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LED interfacing with CoolRunner II CPLD Development Board

It’s always interesting to glow LED’s on any piece of hardware. What you can do with those LED’s? You can Blink them, you can Scroll from Left to Right and Right to Left, you can Count them , you can display any logic output which can be ‘0’ or ‘1’.

Coolrunner II CPLD Development Board got array of 8 LED’s to perform all the above mentioned operations. We are here to explore more on how to perform binary counter with those LED’s.

Now we are going to construct 8- bit Binary Counter. The 8-bit Synchronous Binary Counter counts sequentially on positive edge of every clock cycle.

Schematics to interface LED with Coolrunner II CPLD Development Board


Schematics to interface LED with Coolrunner II CPLD Development Board

LED Placement in coolrunner II CPLD Development Board



LED Placement in oolrunner II CPLD Development Board

VHDL Code for 8-Bit Binary Counter

 

library ieee;
use ieee.std_logic_1164.all;
use ieee.std_logic_unsigned.all;

entity counter is 
port(Clock, PRE : in  std_logic;
Q : out std_logic_vector(7 downto 0));
end counter;
 
architecture bhv of counter is  
signal tmp: std_logic_vector(7 downto 0);
begin
 
process (Clock, PRE) 
begin   
if (PRE='1') then   
tmp <= (others => '0');  
elsif (Clock'event and Clock='1') then 
tmp <= tmp + 1;
end if;     
end process; 
Q <= tmp;
end bhv;

From the above code, we will get counter running at 50MHz Speed which means it will count at the speed of 20 ns. You can’t visibly see the output of Counter with LED’s at 20 ns. Instead you can check them in simulation. To make the count visible we are introducing 33 bit clock divider and assign the last 8 MSB bits to the output LED’s. Which gives the result of binary count at every 1s.

library ieee;
use ieee.std_logic_1164.all;
use ieee.std_logic_unsigned.all;

entity counter is 
port(Clock, PRE : in  std_logic;
         Q : out std_logic_vector(7 downto 0));
end counter;
 
architecture arch of counter is  
signal tmp: std_logic_vector(32 downto 0);
begin
 
process (Clock, PRE) 
begin   
if (PRE='1') then   
tmp <= (others => '0');  
elsif (Clock'event and Clock='1') then 
tmp <= tmp + 1;
end if;     
end process; 
Q <= tmp(32 downto 25);
end arch;

Pin Assignment for coolrunner II CPLD Development Board.

NET "Q[7]" LOC = P14;
NET "Q[6]" LOC = P15;
NET "Q[5]" LOC = P16;
NET "Q[4]" LOC = P17;
NET "Q[3]" LOC = P18;
NET "Q[2]" LOC = P19;
NET "Q[1]" LOC = P20;
NET "Q[0]" LOC = P21;
NET "Clock" LOC = P38;
NET "PRE" LOC = P22;