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1 | //-----------------------------------------------------------------------------\r | |
2 | // The way that we connect things in low-frequency read mode. In this case\r | |
3 | // we are generating the 134 kHz or 125 kHz carrier, and running the \r | |
4 | // unmodulated carrier at that frequency. The A/D samples at that same rate,\r | |
5 | // and the result is serialized.\r | |
6 | //\r | |
7 | // Jonathan Westhues, April 2006\r | |
8 | //-----------------------------------------------------------------------------\r | |
9 | \r | |
10 | module lo_read(\r | |
11 | pck0, ck_1356meg, ck_1356megb,\r | |
12 | pwr_lo, pwr_hi, pwr_oe1, pwr_oe2, pwr_oe3, pwr_oe4,\r | |
13 | adc_d, adc_clk,\r | |
14 | ssp_frame, ssp_din, ssp_dout, ssp_clk,\r | |
15 | cross_hi, cross_lo,\r | |
16 | dbg,\r | |
17 | lo_is_125khz\r | |
18 | );\r | |
19 | input pck0, ck_1356meg, ck_1356megb;\r | |
20 | output pwr_lo, pwr_hi, pwr_oe1, pwr_oe2, pwr_oe3, pwr_oe4;\r | |
21 | input [7:0] adc_d;\r | |
22 | output adc_clk;\r | |
23 | input ssp_dout;\r | |
24 | output ssp_frame, ssp_din, ssp_clk;\r | |
25 | input cross_hi, cross_lo;\r | |
26 | output dbg;\r | |
27 | input lo_is_125khz;\r | |
28 | \r | |
29 | // The low-frequency RFID stuff. This is relatively simple, because most\r | |
30 | // of the work happens on the ARM, and we just pass samples through. The\r | |
31 | // PCK0 must be divided down to generate the A/D clock, and from there by\r | |
32 | // a factor of 8 to generate the carrier (that we apply to the coil drivers).\r | |
33 | //\r | |
34 | // This is also where we decode the received synchronous serial port words,\r | |
35 | // to determine how to drive the output enables.\r | |
36 | \r | |
37 | // PCK0 will run at (PLL clock) / 4, or 24 MHz. That means that we can do\r | |
38 | // 125 kHz by dividing by a further factor of (8*12*2), or ~134 kHz by\r | |
39 | // dividing by a factor of (8*11*2) (for 136 kHz, ~2% error, tolerable).\r | |
40 | \r | |
41 | reg [3:0] pck_divider;\r | |
42 | reg clk_lo;\r | |
43 | \r | |
44 | always @(posedge pck0)\r | |
45 | begin\r | |
46 | if(lo_is_125khz)\r | |
47 | begin\r | |
48 | if(pck_divider == 4'd11)\r | |
49 | begin\r | |
50 | pck_divider <= 4'd0;\r | |
51 | clk_lo = !clk_lo;\r | |
52 | end\r | |
53 | else\r | |
54 | pck_divider <= pck_divider + 1;\r | |
55 | end\r | |
56 | else\r | |
57 | begin\r | |
58 | if(pck_divider == 4'd10)\r | |
59 | begin\r | |
60 | pck_divider <= 4'd0;\r | |
61 | clk_lo = !clk_lo;\r | |
62 | end\r | |
63 | else\r | |
64 | pck_divider <= pck_divider + 1;\r | |
65 | end\r | |
66 | end\r | |
67 | \r | |
68 | reg [2:0] carrier_divider_lo;\r | |
69 | \r | |
70 | always @(posedge clk_lo)\r | |
71 | begin\r | |
72 | carrier_divider_lo <= carrier_divider_lo + 1;\r | |
73 | end\r | |
74 | \r | |
75 | assign pwr_lo = carrier_divider_lo[2];\r | |
76 | \r | |
77 | // This serializes the values returned from the A/D, and sends them out\r | |
78 | // over the SSP.\r | |
79 | \r | |
80 | reg [7:0] to_arm_shiftreg;\r | |
81 | \r | |
82 | always @(posedge clk_lo)\r | |
83 | begin\r | |
84 | if(carrier_divider_lo == 3'b000)\r | |
85 | to_arm_shiftreg <= adc_d;\r | |
86 | else\r | |
87 | to_arm_shiftreg[7:1] <= to_arm_shiftreg[6:0];\r | |
88 | end\r | |
89 | \r | |
90 | assign ssp_clk = clk_lo;\r | |
91 | assign ssp_frame = (carrier_divider_lo == 3'b001);\r | |
92 | assign ssp_din = to_arm_shiftreg[7];\r | |
93 | \r | |
94 | // The ADC converts on the falling edge, and our serializer loads when\r | |
95 | // carrier_divider_lo == 3'b000.\r | |
96 | assign adc_clk = ~carrier_divider_lo[2];\r | |
97 | \r | |
98 | assign pwr_hi = 1'b0;\r | |
99 | \r | |
100 | assign dbg = adc_clk;\r | |
101 | \r | |
102 | endmodule\r |