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Lecture 3: TI MSP430 Introduction
ECE 447 Fall 2009 Lecture 3: TI MSP430 Introduction
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ECE447: General Microcontroller Characteristics
Integration of a CPU plus multiple peripherals on a single chip. Low cost for high volume applications. Lower clock frequencies when compared to devices like microprocessors and DSPs. Typical range for microcontrollers: up to 100Mhz. Low power consumption, allowing battery operation. Data/Instruction word sizes from 4-bit to 32-bit Limited memory, typically less than 1 Mbyte. Various I/O pin-out configurations, from low to high (8 to 150 pins).
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ECE 447: Basic Computer System
Parallel I/O Device Serial I/O Device Parallel Data Serial Data Memory Program + Data I/O Interface CPU Data Bus Address Bus Control Bus
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ECE 447: Microprocessor vs. Microcomputer
Microprocessor – A processor unit typically with only basic I/O interface, off-chip memory. e.g.: Intel 8008, 8086, 80486, Pentium, Pentium 4, Core2Duo, PowerPC Single-chip Microcomputer – A processor unit with on-chip memory, I/O devices, and often other peripheral devices such as timers and A to D. e.g.: Intel 8048, Motorola 68HC11/12, TI MSP430
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ECE 447: Microprocessor vs. Microcomputer
Microprocessor – A processor unit typically with only basic I/O interface, off-chip memory. e.g.: Intel 8008, 8086, 80486, Pentium, Pentium 4, Core2Duo, PowerPC Single-chip Microcomputer – A processor unit with on-chip memory, I/O devices, and often other peripheral devices such as timers and A to D. e.g.: Intel 8048, Motorola 68HC11/12, TI MSP430
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ECE 447: Processor Evolution
Early microcroprocessors (8080, 6800, Z80) integration performance General-purpose microprocessors Single-chip microcomputers (e.g., Pentium, Athlon, Power PC) (e.g., MC68HC11, MSP430) - small price - low power consumption - built-in memory - built-in I/O devices - high speed - long word size volume sold x 1 x 10
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ECE 447: Microcontroller Applications
Cars Engine fuel injection Transmission control Suspension and ride control Instrument display Braking system Home Appliances Washing machine Microwave oven Refrigerator Sports Equipment Exercise Machine Heart Rate Monitor
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ECE 447: Microcontroller Applications
Consumer Electronics Digital/Film cameras Remote Controls Televisions CD players Telephone Computer Peripherals Printers Scanners Disk drive controllers Robots The Brains
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ECE 447: Architecture vs. Organization vs. Realization
Architecture: The instruction set and input/output capabilities available to the programmer Organization: The implementation of the architecture in block diagram form Realization: Actual implementation of an organization in a given technology, eg: CMOS High Level of Abstraction LOW
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ECE 447: Acronyms Used CPU - Central Processing Unit
:= ALU (Arithmetic Logic Unit) + Control RAM - Random Access Memory := Read/Write Memory ROM - Read Only Memory (non-volatile) EPROM – Erasable Programmable ROM EEPROM - Electrically Erasable Programmable ROM SPI - Serial Peripheral Interface (synchronous serial communication interface) ADC - analog-to-digital converter DAC – digital-to-analog converter Port –Parallel I/O providing digital data lines (A,B,C,D,E)
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ECE447: MSP430 Microcontroller Characteristics
16 bit RISC CPU: Compact core design reduces power consumption and cost 16-bit data bus 27 core instructions and 7 addressing modes Extensive vectored-interrupt capability On-chip features: Programmable flash memory and SRAM 10/12/16-bit ADC, 12-bit dual DAC Timer capture and comparator systems Operational Amplifiers Watchdog and Supply Voltage Supervisor Communication systems (I2C, SPI)
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ECE 447: MSP430 Block Diagram CPU Central Processing Unit consisting of: Arithmetic logic unit Registers for basic CPU operation General purpose registers for instruction execution results Instruction decoder and other logic to control the CPU Memory for the executable program: Nonvolatile (ROM/FLASH) Memory for data: RAM, usually volatile Input and Output Ports: To interface with outside world Clock: To keep the system synchronized Timers, Watchdog Timers Communication Interfaces Analog to Digital and Digital to Analog Converters Real-time Clock Monitor, background debugger, embedded emulator
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ECE447: MSP430 Microcontroller Characteristics
Low Power Consumption: 0.1 A for RAM data retention 0.8 A for real-time clock mode operation 250 A/MIPS during active operation Less than 50 nA port leakage current Low Voltage Operation Vcc from 1.8V to 3.6V Flexibility and Performance Startup less than 1 sec Instruction processing on bits, bytes, or words Up to 256 kBytes of Flash, up to 25 Mhz Clock Pin-outs from 14 pins up to 100 pins Embedded Debug/Emulation capability (JTAG) Wide Range of Peripherals
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ECE447: MSP430 Outside View Pin-Out (F2013)
Most pins have multiple features (pin multiplexing) Pin limitations should be taken into account when designing a system so that pin conflicts are avoided Larger devices allow more simultaneous I/O functions Some functions are available on many pins (ie: TA0, TA1) First task of a program is to configure the functions of each pin
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ECE447: MSP430 Inside View Functional Block Diagram (F2013)
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ECE447: MSP430 Inside View Functional Block Diagram (F2013)
This portion shows the CPU and its supporting hardware. Basic Clock Subsystem Emulation, JTAG, and Spy-Bi-Wire are used for communication with a host computer for downloading a program and debugging.
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ECE447: MSP430 Central Processing Unit
The MSP430 is a RISC (Reduced Instructions Set Computing) architecture: Instructions set includes: 27 physical instructions; 24 emulated instructions. Designed with static logic, which allows the CPU to be stopped and retain its state until it is restarted. Arithmetic Logic Unit which performs computation. Interconnect by a using a common memory address bus (MAB) and memory data bus (MDB) - Von Neumann architecture. A set of 16 registers designated R0 - R15.
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ECE447: MSP430 Central Processing Unit Register Map
A set of 16 registers designated R0 - R15. PC: Program Counter contains the address of the next instruction to be executed. SP: Stack Pointer to the address of the stack frame. The stack is primarily responsible for storing the return address of subroutine calls. SR: Status Register contains a set of flags The C,Z,N, and V flags provide information from the last arithmetic operation. The GIE flag enables the maskable interrupts. The CPUOFF, OSCOFF, SCG0 and SCG1 flags control the operation of the MCU. Use of these flags allow operation in low power modes. CG1/CG2: Constant Generator provides the six most frequently used values so that they do not need to be fetched from memory.
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ECE447: MSP430 Inside View Functional Block Diagram (F2013)
The main blocks are linked by the memory address bus (MAB) and the memory data bus (MDB) The device has 2kB of flash (1Kb is in the F2003) The device has 128 bytes of RAM The brownout protection comes into action when the supply voltage drop below an operational level.
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ECE447: MSP430 Memory All memory is byte addressable (8-bits) and a byte is the smallest entity that can be transferred to and from memory. The MSP430 memory address bus (MAB) is 16 bit wide so there are 216=65,536= 64K = 0x10000 addresses. The MSP430X (like the F4618) architecture adds four bits to the address bus and CPU register to allow for 220 addresses. The MSP430 memory data bus is 16 bits wide and can transfer either a word of 16 bits or a byte of 8 bits. Bytes can be accessed at any address, but words must be accessed on a word aligned address (an even address value) The MSP430 is a little-endian ordered machine. The low ordered byte is stored at the lower address.
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ECE 447: Area for Single Bit Cell
Assumes 65 nm technology Flash EPROM human hair ROM EPROM FRAM EEPROM RAM 20 0.8 1.1 1.1 1.1 1.6 3.3
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ECE447: MSP430 Memory Map All memory including RAM, Flash, information memory, Special Function Registers (SFRs), and peripheral registers. Starred (*) start and end addresses vary based on the particular MSP430 variant
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ECE447: MSP430 Inside View Functional Block Diagram (F2013)
Six Peripheral function blocks are shown. Many more exist in larger devices such as the F4618 16 bit Sigma Delta ADC Port P1 8 bit I/O Port P2 2 bit I/O Watchdog timer Timer_A2 (2 Compare/Capture Registers) Universal Serial Interface
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ECE 447: I/O Device Architecture
Control registers instructions address1/name1 ….. Status registers status of the device ….. Data registers inputs (operands) ….. addressN/nameN outputs (results)
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ECE 447: Input/Output Register Types
1. Control registers - hold instructions that regulate the operation of internal I/O devices 2. Status registers - indicate the current status of internal I/O devices 3. Data registers - hold the input data sent to the I/O device and output data generated by this device 4. Data direction registers - control the direction (in or out) of the data flow to/from bidirectional data registers
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ECE 447: I/O Addressing Schemes
Memory mapped I/O Separate I/O (Same Instructions) (Different Instructions) (e.g., Intel) (e.g., Motorola, TI) I/O max I/O MAX MAX Control lines: read/write memory/io Control lines: read/write
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ECE447: MSP430 Memory-Mapped Input and Output
Digital Input and Output are arranged on a set of pins and grouped in ports. The MSP430 designates ports by number (P1, P2,…) Pins can be configured as inputs or outputs Internally, I/O ports appear as memory register (peripheral register) Each port is associated with a byte. Each bit in the byte corresponds to a specific I/O pin. Each register can be read, written, and modified.
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ECE447: MSP430 Memory-Mapped Input and Output
Each port has several registers that are used to read, write, and configure it. Port P1 has 8 registers, three are the most important: Port P1 input, P1IN: Reading this returns the logical values on the P1 pins if they are configure for digital input and output. Port P1 output, P1OUT: Writing to this register sends the value to be driven onto the port output pins if it is configured as a digital output. Port P1 direction, P1DIR: A bit of 0 configures the corresponding pin as an input, which is the power-on default. Writing a 1 switches the pin to an output. Discuss Example 2.3 from Davies: Why is it useful to provide separate register for input and output? Many microcontrollers have only one.
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ECE447: MSP430 Additional Resources
Resources for students working with the MSP430 MSP430 device Data Sheet The data sheet contains a wealth of information including device specific information. MPS430 Family Users Guide Provides a detailed description of all the functional modules within the family. Register descriptions with bit details and reset values. FET User’s Guide (Flash Emulation Tool) A good FAQ on hardware, software development, and debugging. Application Notes TI has published over 100 ANs for the MSP430, from very general topics to very specific. Code Examples TI also has many code examples for the MPS430 available. Discuss Example 2.3 from Davies: Why is it useful to provide separate register for input and output? Many microcontrollers have only one.
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