Project 2: Double Sevens
Purpose: to give you more experience with digital design components.
- Create a circuit that takes in four bits and drives a 7 segment display for the hexadecimal characters 0-9,A-F. Make sure you differentiate the 6 and the b. You can use either gate-level design or VHDL for this circuit. VHDL is recommended.
Demonstrate the 7-segment driver circuit using an 8-bit counter that
drives two seven segment displays. This will require you to include
your 7-segment display driver into your top level design. Download
this circuit onto the board. To see the numbers, you may want to
use a 24- or 30-bit counter and use the highest 8-bits for
Test this circuit using the board. Don't worry about testing using ghdl.
Take a screen capture of your circuits and be prepared to demonstrate the circuit at the beginning of the next lab.
Using either VHDL or graphic design, create a circuit that takes in
two 4-bit unsigned binary numbers and outputs their sum as a 5-bit binary
number. If you use the graphic design tool, you are free to use
standard design elements from the Altera library. If you use VHDL,
make use of the ieee.numeric_std.all package and make your inputs the
Use the 8 switches on the board to control the two inputs. Display the output on the board's 7-segment display as two hexadecimal digits. Note that the most significant digit will always be a 0 or 1, since the output of the circuit is only a 5-bit number.
Note that you will probably want to convert the two 4-bit inputs into 5-bit signals prior to executing the addition in VHDL. Then the result of the addition is a 5-bit signal you can assign to the output signal variable. The concatenation operator in VHDL is the ampersand: &. The following expression concatenates the bit '1' with the bit string "0010". The result would be the bit string "10010".
'1 & "0010"
Given two vector signals A and B that are type UNSIGNED (3 downto 0), you would add them as 5-bit numbers and assign them to a signal UNSIGNED (4 downto 0) using the following signal assignment statement.
C <= ('0' & A) + ('0' & B);
Test your final circuit. You can use either the board or GHDL. Make sure you describe your testing procedure in your project report.
- If you want practice with Karnaugh maps, do the first circuit as an optimized gate-level design.
- Create a circuit that takes in an 8-bit binary integer and returns three 4-bit values that represent the appropriate decimal representation. For example, the input 10100011 (hex A3) would return as 0001 0110 0011 (163 decimal).
- Add functionality to your second circuit so it can execute operations other than addition. Use the push buttons to control the operation.
- Make creative use of the board's inputs/outputs.
Create a wiki page with your writeup. For each task, write a short description of the task, in your own words.
- Include a picture of your final design.
- Include a picture of your simulation, if this is reasonable
- Describe the hardware testing you undertook to prove the circuit works.
- Include a description, and pictures, of any extensions.
- Please supply a list of people you worked with, including TAs, and professors. Include in that list anyone whose code you may have seen, such as those of friends who have taken the course in a previous semester.
Give your wiki page the label cs232f16project2.
Put your bdf/VHDL files in a folder called project2 in your private subdirectory on Courses/COMP/CS232.