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EET 2261 Unit 11 Serial Communications Interface  Read Almy, Chapter 24.  Homework #11 and Lab #11 due next week.  Quiz next week.

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Presentation on theme: "EET 2261 Unit 11 Serial Communications Interface  Read Almy, Chapter 24.  Homework #11 and Lab #11 due next week.  Quiz next week."— Presentation transcript:

1 EET 2261 Unit 11 Serial Communications Interface  Read Almy, Chapter 24.  Homework #11 and Lab #11 due next week.  Quiz next week.

2 We’ve used the HCS12’s general-purpose I/O ports (Ports A, B, E,…) to communicate with simple devices, such as switches and LEDs, that use standard TTL-level signals (  0 V for LOW and  5 V for HIGH). In addition to this low-tech form of communication, our HCS12 contains several blocks that implement more complicated communication bus standards. Communicating with External Devices

3 The HCS12 has two asynchronous serial communications interface blocks named SCI0 & SCI1. Each SCI block has two I/O pins: RXD for receiving data, TXD for transmitting data. These pins are shared with the general-purpose I/O port S. Figure from p. 6 of textbook or page 23 of Device User Guide).Device User Guide Serial Communications Interface (SCI) Blocks on the HCS12

4 The board has movable jumpers that let us reconfigure the board’s communication resources for different needs. But we’ll leave these jumpers alone. SCI0 and SCI1 on the Dragon12 On the Dragon12 board: The HCS12’s SCI0 is normally connected to the board’s USB port, through which the chip communicates with CodeWarrior on the personal computer. The HCS12’s SCI1 is normally connected to the RS232 interface.

5 Block Diagram of Serial Communications Interface (SCI) Block Diagram from page 12 of the SCI Block User Guide. SCI Block User Guide Remember: there are two separate copies of this circuit on our HCS12 chip. One is called SCI0, and the other is SCI1. We’ll use SCI1.

6 Special-Function Registers Associated with the SCI Block The 8 special-function registers located at addresses $00C8 to $00CF let us control the operation of the SCI0 block. The 8 registers at addresses $00D0 to $00D7 are for the SCI1 block. See p. 37 of Device User Guide.Device User Guide

7 SCI Baud Rate Registers (SCInBDH and SCnIBDL) SCInBDH and SCnIBDL combined hold 16 bits, of which 13 form a number called SBR. The SCI’s baud rate depends on SBR and the system’s bus clock frequency, as follows: Baud rate = Bus clock freq / (16 × SBR) Figure from p. 5 of SCI Block User Guide.SCI Block User Guide

8 Possible Baud Rates As stated on the previous slide, the SCI’s baud rate is given by Baud rate = Bus clock freq / (16 × SBR) where SBR is a 13-bit number. So it’s usually not possible to set the baud rate exactly to one of the standard values used by other communications devices (such as 300, 600, 1200, 2400, 4800, 9600, 19200). But usually we can get close enough for communication to take place successfully.

9 SCI Data Registers (SCInDRH and SCInDRL) The SCInDRH and SCInDRL registers hold the data that is being either transmitted or received. For 8-bit data (the most common situation), only SCInDRL is used. Figure from p. 11 of SCI Block User Guide.SCI Block User Guide

10 SCIn Control Register 1 (SCInCR1) The bits we care most about in this control register are: M, which we use to specify whether we’re working with 8-bit or 9-bit data. PE, which we use to enable or disable parity generation/checking. PT, which (if parity is enabled) we use to specify whether even or odd parity is used. Figure from p. 6 of SCI Block User Guide.SCI Block User Guide

11 SCIn Control Register 2 (SCInCR2) The bits we care most about in this control register are: TE, which we use to enable or disable data transmission. RE, which we use to enable or disable data reception. Figure from p. 7 of SCI Block User Guide.SCI Block User Guide

12 SCIn Status Register 1 (SCInSR1) The bits we care most about in this status register are: TDRE, which tells us whether the transmission data register is empty. RDRF, which tells us whether the receive data register is full. Figure from p. 8 of SCI Block User Guide.SCI Block User Guide

13 Steps for Transmitting Data Programming the SCI to transmit data (without using interrupts): 1.Set baud rate using SCInBDH:SCInBDL registers. 2.Write $00 to SCInCR1 register, indicating 8-bit data frame, no parity bit. 3.Write $08 to SCInCR2 register to enable transmission, also disabling interrupts. 4.Monitor the TDRE bit of the SCInSR1 register to make sure data register is empty before sending a byte to SCInDRL. If TDRE = 1, then go to the next step. 5.Write the byte to be transmitted to SCInDRL. 6.To transfer another byte, go to Step 4.

14 Steps for Receiving Data Programming the SCI to receive data (without using interrupts): 1.Set baud rate using SCInBDH:SCInBDL registers. 2.Write $00 to SCInCR1 register, indicating 8-bit data frame, no parity bit. 3.Write $04 to SCInCR2 register to enable reception, also disabling interrupts. 4.Monitor the RDRF bit of the SCInSR1 register to see if an entire byte has been received. If RDRF = 1, then go to the next step. 5.Read the received byte from SCInDRL. 6.To receive another byte, go to Step 4.

15 The two previous slides assumed that we’re not using interrupts. Without interrupts, our program will sit in a loop, polling the TDRE bit (or the RDRF bit) repeatedly until it is set, at which point the program proceeds to take some other action: Over: BRCLR SCI1SR1, %10000000, Over Another way is to use interrupts instead of repeatedly polling the TDRE bit (or the RDRF bit). Polling Versus Interrupts for Serial Communications

16 Each SCI module has its own interrupt, which can be caused by either the receive data register being full or the transmit data register being empty: Enabled or disabled by TIE and RIE in SCInCR2 : We’re familiar with the TDRE and RDRF flag bits in SCInSR1: Serial Communications Interface (SCI) Interrupt

17 In the interrupt vector table, the two words starting at $FFD6 and $FFD4 are reserved for the starting addresses of the service routines for SCI0 and SCI1 interrupts, respectively. Remember: the programmer is responsible for setting up correct addresses in the vector table. Interrupt Vectors for SCIn Interrupts From table on page 75 of the Device User Guide.Device User Guide

18 A Microsoft Windows accessory program named HyperTerminal lets you send or receive data over your computer’s RS-232 port. Shown here is a dialog box for configuring HyperTerminal. Microsoft HyperTerminal

19 In previous weeks we used the HCS12’s general-purpose I/O ports (Ports A, B, E,…) to communicate with simple devices, such as switches and LEDs, that use standard TTL- level signals (  0 V for LOW and  5 V for HIGH). In addition to this low-tech form of communication, our HCS12 contains many blocks that implement more complicated communication bus standards. Review: Communicating with External Devices

20 These blocks include: Two serial communications interface (SCI) blocks. Three serial peripheral interface (SPI) blocks. Two controller area network (CAN) blocks. One inter-integrated circuit (IIC) block. Figure from p. 6 of textbook or page 23 of Device User Guide).Device User Guide Communication Blocks in the HCS12

21 Sometimes the term bus simply refers to a group of conductors (wires or circuit board traces) that carry signals from one device to another. Examples: address bus, data bus At other times it refers to a standard set of specifications (voltage levels, timing specs, connectors, etc.) used for communication between devices. Examples: RS-232, SPI, USB Two Meanings of “Bus”

22 There are dozens of bus standards in common use. From Wikipedia’s article on the USB bus: Many Bus Standards

23 We’ll Focus on the SCI Blocks With all of these HCS12 blocks and bus standards, this is a large and complex topic. We’ll restrict our attention the HCS12’s SCI blocks (Chapter 24). If you’re interested in the SPI blocks, see Chapter 25. For the IIC block, see Chapter 26.

24 Some bus standards apply to serial communication (1 data bit transferred at a time). Others apply to parallel communication (several data bits—usually 8—transferred at a time). Terminology: Serial vs. Parallel

25 These are two common measures of speed in communications. Many writers loosely treat these as being synonyms, but this is not strictly correct. Bits per second (bps) is the easier to understand. Often expressed as kbps or Mbps. In the simplest cases, baud rate equals bps. In more sophisticated schemes, the two are related but not equal. Traditional baud rates are 300, 600, 1200, 2400, 4800, 9600, 19200. Terminology: Bits per Second and Baud Rate

26 Simplex: Information flows in one direction only. Example: a temperature sensor sending data to a personal computer. Half-duplex: Information can flow in both directions, but only one at a time. Example: walkie-talkie. Full-duplex: Information can flow in both directions at the same time. Example: telephone. Terminology: Simplex vs. Duplex

27 In asynchronous communication, the two devices do not share clock signals, so they use “handshaking” signals or some other method to coordinate their activity. Widely used serial asynchronous standards: RS-232 RS-423 RS-422 RS-485 USB (Universal Serial Bus): can operate synchronously or asynchronously.USB (Universal Serial Bus) Communications Terminology: Asynchronous vs. Synchronous

28 In synchronous communication, the sender and receiver share a clock signal. Widely used serial synchronous standards: SPI (“four-wire,” or “three-wire” variant)SPI IIC or I 2 C (also called “two-wire”)IIC 1-wire Communications Terminology: Asynchronous vs. Synchronous

29 Ports on a Typical Laptop Computer USB (Serial) IEEE 1394 (Serial) RS-232 (Serial) Printer (Parallel) PS/2 Mouse (Serial) VGA (Analog video)

30 Ports on a Fluke 45 DMM RS-232 (Serial) IEEE 488 (“GPIB”) option not installed (Parallel)

31 The terms “mark” and “space” are old terms from the days of telegraphs. These terms are still often used when discussing serial communication. Mark simply means a binary 1 level on the serial line. (When no data is being transmitted, the line sits high, and we are “marking time.”) Space simply means a binary 0 level on the line. Communications Terminology: Mark and Space

32 Asynchronous communication standards such as RS232 generally use start bits and stop bits at the beginning and end of a transmitted byte. The start bit is binary 0. The stop bits—there may be one or two—are binary 1. These bits are not part of the data being transmitted. They form a “frame” around the data. Communications Terminology: Start Bits, Stop Bits Figure from page 229 of the textbook.

33 Parity is an error-checking system that attaches an extra bit (called the parity bit) to a byte when the byte is transmitted. When we configure a serial device, we often have the choice of using odd parity, even parity, or no parity. Communications Terminology: Parity Bits Figure from page 229 of the textbook. As shown here, we transmit the data byte’s LSB first.

34 First version created in early 1960’s. Obsolete in some respects, but still very widely used. In recent years, has been applied in ways that its original creators never imagined, sometimes leading to problems. Original spec defined 25 pins (signals), but often only 9 or fewer are used. RS-232 Standard

35 In any RS-232 application, each device is designated as either Data Terminal Equipment (DTE) or Data Communications Equipment (DCE). Simple case: When you connect a personal computer to a modem, the computer is the DTE and the modem is the DCE. Terminology: DCE vs DTE

36 Original RS-232 standard called for a DB-25 connector. Since many later applications didn’t use most of the pins, it became common to use DE-9 connectors (often incorrectly referred to as DB-9). Connectors

37 The nine most important signals: RS-232 Signals DescriptionAbbrev.Direction DTE - DCE DB-25 Pin # DE-9 Pin # Transmitted dataTxD  23 Received dataRxD  32 Request to sendRTS  47 Clear to sendCTS  58 Signal Ground75 Protective Ground1 Data set ReadyDSR  66 Data carrier detectDCD  81 Data terminal readyDTR  204

38 As we’ve seen, the original RS-232 standard defines 25 lines, but most applications make do with far fewer than 25—usually 9 or even less. With the HCS12’s Serial Communications Interface, we use only three lines: RxD, TxD, and Signal Ground. So we’re not using any of the handshaking lines (such as CTS, RTS, DSR, DTR). As a result, data can be lost if the sender transmits data when the receiver is not ready to receive it. HCS12 Uses a Scaled-Down RS- 232 Interface

39 TTL voltage levels are:  0 V for a binary 0.  +5 V for a binary 1. This scheme is “unipolar” because it doesn’t use negative voltages. For transmission over a cable, it’s undesirable to have either logic level close to 0 V. So RS-232 uses a “bipolar” scheme, with: +3 V to +25 V for a binary 0 (“space”) -3 V to -25 V for a binary 1 (“mark”) RS-232 Voltage Levels

40 Since TTL voltage levels are incompatible with RS-232 voltage levels, many digital systems need to translate from one to the other. A popular chip for this purpose is Maxim’s MAX232A. MAX232A MAX232 Chip

41 The Dragon12 board contains an RS-232 interface, which consists of a MAX232A chip and a DE9 connector. See the Dragon12 Schematic Diagram 3.Schematic Diagram 3 RS-232 on the Dragon12


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