MSP50P614/MSP50C614 Computational Modes

Example 4.5.10

MOV STR,

0

 

SFLAG *0x00032

 

MOVS

A0,

*0x0031 * 2

 

RFLAG *0x00032

 

MOVS

A0,

*0x0031 * 2

Refer to Figure 4±4 for this example. This example is to illustrate the effect of the tag/flag bit when used with a string instruction. The string register (STR) is loaded with 0 (string length of 2). The second instruction sets the flag bit to 1 at flag address 0x0032. The next instruction reads the word-string at word memory location, 0x0031, into A0 and also sets the TAG bit of STAT to 1 corre- sponding to the last memory location of the string (which is word address 0x0032 in this case). The next two instructions verify this by setting the flag to zero and reading the memory string again.

4.6 MSP50P614/MSP50C614 Computational Modes

MSP50P614/MSP50C614 has the following computational modes which are the first 4 bits of the status register.

-Sign extension mode (bit 0 or XM bit of STAT)

-Unsigned mode (bit 1 or UM bit of STAT)

-Overflow mode (bit 2 or OM bit of STAT)

-Fractional mode (bit 3 or FM bit of STAT)

These modes can be set by setting the appropriate status register bits or by special instructions (Class 9) as shown in Table 4±41.

Assembly Language Instructions

4-49

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Texas Instruments manual MSP50P614/MSP50C614 Computational Modes

MSP50C614 specifications

The Texas Instruments MSP50C614 is a microcontroller that belongs to the MSP430 family, renowned for its low power consumption and versatile functionality. Primarily designed for embedded applications, this microcontroller is favored in various industries, including consumer electronics, industrial automation, and healthcare devices.

One of the standout features of the MSP50C614 is its ultra-low power technology, which enables it to operate in various power modes. This makes it ideal for battery-powered applications, where energy efficiency is crucial. The MSP430 architecture allows for a flexible power management system, ensuring that energy is conserved while providing robust performance.

The MSP50C614 is equipped with a 16-bit RISC CPU that delivers high performance while maintaining low power usage. With a maximum clock frequency of 16 MHz, it can execute most instructions in a single cycle, resulting in swift operation and responsive performance. This microcontroller also comes with a generous flash memory capacity, allowing developers to store large amounts of code and data conveniently.

In terms of peripherals, the MSP50C614 is highly versatile. It features a range of digital and analog input/output options, including multiple timers, GPIO ports, and various communication interfaces like UART, SPI, and I2C. This extensive set of peripherals allows for seamless integration with other components and simplifies the design of complex systems.

The integrated 12-bit Analog-to-Digital Converter (ADC) stands out as a valuable characteristic of the MSP50C614. This feature enables the microcontroller to convert physical analog signals into digital data, making it particularly useful for sensing applications and real-time monitoring.

Another noteworthy technology employed in the MSP50C614 is its support for low-voltage operations. With a broad supply voltage range, this microcontroller can function efficiently in diverse environments and is suitable for low-power applications, enhancing its practicality.

Moreover, Texas Instruments provides software support in the form of Code Composer Studio and various libraries that make it easier for developers to program and utilize the MSP50C614 effectively.

In summary, the Texas Instruments MSP50C614 microcontroller is a powerful, low-power solution equipped with the features and technologies necessary for efficient operation in a wide array of applications. Its blend of performance, flexibility, and energy efficiency makes it a popular choice among engineers and designers looking to create innovative, sustainable designs in the rapidly evolving tech landscape.