Texas Instruments MSP430F2013IPWR: 16-Bit MCU (14-Pin TSSOP)

Overview of MSP430F2013IPWR 16-Bit Microcontroller

The MSP430F2013IPWR is a 16-bit RISC microcontroller from Texas Instruments (TI), part of the trusted MSP430? F2 family. Engineered for low-power embedded systems, it balances performance and efficiency, making it a top choice for cost-sensitive applications requiring reliable operation. Its integration of core processing capabilities with essential peripherals reduces the need for external components, simplifying designs and lowering system costs. For sourcing and technical support, visit IC Manufacturer.

Technical Parameters of MSP430F2013IPWR MCU

Core & Memory Specifications

Power & Packaging Details

Advantages of MSP430F2013IPWR Over Alternatives

The MSP430F2013IPWR stands out with its ultra-low power efficiency and compact design. Unlike many 16-bit microcontrollers that consume 1??A or more in standby mode, its 0.1??A standby current directly extends battery life??critical for wireless sensors and portable devices. This efficiency reduces long-term operational costs by minimizing battery replacements.

Its integrated peripherals, including a 10-bit ADC and universal serial interface (USI), eliminate the need for external components, shrinking PCB size by up to 20% and cutting bill-of-materials costs. ??TI??s MSP430F2 series has revolutionized our smart thermostat designs,?? notes Elena Ruiz, Lead Engineer at HomeTech Innovations. ??The F2013IPWR??s small package and low power let us create sleeker, longer-lasting products.??

TI??s robust ecosystem further differentiates it: the MSP-EXP430G2 LaunchPad development kit and free Code Composer Studio IDE accelerate prototyping, while TI??s 10+ year product lifecycle commitment ensures supply stability??key for industrial and medical applications.

Typical Applications for MSP430F2013IPWR

The MSP430F2013IPWR excels in efficiency-focused, space-constrained designs:

• Internet of Things (IoT): Powers wireless environmental sensors, operating for years on a single coin cell by minimizing idle power use.
• Home Appliances: Manages low-power functions in smart light switches and coffee makers, reducing standby energy consumption.
• Medical Devices: Enables compact blood glucose monitors, balancing processing needs with extended battery life for patient convenience.

Frequently Asked Questions About MSP430F2013IPWR

How does the MSP430F2013IPWR achieve such low power consumption?

It uses TI??s proprietary low-power architecture with multiple operating modes. Active mode draws 220??A at 1MHz for processing, while standby mode retains RAM data at just 0.1??A. This flexibility lets designers match power use to task demands, maximizing efficiency in battery-powered devices.

Which development tools support this microcontroller?

TI??s MSP-EXP430G2 LaunchPad is fully compatible, offering a low-cost platform with on-board debugging. It integrates with Code Composer Studio, TI??s free IDE, which includes code examples, libraries, and a simulator to streamline programming and reduce time-to-market.

What peripherals does the MSP430F2013IPWR include, and why are they useful?

It features a 10-bit ADC for analog sensor data conversion, comparators for threshold detection, timers for timing tasks, and a USI module for SPI/I2C communication. These eliminate external components, reducing design complexity, lowering costs, and ensuring reliable performance in compact systems.

Can this MCU operate in harsh environments?

Yes, it supports an operating temperature range of -40??C to 85??C, making it suitable for industrial settings, outdoor IoT devices, and automotive auxiliary systems. Its robust design withstands temperature fluctuations and voltage spikes, ensuring consistent performance in challenging conditions.

How does it compare to other MSP430 F2 family members?

It balances 2KB flash, 128B RAM, and a 14-pin package for entry-to-mid range applications. Lower-tier F2 models have less memory, while higher-tier ones add features like extra ADC channels. The F2013IPWR is ideal for cost-sensitive designs needing essential functionality in a compact form.