Difference between revisions of "CSC270 Homework 8 2011"

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(Problem #1)
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;Question 2
 
;Question 2
: Implement the FSM.  Show its state diagram.  Be careful that the FSM has 2 input signals, so that 4 arrows should leave every state.  Figure out the number of states, the number of flipflops required to implement it, and the equations of the D inputs as a function of the Q outputs.
+
: Implement the FSM.  Show its state diagram.  Be careful that the FSM has 2 input signals, so that 4 arrows should leave every state.  Figure out the number of states, the number of flipflops required to implement it, and the equations of the D inputs as a function of the Q outputs. What signal should we use for the clock signal?
  
  

Revision as of 19:22, 13 April 2011

--D. Thiebaut 15:59, 13 April 2011 (EDT)


Page under construction!
UnderConstruction.jpg

Problem #1

We covered the Handshake Protocole in class, where the computer activates a signal called strobe (STB) and the peripheral responds with a signal called acknowledge (ACK).

We wrote a simple program corresponding to the 6811 sending the character 'A' to the peripheral (the printer).

Question 1
Looking at code we wrote, and assuming a very fast printer that absorbs the data bytes as fast as the computer can generate them, what is the maximum speed at which the computer can output bytes to the peripheral? Express the answer in Bytes/sec, KiloBytes/sec, or MegaBytes/sec, whatever is appropriate.


One way to go faster would be to have a sequencer, a finite-state machine, generate the Stobe signal and interact with the peripheral listening to it ACK signal.

The figure below illustrate how the system would be organized.

CSC270 6811 ParallelPort With FSM.png

Here is the way the system would work:

  1. The 6811 picks a character to send to the device (printer) and stores it in the 8-bit register shown as "8 FFs" on the figure. An STAA instruction is used, and in its last cycle, the decoder activates a Yi output which does two things: it loads the character on the data-bus in the 8 flipflops, and it activates the preset of the D flipflop, setting its Q output to 1.
  2. The Q output going to 1 is picked up by the FSM machine which switches state, and now activates the STB signal, indicating to the device that a new byte is available.
  3. The microprocessor now keeps on executing a LDAA instruction which allows a signal generated by the FSM to be loaded in the MSB of Acca. As long as this bit is 0, it means that the device handshake is not over.
  4. The FSM keeps STB high until it sees that the device raises ACK. As long as ACK is not high, the FSM stays in the same state.
  5. As soon as ACK goes high, the FSM switches state and turns STB down.
  6. The FSM keeps on waiting until the device drops ACK
  7. As soon as ACK goes back down, the FSM activates the signal to the 6811 to indicate that the transfer is over.
  8. At the same time it does so, it activates with another signal the CLR (clear) input of the flipflop with the NC clock and data inputs, resetting its Q output to 0.
Question 2
Implement the FSM. Show its state diagram. Be careful that the FSM has 2 input signals, so that 4 arrows should leave every state. Figure out the number of states, the number of flipflops required to implement it, and the equations of the D inputs as a function of the Q outputs. What signal should we use for the clock signal?


Question 3
How much faster can the 6811 send bytes to the device using this new design?