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AN1310 Module Description The AN1310 module is designed based on CC1310F128. The CC1310 device is the first part in a Sub-1-GHz family of cost-effective, ultralow power wireless MCUs. The CC1310 device combines a flexible, very low power RF transceiver with a powerful 48-MHz Cortex- M3 microcontroller in a platform supporting multiple physical layers and RF standards. A dedicated Radio Controller (Cortex-M0) handles low-level RF protocol commands that are stored in ROM or RAM, thus ensuring ultralow power and flexibility. The low-power consumption of the CC1310 device does not come at the expense of RF performance; the CC1310 device has excellent sensitivity and robustness (selectivity and blocking) performance. The CC1310 device is a highly integrated, true single-chip solution incorporating a complete RF system and an on-chip DC-DC converter. Sensors can be handled in a very low-power manner by a dedicated autonomous ultralow power MCU that can be configured to handle analog and digital sensors; thus the main MCU (Cortex-M3) is able to maximize sleep time. The CC1310 power and clock management and radio systems require specific configuration and handling by software to operate correctly. This has been implemented in the TI RTOS, and it is therefore recommended that this software framework is used for all application development on the device. The complete TI-RTOS and device drivers are offered in source code free of charge.
Description The AN1310 module is designed based on CC1310F128. The CC1310 device is the first part in a Sub-1-GHz family of cost-effective, ultralow power wireless MCUs. The CC1310 device combines a flexible, very low power RF transceiver with a powerful 48-MHz Cortex- M3 microcontroller in a platform supporting multiple physical layers and RF standards. A dedicated Radio Controller (Cortex-M0) handles low-level RF protocol commands that are stored in ROM or RAM, thus ensuring ultralow power and flexibility. The low-power consumption of the CC1310 device does not come at the expense of RF performance; the CC1310 device has excellent sensitivity and robustness (selectivity and blocking) performance. The CC1310 device is a highly integrated, true single-chip solution incorporating a complete RF system and an on-chip DC-DC converter. Sensors can be handled in a very low-power manner by a dedicated autonomous ultralow power MCU that can be configured to handle analog and digital sensors; thus the main MCU (Cortex-M3) is able to maximize sleep time. The CC1310 power and clock management and radio systems require specific configuration and handling by software to operate correctly. This has been implemented in the TI RTOS, and it is therefore recommended that this software framework is used for all application development on the device. The complete TI-RTOS and device drivers are offered in source code free of charge.
Applications  433-, 868-, 915- ISM and SRD Systems  Low-Power Wireless Systems With 50-kHz to 5-MHz Channel Spacing  SmartGrid and Automatic Meter Reading  Home and Building Automation  Wireless Alarm and Security Systems  Industrial Monitoring and Control  Wireless Healthcare Applications  Wireless Sensor Networks  Active RFID  IEEE 802.15.4g, IP-Enabled Smart Objects (6LoWPAN), Wireless M-Bus, KNX Systems, Wi-SUN, ZigBee and Proprietary Systems  Energy Harvesting Applications  ESL (Electronic Shelf Label)  Long-Range Sensor Applications  Heat Cost Allocator
Features  Built in CC1310F128 Sub-1-GHz RF System-On-Chip (SOC)  Size:15mm X 22mm  Operating Voltage:1.8V to 3.8V  Operating Temperature: -30℃~+85℃  Storage Temperature: -40℃~+125℃  Microcontroller  Powerful ARM Cortex –M3  Up to 48MHz Clock Speed  128KB of In-System Programming Flash  8KB of SRAM for Cache (or as General-Purpose RAM )  20KB of Ultralow Leakage SRAM  2-Pin cJTAG and JTAG Debugging  Supports Over-the-Air Upgrade (OTA)  Ultralow Power Sensor Controller  Can Run Autonomous From the Rest of the System  16-Bit Architecture  2KB of Ultralow Leakage SRAM for Code and Data  Efficient Code-Size Architecture, Placing TI-RTOS, Drivers and Bootloader in ROM  Peripherals  All digital Peripheral Pins Can Be Routed to Any GPIO  Four General-Purpose Timer Modules (Eight 16-Bit or four 32-Bit Timers, PWM Each)  12-Bit ADC, 200 ksamples/s, 8-Channel Analog MUX  Continuous Time Comparator  Ultralow Power Clocked Comparator  Programmable Current Source  UART  2 x SSI (SPI, MICROWIRE, TI)  I2C  I2S  Real-Time Clock (RTC)  AES-128 Security Module  True Random Number Generator (TRNG  Support for Eight Capacitive Sensing Buttons  Integrated Temperature Sensor  Low Power  Active-Mode RX: 5.4mA  Active-Mode TX at +10 dBm: 13.4mA  Active-Mode MCU: 48MHz Running Coremark: 2.5mA (51μA/MHz)  Active-Mode MCU: 48.5 CoreMark/mA  Active-Mode Sensor Controller at 24 MHz: 0.4mA +8.2μA/MHz  Sensor Controller, One Wake Up Every Second Performing One 12-Bit ADC Sampling: 0.95μA  Standby: 0.7μA (RTC Running and RAM and CPU Retention)  Shutdown: 185nA (Wakeup on External Events)  RF Section  Excellent Receiver Sensitivity -124 dBm Using Long-Range Mode, -110dBm at 50kbps  Excellent Selectivity: 56dB  Excellent Blocking Performance: 90 dB  Programmable Output
Applications  433-, 868-, 915- ISM and SRD Systems  Low-Power Wireless Systems With 50-kHz to 5-MHz Channel Spacing  SmartGrid and Automatic Meter Reading  Home and Building Automation  Wireless Alarm and Security Systems  Industrial Monitoring and Control  Wireless Healthcare Applications  Wireless Sensor Networks  Active RFID  IEEE 802.15.4g, IP-Enabled Smart Objects (6LoWPAN), Wireless M-Bus, KNX Systems, Wi-SUN, ZigBee and Proprietary Systems  Energy Harvesting Applications  ESL (Electronic Shelf Label)  Long-Range Sensor Applications  Heat Cost Allocator
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