make selecting and implementing peripheral devices, both
analog and digital, simple.
Configure User Modules
Each user module that you select establishes the basic register
settings that implement the selected function. They also provide
parameters and properties that allow you to tailor their precise
configuration to your particular application. For example, a PWM
User Module configures one or more digital PSoC blocks, one
for each eight bits of resolution. Using these parameters, you can
establish the pulse width and duty cycle. Configure the
parameters and properties to correspond to your chosen
application. Enter values directly or by selecting values from
drop-down menus. All of the user modules are documented in
datasheets that may be viewed directly in PSoC Designer or on
the Cypress website. These user module datasheets explain the
Document Number: 001-86331 Rev. **
internal operation of the user module and provide performance
specifications. Each datasheet describes the use of each user
module parameter, and other information that you may need to
successfully implement your design.
Organize and Connect
Build signal chains at the chip level by interconnecting user
modules to each other and the I/O pins. Perform the selection,
configuration, and routing so that you have complete control over
all on-chip resources.
Generate, Verify, and Debug
When you are ready to test the hardware configuration or move
on to developing code for the project, perform the “Generate
Configuration Files” step. This causes PSoC Designer to
generate source code that automatically configures the device to
your specification and provides the software for the system. The
generated code provides APIs with high-level functions to control
and respond to hardware events at run time, and interrupt
service routines that you can adapt as needed.
A complete code development environment lets you to develop
and customize your applications in C, assembly language, or
both.
The last step in the development process takes place inside
PSoC Designer’s Debugger (accessed by clicking the Connect
icon). PSoC Designer downloads the HEX image to the ICE
where it runs at full-speed. PSoC Designer debugging
capabilities rival those of systems costing many times more. In
addition to traditional single-step, run-to-breakpoint, and
watch-variable features, the debug interface provides a large
trace buffer. The interface lets you to define complex breakpoint
events that include monitoring address and data bus values,
memory locations, and external signals.
Page 9 of 41
CYRF89135
Pinouts
The CYRF89135-68LTXC PRoC-EMB device is available in a 68-pin QFN package, which is illustrated in the following table. Every
port pin (labeled with a “P”) is capable of Digital I/O and connection to the common analog bus. However, VDD, and XRES are not
capable of Digital I/O.
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
P0[2]
P0[0]
P2[6]
P2[4]
P2[2]
P2[0]
VDD
P4[2]
ANT
P4[0]
P3[6]
ANTB
P3[4]
P3[2]
P3[0]
VDD
XRES
Figure 4. 68-pin QFN pinout
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
51
50
CYRF89135 68-PIN QFN
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
P1[6]
VDD
P1[4]
P1[2]
P1[0]
TEST1
NC
XTALI
XTALO
VDD
GND
P1[1]
VOUT
P1[3]
VIN
HCLK
CCLK
P2[5]
P2[3]
P2[1]
P4[1]
P3[7]
SPI_SS
P3[5]
P3[3]
PKT
P3[1]
CLK
MOSI
MISO
P1[7]
RST_N
P1[5]
VDD
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
TEST2
TEST3
VDD
P0[4]
P0[6]
VIN
VDD
OCDO
OCDE
P0[7]
P0[5]
P0[3]
FIFO
P0[1]
VIN
OCDOE
P2[7]
Pin Definitions
This table gives the pin definitions. [1, 2]
Pin No.
Pin Name
Description
1
TEST2
Reserved for factory test. Do not connect.
2
TEST3
Reserved for factory test. Do not connect.
3
VDD
Core power supply voltage. Connect all VDD pins to VOUT pin
4
P0[4]
Analog I/O, Digital I/O, VREF
5
P0[6]
Analog I/O, Digital I/O
6
VIN
Unregulated input voltage to the on-chip low drop out (LDO) voltage regulator.
7
VDD
Core power supply voltage. Connect all VDD pins to VOUT pin.
8
OCDO
OCD odd data IO, NC
9
OCDE
OCD even data output, NC
10
P0[7]
Analog I/O, Digital I/O,SPI CLK
11
P0[5]
Analog I/O, Digital I/O
Notes
1. Connect all VDD pin to VOUT pin.
2. Each of the ANT and ANTB pins much be DC grounded, 20 k or less.
Document Number: 001-86331 Rev. **
Page 10 of 41
CYRF89135
Pin Definitions (continued)
This table gives the pin definitions. [1, 2]
Pin No.
Pin Name
12
P0[3]
Description
Analog I/O, Digital I/O, Integrating input
13
FIFO
FIFO status indicator bit
14
P0[1]
Analog I/O, Digital I/O, Integrating input
15
VIN
16
OCDOE
17
P2[7]
Unregulated input voltage to the on-chip low drop out (LDO) voltage regulator.
OCD mode direction pin, NC
Analog I/O, Digital I/O
18
P2[5]
Analog I/O, Digital I/O, XTAL Out
19
P2[3]
Analog I/O, Digital I/O, XTAL In
20
P2[1]
Analog I/O, Digital I/O
21
P4[1]
Analog I/O, Digital I/O
22
P3[7]
Analog I/O, Digital I/O
23
SPI_SS
24
P3[5]
Analog I/O, Digital I/O
25
P3[3]
Analog I/O, Digital I/O
Enable input for SPI, active low. Also used to bring device out of sleep state.
26
PKT
Transmit/receive packet status indicator bit
27
P3[1]
Analog I/O, Digital I/O
28
CLK
Clock input for SPI interface
29
MOSI
Data input for the SPI bus
30
MISO
Data output (tristate when not active)
31
P1[7]
Digital I/O, Analog I/O, I2C SCL, SPI SS
32
RST_N
33
P1[5]
Digital I/O, Analog I/O, I2C SDA, SPI MISO
34
VDD
Core power supply voltage. Connect all VDD pins to VOUT pin.
RST_N Low: Chip shutdown to conserve power. Register values lost
RST_N High: Turn on chip, registers restored to default value
35
CCLK
OCD CPU CLK OUTPUT, NC
36
HCLK
OCD HIGH SPEED CLK, NC
37
VIN
Unregulated input voltage to the on-chip low drop out (LDO) voltage regulator
38
P1[3]
Digital I/O, Analog I/O, SPI CLK
39
VOUT
1.8 V output from on-chip LDO. Connect to all Vdd pins, do not connect to external loads.
40
P1[1]
Digital I/O, Analog I/O, TC CLK, I2C SCL, SPI MOSI
41
GND
Ground Pin
42
VDD
Core power supply voltage. Connect all VDD pins to VOUT pin.
43
XTALO
Output of the crystal oscillator gain block
44
XTALI
Input to the crystal oscillator gain block
45
NC
46
TEST1
Reserved for factory test. Do not connect.
47
P1[0]
Analog I/O, Digital I/O, TC DATA, I2C SDA
No Connect
48
P1[2]
Analog I/O, Digital I/O
49
P1[4]
Analog I/O, Digital I/O, EXT CLK
50
VDD
Core power supply voltage. Connect all VDD pins to VOUT pin.
Document Number: 001-86331 Rev. **
Page 11 of 41
CYRF89135
Pin Definitions (continued)
This table gives the pin definitions. [1, 2]
Pin No.
Pin Name
Description
51
P1[6]
Analog I/O, Digital I/O
52
XRES
Active high external reset with internal pull down
53
VDD
Core power supply voltage. Connect all VDD pins to VOUT pin.
54
P3[0]
Analog I/O, Digital I/O
55
P3[2]
Analog I/O, Digital I/O
56
P3[4]
Analog I/O, Digital I/O.
57
ANTb
Differential RF input/output.
58
P3[6]
Analog I/O, Digital I/O.
59
P4[0]
Analog I/O, Digital I/O.
60
ANT
Differential RF input/output.
61
P4[2]
Analog I/O, Digital I/O.
62
VDD
Core power supply voltage. Connect all VDD pins to VOUT pin.
63
P2[0]
Analog I/O, Digital I/O
64
P2[2]
Analog I/O, Digital I/O
65
P2[4]
Analog I/O, Digital I/O
66
P2[6]
Analog I/O, Digital I/O
67
P0[0]
Analog I/O, Digital I/O
68
P0[2]
Analog I/O, Digital I/O
Document Number: 001-86331 Rev. **
Page 12 of 41
CYRF89135
Absolute Maximum Ratings
Exceeding maximum ratings may shorten the useful life of the device. User guidelines are not tested.
Table 2. Absolute Maximum Ratings
Symbol
TSTG
Description
Storage temperature
VIN
Conditions
Min
Typ
Max
Units
Higher storage temperatures
reduce data retention time.
Recommended Storage
Temperature is +25 °C ± 25 °C.
Extended duration storage
temperatures above 85 °C
degrades reliability.
–55
25
125
°C
–
1.9
–
3.63
V
VDD
Supply voltage
–
–0.5
–
1.98
V
VIO
DC input voltage
–
–0.5
–
VDD + 0.5
V
VIOZ[3]
DC voltage applied to tristate
–
–0.5
–
VDD + 0.5
V
IMIO
Maximum current into any port
pin
–
–25
–
50
mA
ESD
Electrostatic discharge voltage
Human body model ESD
i) RF pins (ANT, ANTb)
ii) Analog pins (XTALi, XTALo)
iii) Remaining pins
500
500
2000
–
–
V
LU
Latch-up current
In accordance with JESD78
standard
–
–
140
mA
Min
Typ
Max
Units
0
–
70
°C
Operating Temperature
Table 3. Operating Temperature
Symbol
TA
Description
Ambient temperature
Conditions
–
Note
3. Port1 pins are hot-swap capable with I/O configured in High-Z mode, and pin input voltage above VIN.
Document Number: 001-86331 Rev. **
Page 13 of 41
CYRF89135
Electrical Specifications – PSoC Core
This section presents the DC and AC electrical specifications of the CYRF89435-68LTXC PSoC device. For the latest electrical
specifications, confirm that you have the most recent datasheet by visiting the web at http://www.cypress.com/psoc.
Figure 5. Voltage versus CPU Frequency
3.6 V
V I N Voltage
li d ng
Va rati n
e io
Op Reg
1.9 V
750 kHz
3 MHz
CPU
Document Number: 001-86331 Rev. **
24 MHz
Frequency
Page 14 of 41
CYRF89135
DC Chip-Level Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 4. DC Chip Level Specifications
Symbol
Vdd
[4, 5]
Description
Conditions
Min
Typ
Max
Units
1.71
–
3.6
V
Supply voltage
See table titled DC POR and LVD
Specifications on page 20.
IDD24
Supply current, IMO = 24 MHz
Conditions are Vdd  3.0 V, TA = 25 °C,
CPU = 24 MHz
No I2C/SPI
–
2.9
4.0
mA
IDD12
Supply current, IMO = 12 MHz
Conditions are Vdd  3.0 V, TA = 25 °C,
CPU = 12 MHz
No I2C/SPI
–
1.7
2.6
mA
IDD6
Supply current, IMO = 6 MHz
Conditions are Vdd  3.0 V, TA = 25 °C,
CPU = 6 MHz
No I2C/SPI
–
1.2
1.8
mA
ISB1
Standby current with POR, LVD, and
Sleep timer
Vdd  3.0V, TA = 25 °C, I/O regulator
turned off
–
1.1
1.5
A
ISB0
Deep sleep current
Vdd  3.0 V, TA = 25 °C, I/O regulator
turned off
–
0.1
–
A
Notes
4. If powering down in standby sleep mode, to properly detect and recover from a VIN brown out condition any of the following actions must be taken:
Bring the device out of sleep before powering down.
Assure that VIN falls below 100 mV before powering back up.
Set the No Buzz bit in the OSC_CR0 register to keep the voltage monitoring circuit powered during sleep.
Increase the buzz rate to assure that the falling edge of VIN is captured. The rate is configured through the PSSDC bits in the SLP_CFG register.
For the referenced registers, refer to the CY8C20X36 Technical Reference Manual. In deep sleep mode, additional low power voltage monitoring circuitry allows VIN
brown out conditions to be detected for edge rates slower than 1V/ms.
5. Always greater than 50 mV above VPPOR1 voltage for falling supply.
6. Always greater than 50 mV above VPPOR2 voltage for falling supply.
7. Always greater than 50 mV above VPPOR3 voltage for falling supply.
Document Number: 001-86331 Rev. **
Page 15 of 41
CYRF89135
DC GPIO Specifications
The following tables list guaranteed maximum and minimum specifications for the voltage and temperature ranges: 2.4 V to 3.0 V and
0 °C  TA  70 °C, or 1.9 V to 2.4 V and 0 °C  TA °C, respectively. Typical parameters apply to 3.3 V at 25 °C and are for design
guidance only.
Table 5. 2.4 V to 3.0 V DC GPIO Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
RPU
Pull-up resistor
4
5.60
8
k
VOH1
High output voltage Port 2 or 3 or IOH < 10 A, maximum of 10 mA
4 pins
source current in all I/Os
VIN – 0.20
–
–
V
VOH2
High output voltage Port 2 or 3 or IOH = 0.2 mA, maximum of 10 mA
4 pins
source current in all I/Os
VIN – 0.40
–
–
V
VOH3
High output voltage Port 0 or 1 IOH < 10 A, maximum of 10 mA
pins with LDO regulator Disabled source current in all I/Os
for port 1
VIN – 0.20
–
–
V
VOH4
High output voltage Port 0 or 1 IOH = 2 mA, maximum of 10 mA
pins with LDO regulator Disabled source current in all I/Os
for Port 1
VIN – 0.50
–
–
V
VOH5A
High output voltage Port 1 pins
with LDO enabled for 1.8 V out
IOH < 10 A, VIN > 2.4 V, maximum
of 20 mA source current in all I/Os
1.50
1.80
2.10
V
VOH6A
High output voltage Port 1 pins
with LDO enabled for 1.8 V out
IOH = 1 mA, VIN > 2.4 V, maximum
of 20 mA source current in all I/Os
1.20
–
–
V
VOL
Low output voltage
IOL = 10 mA, maximum of 30 mA
sink current on even port pins (for
example, P0[2] and P1[4]) and
30 mA sink current on odd port
pins (for example, P0[3] and
P1[5])
–
–
0.75
V
VIL
Input low voltage
–
–
–
0.72
V
VIH
Input high voltage
–
1.40
–
VH
Input hysteresis voltage
–
–
80
–
mV
IIL
Input leakage (absolute value)
–
–
1
1000
nA
CPIN
Capacitive load on pins
Package and pin dependent
Temp = 25 C
0.50
1.70
7
pF
VILLVT2.5
Input Low Voltage with low
Bit3 of IO_CFG1 set to enable low
threshold enable set, Enable for threshold voltage of Port1 input
Port1
0.7
–
–
V
VIHLVT2.5
Input High Voltage with low
Bit3 of IO_CFG1 set to enable low
threshold enable set, Enable for threshold voltage of Port1 input
Port1
1.2
–
V
Document Number: 001-86331 Rev. **
–
V
Page 16 of 41
CYRF89135
Table 6. 1.9 V to 2.4 V DC GPIO Specifications
Symbol
Description
Conditions
Typ
Max
Units
4
5.60
8
k
RPU
Pull-up resistor
VOH1
High output voltage Port 2 or 3 or IOH = 10 A, maximum of 10 mA VIN – 0.20
4 pins
source current in all I/Os
–
–
V
VOH2
High output voltage Port 2 or 3 or IOH = 0.5 mA, maximum of 10 mA VIN – 0.50
4 pins
source current in all I/Os
–
–
V
VOH3
High output voltage Port 0 or 1 IOH = 100 A, maximum of 10 mA VIN – 0.20
pins with LDO regulator Disabled source current in all I/Os
for Port 1
–
–
V
VOH4
High output voltage Port 0 or 1
Pins with LDO Regulator
Disabled for Port 1
IOH = 2 mA, maximum of 10 mA VIN – 0.50
source current in all I/Os
–
–
V
VOL
Low output voltage
IOL = 5 mA, maximum of 20 mA
sink current on even port pins (for
example, P0[2] and P1[4]) and
30 mA sink current on odd port
pins (for example, P0[3] and
P1[5])
–
–
0.40
V
VIL
Input low voltage
–
–
–
0.30 × VIN
V
VIH
Input high voltage
–
0.65 × VIN
–
–
V
VH
Input hysteresis voltage
–
–
80
–
mV
IIL
Input leakage (absolute value)
–
–
1
1000
nA
CPIN
Capacitive load on pins
Package and pin dependent
temp = 25 °C
0.50
1.70
7
pF
Document Number: 001-86331 Rev. **
–
Min
Page 17 of 41
CYRF89135
Analog DC Mux Bus Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 7. DC Analog Mux Bus Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
RSW
Switch resistance to common
analog bus
–
–
–
800

RGND
Resistance of initialization switch –
to GND
–
–
800

The maximum pin voltage for measuring RSW and RGND is 1.8 V.
DC Low Power Comparator Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 8. DC Comparator Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
0.0
–
1.8
V
VLPC
Low power comparator (LPC)
common mode
Maximum voltage limited to VIN
ILPC
LPC supply current
–
–
10
40
A
VOSLPC
LPC voltage offset
–
–
3
30
mV
Comparator User Module Electrical Specifications
The following table lists the guaranteed maximum and minimum specifications. Unless stated otherwise, the specifications are for the
entire device voltage and temperature operating range: 0 °C  TA  70 °C, 1.9 V  VIN  3.6 V.
Table 9. Comparator User Module Electrical Specifications
Symbol
Min
Typ
Max
Units
50 mV overdrive
–
70
100
ns
Offset
Valid from 0.2 V to (VIN – 0.2 V)
–
2.5
30
mV
Current
Average DC current, 50 mV
overdrive
–
20
80
µA
Supply voltage > 2 V
Power supply rejection ratio
–
80
–
dB
Supply voltage < 2 V
Power supply rejection ratio
–
40
–
dB
–
0
–
1.5
V
tCOMP
PSRR
Description
Comparator response time
Input range
Document Number: 001-86331 Rev. **
Conditions
Page 18 of 41
CYRF89135
ADC Electrical Specifications
Table 10. ADC User Module Electrical Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
Input
VIN
Input voltage range
–
0
–
VREFADC
V
CIIN
Input capacitance
–
–
–
5
pF
RIN
Input resistance
Equivalent switched cap input
resistance for 8-, 9-, or 10-bit
resolution
ADC reference voltage
–
1.14
–
1.26
V
2.25
–
6
MHz
1/(500fF × 1/(400fF × 1/(300fF ×
data clock) data clock) data clock)

Reference
VREFADC
Conversion Rate
FCLK
Data clock
Source is chip’s internal main
oscillator. See AC Chip-Level
Specifications for accuracy
S8
8-bit sample rate
Data clock set to 6 MHz. sample
rate = 0.001/ (2^Resolution/Data
Clock)
–
23.43
–
ksps
S10
10-bit sample rate
Data clock set to 6 MHz. sample
rate = 0.001/ (2^resolution/data
clock)
–
5.85
–
ksps
RES
Resolution
Can be set to 8-, 9-, or 10-bit
8
–
10
bits
DNL
Differential nonlinearity
–
–1
–
+2
LSB
INL
Integral nonlinearity
–
–2
–
+2
LSB
EOFFSET
Offset error
8-bit resolution
0
3.20
19.20
LSB
10-bit resolution
0
12.80
76.80
LSB
EGAIN
Gain error
For any resolution
–5
–
+5
%FSR
IADC
Operating current
–
–
2.10
2.60
mA
PSRR
Power supply rejection ratio
PSRR (VIN > 3.0 V)
–
24
–
dB
PSRR (VIN < 3.0 V)
–
30
–
dB
DC Accuracy
Power
Document Number: 001-86331 Rev. **
Page 19 of 41
CYRF89135
DC POR and LVD Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 11. DC POR and LVD Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
VPOR1
2.36 V selected in PSoC Designer
PORLEV[1:0] = 00b, HPOR = 1
–
2.36
2.41
V
VPOR2
2.60 V selected in PSoC Designer
PORLEV[1:0] = 01b, HPOR = 1
VIN must be greater than or equal
to 1.9 V during startup, reset from
the XRES pin, or reset from
watchdog.
–
2.60
2.66
VPOR3
2.82 V selected in PSoC Designer
PORLEV[1:0] = 10b, HPOR = 1
–
2.82
2.95
VLVD0
2.45 V selected in PSoC Designer
VLVD1
VLVD2
–
2.71 V selected in PSoC Designer
2.92 V selected in PSoC Designer
2.40
2.45
2.51
2.64
[8]
2.71
2.78
2.85
[9]
2.92
2.99
2.95
[10]
VLVD3
3.02 V selected in PSoC Designer
3.02
3.09
VLVD4
3.13 V selected in PSoC Designer
3.06
3.13
3.20
VLVD5
1.90 V selected in PSoC Designer
1.84
1.90
2.32
V
Notes
8. Always greater than 50 mV above VPPOR1 voltage for falling supply.
9. Always greater than 50 mV above VPPOR2 voltage for falling supply.
10. Always greater than 50 mV above VPPOR3 voltage for falling supply.
Document Number: 001-86331 Rev. **
Page 20 of 41
CYRF89135
DC Programming Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 12. DC Programming Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
VIN
Supply voltage for flash write
operations
–
1.91
–
3.6
V
IDDP
Supply current during
programming or verify
–
–
5
25
mA
VILP
Input low voltage during
programming or verify
See the appropriate DC GPIO
Specifications on page 16
–
–
VIL
V
VIHP
Input high voltage during
programming or verify
See the appropriate DC GPIO
Specifications on page 16
VIH
–
–
V
IILP
Input current when Applying VILP Driving internal pull-down resistor
to P1[0] or P1[1] during
programming or verify
–
–
0.2
mA
IIHP
Input current when applying VIHP Driving internal pull-down resistor
to P1[0] or P1[1] during
programming or verify
–
–
1.5
mA
VOLP
Output low voltage during
programming or verify
–
–
+ 0.75
V
VOHP
Output high voltage during
programming or verify
See appropriate DC GPIO
Specifications on page 16. For
VIN > 3 V use VOH4 in Table 3 on
page 13.
VOH
–
VIN
V
FlashENPB
Flash write endurance
Erase/write cycles per block
50,000
–
–
–
FlashDR
Flash data retention
Following maximum Flash write
cycles; ambient temperature of
55 °C
20
–
–
Years
Document Number: 001-86331 Rev. **
Page 21 of 41
CYRF89135
DC I2C Specifications
The following tables list guaranteed maximum and minimum specifications for the voltage and temperature ranges: 3, 2.4 V to 3.0 V
and 0 °C  TA  70 °C, or 1.9 V to 2.4 V and 0 °C  TA  70 °C, respectively. Typical parameters apply to 3.3 V at 25 °C and are for
design guidance only.
Table 13. DC I2C Specifications
Symbol
VILI2C
VIHI2C
Description
Input low level
Input high level
Conditions
Min
Typ
Max
Units
3.1 V ≤ VIN ≤ 3.6 V
–
–
0.25 × VIN
V
2.5 V ≤ VIN ≤ 3.0 V
–
–
0.3 × VIN
V
1.9 V ≤ VIN ≤ 2.4 V
–
–
0.3 × VIN
V
1.9 V ≤ VIN ≤ 3.6 V
0.65 × VIN
–
–
V
DC Reference Buffer Specifications
The following tables list guaranteed maximum and minimum specifications for the voltage and temperature ranges: 2.4 V to 3.0 V and
0 °C  TA  70 °C, or 1.9 V to 2.4 V and 0 °C  TA  70 °C, respectively. Typical parameters apply to 3.3 V at 25 °C and are for design
guidance only.
Table 14. DC Reference Buffer Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
VRef
Reference buffer output
1.9 V to 3.6 V
1
–
1.05
V
VRefHi
Reference buffer output
1.9 V to 3.6 V
1.2
–
1.25
V
Document Number: 001-86331 Rev. **
Page 22 of 41
CYRF89135
AC Chip-Level Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 15. AC Chip-Level Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
24
25.2
MHz
FIMO24
IMO frequency at
24 MHz Setting
–
22.8
FIMO12
IMO frequency at 12 MHz setting –
11.4
12
12.6
MHz
FIMO6
IMO frequency at 6 MHz setting –
5.7
6.0
6.3
MHz
FCPU
CPU frequency
–
0.75
–
25.20
MHz
F32K1
ILO frequency
–
19
32
50
kHz
F32K_U
ILO untrimmed frequency
–
13
32
82
kHz
DCIMO
Duty cycle of IMO
–
40
50
60
%
DCILO
ILO duty cycle
–
40
50
60
%
SRPOWER_UP
Power supply slew rate
VIN slew rate during power-up
–
–
250
V/ms
tXRST
External reset pulse width at
power-up
After supply voltage is valid
1
–
–
ms
tXRST2
External reset pulse width after
power-up
Applies after part has booted
10
–
–
s
tOS
Startup time of ECO
–
–
1
–
s
tJIT_IMO
N = 32
6 MHz IMO cycle-to-cycle jitter
(RMS)
–
0.7
6.7
ns
6 MHz IMO long term N (N = 32)
cycle-to-cycle jitter (RMS)
–
4.3
29.3
ns
6 MHz IMO period jitter (RMS)
–
0.7
3.3
ns
12 MHz IMO cycle-to-cycle jitter
(RMS)
–
0.5
5.2
ns
12 MHz IMO long term N (N = 32)
cycle-to-cycle jitter (RMS)
–
2.3
5.6
ns
12 MHz IMO period jitter (RMS)
–
0.4
2.6
ns
24 MHz IMO cycle-to-cycle jitter
(RMS)
–
1.0
8.7
ns
24 MHz IMO long term N (N = 32)
cycle-to-cycle jitter (RMS)
–
1.4
6.0
ns
24 MHz IMO period jitter (RMS)
–
0.6
4.0
ns
Document Number: 001-86331 Rev. **
Page 23 of 41
CYRF89135
AC GPIO Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 16. AC GPIO Specifications
Symbol
FGPIO
Description
GPIO operating frequency
Conditions
Min
Typ
Normal strong mode
Port 0, 1
0
–
0
–
Max
Units
6 MHz for
1.9 V <VIN < 2.40 V
12 MHz for
2.40 V < VIN< 3.6 V
MHz
MHz
tRISE23
Rise time, strong mode,
Cload = 50 pF
Port 2 or 3 or 4 pins
VIN = 3.0 to 3.6 V,
10% to 90%
15
–
80
ns
tRISE23L
Rise time, strong mode low
supply, Cload = 50 pF,
Port 2 or 3 or 4 pins
VIN = 1.9 to 3.0 V,
10% to 90%
15
–
80
ns
tRISE01
Rise time, strong mode,
Cload = 50 pF,
Ports 0 or 1
VIN = 3.0 to 3.6 V,
10% to 90%
LDO enabled or
disabled
10
–
50
ns
tRISE01L
Rise time, strong mode low
supply, Cload = 50 pF,
Ports 0 or 1
VIN = 1.9 to 3.0 V,
10% to 90%
LDO enabled or
disabled
10
–
80
ns
tFALL
Fall time, strong mode,
Cload = 50 pF,
all ports
VIN = 3.0 to 3.6 V,
10% to 90%
10
–
50
ns
tFALLL
Fall time,
strong mode low supply,
Cload = 50 pF, all ports
VIN = 1.9 to 3.0 V,
10% to 90%
10
–
70
ns
Figure 6. GPIO Timing Diagram
90%
GPIO Pin
Output
Voltage
10%
tRISE23
tRISE01
tRISE23L
tRISE01L
Document Number: 001-86331 Rev. **
tFALL
tFALLL
Page 24 of 41
CYRF89135
AC Comparator Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 17. AC Low Power Comparator Specifications
Symbol
tLPC
Description
Comparator response time,
50 mV overdrive
Conditions
Min
Typ
Max
Units
50 mV overdrive does not include
offset voltage.
–
–
100
ns
AC External Clock Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 18. AC External Clock Specifications
Symbol
FOSCEXT
Min
Typ
Max
Units
Frequency (external oscillator
frequency)
Description
–
0.75
–
25.20
MHz
High period
–
20.60
–
5300
ns
Low period
–
20.60
–
–
ns
Power-up IMO to switch
–
150
–
–
s
Document Number: 001-86331 Rev. **
Conditions
Page 25 of 41
CYRF89135
AC Programming Specifications
Figure 7. AC Waveform
SCLK (P1[1])
TFSCLK
TRSCLK
SDATA (P1[0])
THSCLK
TSSCLK
TDSCLK
The following table lists the guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 19. AC Programming Specifications
Symbol
Description
Conditions
Min
Typ
Max
Units
1
–
20
ns
–
1
–
20
ns
–
40
–
–
ns
Data hold time from
falling edge of SCLK
–
40
–
–
ns
FSCLK
Frequency of SCLK
–
0
–
8
MHz
tERASEB
Flash erase time (block)
–
–
–
18
ms
tWRITE
Flash block write time
–
–
–
25
ms
tDSCLK3
Data out delay from
falling edge of SCLK
3.0  VIN  3.6
–
–
85
ns
tDSCLK2
Data out delay from
falling edge of SCLK
1.9  VIN  3.0
–
–
130
ns
tXRST3
External reset pulse width after
power-up
Required to enter programming
mode when coming out of sleep
300
–
–
s
tXRES
XRES pulse length
–
300
–
–
s
tVDDWAIT
VDD stable to
wait-and-poll hold off
–
0.1
–
1
ms
tVDDXRES
VDD stable to
XRES assertion delay
–
14.27
–
–
ms
tPOLL
SDATA high pulse time
–
0.01
–
200
ms
tACQ
“Key window” time after a VDD
ramp acquire event, based on
256 ILO clocks.
–
3.20
–
19.60
ms
tXRESINI
“Key window” time after an
XRES event, based on 8 ILO
clocks
–
98
–
615
s
tRSCLK
Rise time of SCLK
–
tFSCLK
Fall time of SCLK
tSSCLK
Data setup time to
falling edge of SCLK
tHSCLK
Document Number: 001-86331 Rev. **
Page 26 of 41
CYRF89135
AC I2C Specifications
The following table lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges.
Table 20. AC Characteristics of the I2C SDA and SCL Pins
Symbol
Description
Standard Mode
Fast Mode
Units
Min
Max
Min
Max
0
100
0
400
kHz
fSCL
SCL clock frequency
tHD;STA
Hold time (repeated) START condition. After this period, the
first clock pulse is generated
4.0
–
0.6
–
µs
tLOW
LOW period of the SCL clock
4.7
–
1.3
–
µs
tHIGH
HIGH Period of the SCL clock
4.0
–
0.6
–
µs
tSU;STA
Setup time for a repeated START condition
4.7
–
0.6
–
µs
tHD;DAT
Data hold time
0
3.45
0
0.90
µs
100
[11]
tSU;DAT
Data setup time
250
–
tSU;STO
Setup time for STOP condition
4.0
–
0.6
–
ns
–
µs
tBUF
Bus free time between a STOP and START condition
4.7
–
tSP
Pulse width of spikes are suppressed by the input filter
–
–
1.3
–
µs
0
50
ns
Figure 8. Definition for Timing for Fast/Standard Mode on the I2C Bus
Note
11. A Fast-Mode I2C-bus device can be used in a standard mode I2C-bus system, but the requirement tSU;DAT  250 ns must then be met. This automatically be the case
if the device does not stretch the LOW period of the SCL signal. If such device does stretch the LOW period of the SCL signal, it must output the next data bit to the
SDA line trmax + tSU;DAT = 1000 + 250 = 1250 ns (according to the Standard-Mode I2C-bus specification) before the SCL line is released.
Document Number: 001-86331 Rev. **
Page 27 of 41
CYRF89135
Table 21. SPI Master AC Specifications
Min
Typ
Max
Units
FSCLK
Symbol
SCLK clock frequency
Description
VIN 2.4 V
VIN < 2.4 V
Conditions
–
–
–
–
6
3
MHz
MHz
DC
SCLK duty cycle
–
–
50
–
%
tSETUP
MISO to SCLK setup time
VIN  2.4 V
VIN < 2.4 V
60
100
–
–
–
–
ns
ns
tHOLD
SCLK to MISO hold time
–
40
–
–
ns
tOUT_VAL
SCLK to MOSI valid time
–
–
–
40
ns
tOUT_HIGH
MOSI high time
–
40
–
–
ns
Figure 9. SPI Master Mode 0 and 2
SPI Master, modes 0 and 2
1/FSCLK
THIGH
TLOW
SCLK
(mode 0)
SCLK
(mode 2)
TSETUP
MISO
(input)
THOLD
LSB
MSB
TOUT_SU
TOUT_H
MOSI
(output)
Figure 10. SPI Master Mode 1 and 3
SPI Master, modes 1 and 3
1/FSCLK
THIGH
TLOW
SCLK
(mode 1)
SCLK
(mode 3)
TSETUP
MISO
(input)
THOLD
TOUT_SU
MOSI
(output)
Document Number: 001-86331 Rev. **
LSB
MSB
TOUT_H
MSB
LSB
Page 28 of 41
CYRF89135
Table 22. SPI Slave AC Specifications
Min
Typ
Max
Units
FSCLK
Symbol
SCLK clock frequency
Description
–
Conditions
–
–
4
MHz
tLOW
SCLK low time
–
42
–
–
ns
tHIGH
SCLK high time
–
42
–
–
ns
tSETUP
MOSI to SCLK setup time
–
30
–
–
ns
tHOLD
SCLK to MOSI hold time
–
50
–
–
ns
tSS_MISO
SS high to MISO valid
–
–
–
153
ns
tSCLK_MISO
SCLK to MISO valid
–
–
–
125
ns
tSS_HIGH
SS high time
–
50
–
–
ns
tSS_CLK
Time from SS low to first SCLK
–
2/SCLK
–
–
ns
tCLK_SS
Time from last SCLK to SS high –
2/SCLK
–
–
ns
Figure 11. SPI Slave Mode 0 and 2
SPI Slave, modes 0 and 2
TCLK_SS
TSS_CLK
TSS_HIGH
/SS
1/FSCLK
THIGH
TLOW
SCLK
(mode 0)
SCLK
(mode 2)
TOUT_H
TSS_MISO
MISO
(output)
TSETUP
MOSI
(input)
THOLD
LSB
MSB
Figure 12. SPI Slave Mode 1 and 3
SPI Slave, modes 1 and 3
TSS_CLK
TCLK_SS
/SS
1/FSCLK
THIGH
TLOW
SCLK
(mode 1)
SCLK
(mode 3)
TOUT_H
TSCLK_MISO
TSS_MISO
MISO
(output)
MSB
TSETUP
MOSI
(input)
Document Number: 001-86331 Rev. **
LSB
THOLD
MSB
LSB
Page 29 of 41
CYRF89135
Electrical Specifications – RF Section
Symbol
Description
Min
Typ
Max
Units
Test Condition and Notes
1.9
–
3.6
VDC Input to VIN pins
–
18.5
–
mA
Transmit power PA2.
–
13.7
–
mA
Transmit power PA12.
Supply voltage
VIN
DC power supply voltage range
Current consumption
IDD_TX2
Current consumption – Tx
IDD_TX12
IDD_RX
Current consumption – Rx
–
18
–
mA
IDD_IDLE1
Current consumption – idle
–
1.1
–
mA
IDD_SLPx
Current consumption – sleep
–
1
–
µA
Temperature = +25 °C.
Using firmware sleep patch.
Register 27 = 0x1200,
for VIN ≥ 3.00 VDC only
IDD_SLPr
–
8
–
µA
Temperature = +25 °C;
using firmware sleep patch
Register 27 = 0x4200.
IDD_SLPh
–
38
–
µA
Temperature = +70 °C
‘C’ grade part;
using firmware sleep patch
Register 27 = 0x4200
VIH
Logic input high
0.8 VIN
–
1.2 VIN
V
VIL
Logic input low
0
–
0.8
V
I_LEAK_IN
Input leakage current
–
–
10
µA
VOH
Logic output high
0.8 VIN
–
–
V
IOH = 100 µA source
VOL
Logic output low
–
–
0.4
V
IOL = 100 µA sink
I_LEAK_OUT
Output leakage current
–
–
10
µA
MISO in tristate
T_RISE_OUT
Rise/fall time (SPI MISO)
7 pF cap. load
T_RISE_IN
Rise/fall time (SPI MOSI)
Tr_spi
CLK rise, fall time (SPI)
F_OP
Operating frequency range
VSWR_I
Antenna port mismatch
(Z0 = 50 )
VSWR_O
–
8
25
ns
–
–
25
ns
–
–
25
ns
2400
–
2482
MHz
–
<2:1
–
VSWR Receive mode. Measured using
LC matching circuit
–
<2:1
–
VSWR Transmit mode. Measured using
LC matching circuit
Receive section
RxSbase
Requirement for error-free
register reading, writing.
Usage on-the-air is subject to
local regulatory agency
restrictions regarding operating
frequency.
Measured using LC matching
circuit for BER  0.1%
Receiver sensitivity
(FEC off)
RxStemp
Document Number: 001-86331 Rev. **
–
–87
–
dBm
Room temperature only
0-ppm crystal frequency error.
–
–84
–
dBm
Over temperature;
0-ppm crystal frequency error.
Page 30 of 41
CYRF89135
Electrical Specifications – RF Section (continued)
Symbol
Description
Min
Typ
Max
Units
RxSppm
–
–84
–
dBm
Room temperature only
80-ppm total frequency error
(± 40-ppm crystal frequency
error, each end of RF link)
RxStemp+ppm
–
–80
–
dBm
Over temperature;
80-ppm total frequency error
(± 40-ppm crystal frequency
error, each end of RF link)
–20
0
–
dBm
Room temperature only
–
1
–
µs
Rxmax-sig
Maximum usable signal
Ts
Data (Symbol) rate
Test Condition and Notes
For BER  0.1%. Room
temperature only.
Minimum Carrier/Interference ratio
CI_cochannel
Co-channel interference
–
+9
–
dB
–60-dBm desired signal
CI_1
Adjacent channel interference,
1-MHz offset
–
+6
–
dB
–60-dBm desired signal
CI_2
Adjacent channel
interference, 2-MHz offset
–
–12
–
dB
–60-dBm desired signal
CI_3
Adjacent channel
interference, 3-MHz offset
–
–24
–
dB
–67-dBm desired signal
OBB
Out-of-band blocking
–
 –27
–
dBm
Transmit section
PAVH
RF output power
PAVL
30 MHz to 12.75 GHz
Measured with ACX BF2520
ceramic filter on ant. pin.
–67-dBm desired signal,
BER  0.1%. Room temperature
only.
Measured using a LC matching
circuit
–
+1
–
dBm
PA0 (PA_GN = 0,
Reg9 = 0x1820).
Room temperature only
–
–11.2
–
dBm
PA12 (PA_GN = 12,
Reg9 = 0x1E20).
Room temperature only.
TxPfx2
Second harmonic
–
–45
–
dBm
Measured using a LC matching
circuit. Room temperature only.
TxPfx3
Third and higher harmonics
–
–45
–
dBm
Measured using a LC matching
circuit. Room temperature only.
Df1avg
–
263
–
kHz
Modulation pattern: 11110000...
Df2avg
–
255
–
kHz
Modulation pattern: 10101010...
–
–
–20
dBm
Modulation characteristics
In-band spurious emission
IBS_2
2-MHz offset
IBS_3
3-MHz offset
–
–
–30
dBm
IBS_4
 4-MHz offset
–
–30
–
dBm
–
1
–
MHz
RF VCO and PLL section
Fstep
Channel (Step) size
Document Number: 001-86331 Rev. **
Page 31 of 41
CYRF89135
Electrical Specifications – RF Section (continued)
Symbol
L100k
Description
Min
SSB phase noise
Crystal oscillator frequency error
THOP
RF PLL settling time
Max
Units
Test Condition and Notes
–75
–
dBc/Hz 100-kHz offset
–105
–
dBc/Hz 1-MHz offset
–40
–
+40
ppm
–
100
150
µs
Settle to within 30 kHz of final
value. AutoCAL off.
–
250
350
µs
Settle to within 30 kHz of final
value. AutoCAL on.
–
0.17
0.3
V
Measured during receive state
L1M
dFX0
Typ
THOP_AC
Relative to 12-MHz crystal
reference frequency
LDO voltage regulator section
VDO
Dropout voltage
Figure 13. Power-on and Register Programming Sequence
TVIN
VIN
RST_n
Clock stable
BRCLK
Clock unstable
SPI_SS
SPI Activity
TRPW
TRSU
TCMIN
Write Reg[27]=
0x4200
(not drawn to scale)
Table 23. Initialization Timing Requirements
■
Timing Parameter
Min
Max
Unit
Notes
TRSU
–
30 /
150
ms
30 ms Reset setup time necessary to ensure complete Reset for
VIN=6.5mV/s, 150 ms Reset setup time necessary to ensure complete
Reset for VIN=2mV/s
TRPW
1
10
µs
Reset pulse width necessary to ensure complete reset
TCMIN
3
–
ms
Minimum recommended crystal oscillator and APLL settling time
TVIN
–
6.5 / 2
mV/s
Maximum ramp time for VIN, measured from 0 to 100% of final voltage.
For example, if VIN= 3.3 V, the max ramp time is 6.5 × 3.3 = 21.45 ms.
If VIN= 1.9 V, the max ramp time = 6.5 × 1.9 = 12.35 ms.Reset setup
time necessary to ensure complete Reset for VIN=6.5mV/sReset
setup time necessary to ensure complete Reset for
VIN=6.5mV/sReset setup time necessary to ensure complete Reset
for VIN=6.5mV/s
After register initialization, CYRF89435 68-pin QFN is ready to transmit or receive.
Document Number: 001-86331 Rev. **
Page 32 of 41
CYRF89135
Figure 14. Initialization Flowchart
Initialize
CYRF89135 at
power-up
MCU generates
negative- going
RST_n pulse
Wait Crystal
Enable Time
Initialize
Registers,
beginning with
Reg[27]
Initialization
Done
RST_n pulls up
along with Vin
Table 24. SPI Timing Requirements
Timing Parameter
Min
Max
Unit
Notes
TSSS
20
–
ns
Setup time from assertion of SPI_SS to CLK edge
TSSH
200
–
ns
Hold time required deassertion of SPI_SS
TSCKH
20
–
ns
CLK minimum high time
TSCKL
20
–
ns
CLK minimum low time
TSCK
83
–
ns
Maximum CLK clock is 12 MHz
TSSU
10
–
ns
MOSI setup time
TSHD
10
–
ns
MOSI hold time
TSS_SU
10
–
ns
Before SPI_SS enable, CLK hold low time requirement
TSS_HD
200
–
ns
Minimum SPI inactive time
TSDO
–
35
ns
MISO setup time, ready to read
TSDO1
–
5
ns
If MISO is configured as tristate, MISO assertion time
TSDO2
–
250
ns
If MISO is configured as tristate, MISO deassertion time
T1 Min_R50
350
–
ns
When reading register 50 (FIFO)
T1 Min
83
–
ns
When writing Register 50 (FIFO), or reading/writing any registers other than register
50.
Document Number: 001-86331 Rev. **
Page 33 of 41
CYRF89135
Packaging Information
This section illustrates the packaging specifications for the CYRF89135-68LTXC PSoC device, along with the thermal impedances
for each package.
Important Note Emulation tools may require a larger area on the target PCB than the chip’s footprint. For a detailed description of
the emulation tools’ dimensions, refer to the document titled PSoC Emulator Pod Dimensions at
http://www.cypress.com/design/MR10161.
Figure 15. 68-pin QFN (8 × 8 × 1.0 mm) LT68 5.7 × 5.7 E-Pad (Sawn Type) Package Outline, 001-09618
001-09618 *E
Important Notes
■ For information on the preferred dimensions for mounting QFN packages, see the following Application Note at
http://www.amkor.com/products/notes_papers/MLFAppNote.pdf.
■ Pinned vias for thermal conduction are not required for the low power PSoC device.
Document Number: 001-86331 Rev. **
Page 34 of 41
CYRF89135
Thermal Impedances
Table 25. Thermal Impedances per Package
Package
[13]
68-pin QFN
Typical JA [12]
Typical JC
29 °C/W
23 °C/W
Capacitance on Crystal Pins
Table 26. Typical Package Capacitance on Crystal Pins
Package
Package Capacitance
68-pin QFN
3.3 pF
Solder Reflow Specifications
Table 27 shows the solder reflow temperature limits that must not be exceeded.
Table 27. Solder Reflow Specifications
Package
68-pin QFN
Maximum Peak Temperature (TC)
Maximum Time above TC – 5 °C
240 °C
260 °C
Notes
12. TJ = TA + Power × JA.
13. To achieve the thermal impedance specified for the QFN package, the center thermal pad must be soldered to the PCB ground plane.
Document Number: 001-86331 Rev. **
Page 35 of 41
CYRF89135
Development Tool Selection
Software
PSoC Designer™
At the core of the PSoC development software suite is PSoC
Designer. Utilized by thousands of PSoC developers, this robust
software has been facilitating PSoC designs for over half a
decade. PSoC Designer is available free of charge at
http://www.cypress.com.
PSoC Programmer
Flexible enough to be used on the bench in development, yet
suitable for factory programming, PSoC Programmer works
either as a standalone programming application or it can operate
directly from PSoC Designer. PSoC Programmer software is
compatible with both PSoC ICE-Cube In-Circuit Emulator and
PSoC MiniProg. PSoC Programmer is available free of charge
at http://www.cypress.com.
Evaluation Tools
All evaluation tools are sold at the Cypress Online Store.
CY8CKIT-002 - MiniProg 3
The CY8CKIT-002 - MiniProg 3 kit enables the user to program
PSoC devices via the MiniProg3 programming unit. The
MiniProg is a small, compact prototyping programmer that
connects to the PC via a provided USB 2.0 cable. The kit
includes:
■
MiniProg Programming Unit
■
USB 2.0 cable to connect it to PC
CY8CKIT-006 PSoC® 3 LCD Segment Drive Evaluation Kit
All development kits are sold at the Cypress Online Store.
Cypress’s PSoC programmable system-on-chip architecture
gives you the freedom to not only imagine revolutionary new
products, but the capability to also get those products to market
faster than anyone else.The ability to drive a 5V display on 0.5V
of input and the ability to drive multiple displays on one PSoC
device can translate to the ultimate in design freedom, lower
BOM costs and new product differentiators with this easy to use
evaluation kit.The kit contains:
CY3215-DK Basic Development Kit
■
PSoC 3 LCD Segment Drive Evaluation Board
■
9V Battery
■
12V Wall Power Supply
■
MiniProg3 Programmer / Debugger
■
USB Cable (to connect MiniProg3 to the PC)
Development Kits
The CY3215-DK is for prototyping and development with PSoC
Designer. This kit supports in-circuit emulation and the software
interface enables users to run, halt, and single step the
processor and view the content of specific memory locations.
PSoC Designer supports the advance emulation features also.
The kit includes:
■
PSoC Designer Software CD
■
Kit Stand
■
ICE-Cube In-Circuit Emulator
■
Quick Start Guide
■
ICE Flex-Pod for CY8C29X66A Family
■
■
Cat-5 Adapter
Kit CD, which includes: PSoC Creator, PSoC Programmer,
Projects and Documentation
■
Mini-Eval Programming Board
■
110 ~ 240 V Power Supply, Euro-Plug Adapter
■
iMAGEcraft C Compiler (Registration Required)
■
ISSP Cable
■
2 CY8C29466A-24PXI 28-PDIP Chip Samples
Device Programmers
Firmware needs to be downloaded to PRoC-EMB device only at
3.3 V using Miniprog3 Programmer. This Programmer kit can be
purchased from Cypress Store using
part#’CY8CKIT-002-MiniProg3’. It is small, compact
programmer which connects PC via a USB 2.0 cable (Provided
along with CY8CKIT-002’
NOTE: MiniProg1 Programmer should not be used as it does not
support programming at 3.3 V.
Document Number: 001-86331 Rev. **
Page 36 of 41
CYRF89135
Ordering Information
The following table lists the CYRF89135-68LTXC PSoC devices' key package features and ordering codes.
Table 28. PSoC Device Key Features and Ordering Information
Package
Ordering Code
68-pin (8 × 8 × 1 mm) QFN
CYRF89135-68LTXC
Flash SRAM CapSense Digital
(Bytes) (Bytes) Blocks I/O Pins
32
2048
0
35
Analog
Inputs
35
XRES ADC
Pin
Yes
No
Ordering Code Definitions
CY
RF 89
135
- 68
LT X
C
Temperature Range: C = Commercial
Pb-free
Package Type:
LT = QFN Package
Pin Count:
68 = 68 Pins
Part Number: 135 = PRoC - Embeeded
Family Code: 89 = Wireless
Marketing Code: RF = Radio Frequency
Company ID: CY = Cypress
Document Number: 001-86331 Rev. **
Page 37 of 41
CYRF89135
Acronyms
Reference Documents
Table 29. Acronyms Used in this Document
Acronym
Description
AC
alternating current
ADC
analog-to-digital converter
API
application programming interface
CMOS
complementary metal oxide semiconductor
CPU
central processing unit
DAC
digital-to-analog converter
DC
direct current
EOP
end of packet
FSR
full scale range
GPIO
general purpose input/output
GUI
graphical user interface
I2C
inter-integrated circuit
ICE
in-circuit emulator
IDAC
digital analog converter current
ILO
internal low speed oscillator
IMO
internal main oscillator
I/O
input/output
ISSP
in-system serial programming
LCD
liquid crystal display
LDO
low dropout (regulator)
LSB
least-significant bit
LVD
low voltage detect
MCU
micro-controller unit
MIPS
mega instructions per second
MISO
master in slave out
MOSI
master out slave in
MSB
most-significant bit
OCD
on-chip debugger
POR
power on reset
PPOR
precision power on reset
PSRR
power supply rejection ratio
PWRSYS power system
PSoC®
Programmable System-on-Chip
SLIMO
slow internal main oscillator
SRAM
static random access memory
SNR
signal to noise ratio
QFN
quad flat no-lead
SCL
serial I2C clock
SDA
serial I2C data
SDATA
serial ISSP data
SPI
serial peripheral interface
SS
slave select
SSOP
shrink small outline package
TC
test controller
USB
universal serial bus
WLCSP
wafer level chip scale package
XTAL
crystal
■
In-system Serial Programming (ISSP) protocol for 20xx6
(AN2026C)
■
Host Sourced Serial Programming for 20xx6 devices
(AN59389)
Document Number: 001-86331 Rev. **
Document Conventions
Units of Measure
Table 30. Units of Measure
Symbol
°C
dB
fF
g
Hz
KB
Kbit
KHz
Ksps
k
MHz
M
A
F
H
s
W
mA
ms
mV
nA
nF
ns
nV
W
pA
pF
pp
ppm
ps
sps
s
V
W
Unit of Measure
degree Celsius
decibels
femtofarad
gram
hertz
1024 bytes
1024 bits
kilohertz
kilo samples per second
kilohm
megahertz
megaohm
microampere
microfarad
microhenry
microsecond
microwatt
milliampere
millisecond
millivolt
nanoampere
nanofarad
nanosecond
nanovolt
ohm
picoampere
picofarad
peak-to-peak
parts per million
picosecond
samples per second
sigma: one standard deviation
volt
watt
Page 38 of 41
CYRF89135
Numeric Naming
Hexadecimal numbers are represented with all letters in uppercase with an appended lowercase ‘h’ (for example, ‘14h’ or ‘3Ah’).
Hexadecimal numbers may also be represented by a ‘0x’ prefix, the C coding convention. Binary numbers have an appended
lowercase ‘b’ (for example, 01010100b’ or ‘01000011b’). Numbers not indicated by an ‘h’, ‘b’, or 0x are decimal.
Glossary
Crosspoint connection
Connection between any GPIO combination via analog multiplexer bus.
Differential non-linearity
Ideally, any two adjacent digital codes correspond to output analog voltages that are exactly
one LSB apart. Differential non-linearity is a measure of the worst case deviation from the
ideal 1 LSB step.
Hold time
Hold time is the time following a clock event during which the data input to a latch or flip-flop
must remain stable in order to guarantee that the latched data is correct.
I2C
It is a serial multi-master bus used to connect low speed peripherals to MCU.
Integral nonlinearity
It is a term describing the maximum deviation between the ideal output of a DAC/ADC and
the actual output level.
Latch-up current
Current at which the latch-up test is conducted according to JESD78 standard (at 125
degree Celsius)
Power supply rejection ratio (PSRR)
The PSRR is defined as the ratio of the change in supply voltage to the corresponding
change in output voltage of the device.
Scan
The conversion of all sensor capacitances to digital values.
Setup time
Period required to prepare a device, machine, process, or system for it to be ready to
function.
Signal-to-noise ratio
The ratio between a capacitive finger signal and system noise.
SPI
Serial peripheral interface is a synchronous serial data link standard.
Document Number: 001-86331 Rev. **
Page 39 of 41
CYRF89135
Document History Page
Document Title: CYRF89135, PRoC™ - Embedded
Document Number: 001-86331
Revision
ECN
Orig. of
Change
Submission
Date
**
3924802
AKHL
04/03/2013
Document Number: 001-86331 Rev. **
Description of Change
New silicon document.
Page 40 of 41
CYRF89135
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.
Products
Automotive
Clocks & Buffers
Interface
Lighting & Power Control
cypress.com/go/automotive
PSoC Solutions
cypress.com/go/clocks
psoc.cypress.com/solutions
cypress.com/go/interface
PSoC 1 | PSoC 3 | PSoC 5
cypress.com/go/powerpsoc
cypress.com/go/plc
Memory
Optical & Image Sensing
cypress.com/go/memory
cypress.com/go/image
PSoC
Touch Sensing
cypress.com/go/psoc
cypress.com/go/touch
USB Controllers
Wireless/RF
cypress.com/go/USB
cypress.com/go/wireless
© Cypress Semiconductor Corporation, 2013. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of any
circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be used for medical,
life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its products for use as critical
components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress products in life-support systems
application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Any Source Code (software and/or firmware) is owned by Cypress Semiconductor Corporation (Cypress) and is protected by and subject to worldwide patent protection (United States and foreign),
United States copyright laws and international treaty provisions. Cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of,
and compile the Cypress Source Code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a Cypress
integrated circuit as specified in the applicable agreement. Any reproduction, modification, translation, compilation, or representation of this Source Code except as specified above is prohibited without
the express written permission of Cypress.
Disclaimer: CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS MATERIAL, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. Cypress reserves the right to make changes without further notice to the materials described herein. Cypress does not
assume any liability arising out of the application or use of any product or circuit described herein. Cypress does not authorize its products for use as critical components in life-support systems where
a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress’ product in a life-support systems application implies that the manufacturer
assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Use may be limited by and subject to the applicable Cypress software license agreement.
Document Number: 001-86331 Rev. **
Revised April 3, 2013
Page 41 of 41
PSoC Designer™ is a trademark and PSoC® and CapSense® are registered trademarks of Cypress Semiconductor Corporation.
Purchase of I2C components from Cypress or one of its sublicensed Associated Companies conveys a license under the Philips I2C Patent Rights to use these components in an I2C system, provided
that the system conforms to the I2C Standard Specification as defined by Philips. As from October 1st, 2006 Philips Semiconductors has a new trade name - NXP Semiconductors.
All products and company names mentioned in this document may be the trademarks of their respective holders.
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