1. Serial Communication Interface (SCI) Kevin Stuart Matt Betts March 27, 2007 ME 6405, Sp 07

2. Types of communication 2 main types Serial Telegraph Light Signal Parallel ISDN line Factory line

3. Serial Communication One line of communication, long string of data Time Signal

4. Parallel Communication Many lines of communication, synchronized bursts of data Time TransmitterReceiver

5. Endianness, how it relates to communication Big Endian- MSB first, less significant bytes in descending order Little Endian- MSB last, data in ascending order Endian type determines how the data is interpreted, and how it should be sent in both serial and parallel communication.

6. RS232, SCI, and SPI RS232- Typical computer COM port SCI- Serial Communication interface, uses the universal asynchronous receiver/transmitter or UART SPI Serial peripheral interface, part of Port D.

7. Cable Length / Data Transfer Rate Relation As cable lengths increase, signal quality degrades As data transfer speed increases, signal quality degrades much faster for increasing length

8. Synchronous Communication Clock speed determines the data transfer rate Transmitter and receiver use the same clock to keep signal cohesive. Constantly sending data to maintain clock synchronization, including idle characters.

9. Asynchronous Communication Transmitter and receiver operate independently No synchronization So no idle characters HC11 uses this type of communication

10. Bit Rate Number of possible on/off switches per second, based on the clock. Faster clock, faster bit rate Standard bit rates Some typical bit rates

11. Baud Rate Number of actual data bits per second Different from Bit Rate because of required setup bits per word transmitted. Setup bits explained more later

12. HC11 SCI registers 5 major registers BAUD$102B SCCR1$102C SCCR2$102D SCSR$102E SCDR$102F

13. BAUD 0 BAUD register, sets speed TCLR : Clear baud rate timing chain bit SCP : Baud rate pre-scale select bits RCKB : Baud rate clock test bit SCR : SCI baud rate select bits 1234567 Read: 00 Write:TCLRRCKB SCR1SCR0SCP00SCP1SCR2

14. SCCR1 SCCR1 : Serial Communication Interface Control Register 1 R8 : Receive data bit 8 T8 : Transmit data bit 8 M : SCI character length bit WAKE : Wakeup method select bit Bits 0 - 2 & 5 are not used (always 0) 01234567 Read: Write: R8 T8MWake 0000

15. SCCR2 SCCR2 : Serial Communication Control Register 2 TIE : Transmit interrupt enable bit TCIE : Transmit complete interrupt enable bit RIE : Receive interrupt enable bit ILIE : Idle-line interrupt enable bit TE : Transmit enable bit RE : Receive enable bit RWU : Receiver wakeup bit SBK : Send break bit 01234567 Read: Write: RWUSBKTIETETCIERIEILIERE

16. SCSR SCI status register TDRE : Transmit data register empty bit TC : Transmit complete bit RDRF : Receive data register full bit IDLE : Idle-line detect bit OR : Overrun error bit NF : Noise flag FE : Framing Error bit Bit 0 is not used (always 0) 01234567 Read: Write: TDRETCRDRFIDLEORNFFE0

17. SCDR SCI data register Two separate registers, same address Used to Read the Received data Used to Write the Transmit data R7 - R0 – Read bits T7 - T0 – Write bits 01234567 Read: Write: R7R6R5R4R3R2R1R0 T7T6T5T4T3T2T1T0

18. SPCR Serial Peripheral Interface Control Register SPIE- Serial Peripheral Interrupt Enable 0 = SPI Interrupts disabled 1 = SPI Interrupts enabled Serial Peripheral System Enable 0 = SPI off 1 = SPI on DWOM – Port D Wired OR mode Option for Port D pins (PD 5:0) 0 = Normal CMOS outputs (Leave it as 0) 1 = Open Drain outputs 01234567 Read: Write: SPIESPEDWOMMSTRCPHASPR1SPR0CPOL

19. How to set up Serial Communication on the HC11 Set Baud rate using BAUD Set interrupt states using SCCR2 Set data length using SCCR1 Make / Set routines to be jumped to when interrupt is triggered Read or Write data to the SCDR Note- Data direction register is overridden by SCI logic

20. UART (Universal Asynchronous Receiver/Transmitter) Beforehand Knowledge Need to know Transmitting speed (and therefore Receiving speed) Need to know packet construction (# data and formatting bits) Packet Construction: Start Bit (1 bit) Data Bits (8-9 bits) Parity Bit (1 bit) …optional Address Marker (1 bit) …optional Stop Bit (1 bit) Challenge: Noise

21. UART: Start Bit 1 Bit (at beginning of message) Only used due to asynchronous nature (synchronous Transmitters/Receivers don’t need start/stop bits) Opposite polarity of data-line’s idle state Idle state for HC11 = all 1’s  start bit = 0

22. UART: Data Bits 8-9 Bits (in middle of message) Most common mode = 8 data bits (SCCR1, M = 0) Alternative mode = 9 data bits (SCCR1, M = 1) Can be used for parity Can be used as an address marker (in “address-mark variation”)  telling a microprocessor when to sleep or wake up LSB first

23. UART: Parity Bit (optional) 1 Bit Located at end of data bits (It is one of the data bits.) Even Parity Parity bit = 1, if # of ones in the set is odd (you make total # even) Odd Parity Some say more reliable (guarantees at least one data transition) Parity bit = 1, if # of ones in the set is even (you make total # odd) Note: Parity can be implemented with 8 Data Bits when transmitting ASCII characters (since ASCII is represented with only 7 bits).

24. UART: Stop Bit 1 bit (at end of message) Only used due to asynchronous nature (synchronous Transmitters/Receivers don’t need start/stop bits) It is the polarity of data-line’s idle state Idle state for HC11 = all 1’s  stop bit = 1

25. Ex: Packet Format

26. Ex: Packet Format-ASCII character ‘H’ (without parity)

27. Ex: Packet Format-ASCII character ‘H’ (with even parity and odd parity)

28. Ex: Packet Format-ASCII character ‘l’ (with odd parity)

29. Ex: Packet Format-ASCII character ‘EOT’ (with odd parity)

30. UART: Noise Problem: A premature ‘1’ or ‘0’ can make the HC11 Receiver think that it’s receiving data before it really is or that it’s receiving incorrect data. One Solution: HC11 takes 3 samples near the middle of each bit time  majority decision Another Solution: Break Command (= all 0’s for >=1 character time, for HC11) Used to get attention of Receiver (i.e. change to default rate)

31. Ex: Full Transmission Format (idle line)EOT!olleH(idle line) H = 0x48 = 0b1001000 e = 0x65 = 0b1100101 l = 0x6C = 0b1101100 o = 0x6F = 0b1101111 ! = 0x21 = 0b0100001 EOT = 0x04 = 0b0000100 Packet composition = Start Bit + 9 Data Bits [+ Parity Bit (odd parity scheme) as last Data Bit] + Stop Bit Note: 9 Data Bit transmission was used (instead of 8) so that the receiver doesn’t store the parity bit in the SCDR register. (You can directly store SCDR [the ASCII values] to memory without having to take off the parity bit.)

32. Advanced Features of HC11 UART HC11 resynchronizes the Receiver’s bit clock on all 1-to-0 transitions (instead of just on startup) HC11 takes 3 logic-samples near the middle of each bit time (majority rules) HC11’s Receiver can enter a standby mode (“sleep mode”) HC11 has a TC (Transmit Complete) Flag …in addition to the standard TDRE (Transmit Data Register Empty) Flag.

33. References: M68HC11ERG/AD Reference Guide (Rev. 2, 10/2003) M68HC11 Reference Manual (Rev. 4, 2001) Section 9: p.317-366 Wikipedia.org: Asynchronous Serial Communication, UART, Parity (Used to get a fundamental understanding.)