ECE 371 Unit 13 - Part 1
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Transcript of ECE 371 Unit 13 - Part 1
ECE 371 Unit 13 - Part 1
Serial Peripheral Interface (SPI)
Serial Peripheral Interface
• Synchronous Serial Interface
• Widely used to interface Peripheral Chips with Microcontrollers
• Much faster bit rate than asynchronous SCI method.
• SPI system consist of one Master Device and one or more Slave Devices
• Master Device sends out a Serial Shift Clock signal (SCK) to all slaves, to serve as timing reference for the serial data transfer.
• No Start Bits or Stop Bits as used in SCI (asynchronous serial I/O method)
• 3 SPI Channels on MC9S12Dp256B Microcontroller
• 4 Pins Associated with Each SPI Channel
- MISO (Serial input data for a Master, serial output data for a Slave)
- MOSI ((Serial output data for a Master, serial input data for a Slave)
- SCK (Serial data clock)
- SS (Slave select; for a system with a single slave, SS = 0 selects the Slave and SS = 1 selects the Master.
Master/Slave SPI Interface
Parallel-to-Serial and Serial to Parallel-to-Serial Registers are needed to interface a peripheral device to the microcontroller using the SPI protocol.
• 74HC 595 - Serial-to-Parallel Converter Register
- Serial Input
- Parallel Output
- (Also serial output)
• 74HC 597 - Parallel-to Serial Converter Register
- Parallel Input
- Serial Output
- (Also Serial Input)
74HC595 8-bit Shift Register(Serial to parallel converter)
Serial input
Parallel output
Serial output
74HC595 8-bit Shift Register and 8-bit Storage
Serial input
ParallelOutput
Serial Output
SPI Connections between the Microcontroller and a 74HC595 Register to implement an Output
Port
MOSI DS (Serial Data Input for 74HC595)
SCK SH_CP (“Shift” Clock Pulse)
SS ST_CP (Store Shift Register Data into Latch)
OE = “0” (Enable Latch Output Bus Drivers)
MR = “1” -- (Master Reset not active)
Microcontroller signal 74HC595 pin
D7 D6 D5 D4 D3 D2 D1 D0
MOSI – Shifted into Shift Register
SCLK
SYNC or SS
Clock Latches
74HC595 8-bit Shift Registerwith Output Latches
SYNC PULSE Transfer Shift Register Data to Data Latches when SYNC Pulse occursSet Flag to Signal that there is Received Data in Data Latches
Shift Data into Shift Register
Shift Data intoShift Register
SPI Overview
Slave – 74HC595
SerialDataOut
SS SCLK
Load Reset Serial Data In
74HC597 – 8 bit Parallel InSerial Out
ParallelInput
SP Slave – 74HC597
LCLK = Load Parallel FF
SPI1 and SPI2 can be implemented on Port P or Port H
SPI1 signals
If MODRR[5]=0
SPI2 signals
If MODRR[6]=0
SPI1 signals
If MODRR[5]=1
SPI2 signals
If MODRR[6]=1
SPI0 can be implemented on Port M or Port S
SPI0 signals if
MODRR[4]=0
SPI0 signals if
MODRR[4]=1
Module Routing Register
SPI Channel 0 Routing
SPI Channel 1 and 2 Routing
Use MODRR[5] = 0 and MODRR[6] = 0
SPI Channel 1
• If SPI pin is output, then DDRx must set pin as out.
• SPI1 uses Port P on our System:– PP0 – MISO1 – In– PP1 – MOSI1 – Out– PP2 – SCK1 – Out– PP3 - SS1 – Out
SPI Register Designations
• SPI1CR1, SPI1CR2, SPI1SR, SPI1DR, SPI1BR, DDRM, PTM, DDRP, PTP
• Laboratory– Port M is Used to Select 1 of 8 SPI Serial
Devices on Project Board– Port S Shares Pins with SPI Channel 0
Project Board Laboratory
• 8 SPI Devices on Project Board
• Port M [6:4] Selects SPI Device– PM[4] = SS0– PM[5] = SS1– PM[6] = SS2
• D/A Converter is Device 5,
(SS2 SS1 SS0 = 1 0 1)
• SPI Slaves Implemented with 74HC595
Slave Selection – 8 Slaves on Project Board
PM[4] => SS0PM[5] => SS1PM[6] => SS2
SS = PP[3]SS => S5
SER_DIS = “1”
Connected to gnd by jumper
SPI Channel 1 – SPI1
• Port P[0] = MISO
• Port P[1] = MOSI
• Port P[2] = SCK
• Port P[3] = SS
SPI Channel 1 Definitions
#define SPI1CR1 _P(0xF0)#define SPI1CR2 _P(0xF1)#define SPI1BR _P(0xF2) #define SPI1SR _P(0xF3)#define SPI1DR _P(0xF5)
SPI Data Register
SPI Baud Rate Register
Baud = BusClock/BaudRateDivisor = 2000000/BaudRateDivisor
SPI Control Register 1
SPI Control Register 1
SPI Control Register 1
SPI Control Register 2