MSP430FR69271IPMR

Product Overview

• Category: Microcontroller
• Use: Embedded systems, Internet of Things (IoT) devices
• Characteristics: Low power consumption, high performance, integrated peripherals
• Package: 64-pin QFN package
• Essence: A microcontroller designed for low-power applications with integrated FRAM memory and various peripherals
• Packaging/Quantity: Available in tape and reel packaging, quantity depends on the supplier

Specifications

• Architecture: 16-bit RISC
• CPU Speed: Up to 24 MHz
• Memory: 256 KB FRAM, 8 KB SRAM
• Operating Voltage: 1.8V - 3.6V
• Digital I/O Pins: 53
• Analog Inputs: 16
• Communication Interfaces: UART, SPI, I2C, USB
• Timers: 4x 16-bit timers, 1x 32-bit timer
• ADC Resolution: 12-bit
• Temperature Sensor: Yes
• Operating Temperature Range: -40°C to +85°C

Detailed Pin Configuration

The MSP430FR69271IPMR has a total of 64 pins. The pin configuration is as follows:

• P1.x: General-purpose digital I/O pins (x = 0 to 7)
• P2.x: General-purpose digital I/O pins (x = 0 to 7)
• P3.x: General-purpose digital I/O pins (x = 0 to 7)
• P4.x: General-purpose digital I/O pins (x = 0 to 7)
• P5.x: General-purpose digital I/O pins (x = 0 to 7)
• P6.x: General-purpose digital I/O pins (x = 0 to 7)
• P7.x: General-purpose digital I/O pins (x = 0 to 7)
• P8.x: General-purpose digital I/O pins (x = 0 to 7)
• P9.x: General-purpose digital I/O pins (x = 0 to 7)
• P10.x: General-purpose digital I/O pins (x = 0 to 7)
• A0-A15: Analog input pins
• AVSS: Analog ground
• AVCC: Analog power supply
• VCC: Digital power supply
• GND: Ground
• RST/NMI: Reset and non-maskable interrupt pin
• TEST/SBWTCK: Test and single-wire background debug test clock pin
• TDO/TDI: Test data out and test data in pins for JTAG debugging
• TMS: Test mode select pin for JTAG debugging
• TCK: Test clock pin for JTAG debugging

Functional Features

• Integrated FRAM memory for non-volatile data storage
• Low-power consumption for extended battery life
• High-performance 16-bit RISC CPU
• Multiple communication interfaces for connectivity options
• On-chip temperature sensor for environmental monitoring
• Rich set of integrated peripherals for versatile applications
• Flexible power management options for efficient energy usage

Advantages and Disadvantages

Advantages: - Low power consumption enables long battery life in portable devices - Integrated FRAM memory provides fast and reliable non-volatile data storage - Wide range of integrated peripherals simplifies system design - High-performance CPU allows for efficient execution of complex tasks - Temperature sensor enables environmental monitoring without additional components

Disadvantages: - Limited memory capacity compared to some other microcontrollers - Higher cost compared to lower-end microcontrollers with similar features - Steeper learning curve for beginners due to the complexity of the device

Working Principles

The MSP430FR69271IPMR operates based on the 16-bit RISC architecture. It executes instructions fetched from its memory to perform various tasks. The integrated FRAM memory allows for non-volatile data storage, ensuring that important information is retained even when power is lost.

The microcontroller can communicate with other devices through its UART, SPI, I2C, and USB interfaces. This enables it to exchange data with sensors, actuators, and other components in an embedded system or IoT device.

The MSP430FR69271IPMR also features a range of timers, analog inputs, and digital I/O pins, providing flexibility in interfacing with external devices and performing precise timing operations.

Detailed Application Field Plans

The MSP430FR69271IPMR is suitable for a wide range of applications, including but not limited to:

1. Home automation systems: Controlling lights, temperature, and security systems.
2. Industrial monitoring and control: Collecting sensor data and controlling machinery.
3. Wearable devices: Tracking health parameters and providing real-time feedback.
4. Smart agriculture: Monitoring soil moisture, temperature, and automating irrigation.
5. Energy management: Optimizing energy consumption in buildings