MSP430F1471IPMR

Product Overview

Category

The MSP430F1471IPMR belongs to the category of microcontrollers.

Use

This microcontroller is commonly used in various electronic devices and systems for control and processing purposes.

Characteristics

• Low power consumption
• High performance
• Integrated peripherals
• Small form factor
• Wide operating voltage range

Package

The MSP430F1471IPMR is available in a small outline package (SOP) with a specific pin configuration.

Essence

The essence of the MSP430F1471IPMR lies in its ability to provide efficient control and processing capabilities in a compact and low-power design.

Packaging/Quantity

The MSP430F1471IPMR is typically packaged in reels or tubes, with a quantity of 250 or 1000 units per package.

Specifications

• Microcontroller core: MSP430
• CPU speed: Up to 16 MHz
• Flash memory: 32 KB
• RAM: 2 KB
• Operating voltage: 1.8V - 3.6V
• Number of I/O pins: 32
• Communication interfaces: UART, SPI, I2C
• Analog-to-digital converter (ADC): 10-bit resolution, up to 8 channels
• Timers: Multiple timers/counters
• Operating temperature range: -40°C to +85°C

Detailed Pin Configuration

The MSP430F1471IPMR has a total of 32 pins, each serving a specific purpose. The pin configuration is as follows:

1. P1.0
2. P1.1
3. P1.2
4. P1.3
5. P1.4
6. P1.5
7. P1.6
8. P1.7
9. P2.0
10. P2.1
11. P2.2
12. P2.3
13. P2.4
14. P2.5
15. P2.6
16. P2.7
17. P3.0
18. P3.1
19. P3.2
20. P3.3
21. P3.4
22. P3.5
23. P3.6
24. P3.7
25. P4.0
26. P4.1
27. P4.2
28. P4.3
29. P4.4
30. P4.5
31. P4.6
32. P4.7

Functional Features

The MSP430F1471IPMR offers several functional features that enhance its usability and performance:

• Low power consumption: The microcontroller is designed to operate efficiently, making it suitable for battery-powered applications.
• Integrated peripherals: It includes various peripherals such as UART, SPI, I2C, and ADC, enabling seamless communication and data acquisition.
• High-performance CPU: The MSP430 core provides fast processing capabilities, allowing for efficient execution of tasks.
• Timers/counters: Multiple timers are available for precise timing and event management.
• Wide operating voltage range: The microcontroller can operate within a wide voltage range, providing flexibility in different applications.

Advantages and Disadvantages

Advantages

• Low power consumption extends battery life in portable devices.
• Integrated peripherals simplify system design and reduce external component count.
• Small form factor enables compact designs.
• High-performance CPU ensures efficient execution of tasks.
• Wide operating voltage range enhances versatility.

Disadvantages

• Limited flash memory and RAM may restrict the complexity of applications.
• Availability of alternative models with more features may limit the competitiveness of this specific microcontroller.

Working Principles

The MSP430F1471IPMR operates based on the principles of microcontroller architecture. It executes instructions stored in its flash memory, processes data, and controls various peripherals to perform desired functions. The CPU interacts with the integrated peripherals and external components through the pin configuration, enabling communication, data acquisition, and control operations.

Detailed Application Field Plans

The MSP430F1471IPMR finds applications in various fields, including but not limited to:

1. Internet of Things (IoT) devices: The low power consumption and integrated peripherals make it suitable for IoT applications that require efficient control and connectivity.
2. Home automation systems: The microcontroller can be used to control and monitor various home automation devices, such as lighting, temperature, and security systems.
3. Industrial automation: It can be employed in industrial control systems for process monitoring and control, motor control, and data acquisition.
4. Medical devices: The small form factor and low power consumption make it ideal for portable medical devices, such as patient monitors and wearable health trackers.

Detailed and Complete Alternative Models