CC2652R74T0RGZR [TI]
CC2652R7 SimpleLink⢠Multiprotocol 2.4 GHz Wireless MCU;型号: | CC2652R74T0RGZR |
厂家: | TEXAS INSTRUMENTS |
描述: | CC2652R7 SimpleLink⢠Multiprotocol 2.4 GHz Wireless MCU 无线 |
文件: | 总58页 (文件大小:2900K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
CC2652R7
SWRS253 – MAY 2021
CC2652R7 SimpleLink™ Multiprotocol 2.4 GHz Wireless MCU
– Active mode TX 5 dBm: 9.9 mA
– Active mode MCU 48 MHz (CoreMark):
3.87 mA (81 μA/MHz)
1 Features
•
Microcontroller
– Powerful 48-MHz Arm® Cortex®-M4F processor
– EEMBC CoreMark® score: 148
– 704KB of in-system programmable flash
– 256KB of ROM for protocols and library
functions
– 8KB of cache SRAM (alternatively available as
general-purpose RAM)
– 144KB of ultra-low leakage SRAM. The SRAM
is protected by parity to ensure high reliability of
operation.
– 2-Pin cJTAG and JTAG debugging
– Supports over-the-air upgrade (OTA)
Ultra-low power sensor controller with 4KB of
SRAM
– Sample, store, and process sensor data
– Operation independent from system CPU
– Fast wake-up for low-power operation
TI-RTOS, drivers, bootloader, Bluetooth®5.2 Low
Energy controller, and IEEE 802.15.4 MAC in
ROM for optimized application size
RoHS-compliant package
– 7-mm × 7-mm RGZ VQFN48 (31 GPIOs)
Peripherals
– Digital peripherals can be routed to any GPIO
– Four 32-bit or eight 16-bit general-purpose
timers
– Sensor controller, low-power mode, 2 MHz,
running infinite loop: 30.1 μA
– Sensor controller, active mode, 24 MHz,
running infinite loop: 808 μA
– Standby: 1.15 µA (RTC on, 144KB RAM and
CPU retention)
– Shutdown: 151 nA (wakeup on external events)
Radio section
– 2.4 GHz RF transceiver compatible with
Bluetooth 5.2 Low Energy and earlier LE
specifications and IEEE 802.15.4 PHY and
MAC
– Excellent receiver sensitivity:
-100 dBm for 802.15.4 (2.4 GHz),
-104 dBm for Bluetooth 125-kbps (LE Coded
PHY)
– Output power up to +5 dBm with temperature
compensation
– Suitable for systems targeting compliance with
worldwide radio frequency regulations
•
•
•
•
•
•
•
•
•
EN 300 328, (Europe)
EN 300 440 Category 2
FCC CFR47 Part 15
ARIB STD-T66 (Japan)
•
•
Wireless protocols
– Thread, Zigbee®, Bluetooth®5.2 Low Energy,
IEEE 802.15.4, IPv6-enabled smart objects
(6LoWPAN), Wi-SUN®, proprietary systems,
SimpleLink™ TI 15.4-stack (2.4 GHz), and
dynamic multiprotocol manager (DMM) driver.
Development Tools and Software
– CC26x2R LaunchPad™ Development Kit
– SimpleLink™ CC13x2 and CC26x2 Software
Development Kit (SDK)
– 12-bit ADC, 200k samples per second, 8
channels
– Two comparators with internal reference DAC
(one continuous time, one ultra-low power)
– Programmable current source
– Two UART
– Two SSI (SPI, MICROWIRE, TI)
– I2C
– I2S
– SmartRF™ Studio for simple radio configuration
– Sensor Controller Studio for building low-power
sensing applications
– Real-time clock (RTC)
– AES 128- and 256-bit crypto accelerator
– ECC and RSA public key hardware Accelerator
– SHA2 Accelerator (full suite up to SHA-512)
– True random number generator (TRNG)
– Capacitive sensing, up to 8 channels
– Integrated temperature and battery monitor
External system
2 Applications
•
2400 to 2480 MHz ISM and SRD systems 1
with down to 4 kHz of receive bandwidth
Building automation
– Building security systems – motion detector,
electronic smart lock, door and window sensor,
garage door system, gateway
•
•
•
– On-chip buck DC/DC converter
Low power
– HVAC – thermostat, wireless environmental
sensor, HVAC system controller, gateway
– Wide supply voltage range: 1.8 V to 3.8 V
– Active mode RX: 7.1 mA
– Active mode TX 0 dBm: 7.6 mA
1
See RF Core for additional details on supported protocol standards, modulation formats, and data rates.
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. ADVANCE INFORMATION for preproduction products; subject to change
without notice.
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SWRS253 – MAY 2021
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– Fire safety system – smoke and heat detector,
fire alarm control panel (FACP)
– Video surveillance – IP network camera
– Elevators and escalators – elevator main
control panel for elevators and escalators
•
•
Medical
Electronic point of sale (EPOS) – Electronic Shelf
Label (ESL)
Communication equipment
– Wired networking – wireless LAN or Wi-Fi
access points, edge router , small business
router
•
•
Grid infrastructure
– Smart meters – water meter, gas meter,
electricity meter, and heat cost allocators
– Grid communications – wireless
communications – Long-range sensor
applications
•
Personal electronics
– Home theater & entertainment – smart
speakers, smart display, set-top box
– Wearables (non-medical) – smart trackers,
smart clothing
•
•
Industrial transport – asset tracking
Factory automation and control
3 Description
The SimpleLink™ CC2652R7 device is a multiprotocol 2.4 GHz wireless microcontroller (MCU) supporting
Thread, Zigbee®, Bluetooth®5.2 Low Energy, IEEE 802.15.4, IPv6-enabled smart objects (6LoWPAN),
proprietary systems, including the TI 15.4-Stack (2.4 GHz), and concurrent multiprotocol through a Dynamic
Multiprotocol Manager (DMM) driver. The device is optimized for low-power wireless communication and
advanced sensing in building security systems, HVAC, medical, wired networking, portable electronics, home
theater & entertainment, and connected peripherals markets. The highlighted features of this device include:
•
Wide flexibility of protocol stack support in the SimpleLink™ CC13x2 and CC26x2 Software Development Kit
(SDK).
•
•
•
Memory scalable portfolio from 32KB to 704KB Flash enabling ease of platform migration.
Longer battery life wireless applications with low standby current of 1.15 µA with full RAM retention.
Advanced sensing with a programmable, autonomous ultra-low power Sensor Controller CPU with fast
wake-up capability. As an example, the sensor controller is capable of 1-Hz ADC sampling at 1 µA system
current.
•
•
•
Low SER (Soft Error Rate) FIT (Failure-in-time) for long operation lifetime with no disruption for industrial
markets with always-on SRAM parity against corruption due to potential radiation events.
Dedicated software controlled radio controller (Arm® Cortex®-M0) providing flexible low-power RF transceiver
capability to support multiple physical layers and RF standards.
Excellent radio sensitivity and robustness (selectivity and blocking) performance for Bluetooth ® Low Energy
(-104 dBm for 125-kbps LE Coded PHY).
The CC2652R7 device is part of the SimpleLink™ MCU platform, which consists of Wi-Fi®, Bluetooth Low
Energy, Thread, Zigbee, Sub-1 GHz MCUs, and host MCUs that all share a common, easy-to-use development
environment with a single core software development kit (SDK) and rich tool set. A one-time integration of the
SimpleLink™ platform enables you to add any combination of the portfolio’s devices into your design, allowing
100 percent code reuse when your design requirements change. For more information, visit SimpleLink™ MCU
platform.
Device Information
PART NUMBER(1)
CC2652R74T0RGZR
PACKAGE
BODY SIZE (NOM)
VQFN (48)
7.00 mm × 7.00 mm
(1) For the most current part, package, and ordering information for all available devices, see the Package Option Addendum in Section
11, or see the TI website.
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3.1 Functional Block Diagram
2.4 GHz
CC2652R7
RF Core
cJTAG
Main CPU
256 KB
ROM
ADC
ADC
Arm®
Cortex®-M4F
Processor
Up to
704 KB
Flash
Digital PLL
with 8 KB
Cache
DSP Modem
48 MHz
16 KB
SRAM
Arm®
Cortex®-M0
Processor
Up to
144 KB
SRAM
ROM
with Parity
General Hardware Peripherals and Modules
Sensor Interface
I2C and I2S
4× 32-bit Timers
2× SSI (SPI)
Watchdog Timer
TRNG
ULP Sensor Controller
8-bit DAC
2× UART
12-bit ADC, 200 ks/s
32 ch. µDMA
31 GPIOs
2x Low-Power Comparator
SPI-I2C Digital Sensor IF
Capacitive Touch IF
Time-to-Digital Converter
4 KB SRAM
Temperature and Battery
Monitor
AES-256, SHA2-512
ECC, RSA
RTC
LDO, Clocks, and References
Optional DC/DC Converter
Figure 3-1. CC2652R7 Block Diagram
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Table of Contents
1 Features............................................................................1
2 Applications.....................................................................1
3 Description.......................................................................2
3.1 Functional Block Diagram...........................................3
4 Revision History.............................................................. 4
5 Device Comparison.........................................................5
6 Terminal Configuration and Functions..........................6
6.1 Pin Diagram – RGZ Package (Top View)....................6
6.2 Signal Descriptions – RGZ Package...........................7
6.3 Connections for Unused Pins and Modules................8
7 Specifications.................................................................. 9
7.1 Absolute Maximum Ratings ....................................... 9
7.2 ESD Ratings .............................................................. 9
7.3 Recommended Operating Conditions ........................9
7.4 Power Supply and Modules ....................................... 9
7.5 Power Consumption - Power Modes ....................... 10
7.6 Power Consumption - Radio Modes ........................ 11
7.7 Nonvolatile (Flash) Memory Characteristics ............ 11
7.8 Thermal Resistance Characteristics ........................ 11
7.9 RF Frequency Bands ...............................................12
7.10 Bluetooth Low Energy - Receive (RX) ................... 13
7.11 Bluetooth Low Energy - Transmit (TX) ...................16
7.12 Zigbee and Thread - IEEE 802.15.4-2006 2.4
8 Detailed Description......................................................37
8.1 Overview...................................................................37
8.2 System CPU............................................................. 37
8.3 Radio (RF Core)........................................................38
8.4 Memory.....................................................................38
8.5 Sensor Controller......................................................40
8.6 Cryptography............................................................ 41
8.7 Timers....................................................................... 42
8.8 Serial Peripherals and I/O.........................................43
8.9 Battery and Temperature Monitor............................. 43
8.10 µDMA......................................................................43
8.11 Debug......................................................................43
8.12 Power Management................................................44
8.13 Clock Systems........................................................ 45
8.14 Network Processor..................................................45
9 Application, Implementation, and Layout................... 46
9.1 Reference Designs................................................... 46
9.2 Junction Temperature Calculation.............................47
10 Device and Documentation Support..........................48
10.1 Tools and Software................................................. 48
10.2 Documentation Support.......................................... 50
10.3 Support Resources................................................. 50
10.4 Trademarks.............................................................50
10.5 Electrostatic Discharge Caution..............................51
10.6 Glossary..................................................................51
11 Mechanical, Packaging, and Orderable
GHz (OQPSK DSSS1:8, 250 kbps) - RX ................... 17
7.13 Zigbee and Thread - IEEE 802.15.4-2006 2.4
GHz (OQPSK DSSS1:8, 250 kbps) - TX ....................18
7.14 Timing and Switching Characteristics..................... 18
7.15 Peripheral Characteristics.......................................23
7.16 Typical Characteristics............................................31
Information.................................................................... 52
11.1 Packaging Information............................................ 52
4 Revision History
DATE
REVISION
NOTES
May 2021
*
Initial Release
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5 Device Comparison
Table 5-1. Device Family Overview
FLASH
(KB)
RAM
(KB)
DEVICE
RADIO SUPPORT
GPIO
PACKAGE SIZE
CC1312R
Sub-1 GHz
352
80-144
30
RGZ (7-mm × 7-mm VQFN48)
Multiprotocol
Sub-1 GHz
Bluetooth 5.2 Low Energy
Zigbee
CC1352P
CC1352R
352-704
80-144
26
28
RGZ (7-mm × 7-mm VQFN48)
Thread
2.4 GHz proprietary FSK-based formats
+20-dBm high-power amplifier
Multiprotocol
Sub-1 GHz
Bluetooth 5.2 Low Energy
Zigbee
352
80
RGZ (7-mm × 7-mm VQFN48)
Thread
2.4 GHz proprietary FSK-based formats
Bluetooth 5.2 Low Energy
2.4 GHz proprietary FSK-based formats
CC2642R
352
352
80
80
31
31
RGZ (7-mm × 7-mm VQFN48)
RTC (7-mm × 7-mm VQFN48)
CC2642R-Q1
Bluetooth 5.2 Low Energy
Multiprotocol
Bluetooth 5.2 Low Energy
Zigbee
CC2652R
352-704
352
80-144
80
31
31
RGZ (7-mm × 7-mm VQFN48)
RGZ (7-mm × 7-mm VQFN48)
Thread
2.4 GHz proprietary FSK-based formats
Multiprotocol
Bluetooth 5.2 Low Energy
Zigbee
CC2652RB
Thread
Multiprotocol
Bluetooth 5.2 Low Energy
Zigbee
CC2652P
CC1310
352-704
32–128
80-144
16-20
26
RGZ (7-mm × 7-mm VQFN48)
Thread
2.4 GHz proprietary FSK-based formats
+19.5-dBm high-power amplifier
RGZ (7-mm × 7-mm VQFN48)
RHB (5-mm × 5-mm VQFN32)
RSM (4-mm × 4-mm VQFN32)
Sub-1 GHz
10-31
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6 Terminal Configuration and Functions
6.1 Pin Diagram – RGZ Package (Top View)
RF_P
RF_N
1
2
3
4
5
6
7
8
9
36 DIO_23
35 RESET_N
34 VDDS_DCDC
33 DCDC_SW
32 DIO_22
X32K_Q1
X32K_Q2
DIO_0
DIO_1
31 DIO_21
DIO_2
30 DIO_20
DIO_3
29 DIO_19
DIO_4
28 DIO_18
DIO_5 10
DIO_6 11
DIO_7 12
27 DIO_17
26 DIO_16
25 JTAG_TCKC
Figure 6-1. RGZ (7-mm × 7-mm) Pinout, 0.5-mm Pitch (Top View)
The following I/O pins marked in Figure 6-1 in bold have high-drive capabilities:
•
•
•
•
•
•
Pin 10, DIO_5
Pin 11, DIO_6
Pin 12, DIO_7
Pin 24, JTAG_TMSC
Pin 26, DIO_16
Pin 27, DIO_17
The following I/O pins marked in Figure 6-1 in italics have analog capabilities:
•
•
•
•
•
•
•
•
Pin 36, DIO_23
Pin 37, DIO_24
Pin 38, DIO_25
Pin 39, DIO_26
Pin 40, DIO_27
Pin 41, DIO_28
Pin 42, DIO_29
Pin 43, DIO_30
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6.2 Signal Descriptions – RGZ Package
Table 6-1. Signal Descriptions – RGZ Package
PIN
I/O
TYPE
DESCRIPTION
NAME
NO.
33
23
5
DCDC_SW
DCOUPL
DIO_0
—
—
Power
Power
Output from internal DC/DC converter(1)
For decoupling of internal 1.27 V regulated digital-supply (2)
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
—
Digital
GPIO
DIO_1
6
Digital
GPIO
DIO_2
7
Digital
GPIO
DIO_3
8
Digital
GPIO
DIO_4
9
Digital
GPIO
DIO_5
10
11
12
14
15
16
17
18
19
20
21
26
27
28
29
30
31
32
36
37
38
39
40
41
42
43
—
24
25
35
Digital
GPIO, high-drive capability
DIO_6
Digital
GPIO, high-drive capability
DIO_7
Digital
GPIO, high-drive capability
DIO_8
Digital
GPIO
DIO_9
Digital
GPIO
DIO_10
DIO_11
DIO_12
DIO_13
DIO_14
DIO_15
DIO_16
DIO_17
DIO_18
DIO_19
DIO_20
DIO_21
DIO_22
DIO_23
DIO_24
DIO_25
DIO_26
DIO_27
DIO_28
DIO_29
DIO_30
EGP
Digital
GPIO
Digital
GPIO
Digital
GPIO
Digital
GPIO
Digital
GPIO
Digital
GPIO
Digital
GPIO, JTAG_TDO, high-drive capability
GPIO, JTAG_TDI, high-drive capability
GPIO
Digital
Digital
Digital
GPIO
Digital
GPIO
Digital
GPIO
Digital
GPIO
Digital or Analog
Digital or Analog
Digital or Analog
Digital or Analog
Digital or Analog
Digital or Analog
Digital or Analog
Digital or Analog
GND
GPIO, analog capability
GPIO, analog capability
GPIO, analog capability
GPIO, analog capability
GPIO, analog capability
GPIO, analog capability
GPIO, analog capability
GPIO, analog capability
Ground – exposed ground pad(3)
JTAG TMSC, high-drive capability
JTAG TCKC
JTAG_TMSC
JTAG_TCKC
RESET_N
I/O
I
Digital
Digital
I
Digital
Reset, active low. No internal pullup resistor
Positive RF input signal to LNA during RX
Positive RF output signal from PA during TX
RF_P
RF_N
VDDR
1
2
—
—
—
RF
RF
Negative RF input signal to LNA during RX
Negative RF output signal from PA during TX
Internal supply, must be powered from the internal DC/DC
converter or the internal LDO(4) (2) (6)
45
Power
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Table 6-1. Signal Descriptions – RGZ Package (continued)
PIN
I/O
TYPE
DESCRIPTION
NAME
NO.
Internal supply, must be powered from the internal DC/DC
converter or the internal LDO(5) (2) (6)
VDDR_RF
48
—
Power
VDDS
44
13
22
34
46
47
3
—
—
—
—
—
—
—
—
Power
Power
Power
Power
Analog
Analog
Analog
Analog
1.8-V to 3.8-V main chip supply(1)
1.8-V to 3.8-V DIO supply(1)
VDDS2
VDDS3
1.8-V to 3.8-V DIO supply(1)
VDDS_DCDC
X48M_N
X48M_P
X32K_Q1
X32K_Q2
1.8-V to 3.8-V DC/DC converter supply
48-MHz crystal oscillator pin 1
48-MHz crystal oscillator pin 2
32-kHz crystal oscillator pin 1
32-kHz crystal oscillator pin 2
4
(1) For more details, see technical reference manual listed in Section 10.2.
(2) Do not supply external circuitry from this pin.
(3) EGP is the only ground connection for the device. Good electrical connection to device ground on printed circuit board (PCB) is
imperative for proper device operation.
(4) If internal DC/DC converter is not used, this pin is supplied internally from the main LDO.
(5) If internal DC/DC converter is not used, this pin must be connected to VDDR for supply from the main LDO.
(6) Output from internal DC/DC and LDO is trimmed to 1.68 V.
6.3 Connections for Unused Pins and Modules
Table 6-2. Connections for Unused Pins – RGZ Package
PREFERRED
FUNCTION
SIGNAL NAME
PIN NUMBER
ACCEPTABLE PRACTICE(1)
PRACTICE(1)
5–12
14–21
26–32
36–43
GPIO
DIO_n
NC or GND
NC
X32K_Q1
3
4
32.768-kHz crystal
NC or GND
NC
X32K_Q2
DCDC_SW
VDDS_DCDC
33
34
NC
NC
DC/DC converter(2)
VDDS
VDDS
(1) NC = No connect
(2) When the DC/DC converter is not used, the inductor between DCDC_SW and VDDR can be removed. VDDR and VDDR_RF must still
be connected and the 22 uF DCDC capacitor must be kept on the VDDR net.
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7 Specifications
7.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1) (2)
MIN
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
MAX UNIT
VDDS(3)
Supply voltage
4.1
V
V
V
Voltage on any digital pin(4)
VDDS + 0.3, max 4.1
Voltage on crystal oscillator pins, X32K_Q1, X32K_Q2, X48M_N and X48M_P
Voltage scaling enabled
VDDR + 0.3, max 2.25
VDDS
1.49
Vin
Voltage on ADC input
Voltage scaling disabled, internal reference
Voltage scaling disabled, VDDS as reference
V
VDDS / 2.9
5
Input level, RF pins
Storage temperature
dBm
°C
Tstg
–40
150
(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
(2) All voltage values are with respect to ground, unless otherwise noted.
(3) VDDS_DCDC, VDDS2 and VDDS3 must be at the same potential as VDDS.
(4) Including analog capable DIOs.
7.2 ESD Ratings
VALUE
±2000
±500
UNIT
V
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001(1)
Charged device model (CDM), per ANSI/ESDA/JEDEC JS-002(2)
All pins
All pins
VESD
Electrostatic discharge
V
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process
7.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
MAX
105
115
3.8
UNIT
°C
Operating ambient temperature(1) (3)
Operating junction temperature(1) (3)
Operating supply voltage (VDDS)
Rising supply voltage slew rate
Falling supply voltage slew rate(2)
–40
–40
1.8
0
°C
V
100
20
mV/µs
mV/µs
0
(1) Limited power on hours when operating at maximum operating temperature.
(2) For small coin-cell batteries, with high worst-case end-of-life equivalent source resistance, a 22-µF VDDS input capacitor must be used
to ensure compliance with this slew rate.
(3) For thermal resistance characteristics refer to Section 7.8. For application considerations, refer to Section 9.2.
7.4 Power Supply and Modules
over operating free-air temperature range (unless otherwise noted)
PARAMETER
VDDS Power-on-Reset (POR) threshold
VDDS Brown-out Detector (BOD) (1)
MIN
TYP
1.1 - 1.55
1.77
MAX
UNIT
V
V
V
V
Rising threshold
Rising threshold
Falling threshold
VDDS Brown-out Detector (BOD), before initial boot (2)
VDDS Brown-out Detector (BOD) (1)
1.70
1.75
(1) For boost mode (VDDR =1.95 V), TI drivers software initialization will trim VDDS BOD limits to maximum (approximately 2.0 V)
(2) Brown-out Detector is trimmed at initial boot, value is kept until device is reset by a POR reset or the RESET_N pin
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7.5 Power Consumption - Power Modes
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V with DC/DC enabled unless
otherwise noted.
PARAMETER
TEST CONDITIONS
TYP
UNIT
Core Current Consumption
Reset. RESET_N pin asserted or VDDS below power-on-reset threshold
Shutdown. No clocks running, no retention
151
151
Reset and Shutdown
nA
RTC running, CPU, 144KB RAM and (partial) register retention.
RCOSC_LF
1.2
1.1
µA
µA
µA
µA
µA
µA
mA
Standby
RTC running, CPU, 64KB RAM and (partial) register retention.
without cache retention RCOSC_LF
RTC running, CPU, 144KB RAM and (partial) register retention
XOSC_LF
Icore
1.3
RTC running, CPU, 144KB RAM and (partial) register retention.
RCOSC_LF
2.6
Standby
with cache retention
RTC running, CPU, 144KB RAM and (partial) register retention.
XOSC_LF
2.8
Supply Systems and RAM powered
RCOSC_HF
Idle
669
3.87
MCU running CoreMark at 48 MHz
RCOSC_HF
Icore
Active
Peripheral Current Consumption
Peripheral power
domain
Delta current with domain enabled
Delta current with domain enabled
97.7
7.2
Serial power domain
RF Core
Delta current with power domain enabled,
clock enabled, RF core idle
211
µDMA
Timers
Delta current with clock enabled, module is idle
Delta current with clock enabled, module is idle(3)
Delta current with clock enabled, module is idle
Delta current with clock enabled, module is idle
Delta current with clock enabled, module is idle
Delta current with clock enabled, module is idle(1)
Delta current with clock enabled, module is idle(2)
Delta current with clock enabled, module is idle
Delta current with clock enabled, module is idle
63.9
81.0
10.1
26.3
82.9
168
Iperi
µA
I2C
I2S
SSI
UART
CRYPTO (AES)
25.6
84.7
35.6
PKA
TRNG
Sensor Controller Engine Consumption
Active mode
ISCE
24 MHz, infinite loop
2 MHz, infinite loop
852
µA
Low-power mode
33.7
(1) Only one UART running
(2) Only one SSI running
(3) Only one GPTimer running
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7.6 Power Consumption - Radio Modes
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V with DC/DC enabled unless
otherwise noted.
PARAMETER
TEST CONDITIONS
TYP UNIT
Radio receive current
2440 MHz
7.1
7.6
mA
mA
0 dBm output power setting
2440 MHz
Radio transmit current
2.4 GHz PA (Bluetooth Low Energy)
+5 dBm output power setting
2440 MHz
9.9
mA
7.7 Nonvolatile (Flash) Memory Characteristics
Over operating free-air temperature range and VDDS = 3.0 V (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Flash sector size
8
KB
Supported flash erase cycles before failure, single-bank(1) (5)
Supported flash erase cycles before failure, single sector(2)
30
60
k Cycles
k Cycles
Write
Maximum number of write operations per row before sector
erase(3)
83
Operations
Years at 105
°C
Flash retention
105 °C
11.4
Flash sector erase current
Average delta current
Zero cycles
10.7
10
mA
ms
ms
mA
µs
Flash sector erase time(4)
30k cycles
4000
Flash write current
Flash write time(4)
Average delta current, 4 bytes at a time
4 bytes at a time
6.2
21.6
(1) A full bank erase is counted as a single erase cycle on each sector
(2) Up to 4 customer-designated sectors can be individually erased an additional 30k times beyond the baseline bank limitation of 30k
cycles
(3) Each wordline is 2048 bits (or 256 bytes) wide. This limitation corresponds to sequential memory writes of 4 (3.1) bytes minimum
per write over a whole wordline. If additional writes to the same wordline are required, a sector erase is required once the maximum
number of write operations per row is reached.
(4) This number is dependent on Flash aging and increases over time and erase cycles
(5) Aborting flash during erase or program modes is not a safe operation.
7.8 Thermal Resistance Characteristics
PACKAGE
RGZ
THERMAL METRIC(1)
UNIT
(VQFN)
48 PINS
23.4
13.3
8.0
RθJA
Junction-to-ambient thermal resistance
Junction-to-case (top) thermal resistance
Junction-to-board thermal resistance
°C/W(2)
°C/W(2)
°C/W(2)
°C/W(2)
°C/W(2)
°C/W(2)
RθJC(top)
RθJB
ψJT
Junction-to-top characterization parameter
Junction-to-board characterization parameter
Junction-to-case (bottom) thermal resistance
0.1
ψJB
7.9
RθJC(bot)
1.7
(1) For more information about traditional and new thermal metrics, see Semiconductor and IC Package Thermal Metrics.
(2) °C/W = degrees Celsius per watt.
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7.9 RF Frequency Bands
Over operating free-air temperature range (unless otherwise noted).
PARAMETER
MIN
TYP
MAX
UNIT
Frequency bands
2360
2500
MHz
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7.10 Bluetooth Low Energy - Receive (RX)
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V, fRF= 2440 MHz with
DC/DC enabled unless otherwise noted. All measurements are performed at the antenna input with a combined RX and TX
path. All measurements are performed conducted.
PARAMETER
125 kbps (LE Coded)
Receiver sensitivity
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Differential mode. BER = 10–3
–104
>5
dBm
dBm
Receiver saturation
Differential mode. BER = 10–3
Difference between the incoming carrier frequency and
the internally generated carrier frequency
Frequency error tolerance
Data rate error tolerance
Data rate error tolerance
Co-channel rejection(1)
Selectivity, ±1 MHz(1)
Selectivity, ±2 MHz(1)
Selectivity, ±3 MHz(1)
Selectivity, ±4 MHz(1)
Selectivity, ±6 MHz(1)
Selectivity, ±7 MHz
> (–300 / 300)
> (–320 / 240)
> (–125 / 100)
–1.5
kHz
ppm
ppm
dB
Difference between incoming data rate and the internally
generated data rate (37-byte packets)
Difference between incoming data rate and the internally
generated data rate (255-byte packets)
Wanted signal at –79 dBm, modulated interferer in
channel, BER = 10–3
Wanted signal at –79 dBm, modulated interferer at ±1
MHz, BER = 10–3
8 / 4.5(2)
dB
Wanted signal at –79 dBm, modulated interferer at ±2
MHz, BER = 10–3
44 / 37(2)
46 / 44(2)
44 / 46(2)
48 / 44(2)
51 / 45(2)
37
dB
Wanted signal at –79 dBm, modulated interferer at ±3
MHz, BER = 10–3
dB
Wanted signal at –79 dBm, modulated interferer at ±4
MHz, BER = 10–3
dB
Wanted signal at –79 dBm, modulated interferer at ≥ ±6
MHz, BER = 10–3
dB
Wanted signal at –79 dBm, modulated interferer at ≥ ±7
MHz, BER = 10–3
dB
Wanted signal at –79 dBm, modulated interferer at image
frequency, BER = 10–3
Selectivity, Image frequency(1)
dB
Note that Image frequency + 1 MHz is the Co- channel
–1 MHz. Wanted signal at –79 dBm, modulated interferer
at ±1 MHz from image frequency, BER = 10–3
Selectivity, Image frequency ±1
MHz(1)
4.5 / 44 (2)
dB
500 kbps (LE Coded)
Receiver sensitivity
Receiver saturation
Differential mode. BER = 10–3
Differential mode. BER = 10–3
–100
> 5
dBm
dBm
Difference between the incoming carrier frequency and
the internally generated carrier frequency
Frequency error tolerance
Data rate error tolerance
Data rate error tolerance
Co-channel rejection(1)
Selectivity, ±1 MHz(1)
Selectivity, ±2 MHz(1)
Selectivity, ±3 MHz(1)
Selectivity, ±4 MHz(1)
Selectivity, ±6 MHz(1)
Selectivity, ±7 MHz
> (–300 / 300)
> (–450 / 450)
> (–150 / 175)
–3.5
kHz
ppm
ppm
dB
Difference between incoming data rate and the internally
generated data rate (37-byte packets)
Difference between incoming data rate and the internally
generated data rate (255-byte packets)
Wanted signal at –72 dBm, modulated interferer in
channel, BER = 10–3
Wanted signal at –72 dBm, modulated interferer at ±1
MHz, BER = 10–3
8 / 4(2)
dB
Wanted signal at –72 dBm, modulated interferer at ±2
MHz, BER = 10–3
43 / 35(2)
46 / 46(2)
45 / 47(2)
46 / 45(2)
49 / 45(2)
35
dB
Wanted signal at –72 dBm, modulated interferer at ±3
MHz, BER = 10–3
dB
Wanted signal at –72 dBm, modulated interferer at ±4
MHz, BER = 10–3
dB
Wanted signal at –72 dBm, modulated interferer at ≥ ±6
MHz, BER = 10–3
dB
Wanted signal at –72 dBm, modulated interferer at ≥ ±7
MHz, BER = 10–3
dB
Wanted signal at –72 dBm, modulated interferer at image
frequency, BER = 10–3
Selectivity, Image frequency(1)
dB
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7.10 Bluetooth Low Energy - Receive (RX) (continued)
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V, fRF= 2440 MHz with
DC/DC enabled unless otherwise noted. All measurements are performed at the antenna input with a combined RX and TX
path. All measurements are performed conducted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Note that Image frequency + 1 MHz is the Co- channel
–1 MHz. Wanted signal at –72 dBm, modulated interferer
at ±1 MHz from image frequency, BER = 10–3
Selectivity, Image frequency ±1
MHz(1)
4 / 46(2)
dB
1 Mbps (LE 1M)
Receiver sensitivity
Receiver saturation
Differential mode. BER = 10–3
Differential mode. BER = 10–3
–97
> 5
dBm
dBm
Difference between the incoming carrier frequency and
the internally generated carrier frequency
Frequency error tolerance
Data rate error tolerance
Co-channel rejection(1)
Selectivity, ±1 MHz(1)
> (–350 / 350)
> (–650 / 750)
–6
kHz
ppm
dB
Difference between incoming data rate and the internally
generated data rate (37-byte packets)
Wanted signal at –67 dBm, modulated interferer in
channel, BER = 10–3
Wanted signal at –67 dBm, modulated interferer at ±1
MHz, BER = 10–3
7 / 4(2)
dB
Wanted signal at –67 dBm, modulated interferer at ±2
MHz,BER = 10–3
Selectivity, ±2 MHz(1)
39 / 33(2)
36 / 40(2)
36 / 45(2)
40
dB
Wanted signal at –67 dBm, modulated interferer at ±3
MHz, BER = 10–3
Selectivity, ±3 MHz(1)
dB
Wanted signal at –67 dBm, modulated interferer at ±4
MHz, BER = 10–3
Selectivity, ±4 MHz(1)
dB
Wanted signal at –67 dBm, modulated interferer at ≥ ±5
MHz, BER = 10–3
Selectivity, ±5 MHz or more(1)
Selectivity, image frequency(1)
dB
Wanted signal at –67 dBm, modulated interferer at image
frequency, BER = 10–3
33
dB
Note that Image frequency + 1 MHz is the Co- channel
–1 MHz. Wanted signal at –67 dBm, modulated interferer
at ±1 MHz from image frequency, BER = 10–3
Selectivity, image frequency
±1 MHz(1)
4 / 41(2)
dB
Out-of-band blocking(3)
Out-of-band blocking
Out-of-band blocking
Out-of-band blocking
30 MHz to 2000 MHz
2003 MHz to 2399 MHz
2484 MHz to 2997 MHz
3000 MHz to 12.75 GHz
–10
–18
–12
–2
dBm
dBm
dBm
dBm
Wanted signal at 2402 MHz, –64 dBm. Two interferers
at 2405 and 2408 MHz respectively, at the given power
level
Intermodulation
–42
dBm
Spurious emissions,
30 to 1000 MHz
Measurement in a 50-Ω single-ended load.
Measurement in a 50-Ω single-ended load.
< –59
< –47
dBm
dBm
Spurious emissions,
1 to 12.75 GHz
RSSI dynamic range
RSSI accuracy
70
±4
dB
dB
2 Mbps (LE 2M)
Differential mode. Measured at SMA connector, BER =
10–3
Receiver sensitivity
–91
> 5
dBm
dBm
kHz
ppm
dB
Differential mode. Measured at SMA connector, BER =
10–3
Receiver saturation
Difference between the incoming carrier frequency and
the internally generated carrier frequency
Frequency error tolerance
Data rate error tolerance
Co-channel rejection(1)
Selectivity, ±2 MHz(1)
> (–500 / 500)
> (–700 / 750)
–7
Difference between incoming data rate and the internally
generated data rate (37-byte packets)
Wanted signal at –67 dBm, modulated interferer in
channel,BER = 10–3
Wanted signal at –67 dBm, modulated interferer at ±2
MHz, Image frequency is at –2 MHz, BER = 10–3
8 / 4(2)
dB
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7.10 Bluetooth Low Energy - Receive (RX) (continued)
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V, fRF= 2440 MHz with
DC/DC enabled unless otherwise noted. All measurements are performed at the antenna input with a combined RX and TX
path. All measurements are performed conducted.
PARAMETER
Selectivity, ±4 MHz(1)
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Wanted signal at –67 dBm, modulated interferer at ±4
MHz, BER = 10–3
36 / 34(2)
dB
Wanted signal at –67 dBm, modulated interferer at ±6
MHz, BER = 10–3
Selectivity, ±6 MHz(1)
37 / 36(2)
4
dB
dB
Wanted signal at –67 dBm, modulated interferer at image
frequency, BER = 10–3
Selectivity, image frequency(1)
Note that Image frequency + 2 MHz is the Co-channel.
Wanted signal at –67 dBm, modulated interferer at ±2
MHz from image frequency, BER = 10–3
Selectivity, image frequency
±2 MHz(1)
–7 / 36(2)
dB
Out-of-band blocking(3)
Out-of-band blocking
Out-of-band blocking
Out-of-band blocking
30 MHz to 2000 MHz
2003 MHz to 2399 MHz
2484 MHz to 2997 MHz
3000 MHz to 12.75 GHz
–16
–21
–15
–12
dBm
dBm
dBm
dBm
Wanted signal at 2402 MHz, –64 dBm. Two interferers
at 2408 and 2414 MHz respectively, at the given power
level
Intermodulation
–38
dBm
(1) Numbers given as I/C dB
(2) X / Y, where X is +N MHz and Y is –N MHz
(3) Excluding one exception at Fwanted / 2, per Bluetooth Specification
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7.11 Bluetooth Low Energy - Transmit (TX)
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V, fRF= 2440 MHz with
DC/DC enabled unless otherwise noted. All measurements are performed at the antenna input with a combined RX and TX
path. All measurements are performed conducted.
PARAMETER
General Parameters
Max output power
TEST CONDITIONS
MIN
TYP
MAX UNIT
Differential mode, delivered to a single-ended 50 Ω load through a balun
Differential mode, delivered to a single-ended 50 Ω load through a balun
5
dBm
dB
Output power
programmable range
26
Spurious emissions and harmonics
f < 1 GHz, outside restricted bands
< –36
< –54
< –55
< –42
< –42
< –42
dBm
dBm
dBm
dBm
dBm
dBm
f < 1 GHz, restricted bands ETSI
f < 1 GHz, restricted bands FCC
f > 1 GHz, including harmonics
Second harmonic
Spurious emissions
+5 dBm setting
Harmonics
Third harmonic
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7.12 Zigbee and Thread - IEEE 802.15.4-2006 2.4 GHz (OQPSK DSSS1:8, 250 kbps) - RX
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V, fRF= 2440 MHz with
DC/DC enabled unless otherwise noted. All measurements are performed at the antenna input with a combined RX and TX
path. All measurements are conducted.
PARAMETER
General Parameters
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Receiver sensitivity
Receiver saturation
PER = 1%
PER = 1%
–99
> 5
dBm
dBm
Wanted signal at –82 dBm, modulated interferer at ±5 MHz,
PER = 1%
Adjacent channel rejection
Alternate channel rejection
36
57
dB
dB
Wanted signal at –82 dBm, modulated interferer at ±10 MHz,
PER = 1%
Wanted signal at –82 dBm, undesired signal is IEEE
802.15.4 modulated channel, stepped through all channels
2405 to 2480 MHz, PER = 1%
Channel rejection, ±15 MHz or more
59
dB
Blocking and desensitization,
5 MHz from upper band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
57
62
dB
dB
Blocking and desensitization,
10 MHz from upper band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
Blocking and desensitization,
20 MHz from upper band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
62
dB
Blocking and desensitization,
50 MHz from upper band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
65
dB
Blocking and desensitization,
–5 MHz from lower band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
59
dB
Blocking and desensitization,
–10 MHz from lower band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
59
dB
Blocking and desensitization,
–20 MHz from lower band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
63
dB
Blocking and desensitization,
–50 MHz from lower band edge
Wanted signal at –97 dBm (3 dB above the sensitivity level),
CW jammer, PER = 1%
65
dB
Spurious emissions, 30 MHz to 1000
MHz
Measurement in a 50-Ω single-ended load
Measurement in a 50-Ω single-ended load
–66
–53
> 350
> 1000
dBm
dBm
ppm
ppm
Spurious emissions, 1 GHz to 12.75
GHz
Difference between the incoming carrier frequency and the
internally generated carrier frequency
Frequency error tolerance
Symbol rate error tolerance
Difference between incoming symbol rate and the internally
generated symbol rate
RSSI dynamic range
RSSI accuracy
95
±4
dB
dB
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7.13 Zigbee and Thread - IEEE 802.15.4-2006 2.4 GHz (OQPSK DSSS1:8, 250 kbps) - TX
When measured on the CC26x2R74EM-7ID reference design with Tc = 25 °C, VDDS = 3.0 V, fRF= 2440 MHz with
DC/DC enabled unless otherwise noted. All measurements are performed at the antenna input with a combined RX and TX
path. All measurements are conducted.
PARAMETER
General Parameters
Max output power
TEST CONDITIONS
MIN
TYP
MAX UNIT
Differential mode, delivered to a single-ended 50-Ω load through a balun
Differential mode, delivered to a single-ended 50-Ω load through a balun
5
dBm
dB
Output power
programmable range
26
Spurious emissions and harmonics
f < 1 GHz, outside restricted
< -36
dBm
bands
Spurious emissions (1)
f < 1 GHz, restricted bands ETSI
f < 1 GHz, restricted bands FCC
f > 1 GHz, including harmonics
Second harmonic
< -47
< -55
< –42
< -42
< -42
dBm
dBm
dBm
dBm
dBm
+5 dBm setting
Harmonics
Third harmonic
IEEE 802.15.4-2006 2.4 GHz (OQPSK DSSS1:8, 250 kbps)
Error vector magnitude +5 dBm setting
2
%
(1) To ensure margins for passing FCC band edge requirements at 2483.5 MHz, a lower than maximum output-power setting or less than
100% duty cycle may be used when operating at 2480 MHz.
7.14 Timing and Switching Characteristics
7.14.1 Reset Timing
PARAMETER
MIN
TYP
MAX
UNIT
RESET_N low duration
1
µs
7.14.2 Wakeup Timing
Measured over operating free-air temperature with VDDS = 3.0 V (unless otherwise noted). The times listed here do not
include software overhead.
PARAMETER
TEST CONDITIONS
MIN
TYP
850 - 3000
850 - 3000
160
MAX
UNIT
MCU, Reset to Active(1)
µs
µs
µs
µs
µs
MCU, Shutdown to Active(1)
MCU, Standby to Active
MCU, Active to Standby
MCU, Idle to Active
36
14
(1) The wakeup time is dependent on remaining charge on VDDR capacitor when starting the device, and thus how long the device has
been in Reset or Shutdown before starting up again. The wake up time increases with a higher capacitor value.
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7.14.3 Clock Specifications
7.14.3.1 48 MHz Crystal Oscillator (XOSC_HF)
Measured on a Texas Instruments reference design with Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.(1)
PARAMETER
MIN
TYP
MAX
UNIT
Crystal frequency
48
MHz
Equivalent series resistance
6 pF < CL ≤ 9 pF
ESR
ESR
20
60
80
Ω
Ω
H
Equivalent series resistance
5 pF < CL ≤ 6 pF
Motional inductance, relates to the load capacitance that is used for the crystal (CL
in Farads)(5)
2
LM
CL
< 3 × 10–25 / CL
Crystal load capacitance(4)
Start-up time(2)
5
7(3)
9
pF
µs
200
(1) Probing or otherwise stopping the crystal while the DC/DC converter is enabled may cause permanent damage to the device.
(2) Start-up time using the TI-provided power driver. Start-up time may increase if driver is not used.
(3) On-chip default connected capacitance including reference design parasitic capacitance. Connected internal capacitance is changed
through software in the Customer Configuration section (CCFG).
(4) Adjustable load capacitance is integrated into the device.
(5) The crystal manufacturer's specification must satisfy this requirement for proper operation.
7.14.3.2 48 MHz RC Oscillator (RCOSC_HF)
Measured on a Texas Instruments reference design with Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
MIN
TYP
MAX
UNIT
MHz
%
Frequency
48
Uncalibrated frequency accuracy
Calibrated frequency accuracy(1)
Start-up time
±1
±0.25
5
%
µs
(1) Accuracy relative to the calibration source (XOSC_HF)
7.14.3.3 2 MHz RC Oscillator (RCOSC_MF)
Measured on a Texas Instruments reference design with Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
MIN
TYP
MAX
UNIT
MHz
µs
Calibrated frequency
Start-up time
2
5
7.14.3.4 32.768 kHz Crystal Oscillator (XOSC_LF)
Measured on a Texas Instruments reference design with Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
MIN
TYP
32.768
30
MAX
UNIT
kHz
kΩ
Crystal frequency
ESR
CL
Equivalent series resistance
Crystal load capacitance
100
12
6
7(1)
pF
(1) Default load capacitance using TI reference designs including parasitic capacitance. Crystals with different load capacitance may be
used.
7.14.3.5 32 kHz RC Oscillator (RCOSC_LF)
Measured on a Texas Instruments reference design with Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
MIN
TYP
MAX
UNIT
Calibrated frequency
32.8 (1)
kHz
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7.14.3.5 32 kHz RC Oscillator (RCOSC_LF) (continued)
Measured on a Texas Instruments reference design with Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
MIN
TYP
MAX
UNIT
Temperature coefficient.
50
ppm/°C
(1) When using RCOSC_LF as source for the low frequency system clock (SCLK_LF), the accuracy of the SCLK_LF-derived Real Time
Clock (RTC) can be improved by measuring RCOSC_LF relative to XOSC_HF and compensating for the RTC tick speed. This
functionality is available through the TI-provided Power driver.
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7.14.4 Synchronous Serial Interface (SSI) Characteristics
7.14.4.1 Synchronous Serial Interface (SSI) Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
PARAMETER
NO.
MIN
TYP
MAX
UNIT
S1
tclk_per
tclk_high
tclk_low
SSIClk cycle time
SSIClk high time
SSIClk low time
12
65024
System Clocks (2)
tclk_per
S2(1)
S3(1)
0.5
0.5
tclk_per
(1) Refer to SSI timing diagrams Figure 7-1, Figure 7-2 and Figure 7-3.
(2) When using the TI-provided Power driver, the SSI system clock is always 48 MHz.
S1
S2
SSIClk
S3
SSIFss
SSITx
MSB
LSB
SSIRx
4 to 16 bits
Figure 7-1. SSI Timing for TI Frame Format (FRF = 01), Single Transfer Timing Measurement
S2
S1
SSIClk
SSIFss
SSITx
SSIRx
S3
MSB
LSB
8-bit control
0
MSB
LSB
4 to 16 bits output data
Figure 7-2. SSI Timing for MICROWIRE Frame Format (FRF = 10), Single Transfer
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S1
S2
SSIClk
(SPO = 0)
S3
SSIClk
(SPO = 1)
SSITx
(Master)
MSB
LSB
SSIRx
(Slave)
MSB
LSB
SSIFss
Figure 7-3. SSI Timing for SPI Frame Format (FRF = 00), With SPH = 1
7.14.5 UART
7.14.5.1 UART Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
MIN
TYP
MAX
UNIT
MBaud
UART rate
3
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7.15 Peripheral Characteristics
7.15.1 ADC
7.15.1.1 Analog-to-Digital Converter (ADC) Characteristics
Tc = 25 °C, VDDS = 3.0 V and voltage scaling enabled, unless otherwise noted.(1)
Performance numbers require use of offset and gain adjustments in software by TI-provided ADC drivers.
PARAMETER
Input voltage range
Resolution
TEST CONDITIONS
MIN
TYP
MAX
UNIT
V
0
VDDS
12
Bits
ksps
LSB
LSB
LSB
LSB
Sample Rate
200
Offset
Internal 4.3 V equivalent reference(2)
–0.24
7.14
>–1
±4
Gain error
Internal 4.3 V equivalent reference(2)
DNL(4)
INL
Differential nonlinearity
Integral nonlinearity
Internal 4.3 V equivalent reference(2), 200 kSamples/s,
9.6 kHz input tone
9.8
Internal 4.3 V equivalent reference(2), 200 kSamples/s,
9.6 kHz input tone, DC/DC enabled
9.8
10.1
11.1
VDDS as reference, 200 kSamples/s, 9.6 kHz input tone
ENOB
Effective number of bits
Bits
Internal reference, voltage scaling disabled,
32 samples average, 200 kSamples/s, 300 Hz input tone
Internal reference, voltage scaling disabled,
11.3
11.6
14-bit mode, 200 kSamples/s, 300 Hz input tone (5)
Internal reference, voltage scaling disabled,
15-bit mode, 200 kSamples/s, 300 Hz input tone (5)
Internal 4.3 V equivalent reference(2), 200 kSamples/s,
9.6 kHz input tone
–65
–70
–72
THD
Total harmonic distortion
VDDS as reference, 200 kSamples/s, 9.6 kHz input tone
dB
dB
dB
Internal reference, voltage scaling disabled,
32 samples average, 200 kSamples/s, 300 Hz input tone
Internal 4.3 V equivalent reference(2), 200 kSamples/s,
9.6 kHz input tone
60
63
68
Signal-to-noise
and
distortion ratio
SINAD,
SNDR
VDDS as reference, 200 kSamples/s, 9.6 kHz input tone
Internal reference, voltage scaling disabled,
32 samples average, 200 kSamples/s, 300 Hz input tone
Internal 4.3 V equivalent reference(2), 200 kSamples/s,
9.6 kHz input tone
70
73
75
SFDR
Spurious-free dynamic range VDDS as reference, 200 kSamples/s, 9.6 kHz input tone
Internal reference, voltage scaling disabled,
32 samples average, 200 kSamples/s, 300 Hz input tone
Conversion time
Serial conversion, time-to-output, 24 MHz clock
Internal 4.3 V equivalent reference(2)
VDDS as reference
50
0.42
0.6
Clock Cycles
Current consumption
Current consumption
mA
mA
Equivalent fixed internal reference (input voltage scaling
enabled). For best accuracy, the ADC conversion should be
initiated through the TI-RTOS API in order to include the gain/
offset compensation factors stored in FCFG1
Reference voltage
4.3(2) (3)
V
Fixed internal reference (input voltage scaling disabled).
For best accuracy, the ADC conversion should be initiated
through the TI-RTOS API in order to include the gain/offset
compensation factors stored in FCFG1. This value is derived
from the scaled value (4.3 V) as follows:
Reference voltage
1.48
V
Vref = 4.3 V × 1408 / 4095
Reference voltage
Reference voltage
VDDS as reference, input voltage scaling enabled
VDDS as reference, input voltage scaling disabled
VDDS
V
V
VDDS /
2.82(3)
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7.15.1.1 Analog-to-Digital Converter (ADC) Characteristics (continued)
Tc = 25 °C, VDDS = 3.0 V and voltage scaling enabled, unless otherwise noted.(1)
Performance numbers require use of offset and gain adjustments in software by TI-provided ADC drivers.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
200 kSamples/s, voltage scaling enabled. Capacitive input,
Input impedance depends on sampling frequency and sampling
time
Input impedance
>1
MΩ
(1) Using IEEE Std 1241-2010 for terminology and test methods
(2) Input signal scaled down internally before conversion, as if voltage range was 0 to 4.3 V
(3) Applied voltage must be within Absolute Maximum Ratings (see Section 7.1 ) at all times
(4) No missing codes
(5) ADC_output = Σ(4n samples ) >> n, n = desired extra bits
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7.15.2 DAC
7.15.2.1 Digital-to-Analog Converter (DAC) Characteristics
Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
PARAMETER
General Parameters
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Resolution
8
Bits
Any load, any VREF, pre-charge OFF, DAC charge-pump ON
1.8
2.0
3.8
3.8
External Load(4), any VREF, pre-charge OFF, DAC charge-pump
OFF
VDDS
Supply voltage
V
Any load, VREF = DCOUPL, pre-charge ON
Buffer ON (recommended for external load)
Buffer OFF (internal load)
2.6
16
16
3.8
250
FDAC
Clock frequency
kHz
1000
VREF = VDDS, buffer OFF, internal load
VREF = VDDS, buffer ON, external capacitive load = 20 pF(3)
13
13.8
20
Voltage output settling time
1 / FDAC
External capacitive load
External resistive load
Short circuit current
200
400
pF
MΩ
µA
10
VDDS = 3.8 V, DAC charge-pump OFF
VDDS = 3.0 V, DAC charge-pump ON
VDDS = 3.0 V, DAC charge-pump OFF
VDDS = 2.0 V, DAC charge-pump ON
VDDS = 2.0 V, DAC charge-pump OFF
VDDS = 1.8 V, DAC charge-pump ON
VDDS = 1.8 V, DAC charge-pump OFF
50.8
51.7
53.2
48.7
70.2
46.3
88.9
Max output impedance Vref =
VDDS, buffer ON, CLK 250
kHz
ZMAX
kΩ
Internal Load - Continuous Time Comparator / Low Power Clocked Comparator
VREF = VDDS,
load = Continuous Time Comparator or Low Power Clocked
Comparator
FDAC = 250 kHz
Differential nonlinearity
Differential nonlinearity
±1
DNL
LSB(1)
LSB(1)
LSB(1)
LSB(1)
VREF = VDDS,
load = Continuous Time Comparator or Low Power Clocked
Comparator
±1.2
FDAC = 16 kHz
VREF = VDDS = 3.8 V
±0.64
±0.81
±1.27
±3.43
±2.88
±2.37
±0.78
±0.77
±3.46
±3.44
±4.70
±4.11
±1.53
±1.71
±2.10
±6.00
±3.85
±5.84
VREF = VDDS= 3.0 V
Offset error(2)
Load = Continuous Time
Comparator
VREF = VDDS = 1.8 V
VREF = DCOUPL, pre-charge ON
VREF = DCOUPL, pre-charge OFF
VREF = ADCREF
VREF = VDDS= 3.8 V
VREF = VDDS = 3.0 V
Offset error(2)
Load = Low Power Clocked
Comparator
VREF = VDDS= 1.8 V
VREF = DCOUPL, pre-charge ON
VREF = DCOUPL, pre-charge OFF
VREF = ADCREF
VREF = VDDS = 3.8 V
VREF = VDDS = 3.0 V
Max code output voltage
variation(2)
Load = Continuous Time
Comparator
VREF = VDDS= 1.8 V
VREF = DCOUPL, pre-charge ON
VREF = DCOUPL, pre-charge OFF
VREF = ADCREF
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7.15.2.1 Digital-to-Analog Converter (DAC) Characteristics (continued)
Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
±2.92
±3.06
±3.91
±7.84
±4.06
±6.94
0.03
3.62
0.02
2.86
0.01
1.71
0.01
1.21
1.27
2.46
0.01
1.41
0.03
3.61
0.02
2.85
0.01
1.71
0.01
1.21
1.27
2.46
0.01
1.41
MAX
UNIT
VREF = VDDS= 3.8 V
VREF =VDDS= 3.0 V
VREF = VDDS= 1.8 V
Max code output voltage
variation(2)
Load = Low Power Clocked
Comparator
LSB(1)
VREF = DCOUPL, pre-charge ON
VREF = DCOUPL, pre-charge OFF
VREF = ADCREF
VREF = VDDS = 3.8 V, code 1
VREF = VDDS = 3.8 V, code 255
VREF = VDDS= 3.0 V, code 1
VREF = VDDS= 3.0 V, code 255
VREF = VDDS= 1.8 V, code 1
Output voltage range(2)
Load = Continuous Time
Comparator
VREF = VDDS = 1.8 V, code 255
VREF = DCOUPL, pre-charge OFF, code 1
VREF = DCOUPL, pre-charge OFF, code 255
VREF = DCOUPL, pre-charge ON, code 1
VREF = DCOUPL, pre-charge ON, code 255
VREF = ADCREF, code 1
V
VREF = ADCREF, code 255
VREF = VDDS = 3.8 V, code 1
VREF = VDDS= 3.8 V, code 255
VREF = VDDS= 3.0 V, code 1
VREF = VDDS= 3.0 V, code 255
VREF = VDDS = 1.8 V, code 1
Output voltage range(2)
Load = Low Power Clocked
Comparator
VREF = VDDS = 1.8 V, code 255
VREF = DCOUPL, pre-charge OFF, code 1
VREF = DCOUPL, pre-charge OFF, code 255
VREF = DCOUPL, pre-charge ON, code 1
VREF = DCOUPL, pre-charge ON, code 255
VREF = ADCREF, code 1
V
VREF = ADCREF, code 255
External Load
VREF = VDDS, FDAC = 250 kHz
VREF = DCOUPL, FDAC = 250 kHz
VREF = ADCREF, FDAC = 250 kHz
VREF = VDDS, FDAC = 250 kHz
VREF = VDDS= 3.8 V
±1
±1
INL
Integral nonlinearity
LSB(1)
LSB(1)
±1
DNL
Differential nonlinearity
±1
±0.40
±0.50
±0.75
±1.55
±1.30
±1.10
±1.00
±1.00
±1.00
±3.45
±2.10
±1.90
VREF = VDDS= 3.0 V
VREF = VDDS = 1.8 V
Offset error
LSB(1)
VREF = DCOUPL, pre-charge ON
VREF = DCOUPL, pre-charge OFF
VREF = ADCREF
VREF = VDDS= 3.8 V
VREF = VDDS= 3.0 V
VREF = VDDS= 1.8 V
Max code output voltage
variation
LSB(1)
VREF = DCOUPL, pre-charge ON
VREF = DCOUPL, pre-charge OFF
VREF = ADCREF
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7.15.2.1 Digital-to-Analog Converter (DAC) Characteristics (continued)
Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
0.03
3.61
0.02
2.85
0.02
1.71
0.02
1.20
1.27
2.46
0.02
1.42
MAX
UNIT
VREF = VDDS = 3.8 V, code 1
VREF = VDDS = 3.8 V, code 255
VREF = VDDS = 3.0 V, code 1
VREF = VDDS= 3.0 V, code 255
VREF = VDDS= 1.8 V, code 1
Output voltage range
Load = Low Power Clocked
Comparator
VREF = VDDS = 1.8 V, code 255
VREF = DCOUPL, pre-charge OFF, code 1
VREF = DCOUPL, pre-charge OFF, code 255
VREF = DCOUPL, pre-charge ON, code 1
VREF = DCOUPL, pre-charge ON, code 255
VREF = ADCREF, code 1
V
VREF = ADCREF, code 255
(1) 1 LSB (VREF 3.8 V/3.0 V/1.8 V/DCOUPL/ADCREF) = 14.10 mV/11.13 mV/6.68 mV/4.67 mV/5.48 mV
(2) Includes comparator offset
(3) A load > 20 pF will increases the settling time
(4) Keysight 34401A Multimeter
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7.15.3 Temperature and Battery Monitor
7.15.3.1 Temperature Sensor
Measured on a Texas Instruments reference design with Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
°C
Resolution
Accuracy
Accuracy
2
-40 °C to 0 °C
0 °C to 105 °C
±4.0
±2.5
3.6
°C
°C
Supply voltage coefficient(1)
°C/V
(1) The temperature sensor is automatically compensated for VDDS variation when using the TI-provided temperature driver.
7.15.3.2 Battery Monitor
Measured on a Texas Instruments reference design with Tc = 25 °C, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
mV
V
Resolution
Range
25
1.8
3.8
Integral nonlinearity (max)
Accuracy
23
22.5
-32
-1
mV
mV
mV
%
VDDS = 3.0 V
Offset error
Gain error
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7.15.4 Comparators
7.15.4.1 Low-Power Clocked Comparator
Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
Input voltage range
Clock frequency
0
VDDS
V
SCLK_LF
Using internal DAC with VDDS as reference voltage,
DAC code = 0 - 255
Internal reference voltage(1)
Offset
0.024 - 2.865
V
Measured at VDDS / 2, includes error from internal DAC
Step from –50 mV to 50 mV
±5
1
mV
Clock
Cycle
Decision time
(1) The comparator can use an internal 8 bits DAC as its reference. The DAC output voltage range depends on the reference voltage
selected. See Section 7.15.2.1
7.15.4.2 Continuous Time Comparator
Tc = 25°C, VDDS = 3.0 V, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
V
Input voltage range(1)
Offset
0
VDDS
Measured at VDDS / 2
±5
0.78
8.6
mV
µs
Decision time
Step from –10 mV to 10 mV
Internal reference
Current consumption
µA
(1) The input voltages can be generated externally and connected throughout I/Os or an internal reference voltage can be generated using
the DAC
7.15.5 Current Source
7.15.5.1 Programmable Current Source
Tc = 25 °C, VDDS = 3.0 V, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
0.25 - 20
0.25
MAX UNIT
Current source programmable output range (logarithmic
range)
µA
µA
Resolution
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7.15.6 GPIO
7.15.6.1 GPIO DC Characteristics
PARAMETER
TA = 25 °C, VDDS = 1.8 V
TEST CONDITIONS
MIN
TYP
GPIO VOH at 8 mA load
IOCURR = 2, high-drive GPIOs only
IOCURR = 2, high-drive GPIOs only
IOCURR = 1
1.56
0.24
1.59
0.21
73
V
V
GPIO VOL at 8 mA load
GPIO VOH at 4 mA load
V
GPIO VOL at 4 mA load
IOCURR = 1
V
GPIO pullup current
Input mode, pullup enabled, Vpad = 0 V
Input mode, pulldown enabled, Vpad = VDDS
IH = 1, transition voltage for input read as 0 → 1
IH = 1, transition voltage for input read as 1 → 0
µA
µA
V
GPIO pulldown current
19
GPIO low-to-high input transition, with hysteresis
GPIO high-to-low input transition, with hysteresis
1.08
0.73
V
IH = 1, difference between 0 → 1
and 1 → 0 points
GPIO input hysteresis
0.35
V
TA = 25 °C, VDDS = 3.0 V
GPIO VOH at 8 mA load
IOCURR = 2, high-drive GPIOs only
IOCURR = 2, high-drive GPIOs only
IOCURR = 1
2.59
0.42
2.63
0.40
V
V
V
V
GPIO VOL at 8 mA load
GPIO VOH at 4 mA load
GPIO VOL at 4 mA load
IOCURR = 1
TA = 25 °C, VDDS = 3.8 V
GPIO pullup current
Input mode, pullup enabled, Vpad = 0 V
282
110
µA
µA
V
GPIO pulldown current
Input mode, pulldown enabled, Vpad = VDDS
IH = 1, transition voltage for input read as 0 → 1
IH = 1, transition voltage for input read as 1 → 0
GPIO low-to-high input transition, with hysteresis
GPIO high-to-low input transition, with hysteresis
1.97
1.55
V
IH = 1, difference between 0 → 1
and 1 → 0 points
GPIO input hysteresis
TA = 25 °C
0.42
V
V
Lowest GPIO input voltage reliably interpreted as a
High
VIH
0.8*VDDS
Highest GPIO input voltage reliably interpreted as a
Low
VIL
0.2*VDDS
V
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7.16 Typical Characteristics
All measurements in this section are done with Tc = 25 °C and VDDS = 3.0 V, unless otherwise noted. See
Section 7.3 for device limits. Values exceeding these limits are for reference only.
7.16.1 MCU Current
Active Current vs. VDDS
Running CoreMark, SCLK_HF = 48 MHz RCOSC
Standby Current vs. Temperature
80 kB RAM Retention, no Cache Retention, RTC On
SCLK_LF = 32 kHz XOSC
6
5.5
5
12
10
8
4.5
4
6
4
3.5
3
2
0
2.5
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
Temperature [°C]
Voltage [V]
D006
D001
Figure 7-5. Standby Mode (MCU) Current vs. Temperature
Figure 7-4. Active Mode (MCU) Current vs. Supply Voltage
(VDDS)
7.16.2 RX Current
RX Current vs. Temperature
Bluetooth Low Energy 1 Mbps, 2.44 GHz
RX Current vs. VDDS
Bluetooth Low Energy 1 Mbps, 2.44 GHz
8.5
8.4
8.3
8.2
8.1
8
11.5
11
10.5
10
9.5
9
7.9
7.8
7.7
7.6
7.5
7.4
7.3
7.2
7.1
7
8.5
8
7.5
7
6.9
6.8
6.7
6.6
6.5
6.5
6
5.5
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
Voltage [V]
Temperature [°C]
D013
D010
Figure 7-7. RX Current vs. Supply Voltage (VDDS) (Bluetooth
Low Energy 1 Mbps, 2.44 GHz)
Figure 7-6. RX Current vs. Temperature (Bluetooth Low Energy
1 Mbps, 2.44 GHz)
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7.16.3 TX Current
TX Current vs. Temperature
Bluetooth Low Energy 1 Mbps, 2.44 GHz, 0 dBm
TX Current vs. VDDS
Bluetooth Low Energy 1 Mbps, 2.44 GHz, 0 dBm
9
8.85
8.7
12
11.5
11
10.5
10
9.5
9
8.55
8.4
8.25
8.1
7.95
7.8
7.65
7.5
8.5
8
7.35
7.2
7.5
7
7.05
6.9
6.75
6.6
6.5
6
6.45
6.3
5.5
6.15
6
5
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
Voltage [V]
Temperature [°C]
D024
D018
Figure 7-9. TX Current vs. Supply Voltage (VDDS) (Bluetooth
Low Energy 1 Mbps, 2.44 GHz)
Figure 7-8. TX Current vs. Temperature (Bluetooth Low Energy
1 Mbps, 2.44 GHz)
Table 7-1. Typical TX Current and Output Power
CC2652R at 2.4 GHz, VDDS = 3.0 V (Measured on CC2652REM-7ID)
txPower
0x7217
0x4E63
0x385D
0x3259
0x2856
0x2853
0x12D6
0x0ACF
0x06CA
0x04C6
TX Power Setting (SmartRF Studio)
Typical Output Power [dBm]
Typical Current Consumption [mA]
5
4
4.9
3.9
9.5
9.0
8.6
8.0
7.6
7.3
6.2
5.6
5.2
4.8
3
2.8
2
1.8
1
0.9
0
-0.3
-4.9
-9.4
-14.5
-20.3
-5
-10
-15
-20
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7.16.4 RX Performance
Sensitivity vs. Frequency
IEEE 802.15.4 (OQPSK DSSS1:8, 250 kbps)
Sensitivity vs. Frequency
Bluetooth Low Energy 1 Mbps, 2.44 GHz
-95
-96
-92
-93
-97
-94
-98
-95
-99
-96
-100
-101
-102
-103
-104
-105
-97
-98
-99
-100
-101
-102
2.4
2.408 2.416 2.424 2.432 2.44 2.448 2.456 2.464 2.472 2.48
2.4
2.408
2.416
2.424
2.432
2.44
2.448
2.456
2.464
2.472
2.48
Frequency [GHz]
Frequency [GHz]
D028
D029
Figure 7-10. Sensitivity vs. Frequency (Bluetooth Low Energy 1
Mbps, 2.44 GHz)
Figure 7-11. Sensitivity vs. Frequency (250 kbps, 2.44 GHz)
Sensitivity vs. Temperature
Bluetooth Low Energy 1 Mbps, 2.44 GHz
Sensitivity vs. Temperature
IEEE 802.15.4 (OQPSK DSSS1:8, 250 kbps), 2.44 GHz
-92
-93
-95
-96
-97
-94
-98
-95
-99
-96
-100
-101
-102
-103
-104
-105
-97
-98
-99
-100
-101
-102
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
Temperature [°C]
Temperature [°C]
D032
D031
Figure 7-13. Sensitivity vs. Temperature (250 kbps, 2.44 GHz)
Figure 7-12. Sensitivity vs. Temperature (Bluetooth Low Energy
1 Mbps, 2.44 GHz)
Sensitivity vs. VDDS
Bluetooth Low Energy 1 Mbps, 2.44 Ghz
Sensitivity vs. VDDS
Bluetooth Low Energy 1 Mbps, 2.44 GHz, DCDC Off
-92
-93
-92
-93
-94
-94
-95
-95
-96
-96
-97
-97
-98
-98
-99
-99
-100
-101
-102
-100
-101
-102
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
Voltage [V]
Voltage [V]
D034
D035
Figure 7-14. Sensitivity vs. Supply Voltage (VDDS) (Bluetooth
Low Energy 1 Mbps, 2.44 GHz)
Figure 7-15. Sensitivity vs. Supply Voltage (VDDS) (Bluetooth
Low Energy 1 Mbps, 2.44 GHz, DCDC Off)
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7.16.4 RX Performance (continued)
Sensitivity vs. VDDS
IEEE 802.15.4 (OQPSK DSSS1:8, 250 kbps), 2.44 GHz
-95
-96
-97
-98
-99
-100
-101
-102
-103
-104
-105
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
Voltage [V]
D036
Figure 7-16. Sensitivity vs. Supply Voltage (VDDS) (250 kbps, 2.44 GHz)
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7.16.5 TX Performance
Output Power vs. Temperature
Bluetooth Low Energy 1 Mbps, 2.44 GHz, 0 dBm
Output Power vs. Temperature
Bluetooth Low Energy 1 Mbps, 2.44 GHz, +5 dBm
2
1.8
1.6
1.4
1.2
1
7
6.8
6.6
6.4
6.2
6
5.8
5.6
5.4
5.2
5
0.8
0.6
0.4
0.2
0
4.8
4.6
4.4
4.2
4
-0.2
-0.4
-0.6
-0.8
-1
3.8
3.6
3.4
3.2
3
-1.2
-1.4
-1.6
-1.8
-2
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
Temperature [°C]
Temperature [°C]
D042
D041
Figure 7-18. Output Power vs. Temperature (Bluetooth Low
Energy 1 Mbps, 2.44 GHz, +5 dBm)
Figure 7-17. Output Power vs. Temperature (Bluetooth Low
Energy 1 Mbps, 2.44 GHz)
Output Power vs. VDDS
Bluetooth Low Energy 1 Mbps, 2.44 GHz, 0 dBm
Output Power vs. VDDS
Bluetooth Low Energy 1 Mbps, 2.44 GHz, +5 dBm
2
1.8
1.6
1.4
1.2
1
7
6.8
6.6
6.4
6.2
6
0.8
0.6
0.4
0.2
0
5.8
5.6
5.4
5.2
5
-0.2
-0.4
-0.6
-0.8
-1
4.8
4.6
4.4
4.2
4
-1.2
-1.4
-1.6
-1.8
-2
3.8
3.6
3.4
3.2
3
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
Voltage [V]
Voltage [V]
D046
D048
Figure 7-19. Output Power vs. Supply Voltage (VDDS)
(Bluetooth Low Energy 1 Mbps, 2.44 GHz)
Figure 7-20. Output Power vs. Supply Voltage (VDDS)
(Bluetooth Low Energy 1 Mbps, 2.44 GHz, +5 dBm)
Output Power vs. Frequency
Bluetooth Low Energy 1 Mbps, 2.44 Ghz, 0 dBm
Output Power vs. Frequency
Bluetooth Low Energy 1 Mbps, 2.44 Ghz, +5 dBm
2
1.8
1.6
1.4
1.2
1
7
6.8
6.6
6.4
6.2
6
0.8
0.6
0.4
0.2
0
5.8
5.6
5.4
5.2
5
-0.2
-0.4
-0.6
-0.8
-1
4.8
4.6
4.4
4.2
4
-1.2
-1.4
-1.6
-1.8
-2
3.8
3.6
3.4
3.2
3
2.4
2.408 2.416 2.424 2.432 2.44 2.448 2.456 2.464 2.472 2.48
2.4
2.408 2.416 2.424 2.432 2.44 2.448 2.456 2.464 2.472 2.48
Frequency [GHz]
Frequency [GHz]
D058
D059
Figure 7-21. Output Power vs. Frequency (Bluetooth Low
Energy 1 Mbps, 2.44 GHz)
Figure 7-22. Output Power vs. Frequency (Bluetooth Low
Energy 1 Mbps, 2.44 GHz, +5 dBm)
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7.16.6 ADC Performance
ENOB vs. Input Frequency
ENOB vs. Sampling Frequency
Vin = 3.0 V Sine wave, Internal reference,
Fin = Fs / 10
11.4
11.1
10.8
10.5
10.2
9.9
Internal Reference, No Averaging
Internal Unscaled Reference, 14-bit Mode
10.2
10.15
10.1
10.05
10
9.95
9.9
9.85
9.8
9.6
1
2
3
4
5
6
7 8 10
20
30 40 50 70 100
200
D062
0.2 0.3
0.5 0.7
1
2
3
4
5
6 7 8 10
20
30 40 50 70 100
Frequency [kHz]
Frequency [kHz]
D061
Figure 7-24. ENOB vs. Sampling Frequency
Figure 7-23. ENOB vs. Input Frequency
INL vs. ADC Code
Vin = 3.0 V Sine wave, Internal reference,
200 kSamples/s
DNL vs. ADC Code
Vin = 3.0 V Sine wave, Internal reference,
200 kSamples/s
1.5
1
2.5
2
0.5
0
1.5
1
-0.5
-1
0.5
0
-1.5
-0.5
0
0
400
800
1200 1600 2000 2400 2800 3200 3600 4000
400
800
1200 1600 2000 2400 2800 3200 3600 4000
ADC Code
ADC Code
D064
D065
Figure 7-25. INL vs. ADC Code
Figure 7-26. DNL vs. ADC Code
ADC Accuracy vs. VDDS
Vin = 1 V, Internal reference,
200 kSamples/s
ADC Accuracy vs. Temperature
Vin = 1 V, Internal reference,
200 kSamples/s
1.01
1.009
1.008
1.007
1.006
1.005
1.004
1.003
1.002
1.001
1
1.01
1.009
1.008
1.007
1.006
1.005
1.004
1.003
1.002
1.001
1
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90 100
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
Temperature [°C]
Voltage [V]
D066
D067
Figure 7-27. ADC Accuracy vs. Temperature
Figure 7-28. ADC Accuracy vs. Supply Voltage (VDDS)
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8 Detailed Description
8.1 Overview
Section 3.1 shows the core modules of the CC2652R7 device.
8.2 System CPU
The CC2652R7 SimpleLink™ Wireless MCU contains an Arm® Cortex®-M4F system CPU, which runs the
application and the higher layers of radio protocol stacks.
The system CPU is the foundation of a high-performance, low-cost platform that meets the system requirements
of minimal memory implementation, and low-power consumption, while delivering outstanding computational
performance and exceptional system response to interrupts.
Its features include the following:
•
•
ARMv7-M architecture optimized for small-footprint embedded applications
Arm Thumb®-2 mixed 16- and 32-bit instruction set delivers the high performance expected of a 32-bit Arm
core in a compact memory size
•
•
•
•
•
•
•
•
Fast code execution permits increased sleep mode time
Deterministic, high-performance interrupt handling for time-critical applications
Single-cycle multiply instruction and hardware divide
Hardware division and fast digital-signal-processing oriented multiply accumulate
Saturating arithmetic for signal processing
IEEE 754-compliant single-precision Floating Point Unit (FPU)
Memory Protection Unit (MPU) for safety-critical applications
Full debug with data matching for watchpoint generation
– Data Watchpoint and Trace Unit (DWT)
– JTAG Debug Access Port (DAP)
– Flash Patch and Breakpoint Unit (FPB)
•
Trace support reduces the number of pins required for debugging and tracing
– Instrumentation Trace Macrocell Unit (ITM)
– Trace Port Interface Unit (TPIU) with asynchronous serial wire output (SWO)
Optimized for single-cycle flash memory access
Tightly connected to 8-KB 4-way random replacement cache for minimal active power consumption and wait
states
•
•
•
•
•
Ultra-low-power consumption with integrated sleep modes
48 MHz operation
1.25 DMIPS per MHz
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8.3 Radio (RF Core)
The RF Core is a highly flexible and future proof radio module which contains an Arm Cortex-M0 processor
that interfaces the analog RF and base-band circuitry, handles data to and from the system CPU side, and
assembles the information bits in a given packet structure. The RF core offers a high level, command-based
API to the main CPU that configurations and data are passed through. The Arm Cortex-M0 processor is not
programmable by customers and is interfaced through the TI-provided RF driver that is included with the
SimpleLink Software Development Kit (SDK).
The RF core can autonomously handle the time-critical aspects of the radio protocols, thus offloading the
main CPU, which reduces power and leaves more resources for the user application. Several signals are also
available to control external circuitry such as RF switches or range extenders autonomously.
Multiprotocol solutions are enabled through time-sliced access of the radio, handled transparently for the
application through the TI-provided RF driver and dual-mode manager.
The various physical layer radio formats are partly built as a software defined radio where the radio behavior is
either defined by radio ROM contents or by non-ROM radio formats delivered in form of firmware patches with
the SimpleLink SDKs. This allows the radio platform to be updated for support of future versions of standards
even with over-the-air (OTA) updates while still using the same silicon.
8.3.1 Bluetooth 5.2 Low Energy
The RF Core offers full support for Bluetooth 5.2 Low Energy, including the high-sped 2-Mbps physical layer
and the 500-kbps and 125-kbps long range PHYs (Coded PHY) through the TI provided Bluetooth 5.2 stack or
through a high-level Bluetooth API. The Bluetooth 5.2 PHY and part of the controller are in radio and system
ROM, providing significant savings in memory usage and more space available for applications.
The new high-speed mode allows data transfers up to 2 Mbps, twice the speed of Bluetooth 4.2 and five times
the speed of Bluetooth 4.0, without increasing power consumption. In addition to faster speeds, this mode offers
significant improvements for energy efficiency and wireless coexistence with reduced radio communication time.
Bluetooth 5.2 also enables unparalleled flexibility for adjustment of speed and range based on application
needs, which capitalizes on the high-speed or long-range modes respectively. Data transfers are now possible
at 2 Mbps, enabling development of applications using voice, audio, imaging, and data logging that were not
previously an option using Bluetooth low energy. With high-speed mode, existing applications deliver faster
responses, richer engagement, and longer battery life. Bluetooth 5.2 enables fast, reliable firmware updates.
8.3.2 802.15.4 (Thread, Zigbee, 6LoWPAN)
Through a dedicated IEEE radio API, the RF Core supports the 2.4-GHz IEEE 802.15.4-2011 physical layer
(2 Mchips per second Offset-QPSK with DSSS 1:8), used in Thread, Zigbee, and 6LoWPAN protocols. The
802.15.4 PHY and MAC are in radio and system ROM. TI also provides royalty-free protocol stacks for Thread
and Zigbee as part of the SimpleLink SDK, enabling a robust end-to-end solution.
8.4 Memory
The up to 704KB nonvolatile (flash) memory provides storage for code and data. The flash memory is in-system
programmable and erasable. The last flash memory sector must contain a Customer Configuration section
(CCFG) that is used by boot ROM and TI provided drivers to configure the device. This configuration is done
through the ccfg.c source file that is included in all TI provided examples.
The ultra-low leakage system static RAM (SRAM) is split into four 32KB and one 16KB blocks and can be used
for both storage of data and execution of code. Retention of SRAM contents in Standby power mode is enabled
by default and included in Standby mode power consumption numbers. Parity checking for detection of bit errors
in memory is built-in, which reduces chip-level soft errors and thereby increases reliability. System SRAM is
always initialized to zeroes upon code execution from boot.
To improve code execution speed and lower power when executing code from nonvolatile memory, a 4-way
nonassociative 8-KB cache is enabled by default to cache and prefetch instructions read by the system CPU.
The cache can be used as a general-purpose RAM by enabling this feature in the Customer Configuration Area
(CCFG).
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There is a 4KB ultra-low leakage SRAM available for use with the Sensor Controller Engine which is typically
used for storing Sensor Controller programs, data and configuration parameters. This RAM is also accessible by
the system CPU. The Sensor Controller RAM is not cleared to zeroes between system resets.
The ROM includes a TI-RTOS kernel and low-level drivers, as well as significant parts of selected radio stacks,
which frees up flash memory for the application. The ROM also contains a serial (SPI and UART) bootloader that
can be used for initial programming of the device.
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8.5 Sensor Controller
The Sensor Controller contains circuitry that can be selectively enabled in both Standby and Active power
modes. The peripherals in this domain can be controlled by the Sensor Controller Engine, which is a proprietary
power-optimized CPU. This CPU can read and monitor sensors or perform other tasks autonomously; thereby
significantly reducing power consumption and offloading the system CPU.
The Sensor Controller Engine is user programmable with a simple programming language that has syntax
similar to C. This programmability allows for sensor polling and other tasks to be specified as sequential
algorithms rather than static configuration of complex peripheral modules, timers, DMA, register programmable
state machines, or event routing.
The main advantages are:
•
•
•
•
•
Flexibility - data can be read and processed in unlimited manners while still ensuring ultra-low power
2 MHz low-power mode enables lowest possible handling of digital sensors
Dynamic reuse of hardware resources
40-bit accumulator supporting multiplication, addition and shift
Observability and debugging options
Sensor Controller Studio is used to write, test, and debug code for the Sensor Controller. The tool produces
C driver source code, which the System CPU application uses to control and exchange data with the Sensor
Controller. Typical use cases may be (but are not limited to) the following:
•
•
•
•
•
•
Read analog sensors using integrated ADC or comparators
Interface digital sensors using GPIOs, SPI, UART, or I2C (UART and I2C are bit-banged)
Capacitive sensing
Waveform generation
Very low-power pulse counting (flow metering)
Key scan
The peripherals in the Sensor Controller include the following:
•
The low-power clocked comparator can be used to wake the system CPU from any state in which the
comparator is active. A configurable internal reference DAC can be used in conjunction with the comparator.
The output of the comparator can also be used to trigger an interrupt or the ADC.
Capacitive sensing functionality is implemented through the use of a constant current source, a time-to-digital
converter, and a comparator. The continuous time comparator in this block can also be used as a higher-
accuracy alternative to the low-power clocked comparator. The Sensor Controller takes care of baseline
tracking, hysteresis, filtering, and other related functions when these modules are used for capacitive
sensing.
•
•
The ADC is a 12-bit, 200-ksamples/s ADC with eight inputs and a built-in voltage reference. The ADC can be
triggered by many different sources including timers, I/O pins, software, and comparators.
The analog modules can connect to up to eight different GPIOs
•
•
Dedicated SPI master with up to 6 MHz clock speed
The peripherals in the Sensor Controller can also be controlled from the main application processor.
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8.6 Cryptography
The CC2652R7 device comes with a wide set of modern cryptography-related hardware accelerators, drastically
reducing code footprint and execution time for cryptographic operations. It also has the benefit of being lower
power and improves availability and responsiveness of the system because the cryptography operations runs in
a background hardware thread.
Together with a large selection of open-source cryptography libraries provided with the Software Development
Kit (SDK), this allows for secure and future proof IoT applications to be easily built on top of the platform. The
hardware accelerator modules are:
•
True Random Number Generator (TRNG) module provides a true, nondeterministic noise source for the
purpose of generating keys, initialization vectors (IVs), and other random number requirements. The TRNG is
built on 24 ring oscillators that create unpredictable output to feed a complex nonlinear-combinatorial circuit.
Secure Hash Algorithm 2 (SHA-2) with support for SHA224, SHA256, SHA384, and SHA512
Advanced Encryption Standard (AES) with 128 and 256 bit key lengths
•
•
•
Public Key Accelerator - Hardware accelerator supporting mathematical operations needed for elliptic
curves up to 512 bits and RSA key pair generation up to 1024 bits.
Through use of these modules and the TI provided cryptography drivers, the following capabilities are available
for an application or stack:
•
Key Agreement Schemes
– Elliptic curve Diffie–Hellman with static or ephemeral keys (ECDH and ECDHE)
– Elliptic curve Password Authenticated Key Exchange by Juggling (ECJ-PAKE)
Signature Generation
– Elliptic curve Diffie-Hellman Digital Signature Algorithm (ECDSA)
Curve Support
•
•
– Short Weierstrass form (full hardware support), such as:
•
•
•
NIST-P224, NIST-P256, NIST-P384, NIST-P521
Brainpool-256R1, Brainpool-384R1, Brainpool-512R1
secp256r1
– Montgomery form (hardware support for multiplication), such as:
•
Curve25519
•
•
SHA2 based MACs
– HMAC with SHA224, SHA256, SHA384, or SHA512
Block cipher mode of operation
– AESCCM
– AESGCM
– AESECB
– AESCBC
– AESCBC-MAC
•
True random number generation
Other capabilities, such as RSA encryption and signatures as well as Edwards type of elliptic curves such as
Curve1174 or Ed25519, can also be implemented using the provided hardware accelerators but are not part of
the TI SimpleLink SDK for the CC2652R7 device.
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8.7 Timers
A large selection of timers are available as part of the CC2652R7 device. These timers are:
•
Real-Time Clock (RTC)
A 70-bit 3-channel timer running on the 32 kHz low frequency system clock (SCLK_LF)
This timer is available in all power modes except Shutdown. The timer can be calibrated to compensate for
frequency drift when using the RCOSC_LF as the low frequency system clock. If an external LF clock with
frequency different from 32.768 kHz is used, the RTC tick speed can be adjusted to compensate for this.
When using TI-RTOS, the RTC is used as the base timer in the operating system and should thus only be
accessed through the kernel APIs such as the Clock module. The real time clock can also be read by the
Sensor Controller Engine to timestamp sensor data and also has dedicated capture channels. By default, the
RTC halts when a debugger halts the device.
•
•
General Purpose Timers (GPTIMER)
The four flexible GPTIMERs can be used as either 4× 32 bit timers or 8× 16 bit timers, all running on up to 48
MHz. Each of the 16- or 32-bit timers support a wide range of features such as one-shot or periodic counting,
pulse width modulation (PWM), time counting between edges and edge counting. The inputs and outputs of
the timer are connected to the device event fabric, which allows the timers to interact with signals such as
GPIO inputs, other timers, DMA and ADC. The GPTIMERs are available in Active and Idle power modes.
Sensor Controller Timers
The Sensor Controller contains 3 timers:
AUX Timer 0 and 1 are 16-bit timers with a 2N prescaler. Timers can either increment on a clock or on each
edge of a selected tick source. Both one-shot and periodical timer modes are available.
AUX Timer 2 is a 16-bit timer that can operate at 24 MHz, 2 MHz or 32 kHz independent of the Sensor
Controller functionality. There are 4 capture or compare channels, which can be operated in one-shot or
periodical modes. The timer can be used to generate events for the Sensor Controller Engine or the ADC, as
well as for PWM output or waveform generation.
•
Radio Timer
A multichannel 32-bit timer running at 4 MHz is available as part of the device radio. The radio timer is
typically used as the timing base in wireless network communication using the 32-bit timing word as the
network time. The radio timer is synchronized with the RTC by using a dedicated radio API when the device
radio is turned on or off. This ensures that for a network stack, the radio timer seems to always be running
when the radio is enabled. The radio timer is in most cases used indirectly through the trigger time fields in
the radio APIs and should only be used when the accurate 48 MHz high frequency crystal is the source of
SCLK_HF.
•
Watchdog timer
The watchdog timer is used to regain control if the system operates incorrectly due to software errors. It is
typically used to generate an interrupt to and reset of the device for the case where periodic monitoring of the
system components and tasks fails to verify proper functionality. The watchdog timer runs on a 1.5 MHz clock
rate and cannot be stopped once enabled. The watchdog timer pauses to run in Standby power mode and
when a debugger halts the device.
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8.8 Serial Peripherals and I/O
The SSIs are synchronous serial interfaces that are compatible with SPI, MICROWIRE, and TI's synchronous
serial interfaces. The SSIs support both SPI master and slave up to 4 MHz. The SSI modules support
configurable phase and polarity.
The UARTs implement universal asynchronous receiver and transmitter functions. They support flexible baud-
rate generation up to a maximum of 3 Mbps.
The I2S interface is used to handle digital audio and can also be used to interface pulse-density modulation
microphones (PDM).
The I2C interface is used to communicate with devices compatible with the I2C standard. The I2C interface can
handle 100 kHz and 400 kHz operation, and can serve as both master and slave.
The I/O controller (IOC) controls the digital I/O pins and contains multiplexer circuitry to allow a set of peripherals
to be assigned to I/O pins in a flexible manner. All digital I/Os are interrupt and wake-up capable, have a
programmable pullup and pulldown function, and can generate an interrupt on a negative or positive edge
(configurable). When configured as an output, pins can function as either push-pull or open-drain. Five GPIOs
have high-drive capabilities, which are marked in bold in Section 6. All digital peripherals can be connected to
any digital pin on the device.
For more information, see the CC13x2, CC26x2 SimpleLink™ Wireless MCU Technical Reference Manual.
8.9 Battery and Temperature Monitor
A combined temperature and battery voltage monitor is available in the CC2652R7 device. The battery and
temperature monitor allows an application to continuously monitor on-chip temperature and supply voltage
and respond to changes in environmental conditions as needed. The module contains window comparators to
interrupt the system CPU when temperature or supply voltage go outside defined windows. These events can
also be used to wake up the device from Standby mode through the Always-On (AON) event fabric.
8.10 µDMA
The device includes a direct memory access (µDMA) controller. The µDMA controller provides a way to offload
data-transfer tasks from the system CPU, thus allowing for more efficient use of the processor and the available
bus bandwidth. The µDMA controller can perform a transfer between memory and peripherals. The µDMA
controller has dedicated channels for each supported on-chip module and can be programmed to automatically
perform transfers between peripherals and memory when the peripheral is ready to transfer more data.
Some features of the µDMA controller include the following (this is not an exhaustive list):
•
•
Highly flexible and configurable channel operation of up to 32 channels
Transfer modes: memory-to-memory, memory-to-peripheral, peripheral-to-memory, and
peripheral-to-peripheral
•
•
Data sizes of 8, 16, and 32 bits
Ping-pong mode for continuous streaming of data
8.11 Debug
The on-chip debug support is done through a dedicated cJTAG (IEEE 1149.7) or JTAG (IEEE 1149.1) interface.
The device boots by default into cJTAG mode and must be reconfigured to use 4-pin JTAG.
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8.12 Power Management
To minimize power consumption, the CC2652R7 supports a number of power modes and power management
features (see Table 8-1).
Table 8-1. Power Modes
SOFTWARE CONFIGURABLE POWER MODES
RESET PIN
HELD
MODE
ACTIVE
Active
On
IDLE
Off
STANDBY
Off
SHUTDOWN
CPU
Off
Off
Off
Off
No
No
Off
Off
Off
Off
No
No
Flash
Available
On
Off
SRAM
On
Retention
Duty Cycled
Partial
Full
Supply System
Register and CPU retention
SRAM retention
On
On
Full
Full
Full
Full
48 MHz high-speed clock
(SCLK_HF)
XOSC_HF or
RCOSC_HF
XOSC_HF or
RCOSC_HF
Off
Off
Off
Off
Off
Off
Off
2 MHz medium-speed clock
(SCLK_MF)
RCOSC_MF
RCOSC_MF
Available
32 kHz low-speed clock
(SCLK_LF)
XOSC_LF or
RCOSC_LF
XOSC_LF or
RCOSC_LF
XOSC_LF or
RCOSC_LF
Peripherals
Available
Available
Available
Available
On
Available
Available
Available
Available
On
Off
Available
Available
Available
On
Off
Off
Off
Off
Off
Off
On
Off
Off
Off
Sensor Controller
Wake-up on RTC
Off
Wake-up on pin edge
Wake-up on reset pin
Brownout detector (BOD)
Power-on reset (POR)
Watchdog timer (WDT)
Available
On
On
On
Duty Cycled
On
Off
On
On
Off
Available
Available
Paused
Off
In Active mode, the application system CPU is actively executing code. Active mode provides normal operation
of the processor and all of the peripherals that are currently enabled. The system clock can be any available
clock source (see Table 8-1).
In Idle mode, all active peripherals can be clocked, but the Application CPU core and memory are not clocked
and no code is executed. Any interrupt event brings the processor back into active mode.
In Standby mode, only the always-on (AON) domain is active. An external wake-up event, RTC event, or Sensor
Controller event is required to bring the device back to active mode. MCU peripherals with retention do not need
to be reconfigured when waking up again, and the CPU continues execution from where it went into standby
mode. All GPIOs are latched in standby mode.
In Shutdown mode, the device is entirely turned off (including the AON domain and Sensor Controller), and
the I/Os are latched with the value they had before entering shutdown mode. A change of state on any I/O
pin defined as a wake from shutdown pin wakes up the device and functions as a reset trigger. The CPU can
differentiate between reset in this way and reset-by-reset pin or power-on reset by reading the reset status
register. The only state retained in this mode is the latched I/O state and the flash memory contents.
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The Sensor Controller is an autonomous processor that can control the peripherals in the Sensor Controller
independently of the system CPU. This means that the system CPU does not have to wake up, for example to
perform an ADC sampling or poll a digital sensor over SPI, thus saving both current and wake-up time that would
otherwise be wasted. The Sensor Controller Studio tool enables the user to program the Sensor Controller,
control its peripherals, and wake up the system CPU as needed. All Sensor Controller peripherals can also be
controlled by the system CPU.
Note
The power, RF and clock management for the CC2652R7 device require specific configuration and
handling by software for optimized performance. This configuration and handling is implemented in
the TI-provided drivers that are part of the CC2652R7 software development kit (SDK). Therefore, TI
highly recommends using this software framework for all application development on the device. The
complete SDK with TI-RTOS (optional), device drivers, and examples are offered free of charge in
source code.
8.13 Clock Systems
The CC2652R7 device has several internal system clocks.
The 48 MHz SCLK_HF is used as the main system (MCU and peripherals) clock. This can be driven by
the internal 48 MHz RC Oscillator (RCOSC_HF) or an external 48 MHz crystal (XOSC_HF). Radio operation
requires an external 48 MHz crystal.
SCLK_MF is an internal 2 MHz clock that is used by the Sensor Controller in low-power mode and also for
internal power management circuitry. The SCLK_MF clock is always driven by the internal 2 MHz RC Oscillator
(RCOSC_MF).
SCLK_LF is the 32.768 kHz internal low-frequency system clock. It can be used by the Sensor Controller for
ultra-low-power operation and is also used for the RTC and to synchronize the radio timer before or after
Standby power mode. SCLK_LF can be driven by the internal 32.8 kHz RC Oscillator (RCOSC_LF), a 32.768
kHz watch-type crystal, or a clock input on any digital IO.
When using a crystal or the internal RC oscillator, the device can output the 32 kHz SCLK_LF signal to other
devices, thereby reducing the overall system cost.
8.14 Network Processor
Depending on the product configuration, the CC2652R7 device can function as a wireless network processor
(WNP - a device running the wireless protocol stack with the application running on a separate host MCU), or as
a system-on-chip (SoC) with the application and protocol stack running on the system CPU inside the device.
In the first case, the external host MCU communicates with the device using SPI or UART. In the second case,
the application must be written according to the application framework supplied with the wireless protocol stack.
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9 Application, Implementation, and Layout
Note
Information in the following Applications section is not part of the TI component specification, and
TI does not warrant its accuracy or completeness. TI's customers are responsible for determining
suitability of components for their purposes. Customers should validate and test their design
implementation to confirm system functionality.
For general design guidelines and hardware configuration guidelines, refer to CC13xx/CC26xx Hardware
Configuration and PCB Design Considerations Application Report.
9.1 Reference Designs
The following reference designs should be followed closely when implementing designs using the CC2652R7
device.
Special attention must be paid to RF component placement, decoupling capacitors and DCDC regulator
components, as well as ground connections for all of these.
CC26x2REM-7ID Design
Files
The differential CC26x2REM-7ID reference design provides schematic, layout and
production files for the characterization board used for deriving the performance
number found in this document.
LAUNCHXL-CC26X2R
Design Files
The CC26X2R LaunchPad Design Files contain detailed schematics and layouts
to build application specific boards using the CC2652R7 device. This design
applies to both the CC2642R and CC2652R devices.
Sub-1 GHz and
2.4 GHz Antenna Kit for
The antenna kit allows real-life testing to identify the optimal antenna for your
application. The antenna kit includes 16 antennas for frequencies from 169 MHz to
LaunchPad™ Development 2.4 GHz, including:
Kit and SensorTag
•
•
•
•
PCB antennas
Helical antennas
Chip antennas
Dual-band antennas for 868 MHz and 915 MHz combined with 2.4 GHz
The antenna kit includes a JSC cable to connect to the Wireless MCU LaunchPad
Development Kits and SensorTags.
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9.2 Junction Temperature Calculation
This section shows the different techniques for calculating the junction temperature under various operating
conditions. For more details, see Semiconductor and IC Package Thermal Metrics.
There are three recommended ways to derive the junction temperature from other measured temperatures:
1. From package temperature:
T = ψ × P + T
case
(1)
(2)
(3)
J
JT
2. From board temperature:
T = ψ × P + T
board
J
JB
3. From ambient temperature:
T = R
× P + T
A
J
θJA
P is the power dissipated from the device and can be calculated by multiplying current consumption with supply
voltage. Thermal resistance coefficients are found in Section 7.8.
Example:
Using Equation 3, the temperature difference between ambient temperature and junction temperature is
calculated. In this example, we assume a simple use case where the radio is transmitting continuously at 0 dBm
output power. Let us assume the ambient temperature is 85 °C and the supply voltage is 3 V. To calculate P, we
need to look up the current consumption for Tx at 85 °C in Section 7.16. From the plot, we see that the current
consumption is 7.8 mA. This means that P is 7.8 mA × 3 V = 23.4 mW.
The junction temperature is then calculated as:
°C
T = 23.4
× 23.4mW + T = 0.6°C + T
A A
(4)
W
J
As can be seen from the example, the junction temperature is 0.6 °C higher than the ambient temperature when
running continuous Tx at 85 °C and, thus, well within the recommended operating conditions.
For various application use cases current consumption for other modules may have to be added to calculate the
appropriate power dissipation. For example, the MCU may be running simultaneously as the radio, peripheral
modules may be enabled, etc. Typically, the easiest way to find the peak current consumption, and thus the
peak power dissipation in the device, is to measure as described in Measuring CC13xx and CC26xx Current
Consumption.
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10 Device and Documentation Support
TI offers an extensive line of development tools. Tools and software to evaluate the performance of the device,
generate code, and develop solutions are listed as follows.
10.1 Tools and Software
The CC2652R7 device is supported by a variety of software and hardware development tools.
Development Kit
CC26x2
LaunchPad™
Development Kit
The CC26x2R LaunchPad™ Development Kit enables development of high-performance
wireless applications that benefit from low-power operation. The kit features the CC2652R
SimpleLink Wireless MCU, which allows you to quickly evaluate and prototype 2.4-
GHz wireless applications such as Bluetooth 5 Low Energy, Zigbee and Thread, plus
combinations of these. The kit works with the LaunchPad ecosystem, easily enabling
additional functionality like sensors, display and more. The built-in EnergyTrace™ software
is an energy-based code analysis tool that measures and displays the application’s energy
profile and helps to optimize it for ultra-low-power consumption. See Table 5-1 for guidance
in selecting the correct device for single-protocol products.
Software
SimpleLink™
CC13X2-
CC26X2 SDK
The SimpleLink CC13X2-CC26X2 Software Development Kit (SDK) provides a complete
package for the development of wireless applications on the CC13X2 / CC26X2 family of
devices. The SDK includes a comprehensive software package for the CC2652R7 device,
including the following protocol stacks:
•
•
•
•
Bluetooth Low Energy 4 and 5.2
Thread (based on OpenThread)
Zigbee 3.0
TI 15.4-Stack - an IEEE 802.15.4-based star networking solution for Sub-1 GHz and
2.4 GHz
•
•
EasyLink - a large set of building blocks for building proprietary RF software stacks
Multiprotocol support - concurrent operation between stacks using the Dynamic
Multiprotocol Manager (DMM)
The SimpleLink CC13X2-CC26X2 SDK is part of TI’s SimpleLink MCU platform, offering a
single development environment that delivers flexible hardware, software and tool options
for customers developing wired and wireless applications. For more information about the
SimpleLink MCU Platform, visit http://www.ti.com/simplelink.
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Development Tools
Code Composer
Code Composer Studio is an integrated development environment (IDE) that supports TI's
Microcontroller and Embedded Processors portfolio. Code Composer Studio comprises a
suite of tools used to develop and debug embedded applications. It includes an optimizing
C/C++ compiler, source code editor, project build environment, debugger, profiler, and many
other features. The intuitive IDE provides a single user interface taking you through each
step of the application development flow. Familiar tools and interfaces allow users to get
started faster than ever before. Code Composer Studio combines the advantages of the
Eclipse® software framework with advanced embedded debug capabilities from TI resulting
in a compelling feature-rich development environment for embedded developers.
Studio™
Integrated
Development
Environment
(IDE)
CCS has support for all SimpleLink Wireless MCUs and includes support for EnergyTrace™
software (application energy usage profiling). A real-time object viewer plugin is available for
TI-RTOS, part of the SimpleLink SDK.
Code Composer Studio is provided free of charge when used in conjunction with the XDS
debuggers included on a LaunchPad Development Kit.
Code Composer
Studio™ Cloud
IDE
Code Composer Studio (CCS) Cloud is a web-based IDE that allows you to create, edit and
build CCS and Energia™ projects. After you have successfully built your project, you can
download and run on your connected LaunchPad. Basic debugging, including features like
setting breakpoints and viewing variable values is now supported with CCS Cloud.
IAR Embedded
Workbench® for
Arm®
IAR Embedded Workbench® is a set of development tools for building and debugging
embedded system applications using assembler, C and C++. It provides a completely
integrated development environment that includes a project manager, editor, and build
tools. IAR has support for all SimpleLink Wireless MCUs. It offers broad debugger support,
including XDS110, IAR I-jet™ and Segger J-Link™. A real-time object viewer plugin is
available for TI-RTOS, part of the SimpleLink SDK. IAR is also supported out-of-the-box
on most software examples provided as part of the SimpleLink SDK.
A 30-day evaluation or a 32 KB size-limited version is available through iar.com.
SmartRF™
Studio
SmartRF™ Studio is a Windows® application that can be used to evaluate and configure
SimpleLink Wireless MCUs from Texas Instruments. The application will help designers
of RF systems to easily evaluate the radio at an early stage in the design process. It is
especially useful for generation of configuration register values and for practical testing
and debugging of the RF system. SmartRF Studio can be used either as a standalone
application or together with applicable evaluation boards or debug probes for the RF device.
Features of the SmartRF Studio include:
•
•
•
•
Link tests - send and receive packets between nodes
Antenna and radiation tests - set the radio in continuous wave TX and RX states
Export radio configuration code for use with the TI SimpleLink SDK RF driver
Custom GPIO configuration for signaling and control of external switches
Sensor Controller
Studio
Sensor Controller Studio is used to write, test and debug code for the Sensor Controller
peripheral. The tool generates a Sensor Controller Interface driver, which is a set of C
source files that are compiled into the System CPU application. These source files also
contain the Sensor Controller binary image and allow the System CPU application to control
and exchange data with the Sensor Controller. Features of the Sensor Controller Studio
include:
•
•
Ready-to-use examples for several common use cases
Full toolchain with built-in compiler and assembler for programming in a C-like
programming language
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•
Provides rapid development by using the integrated sensor controller task testing
and debugging functionality, including visualization of sensor data and verification of
algorithms
CCS UniFlash
CCS UniFlash is a standalone tool used to program on-chip flash memory on TI MCUs.
UniFlash has a GUI, command line, and scripting interface. CCS UniFlash is available free
of charge.
10.1.1 SimpleLink™ Microcontroller Platform
The SimpleLink microcontroller platform sets a new standard for developers with the broadest portfolio of
wired and wireless Arm® MCUs (System-on-Chip) in a single software development environment. Delivering
flexible hardware, software and tool options for your IoT applications. Invest once in the SimpleLink software
development kit and use throughout your entire portfolio. Learn more on ti.com/simplelink.
10.2 Documentation Support
To receive notification of documentation updates on data sheets, errata, application notes and similar, navigate
to the device product folder on ti.com/product/CC2652R. In the upper right corner, click on Alert me to register
and receive a weekly digest of any product information that has changed. For change details, review the revision
history included in any revised document.
The current documentation that describes the MCU, related peripherals, and other technical collateral is listed as
follows.
TI Resource Explorer
TI Resource Explorer
Software examples, libraries, executables, and documentation are available for your
device and development board.
Errata
CC2652R7 Silicon
Errata
The silicon errata describes the known exceptions to the functional specifications for
each silicon revision of the device and description on how to recognize a device
revision.
Application Reports
All application reports for the CC2652R7 device are found on the device product folder at: ti.com/product/
CC2652R/technicaldocuments.
Technical Reference Manual (TRM)
CC13x2, CC26x2 SimpleLink™ Wireless
MCU TRM
The TRM provides a detailed description of all modules and
peripherals available in the device family.
10.3 Support Resources
TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight
from the experts. Search existing answers or ask your own question to get the quick design help you need.
Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do
not necessarily reflect TI's views; see TI's Terms of Use.
10.4 Trademarks
SimpleLink™, SmartRF™, LaunchPad™, EnergyTrace™, Code Composer Studio™, TI E2E™ are trademarks of
Texas Instruments.
I-jet™ is a trademark of IAR Systems AB.
J-Link™ is a trademark of SEGGER Microcontroller Systeme GmbH.
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Arm®, Cortex®, and Arm Thumb® are registered trademarks of Arm Limited (or its subsidiaries).
CoreMark® is a registered trademark of Embedded Microprocessor Benchmark Consortium.
Bluetooth® are registered trademarks of Bluetooth SIG Inc.
Zigbee® are registered trademarks of Zigbee Alliance Inc.
Wi-SUN® is a registered trademark of Wi-SUN Alliance Inc.
Wi-Fi® is a registered trademark of Wi-Fi Alliance.
Eclipse® is a registered trademark of Eclipse Foundation.
IAR Embedded Workbench® is a registered trademark of IAR Systems AB.
Windows® is a registered trademark of Microsoft Corporation.
All trademarks are the property of their respective owners.
10.5 Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled
with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric changes could cause the device not to meet its published
specifications.
10.6 Glossary
TI Glossary
This glossary lists and explains terms, acronyms, and definitions.
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11 Mechanical, Packaging, and Orderable Information
11.1 Packaging Information
The following pages include mechanical packaging and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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PACKAGE OUTLINE
VQFN - 1 mm max height
RGZ0048A
PLASTIC QUADFLAT PACK- NO LEAD
A
7.1
6.9
B
(0.1) TYP
7.1
6.9
SIDE WALL DETAIL
OPTIONAL METAL THICKNESS
PIN 1 INDEX AREA
(0.45) TYP
CHAMFERED LEAD
CORNER LEAD OPTION
1 MAX
C
SEATING PLANE
0.08
0.05
0.00
C
2X 5.5
5.15 0.1
(0.2) TYP
13
24
44X 0.5
12
25
SEE SIDE WALL
DETAIL
SYMM
2X
5.5
1
36
0.30
48X
PIN1 ID
(OPTIONAL)
0.18
48
37
SYMM
0.1
C A B
0.5
0.3
48X
0.05
C
SEE LEAD OPTION
4219044/C 09/2020
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. The package thermal pad must be soldered to the printed circuit board for optimal thermal and mechanical performance.
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EXAMPLE BOARD LAYOUT
VQFN - 1 mm max height
RGZ0048A
PLASTIC QUADFLAT PACK- NO LEAD
2X (6.8)
5.15)
SYMM
(
48X (0.6)
48X (0.24)
44X (0.5)
35
48
1
34
SYMM
2X
(5.5)
2X
(6.8)
2X
(1.26)
2X
(1.065)
(R0.05)
TYP
23
12
21X (Ø0.2) VIA
TYP
22
13
2X (1.065)
2X (1.26)
2X (5.5)
LAND PATTERN EXAMPLE
SCALE: 15X
SOLDER MASK
OPENING
0.07 MIN
ALL AROUND
0.07 MAX
ALL AROUND
EXPOSED METAL
EXPOSED METAL
METAL
SOLDER MASK
OPENING
METAL UNDER
SOLDER MASK
NON SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK
DEFINED
4219044/C 09/2020
SOLDER MASK DETAILS
NOTES: (continued)
4. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature
number SLUA271 (www.ti.com/lit/slua271)
.
5. Vias are optional depending on application, refer to device data sheet. If any vias are implemented, refer to their locations shown
on this view. It is recommended that vias under paste be filled, plugged or tented.
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EXAMPLE STENCIL DESIGN
VQFN - 1 mm max height
RGZ0048A
PLASTIC QUADFLAT PACK- NO LEAD
2X (6.8)
SYMM
(
1.06)
48X (0.6)
48X (0.24)
44X (0.5)
SYMM
2X
(5.5)
2X
(6.8)
2X
(0.63)
2X
(1.26)
(R0.05)
TYP
2X
(1.26)
2X (0.63)
2X (5.5)
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICK STENCIL
EXPOSED PAD
67% PRINTED COVERAGE BY AREA
SCALE: 15X
4219044/C 09/2020
NOTES: (continued)
6. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
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PACKAGE OPTION ADDENDUM
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3-Jun-2021
PACKAGING INFORMATION
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
XCC2652R74T0RGZ
ACTIVE
VQFN
RGZ
48
2500
Non-RoHS &
Non-Green
Call TI
Call TI
-40 to 105
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
GENERIC PACKAGE VIEW
RGZ 48
7 x 7, 0.5 mm pitch
VQFN - 1 mm max height
PLASTIC QUADFLAT PACK- NO LEAD
Images above are just a representation of the package family, actual package may vary.
Refer to the product data sheet for package details.
4224671/A
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