Awesome
mit_sd_controller_improved
Improved version of http://web.mit.edu/6.111/volume2/www/f2018/tools/sd_controller.v
... and more.
Improvements
- SDHC card support: send CMD8 after CMD0 and read the full R7 response. Change ACMD41 parameter to show host SDHC support.
- Send about 74 <400KHz pulses to initialize, instead of default which wait for a few seconds.
- Use a normal speed clock and a slow pulsed clock instead of clock dividers. Good for timing analysis.
- Initialization/Read/Write tested OK on a SanDisk 16GB SDHC card -- works on my machine!
sd_controller.v usage
Interfaces are the same as the original except clocks.
clk
is the main, fast clock and clk_pulse_slow
is the pulsed, slow SPI clock.
My clk
is 62.5MHz and clk_pulse_slow
is generated by:
// slow clock
reg [4:0]clkcounter = 0;
always @ (posedge clk) begin
if (rst) clkcounter <= 5'b0;
else clkcounter <= clkcounter + 1;
end
wire clk_pulse_slow = (clkcounter == 5'b0);
If you use a different main clock or slow pulse frequency, you may want to change the boot counter:
boot_counter <= 27'd005_000;
and this:
if (boot_counter[2]) sclk_sig <= ~sclk_sig;
to make sure more than 74 cycles are sent slower than 400KHz during initialization.
References are at the top of sd_controller.v
.
below are my own stuffs
sdcard.v wrapper
This wrapper(written by me) can provide an easy memory-like interface to the sdcard. Can be used as memory-mapped IO for home-brew FPGA CPUs. Has 512 bytes cache(will be synthesis into block RAM).
Interface:
input [15:0]a,
input [31:0]d,
input we,
output reg [31:0]spo,
Usage:
read/write 0x0000 to 0x01fc: 128*32 block cache
read/write 0x1000: get/set <address> for R/W, auto 512 aligned (may purge existing cache)
write 0x1004: do a read at <address> (may purge existing cache)
write 0x1008: do a write to <address> (write cache to sector)
read 0x2000: negative card detect
read 0x2004: write protected
read 0x2010: ready, used for polling
read 0x2014: cache dirty?
For example write 0xdeadbeef to the beginning of sector 16:
write 0x10 to 0x1000
write 1 to 0x1004
read 0x2010 until get 1
write 0xdeadbeef to 0x0000
write 1 to 0x1008
read 0x2010 until get 1
Circuit connection
Theoretically this will work:
3.3V ----+++ wp
||| +---- =-----
RRR =8
MISO(SD_DAT[0]) --|||---------=7
||| GND ---=6
SCLK(SD_CLK) --||+---------=5
|| VCC ---=4
|| GND ---=3
MOSI(SD_CMD) --|+----------=2
CS(SD_DAT[3]) --+-----------=1
+=9
+-------
My PMOD extension board is different from this but also works.
License
GPL-v3. Original author has approved the use of his code in GPL-v3 projects.