(* clock_signal = "yes" *) reg adc_clk; // sample frequency, always 16 * fc
always @(ck_1356megb, xcorr_is_848, xcorr_quarter_freq, fc_div)
- if (xcorr_is_848 & ~xcorr_quarter_freq) // fc = 847.5 kHz
+ if (xcorr_is_848 & ~xcorr_quarter_freq) // fc = 847.5 kHz, standard ISO14443B
adc_clk <= ck_1356megb;
- else if (~xcorr_is_848 & ~xcorr_quarter_freq) // fc = 424.25 kHz
+ else if (~xcorr_is_848 & ~xcorr_quarter_freq) // fc = 423.75 kHz
adc_clk <= fc_div[0];
- else if (xcorr_is_848 & xcorr_quarter_freq) // fc = 212.125 kHz
+ else if (xcorr_is_848 & xcorr_quarter_freq) // fc = 211.875 kHz
adc_clk <= fc_div[1];
- else // fc = 106.0625 kHz
+ else // fc = 105.9375 kHz
adc_clk <= fc_div[2];
// When we're a reader, we just need to do the BPSK demod; but when we're an
end
end
-// Let us report a correlation every 4 subcarrier cycles, or 4*16 samples,
+// Let us report a correlation every 4 subcarrier cycles, or 4*16=64 samples,
// so we need a 6-bit counter.
reg [5:0] corr_i_cnt;
// And a couple of registers in which to accumulate the correlations.
-// we would add/sub at most 32 times adc_d, the signed result can be held in 14 bits.
-reg signed [13:0] corr_i_accum;
-reg signed [13:0] corr_q_accum;
+// We would add at most 32 times the difference between unmodulated and modulated signal. It should
+// be safe to assume that a tag will not be able to modulate the carrier signal by more than 25%.
+// 32 * 255 * 0,25 = 2040, which can be held in 11 bits. Add 1 bit for sign.
+reg signed [11:0] corr_i_accum;
+reg signed [11:0] corr_q_accum;
+// we will report maximum 8 significant bits
reg signed [7:0] corr_i_out;
reg signed [7:0] corr_q_out;
// clock and frame signal for communication to ARM
begin
if(snoop)
begin
- // Send only 7 most significant bits of tag signal (signed), LSB is reader signal:
- corr_i_out <= {corr_i_accum[13:7], after_hysteresis_prev_prev};
- corr_q_out <= {corr_q_accum[13:7], after_hysteresis_prev};
+ // Send 7 most significant bits of tag signal (signed), plus 1 bit reader signal
+ corr_i_out <= {corr_i_accum[11:5], after_hysteresis_prev_prev};
+ corr_q_out <= {corr_q_accum[11:5], after_hysteresis_prev};
after_hysteresis_prev_prev <= after_hysteresis;
end
else
begin
- // 8 most significant bits of tag signal
- corr_i_out <= corr_i_accum[13:6];
- corr_q_out <= corr_q_accum[13:6];
+ // 8 bits of tag signal
+ corr_i_out <= corr_i_accum[11:4];
+ corr_q_out <= corr_q_accum[11:4];
end
corr_i_accum <= adc_d;
output dbg;
input shallow_modulation;
+// low frequency outputs, not relevant
+assign pwr_lo = 1'b0;
+assign pwr_oe2 = 1'b0;
+
// The high-frequency stuff. For now, for testing, just bring out the carrier,
// and allow the ARM to modulate it over the SSP.
reg pwr_hi;
reg pwr_oe1;
-reg pwr_oe2;
reg pwr_oe3;
reg pwr_oe4;
+
always @(ck_1356megb or ssp_dout or shallow_modulation)
begin
if(shallow_modulation)
begin
pwr_hi <= ck_1356megb;
- pwr_oe1 <= ~ssp_dout;
- pwr_oe2 <= ~ssp_dout;
- pwr_oe3 <= ~ssp_dout;
- pwr_oe4 <= 1'b0;
+ pwr_oe1 <= 1'b0;
+ pwr_oe3 <= 1'b0;
+ pwr_oe4 <= ~ssp_dout;
end
else
begin
pwr_hi <= ck_1356megb & ssp_dout;
pwr_oe1 <= 1'b0;
- pwr_oe2 <= 1'b0;
pwr_oe3 <= 1'b0;
pwr_oe4 <= 1'b0;
end
end
+
// Then just divide the 13.56 MHz clock down to produce appropriate clocks
// for the synchronous serial port.
assign ssp_din = after_hysteresis;
-assign pwr_lo = 1'b0;
assign dbg = ssp_din;
endmodule
projects / proxmark3-svn / commitdiff