16×2 LCD interfacing with Cyclone3 FPGA
The expansion of LCD is Liquid Crystal Display which is used to display the character. The character is represented as the ASCII value (American Standard Code for Information Interchange). To display the character only the ASCII values are sent to LCD. The ASCII is 8bit. Here we have used 16×2 LCD with 5×8 pixel matrix (per character). The definition of 16×2 is the LCD contains 2 rows and 16 characters can be displayed per line. The single character displayed in 5×8 pixel matrix.
The first two pins of LCD must be connected to +5v and 0v.
The Vo pin is a contrast pin which is used to control the contrast of LCD. That is done by variable resistor. In FPGA kit the 10K variable resistor is used to control the contrast. The simple connection is given below Fig 2. There are three pins the two pins are connected to power supply and middle one is connected to Vo.
Note: The contrast range must be (0- 5v) for proper condition.
RS (Register Select)
RS is a command pin for LCD. The LCD command and RW operations are determined by RS pin. The LCD contains two register which is the data and command register. When command writes on the LCD, the data register is used. When the data either read or write on the LCD, the command register is used. The selections of register are determined by the logic status of RS.
If the logic state of RS is ‘1’, the data register is selected. If the logic state of RS is ‘0’, the command register is selected.
When the data send to data pins of LCD, the high to low pulse will be given.
Data pins (D0-D1)
The D0-D1 is data I/O pins. The LCD is accepted the 8 bit data as a parallel form. The format of data stream is first bit must be LSB bit continue it the other bits are sent.
Note: The LCD support only ASCII value of whatever the data is.
The pin no’s 15 & 16 are allocated for LCD backlight. The supply of LED backlight is +5v & 0v. It makes brightness of LCD display. The LED backlight pins denoted as (Anode (A), Cathode (K)) on LCD.
Interfacing with Cyclone3 FPGA Development Kit
LCD consist of 8- Data lines D0-D7, RS- Register Select line, RW-Read Write line, En- Enable line.
First we need to send commands to initialize the display, Curser Position, Clear Display, increment curser etc. All this command are send to instruction Register. Instruction Register can be enabled by RS = ‘0’, RW = ‘1’, En= ‘1’.
ASCI Values for Commands used in the code
38 = Function Set: 8-bit, 2 Line, 5×7 Dots
0c = Display on Cursor off
06 = Entry Mode
01= Clear Display
C0 = Place Curser to 2nd line
After sending commands, Data can be transferred to Display in the LCD. For sending Data enable Data Register by sending RS= ’1’, RW= ‘1’, En= ’1’.
Data can be transferred in 2 ways 8-bit mode and 4-bit mode. Here we are interfacing in 8-bit mode with the entire Data pin D0-D7.
ASCI Values for Data’s used in the code
50 – P 41- A 4e- N 54- T 45- E 43- C 48- H
53- S 4f- O 4c- L 55- U 54- T 49- I 4f- O 4e- N 53- S
VHDL Code consists for 2 counters i and j. i counter used to divide the clock and j counter used to get the array elements.
VHDL Code for 2×16 LCD Display
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_ARITH.ALL; use IEEE.STD_LOGIC_UNSIGNED.ALL; entity lcd is port ( clk : in std_logic; --clock i/p lcd_rw : out std_logic; --read & write control lcd_e : out std_logic; --enable control lcd_rs : out std_logic; --data or command control data : out std_logic_vector(7 downto 0)); --data line end lcd; architecture Behavioral of lcd is constant N: integer :=22; type arr is array (1 to N) of std_logic_vector(7 downto 0); constant datas : arr := (X"38",X"0c",X"06",X"01",X"C0",X"50",x"41",x"4e",x"54",x"45",x"43",x"48",x"20",x"53",x"4f",x"4c",x"55",x"54",x"49",x"4f",x"4e",X"53"); --command and data to display begin lcd_rw <= '0'; --lcd write process(clk) variable i : integer := 0; variable j : integer := 1; begin if clk'event and clk = '1' then if i <= 1000000 then i := i + 1; lcd_e <= '1'; data <= datas(j)(7 downto 0); elsif i > 1000000 and i < 2000000 then i := i + 1; lcd_e <= '0'; elsif i = 2000000 then j := j + 1; i := 0; end if; if j <= 5 then lcd_rs <= '0'; --command signal elsif j > 5 then lcd_rs <= '1'; --data signal end if; if j = 22 then --repeated display of data j := 5; end if; end if; end process; end Behavioral;