Difference between revisions of "Simple blinking LED"
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[[Category: FPGA]] | [[Category: FPGA]] | ||
This design introduce FPGA usage on APF. The design will allow you to synthesize a design and configure the FGPA to blink a LED. | This design introduce FPGA usage on APF. The design will allow you to synthesize a design and configure the FGPA to blink a LED. | ||
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== The design == | == The design == | ||
+ | === VHDL code === | ||
The VHDL code above describe a clock divider by 48000000 to generate a 0.5 Hz clock that will blink the LED. | The VHDL code above describe a clock divider by 48000000 to generate a 0.5 Hz clock that will blink the LED. | ||
Line 17: | Line 12: | ||
use IEEE.numeric_std.all; | use IEEE.numeric_std.all; | ||
− | entity | + | entity led is |
Port ( | Port ( | ||
− | + | refclk : in std_logic; | |
− | + | led : out std_logic | |
− | + | ||
); | ); | ||
− | end | + | end led; |
− | architecture RTL of | + | architecture RTL of led is |
− | + | constant max_count : natural := 48000000; | |
− | + | signal Rst : std_logic; | |
begin | begin | ||
− | + | ||
− | + | Rst <= '0'; | |
− | + | ||
-- 0 to max_count counter | -- 0 to max_count counter | ||
− | compteur : process( | + | compteur : process(refclk, Rst) |
variable count : natural range 0 to max_count; | variable count : natural range 0 to max_count; | ||
begin | begin | ||
− | if | + | if Rst = '1' then |
count := 0; | count := 0; | ||
− | + | led <= '1'; | |
− | elsif rising_edge( | + | elsif rising_edge(refclk) then |
if count < max_count/2 then | if count < max_count/2 then | ||
− | |||
count := count + 1; | count := count + 1; | ||
+ | led <= '1'; | ||
elsif count < max_count then | elsif count < max_count then | ||
− | + | led <= '0'; | |
count := count + 1; | count := count + 1; | ||
else | else | ||
+ | led <= '1'; | ||
count := 0; | count := 0; | ||
− | |||
end if; | end if; | ||
end if; | end if; | ||
Line 56: | Line 49: | ||
</source> | </source> | ||
+ | === Pinout === | ||
To synthesize this code, use [[ISE_WebPack_installation_on_Linux | Xilinx Web Pack]], create a new project and add this VHDL module. | To synthesize this code, use [[ISE_WebPack_installation_on_Linux | Xilinx Web Pack]], create a new project and add this VHDL module. | ||
− | ISE need to know where to branch LED pins on its IO, this pinout is describe in constraint file with extension '''.ucf'''. | + | {{Note| Don't forget to power the FPGA IO bank as explained in [[datasheet]]}} |
+ | |||
+ | ISE/Quartus need to know where to branch LED pins on its IO, this pinout is describe in constraint file with extension '''.ucf'''. | ||
* For '''APF9328''': | * For '''APF9328''': | ||
Line 65: | Line 61: | ||
NET "Clk" LOC = "P55"; | NET "Clk" LOC = "P55"; | ||
NET "Clk" TNM_NET = "Clk"; | NET "Clk" TNM_NET = "Clk"; | ||
− | TIMESPEC "TS_Clk" = PERIOD "Clk" 10 ns HIGH 50 %; | + | TIMESPEC "TS_Clk" = PERIOD "Clk" 10.42 ns HIGH 50 %; |
# LED | # LED | ||
− | NET " | + | NET "led" LOC = "P118"| IOSTANDARD = LVCMOS33 ; |
− | + | ||
</source> | </source> | ||
Line 78: | Line 73: | ||
TIMESPEC "TS_Clk" = PERIOD "Clk" 10 ns HIGH 50 %; | TIMESPEC "TS_Clk" = PERIOD "Clk" 10 ns HIGH 50 %; | ||
# LED | # LED | ||
− | NET " | + | NET "led" LOC = "C15"| IOSTANDARD = LVCMOS33 ; #IO_L24N_1 |
− | + | ||
</source> | </source> | ||
* For '''APF51''' | * For '''APF51''' | ||
<source lang="VHDL"> | <source lang="VHDL"> | ||
− | # Clock at | + | # Clock at 92.85MHz |
NET "Clk" LOC = "N8"; # EIM_BCLK | NET "Clk" LOC = "N8"; # EIM_BCLK | ||
NET "Clk" TNM_NET = "Clk"; | NET "Clk" TNM_NET = "Clk"; | ||
− | TIMESPEC "TS_Clk" = PERIOD "Clk" 10 ns HIGH 50 %; | + | TIMESPEC "TS_Clk" = PERIOD "Clk" 10.77 ns HIGH 50 %; |
# LED | # LED | ||
− | NET " | + | NET "led" LOC = "G15"| IOSTANDARD = LVCMOS33 ; #IO_L41N_GCLK8_M1CASN_1 |
− | + | ||
</source> | </source> | ||
− | + | * For '''APF6_SP''' | |
+ | <source lang="tcl"> | ||
+ | # Clock is the differential PCIe clock (LVDS) at 100MHz | ||
+ | set_instance_assignment -name IO_STANDARD "1.5-V PCML" -to Clk | ||
+ | set_location_assignment PIN_V4 -to Clk | ||
+ | set_location_assignment PIN_U4 -to "Clk(n)" | ||
+ | # LED | ||
+ | # For the first apf6dev serie this pin must be used : | ||
+ | set_location_assignment PIN_M10 -to led | ||
+ | # Others apf6dev will use PIN_K15 | ||
+ | </source> | ||
+ | These constraints files examples can be found in Armadeus BSP's ''firmware/leds/blinking_led/src/'' directory. | ||
== Generate bitstream == | == Generate bitstream == | ||
+ | === ISE === | ||
Once these two files are written, FPGA configuration file, also named "bitstream", can be generated by clicking on ''Synthetize - XST'' then ''Implement Design'' and finally ''Generate Programming File''. If all these operations are correctly done, a file with ".bit" extension will be generated. | Once these two files are written, FPGA configuration file, also named "bitstream", can be generated by clicking on ''Synthetize - XST'' then ''Implement Design'' and finally ''Generate Programming File''. If all these operations are correctly done, a file with ".bit" extension will be generated. | ||
+ | |||
+ | === Quartus === | ||
+ | |||
+ | See the [[Quartus]] page for tutorials. | ||
== Configure FPGA == | == Configure FPGA == |
Latest revision as of 14:24, 25 November 2021
This design introduce FPGA usage on APF. The design will allow you to synthesize a design and configure the FGPA to blink a LED.
Contents
The design
VHDL code
The VHDL code above describe a clock divider by 48000000 to generate a 0.5 Hz clock that will blink the LED.
library IEEE;
use IEEE.STD_LOGIC_1164.ALL;
use IEEE.numeric_std.all;
entity led is
Port (
refclk : in std_logic;
led : out std_logic
);
end led;
architecture RTL of led is
constant max_count : natural := 48000000;
signal Rst : std_logic;
begin
Rst <= '0';
-- 0 to max_count counter
compteur : process(refclk, Rst)
variable count : natural range 0 to max_count;
begin
if Rst = '1' then
count := 0;
led <= '1';
elsif rising_edge(refclk) then
if count < max_count/2 then
count := count + 1;
led <= '1';
elsif count < max_count then
led <= '0';
count := count + 1;
else
led <= '1';
count := 0;
end if;
end if;
end process compteur;
end RTL;
Pinout
To synthesize this code, use Xilinx Web Pack, create a new project and add this VHDL module.
Note: Don't forget to power the FPGA IO bank as explained in datasheet |
ISE/Quartus need to know where to branch LED pins on its IO, this pinout is describe in constraint file with extension .ucf.
- For APF9328:
# Clock at 96MHz
NET "Clk" LOC = "P55";
NET "Clk" TNM_NET = "Clk";
TIMESPEC "TS_Clk" = PERIOD "Clk" 10.42 ns HIGH 50 %;
# LED
NET "led" LOC = "P118"| IOSTANDARD = LVCMOS33 ;
- For APF27
# Clock at 100MHz
NET "Clk" LOC = "N9"; # CLK0
NET "Clk" TNM_NET = "Clk";
TIMESPEC "TS_Clk" = PERIOD "Clk" 10 ns HIGH 50 %;
# LED
NET "led" LOC = "C15"| IOSTANDARD = LVCMOS33 ; #IO_L24N_1
- For APF51
# Clock at 92.85MHz
NET "Clk" LOC = "N8"; # EIM_BCLK
NET "Clk" TNM_NET = "Clk";
TIMESPEC "TS_Clk" = PERIOD "Clk" 10.77 ns HIGH 50 %;
# LED
NET "led" LOC = "G15"| IOSTANDARD = LVCMOS33 ; #IO_L41N_GCLK8_M1CASN_1
- For APF6_SP
# Clock is the differential PCIe clock (LVDS) at 100MHz
set_instance_assignment -name IO_STANDARD "1.5-V PCML" -to Clk
set_location_assignment PIN_V4 -to Clk
set_location_assignment PIN_U4 -to "Clk(n)"
# LED
# For the first apf6dev serie this pin must be used :
set_location_assignment PIN_M10 -to led
# Others apf6dev will use PIN_K15
These constraints files examples can be found in Armadeus BSP's firmware/leds/blinking_led/src/ directory.
Generate bitstream
ISE
Once these two files are written, FPGA configuration file, also named "bitstream", can be generated by clicking on Synthetize - XST then Implement Design and finally Generate Programming File. If all these operations are correctly done, a file with ".bit" extension will be generated.
Quartus
See the Quartus page for tutorials.
Configure FPGA
To configure FGPA the bitstream must be downloaded from Host to APF's memory and then from APF's memory to FPGA.
Host to APF
Downloading Bitstream from Host to APF can be done in different way : with tftp from U-Boot, with tftp from Linux, with serial from U-Boot or with nfs from Linux. Here the file is downloaded with tftp in U-Boot:
- First copy bitstream in the host tftp directory:
cp blinking_led_apfXX_200k.bit /tftpboot
- Then download it in APF ram with U-Boot command :
BIOS> tftpboot ${loadaddr} blinking_led_apfXX_200k.bit dm9000 i/o: 0x15c00000, id: 0x90000a46 MAC: 00:0e:32:00:00:01 operating at 10M half duplex mode TFTP from server 192.168.0.143; our IP address is 192.168.0.10 Filename 'Clk_div_led.bit'. Load address: 0x8000000 Loading: T ########################## done Bytes transferred = 131029 (1ffd5 hex)
APF to FPGA
Finally, to download bitstream in FPGA (to configure the FGPA) use the U-Boot fpga command:
BIOS>fpga load 0 ${loadaddr} ${firmware_len}
FPGA configuration can also be done in Linux.
Enjoy the beauty of a blinking LED
To see the LED blinking, the FPGA bank must be powered as explain in the datasheet.