Diferență între revizuiri ale paginii „Applications 4”

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Linia 69: Linia 69:
 
To display the ASCII values on the waveforms in simulation, right-click the name of the variable in the Simulation panel and select from the pop-up menu '''radix''' -> '''ASCII'''
 
To display the ASCII values on the waveforms in simulation, right-click the name of the variable in the Simulation panel and select from the pop-up menu '''radix''' -> '''ASCII'''
  
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== <span id="transcoder">Exercise 1</span> ==
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== <span id="transcoder">Exercise 2</span> ==
  
 
Make a 7-segment display transcoder using a '''case''' block that displays values ​​from 0 to 9. The input of the module will be called '''value''' and the output '''seg'''.
 
Make a 7-segment display transcoder using a '''case''' block that displays values ​​from 0 to 9. The input of the module will be called '''value''' and the output '''seg'''.
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| <syntaxhighlight lang="Verilog" inline>8'b0000_0011</syntaxhighlight> || when there are too many bits, the underline, '''_''' may be used to split bits into smaller groups
 
| <syntaxhighlight lang="Verilog" inline>8'b0000_0011</syntaxhighlight> || when there are too many bits, the underline, '''_''' may be used to split bits into smaller groups
 
|}
 
|}
 
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Open the ''transcoder'' VPL activity on Moodle, upload the source file of the transcoder, run the test and check the results. In case of errors fix the design and retry. After you get TEST PASS on Moodle, proceed to implementation.
 
Open the ''transcoder'' VPL activity on Moodle, upload the source file of the transcoder, run the test and check the results. In case of errors fix the design and retry. After you get TEST PASS on Moodle, proceed to implementation.
  
Test the transcoder by connecting its 4 bit input to SW[3], SW[2], SW[1] and SW[0], and displaying the output on a 7-segment display, the right digit (Digit0) of DE1-SOC display.
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Test the transcoder by connecting its 4 bit input to BTN[3], BTN[2], BTN[1] and BTN[0], and displaying the output on a 7-segment display, the right digit (Digit0) of PMOD-SSD <!--(DE1-SOC for)--> display.
  
 
'''Coding style:'''
 
'''Coding style:'''
 
* '''case''' statements should always include the '''default''' case.
 
* '''case''' statements should always include the '''default''' case.
  
== Exercise 2 ==
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The transcoder may be extended to show hexadecimal digits greater than 9. Use the most common 7-segment symbols for them:
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[[Fișier: letters.png]]
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== Exercise 3 ==
  
 
Implement a 3 bit adder whose result is displayed as a hexadecimal digit.
 
Implement a 3 bit adder whose result is displayed as a hexadecimal digit.

Versiunea de la data 18 aprilie 2022 06:29

Exercise 1

Caesar cipher

The Caesar cipher is the simplest substitution cipher. A plain text message is encrypted by replacing each letter from the message by another one that is some fixed number of positions down the alphabet. All letters of the alphabet are changed using the same fixed number of positions. The letters are “shifted” down the alphabet, this code being also named shift cipher. In this exercise and the following ones, we assume that the plain and encoded messages contain only ASCII uppercase letters A to Z, without blank spaces between words. The encryption is done such that A-Z set of letters are translated to letters from the same set A-Z. For example, if the shift is of 3 positions down the alphabet, A translates to D, B to E, C to F, a.s.o. To achieve the circularity of the encoding, W translates to Z, X to A, Y to B and Z to C.

Dic lab4 cipher shift.png

ASCII code

The ASCII code is the widest used character encoding standard in digital technology. Originally limited to 7 bits it usually uses 8 bits to code for the Latin alphabet letters, uppercase and lowercase, digits, punctuation marks, some special symbols, and some commands. We need to know the ASCII codes for the uppercase letters of the alphabet:

Letter A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
hex code 41 42 43 44 45 46 47 48 49 4a 4b 4c 4d 4e 4f 50 51 52 53 54 55 56 57 58 59 5a

Caesar encoder

Your goal is to design a configurable Caesar encoder, where the shift is set from the outside. The circuit receives an ASCII letter on data_in input, shifts it by a number of positions given by the key input and outputs the resulting letter as data_out. It is supposed that the input data are restricted to the A-Z ASCII codes and the shift is an unsigned integer no greater than 26 (the length of the alphabet)

Dic lab4 caesar.png

The implementation adds the shift number to the ASCII code of the input letter and corrects the sum such that the output ASCII code is also in the A-Z range of ASCII codes.

assign data_out = data_in + shift > 8'd90 ?
                  data_in + shift - 8'd26 :
                  data_in + shift;

Caesar decoding

The Caesar encrypted message is easy to decode: we need only to shift back all letters to undo the coding. Of course the decoder needs to know the shift number (by the way, the Caesar code may be easily broken by trying for the encrypted message various shifts until a meaningful message is found). To reverse the coding of our Caesar encoder, the decoder uses shift_decode = 26 - shift_code

Dic lab4 caesar tb.png

Testbench

The testbench instantiates two Caesar encoder modules. The first one is the encoder itself, that generates the encoded message. The second instance uses the reversed shift to decode the encrypted message. The shift value (for example 13) may be assigned directly to the shift port of the instance as a literal constant:

caesar encoder (
    .shift (8'd13),
    // other port connections
);

The constant value assigned to an input port is actually a hardwired connection of its bits to the power supply and to the ground.

The testbench generates a sequence of ASCII values for the data_sent input of the encoder. The verilog language allows you to assign to an 8-bit logic variable an ASCII value as a character:

initial begin
    #0 data_sent = "C";
    #1 data_sent = "O";
    #1 data_sent = "M";
    #1 data_sent = "B";
    #1 data_sent = "I";
    #1 data_sent = "N";
    #1 data_sent = "A";
    #1 data_sent = "T";
    #1 data_sent = "I";
    #1 data_sent = "O";
    #1 data_sent = "N";
    #1 data_sent = "A";
    #1 data_sent = "L";
    #1 $stop;
end

To display the ASCII values on the waveforms in simulation, right-click the name of the variable in the Simulation panel and select from the pop-up menu radix -> ASCII


Exercise 2

Make a 7-segment display transcoder using a case block that displays values ​​from 0 to 9. The input of the module will be called value and the output seg.

Segment.png

The output bits would control the segments of a digit display, one bit for each segment. The segment is lit when the corresponding bit is 0, otherwise it is off (negative logic).

Digits.png

For all numbers greater than 9 the digit must be off. All these 6 cases may be covered in a single assignment under the default case.

Because seg values are easier to handle in binary, the assigned values for seg should be given as binary constants. A number in binary format (or a combination of bit values) must be preceded by the base specificator, 'b, according to the template numberOfBits'bvalue as in the following examples:

8'b11 3, in binary format on 8 bits
8'b00000011 3, in binary format on 8 bits. Leading zeros are explicitly written
8'b0000_0011 when there are too many bits, the underline, _ may be used to split bits into smaller groups
display.

Coding style:

  • case statements should always include the default case.

The transcoder may be extended to show hexadecimal digits greater than 9. Use the most common 7-segment symbols for them:

Letters.png