Introduction, System Registers | Texas Instruments MSP50C614

Introduction

4.1 Introduction

In this chapter each MSP50P614/MSP50C614 class of instructions is explained in detail with examples and restrictions. Most instructions can individually address bits, bytes, words or strings of words or bytes. Usable program memory is 30K by 17-bit wide and the entire 17-bits are used for instruction set encoding. The execution of programs can only be executed from internal program memory. Usable program memory starts from location 800h. The data memory is 640 by 17-bits of static RAM, 16 bits of which are an arithmetic value. The 17th bit is used for flags or tags.

4.2 System Registers

A functional description of each system register is described below.

4.2.1Multiplier Register (MR)

The multiplier uses this 16-bit register to multiply with the multiplicand. MOV instructions are used to load the MR register. The multiplicand is usually the operand of the multiply instructions. All multiply, multiply-accumulate instructions, and filter instructions (FIR, FIRK, COR and CORK) use the MR register (see Section 4.11 for detail).

4.2.2Shift Value Register (SV)

The shift value register is 4-bits wide. For barrel shift instructions, the multiplier operand decodes a 4 bit value in the shift value register (SV) to a 16 bit value. For example, a value of 7H in the SV register is decoded to a multiplier operand of 0000000010000000 binary. In effect, this causes a left shift of 7 bits to in the final 32 bit product. In other words, a nonzero value, say k (0 ≤ k ≤ 15), in the SV register means padding k number of zeros to the right of the final result.

4.2.3Data Pointer Register (DP)

The data pointer register (DP) is a 16-bit register that is used to point to a program memory location for various look up table instructions. DP is not directly loaded by the user, It is loaded during the execution of lookup instructions overwriting the previous content of the DP register. Lookup instructions are described in detail in section 4.9. The DP register auto- increments the next logical program memory location after the execution of a lookup instruction. In addition to lookup instructions, the filter instructions FIRK and CORK (see Section 4.11 for detail) use the DP pointer to look up filter coefficients. It may be required to context save and restore the DP in interrupt service routines.

4.2.4Program Counter (PC)

The program counter (PC) holds the program memory location to be used for the next instruction's execution. It increments (by 1 for single word instructions

4-2

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.

Texas Instruments MSP50C614 manual Introduction, System Registers

Models: MSP50C614