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Getting the first design to work is always the hardest.
Aim of project
To wire two switches up to the LEDs.
- Create a new project
- Create a new VHDL module
- Enter basic code
- Implement the design
- Create an implementation constraints file
- Try the programming tools
- Test the design in hardware
- Build experience single wire inputs and outputs
Wow! That is a lot of learning for a second module
Step 1 - Create a new Project
- Click on "Xilinx ISE Design Suite 13.3" Studio Icon - From the "File" menu, choose "New Project" - Name the project "Switches+LEDs", and click on "Next".
- This screen is where you say what FPGA you are using. Choose the following settings to tell the design tools what chip you are using, then press the "Next" button.
- Click on the "Finish" button to create and open the new project
Step 2 - Create a new VHDL Module
- Right-click on the design window, on the FPGA device, and choose "New Source"
- Highlight "VHDL module" and in the file name enter "Switches_LEDs", then press the "Next button". - This next dialog box allows you to define what connections the module has. We need four connections - two the the switches and two for the LEDs:
- Click the "Next" button, then "Finish" to create the module and open it in the editor. To make things clearer, delete any line that starts with "--" - they are comments that do not influence the design.
1: library IEEE; 2: use IEEE.STD_LOGIC_1164.ALL; 3: 4: entity Switches_LEDs is 5: Port ( switch_0 : in STD_LOGIC; 6: switch_1 : in STD_LOGIC; 7: LED_0 : out STD_LOGIC; 8: LED_1 : out STD_LOGIC); 9: end Switches_LEDs; 10: 11: architecture Behavioral of Switches_LEDs is 12: begin 13: 14: end Behavioral;
As you can see, it has created the definition for an entity called Switches_LEDs, with two inputs and two outputs - STD_LOGIC is used to indicate what values these inputs and outputs can have.
The architecture section is where you describe how the internal logic of the module actually works. For this project we use the "assignment" operator ("<=") to assign the LEDs the values of the switches:
1: library IEEE; 2: use IEEE.STD_LOGIC_1164.ALL; 3: 4: entity Switches_LEDs is 5: Port ( switch_0 : in STD_LOGIC; 6: switch_1 : in STD_LOGIC; 7: LED_0 : out STD_LOGIC; 8: LED_1 : out STD_LOGIC); 9: end Switches_LEDs; 10: 11: architecture Behavioral of Switches_LEDs is 12: begin 13: LED_0 <= switch_0; 14: LED_1 <= switch_1; 15: end Behavioral;
If you press the green "play" arrow in the middle left of the design window the project should start building.
If your code has been entered successfully the project will build without any errors, and the design Window will now look like this:
Great! You've built your first design! There is only one problem, and that is we haven't told the design tools which pin to connect these signals to.
Step 3 - Creating constraints
To tell the tools which pins to connect the signals to an "Implementation Constraints File" is needed.
- From the "Project Menu" choose "New Source"
- Select "Implemntation Constraints File" and call it "constraints":
- Click "Next" and "Finished".
- In the design windows, a small '+' will appear by the Switches_LEDs module. Click that to show the new file:
- Double click "constraints.ucf" to open it in the editor window.
- Add the following lines, which assign locations to the four wires, and instructs the tools to create a design that uses "Low Voltage Transistor Transistor Logic" signal levels:
NET LED_0 LOC="P75" | IOSTANDARD=LVTTL; NET LED_1 LOC="P67" | IOSTANDARD=LVTTL; NET Switch_0 LOC="P74" | IOSTANDARD=LVTTL; NET Switch_1 LOC="P95" | IOSTANDARD=LVTTL;
Save the changes to this file, and then once again click on the Green arrow to build the design. The design is now ready to test!
Step 4 - Downloading the design into the device
TBA - Waiting on hardware