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https://github.com/RfidResearchGroup/proxmark3.git
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dbfd8b7a6d
This adds a new command "hw sethfthresh" to configure the thresholds used inside the FPGA while demodulating ISO14443A. The thresholds need to be increased on particularly noisy hardware, such as certain Chinese PM3 Easy clones.
564 lines
22 KiB
Verilog
564 lines
22 KiB
Verilog
//-----------------------------------------------------------------------------
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// Copyright (C) Proxmark3 contributors. See AUTHORS.md for details.
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//
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// This program is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// This program is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU General Public License for more details.
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//
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// See LICENSE.txt for the text of the license.
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//-----------------------------------------------------------------------------
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// ISO14443-A support for the Proxmark3
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module hi_iso14443a(
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input ck_1356meg,
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input [7:0] adc_d,
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input [3:0] mod_type,
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input [10:0] edge_detect_threshold,
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input [10:0] edge_detect_threshold_high,
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input ssp_dout,
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output ssp_din,
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output reg ssp_frame,
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output reg ssp_clk,
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output adc_clk,
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output pwr_lo,
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output pwr_hi,
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output pwr_oe1,
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output pwr_oe2,
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output pwr_oe3,
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output pwr_oe4,
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output debug
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);
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assign adc_clk = ck_1356meg;
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Reader -> PM3:
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// detecting and shaping the reader's signal. Reader will modulate the carrier by 100% (signal is either on or off). Use a
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// hysteresis (Schmitt Trigger) to avoid false triggers during slowly increasing or decreasing carrier amplitudes
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reg after_hysteresis;
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reg [11:0] has_been_low_for;
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always @(negedge adc_clk)
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begin
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if(adc_d >= 16) after_hysteresis <= 1'b1; // U >= 1,14V -> after_hysteresis = 1
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else if(adc_d < 8) after_hysteresis <= 1'b0; // U < 1,04V -> after_hysteresis = 0
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// Note: was >= 3,53V and <= 1,19V. The new trigger values allow more reliable detection of the first bit
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// (it might not reach 3,53V due to the high time constant of the high pass filter in the analogue RF part).
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// In addition, the new values are more in line with ISO14443-2: "The PICC shall detect the ”End of Pause” after the field exceeds
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// 5% of H_INITIAL and before it exceeds 60% of H_INITIAL." Depending on the signal strength, 60% might well be less than 3,53V.
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// detecting a loss of reader's field (adc_d < 192 for 4096 clock cycles). If this is the case,
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// set the detected reader signal (after_hysteresis) to '1' (unmodulated)
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if(adc_d >= 192)
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begin
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has_been_low_for <= 12'd0;
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end
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else
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begin
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if(has_been_low_for == 12'd4095)
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begin
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has_been_low_for <= 12'd0;
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after_hysteresis <= 1'b1;
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end
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else
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begin
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has_been_low_for <= has_been_low_for + 1;
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end
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Reader -> PM3
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// detect when a reader is active (modulating). We assume that the reader is active, if we see the carrier off for at least 8
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// carrier cycles. We assume that the reader is inactive, if the carrier stayed high for at least 256 carrier cycles.
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reg deep_modulation;
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reg [2:0] deep_counter;
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reg [8:0] saw_deep_modulation;
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always @(negedge adc_clk)
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begin
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if(~(| adc_d[7:0])) // if adc_d == 0 (U <= 0,94V)
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begin
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if(deep_counter == 3'd7) // adc_d == 0 for 8 adc_clk ticks -> deep_modulation (by reader)
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begin
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deep_modulation <= 1'b1;
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saw_deep_modulation <= 8'd0;
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end
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else
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deep_counter <= deep_counter + 1;
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end
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else
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begin
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deep_counter <= 3'd0;
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if(saw_deep_modulation == 8'd255) // adc_d != 0 for 256 adc_clk ticks -> deep_modulation is over, probably waiting for tag's response
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deep_modulation <= 1'b0;
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else
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saw_deep_modulation <= saw_deep_modulation + 1;
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Tag -> PM3
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// filter the input for a tag's signal. The filter box needs the 4 previous input values and is a gaussian derivative filter
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// for noise reduction and edge detection.
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// store 4 previous samples:
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reg [7:0] input_prev_4, input_prev_3, input_prev_2, input_prev_1;
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always @(negedge adc_clk)
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begin
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input_prev_4 <= input_prev_3;
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input_prev_3 <= input_prev_2;
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input_prev_2 <= input_prev_1;
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input_prev_1 <= adc_d;
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end
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// adc_d_filtered = 2*input_prev4 + 1*input_prev3 + 0*input_prev2 - 1*input_prev1 - 2*input
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// = (2*input_prev4 + input_prev3) - (2*input + input_prev1)
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wire [8:0] input_prev_4_times_2 = input_prev_4 << 1;
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wire [8:0] adc_d_times_2 = adc_d << 1;
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wire [9:0] tmp1 = input_prev_4_times_2 + input_prev_3;
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wire [9:0] tmp2 = adc_d_times_2 + input_prev_1;
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// convert intermediate signals to signed and calculate the filter output
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wire signed [10:0] adc_d_filtered = {1'b0, tmp1} - {1'b0, tmp2};
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// internal FPGA timing. Maximum required period is 128 carrier clock cycles for a full 8 Bit transfer to ARM. (i.e. we need a
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// 7 bit counter). Adjust its frequency to external reader's clock when simulating a tag or sniffing.
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reg pre_after_hysteresis;
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reg [3:0] reader_falling_edge_time;
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reg [6:0] negedge_cnt;
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always @(negedge adc_clk)
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begin
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// detect a reader signal's falling edge and remember its timing:
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pre_after_hysteresis <= after_hysteresis;
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if (pre_after_hysteresis && ~after_hysteresis)
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begin
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reader_falling_edge_time[3:0] <= negedge_cnt[3:0];
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end
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// adjust internal timer counter if necessary:
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if (negedge_cnt[3:0] == 4'd13 && (mod_type == `FPGA_HF_ISO14443A_SNIFFER || mod_type == `FPGA_HF_ISO14443A_TAGSIM_LISTEN) && deep_modulation)
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begin
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if (reader_falling_edge_time == 4'd1) // reader signal changes right after sampling. Better sample earlier next time.
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begin
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negedge_cnt <= negedge_cnt + 2; // time warp
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end
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else if (reader_falling_edge_time == 4'd0) // reader signal changes right before sampling. Better sample later next time.
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begin
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negedge_cnt <= negedge_cnt; // freeze time
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end
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else
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begin
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negedge_cnt <= negedge_cnt + 1; // Continue as usual
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end
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reader_falling_edge_time[3:0] <= 4'd8; // adjust only once per detected edge
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end
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else if (negedge_cnt == 7'd127) // normal operation: count from 0 to 127
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begin
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negedge_cnt <= 0;
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end
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else
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begin
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negedge_cnt <= negedge_cnt + 1;
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Tag -> PM3:
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// determine best possible time for starting/resetting the modulation detector.
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reg [3:0] mod_detect_reset_time;
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always @(negedge adc_clk)
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begin
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if (mod_type == `FPGA_HF_ISO14443A_READER_LISTEN)
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// (our) reader signal changes at negedge_cnt[3:0]=9, tag response expected to start n*16+4 ticks later, further delayed by
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// 3 ticks ADC conversion. The maximum filter output (edge detected) will be detected after subcarrier zero crossing (+7 ticks).
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// To allow some timing variances, we want to have the maximum filter outputs well within the detection window, i.e.
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// at mod_detect_reset_time+4 and mod_detect_reset_time+12 (-4 ticks).
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// 9 + 4 + 3 + 7 - 4 = 19. 19 mod 16 = 3
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begin
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mod_detect_reset_time <= 4'd4;
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end
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else
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if (mod_type == `FPGA_HF_ISO14443A_SNIFFER)
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begin
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// detect a rising edge of reader's signal and sync modulation detector to the tag's answer:
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if (~pre_after_hysteresis && after_hysteresis && deep_modulation)
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// reader signal rising edge detected at negedge_cnt[3:0]. This signal had been delayed
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// 9 ticks by the RF part + 3 ticks by the A/D converter + 1 tick to assign to after_hysteresis.
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// Then the same as above.
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// - 9 - 3 - 1 + 4 + 3 + 7 - 4 = -3
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begin
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mod_detect_reset_time <= negedge_cnt[3:0] - 4'd3;
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end
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Tag -> PM3:
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// modulation detector. Looks for the steepest falling and rising edges within a 16 clock period. If there is both a significant
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// falling and rising edge (in any order), a modulation is detected.
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reg signed [10:0] rx_mod_falling_edge_max;
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reg signed [10:0] rx_mod_rising_edge_max;
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reg curbit;
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always @(negedge adc_clk)
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begin
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if(negedge_cnt[3:0] == mod_detect_reset_time)
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begin
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if (mod_type == `FPGA_HF_ISO14443A_SNIFFER)
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begin
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// detect modulation signal: if modulating, there must have been a falling AND a rising edge
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if ((rx_mod_falling_edge_max > edge_detect_threshold_high) && (rx_mod_rising_edge_max < -edge_detect_threshold_high))
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curbit <= 1'b1; // modulation
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else
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curbit <= 1'b0; // no modulation
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end
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else
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begin
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// detect modulation signal: if modulating, there must have been a falling AND a rising edge
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if ((rx_mod_falling_edge_max > edge_detect_threshold) && (rx_mod_rising_edge_max < -edge_detect_threshold))
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curbit <= 1'b1; // modulation
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else
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curbit <= 1'b0; // no modulation
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end
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// reset modulation detector
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rx_mod_rising_edge_max <= 0;
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rx_mod_falling_edge_max <= 0;
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end
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else // look for steepest edges (slopes)
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begin
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if (adc_d_filtered > 0)
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begin
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if (adc_d_filtered > rx_mod_falling_edge_max)
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rx_mod_falling_edge_max <= adc_d_filtered;
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end
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else
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begin
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if (adc_d_filtered < rx_mod_rising_edge_max)
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rx_mod_rising_edge_max <= adc_d_filtered;
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end
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Tag+Reader -> PM3
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// sample 4 bits reader data and 4 bits tag data for sniffing
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reg [3:0] reader_data;
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reg [3:0] tag_data;
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always @(negedge adc_clk)
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begin
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if(negedge_cnt[3:0] == 4'd0)
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begin
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reader_data[3:0] <= {reader_data[2:0], after_hysteresis};
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tag_data[3:0] <= {tag_data[2:0], curbit};
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// PM3 -> Reader:
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// a delay line to ensure that we send the (emulated) tag's answer at the correct time according to ISO14443-3
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reg [31:0] mod_sig_buf;
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reg [4:0] mod_sig_ptr;
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reg mod_sig;
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always @(negedge adc_clk)
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begin
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if(negedge_cnt[3:0] == 4'd0) // sample data at rising edge of ssp_clk - ssp_dout changes at the falling edge.
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begin
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mod_sig_buf[31:2] <= mod_sig_buf[30:1]; // shift
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if (~ssp_dout && ~mod_sig_buf[1])
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mod_sig_buf[1] <= 1'b0; // delete the correction bit (a single 1 preceded and succeeded by 0)
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else
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mod_sig_buf[1] <= mod_sig_buf[0];
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mod_sig_buf[0] <= ssp_dout; // add new data to the delay line
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mod_sig = mod_sig_buf[mod_sig_ptr]; // the delayed signal.
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// PM3 -> Reader, internal timing:
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// a timer for the 1172 cycles fdt (Frame Delay Time). Start the timer with a rising edge of the reader's signal.
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// set fdt_elapsed when we no longer need to delay data. Set fdt_indicator when we can start sending data.
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// Note: the FPGA only takes care for the 1172 delay. To achieve an additional 1236-1172=64 ticks delay, the ARM must send
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// a correction bit (before the start bit). The correction bit will be coded as 00010000, i.e. it adds 4 bits to the
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// transmission stream, causing the required additional delay.
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reg [10:0] fdt_counter;
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reg fdt_indicator, fdt_elapsed;
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reg [3:0] mod_sig_flip;
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reg [3:0] sub_carrier_cnt;
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// we want to achieve a delay of 1172. The RF part already has delayed the reader signals's rising edge
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// by 9 ticks, the ADC took 3 ticks and there is always a delay of 32 ticks by the mod_sig_buf. Therefore need to
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// count to 1172 - 9 - 3 - 32 = 1128
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`define FDT_COUNT 11'd1128
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// The ARM must not send too early, otherwise the mod_sig_buf will overflow, therefore signal that we are ready
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// with fdt_indicator. The mod_sig_buf can buffer 29 excess data bits, i.e. a maximum delay of 29 * 16 = 464 adc_clk ticks.
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// fdt_indicator is assigned to sendbit after at least 1 tick, the transfer to ARM needs minimum 8 ticks. Response from
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// ARM could appear at ssp_dout 8 ticks later.
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// 1128 - 464 - 1 - 8 - 8 = 647
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`define FDT_INDICATOR_COUNT 11'd647
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// Note: worst case, assignment to sendbit takes 15 ticks more, and transfer to ARM needs 7*16 = 112 ticks more.
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// When the ARM's response then appears, the fdt_count is already 647 + 15 + 112 = 774, which still allows the ARM a possible
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// response window of 1128 - 774 = 354 ticks.
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// reset on a pause in listen mode. I.e. the counter starts when the pause is over:
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assign fdt_reset = ~after_hysteresis && mod_type == `FPGA_HF_ISO14443A_TAGSIM_LISTEN;
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always @(negedge adc_clk)
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begin
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if (fdt_reset)
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begin
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fdt_counter <= 11'd0;
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fdt_elapsed <= 1'b0;
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fdt_indicator <= 1'b0;
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end
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else
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begin
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if(fdt_counter == `FDT_COUNT)
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begin
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if(~fdt_elapsed) // just reached fdt.
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begin
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mod_sig_flip <= negedge_cnt[3:0]; // start modulation at this time
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sub_carrier_cnt <= 4'd0; // subcarrier phase in sync with start of modulation
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fdt_elapsed <= 1'b1;
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end
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else
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begin
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sub_carrier_cnt <= sub_carrier_cnt + 1;
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end
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end
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else
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begin
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fdt_counter <= fdt_counter + 1;
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end
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end
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if(fdt_counter == `FDT_INDICATOR_COUNT) fdt_indicator <= 1'b1;
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// PM3 -> Reader or Tag
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// assign a modulation signal to the antenna. This signal is either a delayed signal (to achieve fdt when sending to a reader)
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// or undelayed when sending to a tag
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reg mod_sig_coil;
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always @(negedge adc_clk)
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begin
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if (mod_type == `FPGA_HF_ISO14443A_TAGSIM_MOD) // need to take care of proper fdt timing
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begin
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if(fdt_counter == `FDT_COUNT)
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begin
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if(fdt_elapsed)
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begin
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if(negedge_cnt[3:0] == mod_sig_flip) mod_sig_coil <= mod_sig;
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end
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else
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begin
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mod_sig_coil <= mod_sig; // just reached fdt. Immediately assign signal to coil
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end
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end
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end
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else // other modes: don't delay
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begin
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mod_sig_coil <= ssp_dout;
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// PM3 -> Reader
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// determine the required delay in the mod_sig_buf (set mod_sig_ptr).
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reg temp_buffer_reset;
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always @(negedge adc_clk)
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begin
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if(fdt_reset)
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begin
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mod_sig_ptr <= 5'd0;
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temp_buffer_reset = 1'b0;
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end
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else
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begin
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if(fdt_counter == `FDT_COUNT && ~fdt_elapsed) // if we just reached fdt
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if(~(| mod_sig_ptr[4:0]))
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mod_sig_ptr <= 5'd8; // ... but didn't buffer a 1 yet, delay next 1 by n*128 ticks.
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else
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temp_buffer_reset = 1'b1; // else no need for further delays.
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if(negedge_cnt[3:0] == 4'd0) // at rising edge of ssp_clk - ssp_dout changes at the falling edge.
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begin
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if((ssp_dout || (| mod_sig_ptr[4:0])) && ~fdt_elapsed) // buffer a 1 (and all subsequent data) until fdt is reached.
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if (mod_sig_ptr == 5'd31)
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mod_sig_ptr <= 5'd0; // buffer overflow - data loss.
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else
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mod_sig_ptr <= mod_sig_ptr + 1; // increase buffer (= increase delay by 16 adc_clk ticks). mod_sig_ptr always points ahead of first 1.
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else if(fdt_elapsed && ~temp_buffer_reset)
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begin
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// wait for the next 1 after fdt_elapsed before fixing the delay and starting modulation. This ensures that the response can only happen
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// at intervals of 8 * 16 = 128 adc_clk ticks (as defined in ISO14443-3)
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if(ssp_dout)
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temp_buffer_reset = 1'b1;
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if(mod_sig_ptr == 5'd1)
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mod_sig_ptr <= 5'd8; // still nothing received, need to go for the next interval
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else
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mod_sig_ptr <= mod_sig_ptr - 1; // decrease buffer.
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end
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end
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end
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end
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// FPGA -> ARM communication:
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// buffer 8 bits data to be sent to ARM. Shift them out bit by bit.
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reg [7:0] to_arm;
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always @(negedge adc_clk)
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begin
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if (negedge_cnt[5:0] == 6'd63) // fill the buffer
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begin
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if (mod_type == `FPGA_HF_ISO14443A_SNIFFER)
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begin
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if(deep_modulation) // a reader is sending (or there's no field at all)
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begin
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to_arm <= {reader_data[3:0], 4'b0000}; // don't send tag data
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end
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else
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begin
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to_arm <= {reader_data[3:0], tag_data[3:0]};
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end
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end
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else
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begin
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to_arm[7:0] <= {mod_sig_ptr[4:0], mod_sig_flip[3:1]}; // feedback timing information
|
|
end
|
|
end
|
|
|
|
if(negedge_cnt[2:0] == 3'b000 && mod_type == `FPGA_HF_ISO14443A_SNIFFER) // shift at double speed
|
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begin
|
|
// Don't shift if we just loaded new data, obviously.
|
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if(negedge_cnt[5:0] != 6'd0)
|
|
begin
|
|
to_arm[7:1] <= to_arm[6:0];
|
|
end
|
|
end
|
|
|
|
if(negedge_cnt[3:0] == 4'b0000 && mod_type != `FPGA_HF_ISO14443A_SNIFFER)
|
|
begin
|
|
// Don't shift if we just loaded new data, obviously.
|
|
if(negedge_cnt[6:0] != 7'd0)
|
|
begin
|
|
to_arm[7:1] <= to_arm[6:0];
|
|
end
|
|
end
|
|
end
|
|
|
|
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
|
|
// FPGA <-> ARM communication:
|
|
// generate a ssp clock and ssp frame signal for the synchronous transfer from/to the ARM
|
|
|
|
always @(negedge adc_clk)
|
|
begin
|
|
if(mod_type == `FPGA_HF_ISO14443A_SNIFFER)
|
|
// FPGA_HF_ISO14443A_SNIFFER mode (ssp_clk = adc_clk / 8, ssp_frame clock = adc_clk / 64)):
|
|
begin
|
|
if(negedge_cnt[2:0] == 3'd0)
|
|
ssp_clk <= 1'b1;
|
|
if(negedge_cnt[2:0] == 3'd4)
|
|
ssp_clk <= 1'b0;
|
|
|
|
if(negedge_cnt[5:0] == 6'd0) // ssp_frame rising edge indicates start of frame
|
|
ssp_frame <= 1'b1;
|
|
if(negedge_cnt[5:0] == 6'd8)
|
|
ssp_frame <= 1'b0;
|
|
end
|
|
else
|
|
// all other modes (ssp_clk = adc_clk / 16, ssp_frame clock = adc_clk / 128):
|
|
begin
|
|
if(negedge_cnt[3:0] == 4'd0)
|
|
ssp_clk <= 1'b1;
|
|
if(negedge_cnt[3:0] == 4'd8)
|
|
ssp_clk <= 1'b0;
|
|
|
|
if(negedge_cnt[6:0] == 7'd7) // ssp_frame rising edge indicates start of frame, sampled on falling edge of ssp_clk
|
|
ssp_frame <= 1'b1;
|
|
if(negedge_cnt[6:0] == 7'd23)
|
|
ssp_frame <= 1'b0;
|
|
end
|
|
end
|
|
|
|
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
|
|
// FPGA -> ARM communication:
|
|
// select the data to be sent to ARM
|
|
reg bit_to_arm;
|
|
reg sendbit;
|
|
|
|
always @(negedge adc_clk)
|
|
begin
|
|
if(negedge_cnt[3:0] == 4'd0)
|
|
begin
|
|
// What do we communicate to the ARM
|
|
if(mod_type == `FPGA_HF_ISO14443A_TAGSIM_LISTEN)
|
|
sendbit = after_hysteresis;
|
|
else if(mod_type == `FPGA_HF_ISO14443A_TAGSIM_MOD)
|
|
/* if(fdt_counter > 11'd772) sendbit = mod_sig_coil; // huh?
|
|
else */
|
|
sendbit = fdt_indicator;
|
|
else if (mod_type == `FPGA_HF_ISO14443A_READER_LISTEN)
|
|
sendbit = curbit;
|
|
else
|
|
sendbit = 1'b0;
|
|
end
|
|
|
|
if(mod_type == `FPGA_HF_ISO14443A_SNIFFER)
|
|
// send sampled reader and tag data:
|
|
bit_to_arm = to_arm[7];
|
|
else if (mod_type == `FPGA_HF_ISO14443A_TAGSIM_MOD && fdt_elapsed && temp_buffer_reset)
|
|
// send timing information:
|
|
bit_to_arm = to_arm[7];
|
|
else
|
|
// send data or fdt_indicator
|
|
bit_to_arm = sendbit;
|
|
end
|
|
|
|
assign ssp_din = bit_to_arm;
|
|
|
|
// Subcarrier (adc_clk/16, for FPGA_HF_ISO14443A_TAGSIM_MOD only).
|
|
wire sub_carrier;
|
|
assign sub_carrier = ~sub_carrier_cnt[3];
|
|
|
|
// in FPGA_HF_ISO14443A_READER_MOD: drop carrier for mod_sig_coil == 1 (pause);
|
|
// in FPGA_HF_ISO14443A_READER_LISTEN: carrier always on; in other modes: carrier always off
|
|
assign pwr_hi = (ck_1356meg & (((mod_type == `FPGA_HF_ISO14443A_READER_MOD) & ~mod_sig_coil) || (mod_type == `FPGA_HF_ISO14443A_READER_LISTEN)));
|
|
|
|
// Enable HF antenna drivers:
|
|
assign pwr_oe1 = 1'b0;
|
|
assign pwr_oe3 = 1'b0;
|
|
|
|
// FPGA_HF_ISO14443A_TAGSIM_MOD: short circuit antenna with different resistances (modulated by sub_carrier modulated by mod_sig_coil)
|
|
// for pwr_oe4 = 1 (tristate): antenna load = 10k || 33 = 32,9 Ohms
|
|
// for pwr_oe4 = 0 (active): antenna load = 10k || 33 || 33 = 16,5 Ohms
|
|
assign pwr_oe4 = mod_sig_coil & sub_carrier & (mod_type == `FPGA_HF_ISO14443A_TAGSIM_MOD);
|
|
|
|
// This is all LF, so doesn't matter.
|
|
assign pwr_oe2 = 1'b0;
|
|
assign pwr_lo = 1'b0;
|
|
|
|
assign debug = negedge_cnt[3];
|
|
|
|
endmodule
|