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NawfalMotii79-PLFM_RADAR/9_Firmware/9_2_FPGA/radar_transmitter.v
T
Jason a1a8fa7107 chirp-v2 PR-E: plfm_chirp_controller_v2 + scheduler-driven TX via async-FIFO 
Replaces plfm_chirp_controller_enhanced (5-state FSM with hardcoded
LONG/SHORT timings + 60-entry inline short LUT) with plfm_chirp_controller_v2,
a pure DAC playback driver: IDLE -> CHIRP -> IDLE keyed off a 1-cycle
dst_chirp_valid pulse, with sample count selected by dst_wave_sel
(SHORT=120 / MEDIUM=600 / LONG=3600). Inter-chirp timing (LISTEN, GUARD,
frame boundaries) is now owned exclusively by chirp_scheduler.

Scheduler -> TX bridge: cdc_async_fifo (Cummings style #2, WIDTH=2 DEPTH=4)
crosses {wave_sel} from clk_100m to clk_120m_dac, with chirp_pulse as
src_valid. frame_pulse rides a separate toggle CDC for chirp_counter
clear and the new_chirp_frame status output. mixers_enable now also gates
the scheduler so it stays in S_IDLE while the radar is "off" — without
this gate the first chirp_pulse fires at reset and gets dropped before
mixers come up.

Files:
- NEW  plfm_chirp_controller_v2.v      DAC playback driver (3 LUTs, FSM)
- DEL  plfm_chirp_controller.v         legacy controller (382 lines)
- DEL  long_chirp_lut.mem              legacy LUT (3600 lines), replaced
                                       by tx_long_lut.mem from PR-B
- chirp_scheduler.v       + mixers_enable input (master quiesce)
- radar_receiver_final.v  + sched_*_out output ports + mixers_enable_100m
- radar_system_top.v      wire sched_*_out -> tx_inst.sched_*; pass
                          stm32_mixers_enable_100m to rx_inst
- radar_transmitter.v     full rewrite: drop new_chirp edge detector +
                          toggle CDC, instantiate cdc_async_fifo for
                          {wave_sel}, toggle CDC for frame_pulse,
                          plfm_chirp_controller_v2 in place of _enhanced
- tb/tb_chirp_controller.v  + tb/tb_chirp_contract.v  rewritten for v2
                          contract (43/43 unit + 10/10 contract green)
- tb/tb_radar_receiver_final.v  + .mixers_enable_100m(1'b1) pin
- run_regression.sh, scripts/200t/build_200t.tcl  file-list bumped

Test summary:
- tb_chirp_controller_v2:   43/43 PASS
- tb_chirp_contract:        10/10 contracts upheld
- tb_rxb_fullchain:         peak 24033 ~80x (parity with PR-D)
- tb_mti_canceller:         43/43 PASS
- tb_system_e2e:            33/49 (1 new vs 34/49 PR-D baseline: G2.2
                            new_chirp_frame, intentional v2 frame-pulse
                            semantics — fires once per Doppler frame
                            instead of once per stm32 chirp toggle.
                            TB needs widening in PR-H to wait the full
                            frame.)
2026-04-30 21:51:46 +05:45

280 lines
9.5 KiB
Verilog
Raw Blame History

`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// radar_transmitter — DAC-side wrapper around plfm_chirp_controller_v2.
//
// chirp-v2 PR-E reorganization:
// chirp_scheduler (clk_100m, in receiver_final) is now the master timekeeper.
// It emits {wave_sel[1:0], chirp_pulse, frame_pulse} on clk_100m. We bridge
// them to clk_120m_dac here:
// - wave_sel + chirp_pulse → cdc_async_fifo (Cummings style #2). Each
// chirp_pulse pushes wave_sel into the FIFO; the dst-side dst_valid
// pulse drives plfm_chirp_controller_v2.dst_chirp_valid.
// - frame_pulse → toggle CDC → 1-cycle pulse on clk_120m_dac for
// chirp_counter clear and the new_chirp_frame status output.
//
// Beam steering:
// stm32_new_elevation / stm32_new_azimuth still run through edge detectors
// on clk_100m and feed the controller's internal beam counters. These are
// independent of the chirp FSM and unchanged from chirp-v1.
//
// stm32_new_chirp:
// Removed from this module — the scheduler in receiver_final now owns chirp
// timing. The top-level GPIO is still wired to receiver_final via
// stm32_new_chirp_rx; the transmitter has no separate path.
//////////////////////////////////////////////////////////////////////////////////
module radar_transmitter(
// System Clocks
input wire clk_100m, // System clock
input wire clk_120m_dac, // 120MHz DAC clock
input wire reset_n, // Reset synchronized to clk_120m_dac
input wire reset_100m_n, // Reset synchronized to clk_100m (for edge detectors/CDC)
// DAC Interface
output wire [7:0] dac_data,
output wire dac_clk,
output wire dac_sleep,
output wire rx_mixer_en,
output wire tx_mixer_en,
// Scheduler outputs from receiver_final (clk_100m domain) — PR-E
input wire [1:0] sched_wave_sel,
input wire sched_chirp_pulse,
input wire sched_frame_pulse,
// STM32 Control Interface (chirp moved to scheduler; beam-step still here)
input wire stm32_new_elevation,
input wire stm32_new_azimuth,
input wire stm32_mixers_enable,
output wire fpga_rf_switch,
// ADAR1000 Control Interface
output wire adar_tx_load_1,
output wire adar_rx_load_1,
output wire adar_tx_load_2,
output wire adar_rx_load_2,
output wire adar_tx_load_3,
output wire adar_rx_load_3,
output wire adar_tx_load_4,
output wire adar_rx_load_4,
output wire adar_tr_1,
output wire adar_tr_2,
output wire adar_tr_3,
output wire adar_tr_4,
// Level Shifter SPI Interface (STM32F7 to ADAR1000)
input wire stm32_sclk_3v3,
input wire stm32_mosi_3v3,
output wire stm32_miso_3v3,
input wire stm32_cs_adar1_3v3,
input wire stm32_cs_adar2_3v3,
input wire stm32_cs_adar3_3v3,
input wire stm32_cs_adar4_3v3,
output wire stm32_sclk_1v8,
output wire stm32_mosi_1v8,
input wire stm32_miso_1v8,
output wire stm32_cs_adar1_1v8,
output wire stm32_cs_adar2_1v8,
output wire stm32_cs_adar3_1v8,
output wire stm32_cs_adar4_1v8,
// Beam Position Tracking
output wire [5:0] current_elevation,
output wire [5:0] current_azimuth,
output wire [5:0] current_chirp,
output wire new_chirp_frame
);
// ========== SPI LEVEL SHIFTER PASSTHROUGH ==========
// FPGA bridges 3.3V STM32 SPI bus (Bank 15) to 1.8V ADAR1000 SPI bus (Bank 34).
// The FPGA I/O banks handle the actual voltage translation; these assigns
// route the signals through the fabric.
assign stm32_sclk_1v8 = stm32_sclk_3v3;
assign stm32_mosi_1v8 = stm32_mosi_3v3;
assign stm32_miso_3v3 = stm32_miso_1v8;
assign stm32_cs_adar1_1v8 = stm32_cs_adar1_3v3;
assign stm32_cs_adar2_1v8 = stm32_cs_adar2_3v3;
assign stm32_cs_adar3_1v8 = stm32_cs_adar3_3v3;
assign stm32_cs_adar4_1v8 = stm32_cs_adar4_3v3;
// Beam-step edge detection (STM32 GPIO -> clk_100m pulses)
wire new_elevation_pulse;
wire new_azimuth_pulse;
// CDC: Synchronized versions of async STM32 GPIO inputs to clk_100m
wire stm32_new_elevation_sync;
wire stm32_new_azimuth_sync;
// CDC: stm32_mixers_enable into clk_120m_dac domain
wire mixers_enable_120m;
// PR-E: scheduler bridge outputs in clk_120m_dac domain
wire dst_chirp_valid;
wire [1:0] dst_wave_sel;
wire sched_overrun_unused;
wire frame_pulse_120m;
// Chirp Control Signals
wire [7:0] chirp_data;
wire chirp_valid;
wire chirp_sequence_done;
// ============================================================================
// PR-E: chirp_pulse + wave_sel CDC (clk_100m → clk_120m_dac)
//
// Each scheduler chirp_pulse on clk_100m pushes wave_sel into a Gray-coded
// async FIFO. The dst side auto-drains so dst_chirp_valid is a 1-cycle pulse
// on clk_120m_dac, and dst_wave_sel carries the matching waveform identity.
// ============================================================================
cdc_async_fifo #(
.WIDTH(2),
.DEPTH(4)
) cdc_chirp_fifo (
.src_clk (clk_100m),
.dst_clk (clk_120m_dac),
.src_reset_n (reset_100m_n),
.dst_reset_n (reset_n),
.src_data (sched_wave_sel),
.src_valid (sched_chirp_pulse),
.dst_data (dst_wave_sel),
.dst_valid (dst_chirp_valid),
.overrun (sched_overrun_unused)
);
// ============================================================================
// frame_pulse toggle CDC (clk_100m → clk_120m_dac)
// ============================================================================
reg frame_toggle_100m;
always @(posedge clk_100m or negedge reset_100m_n) begin
if (!reset_100m_n)
frame_toggle_100m <= 1'b0;
else if (sched_frame_pulse)
frame_toggle_100m <= ~frame_toggle_100m;
end
wire frame_toggle_120m;
cdc_single_bit #(.STAGES(3)) cdc_frame_toggle (
.src_clk(clk_100m),
.dst_clk(clk_120m_dac),
.reset_n(reset_n),
.src_signal(frame_toggle_100m),
.dst_signal(frame_toggle_120m)
);
reg frame_toggle_120m_prev;
always @(posedge clk_120m_dac or negedge reset_n) begin
if (!reset_n)
frame_toggle_120m_prev <= 1'b0;
else
frame_toggle_120m_prev <= frame_toggle_120m;
end
assign frame_pulse_120m = frame_toggle_120m ^ frame_toggle_120m_prev;
// ============================================================================
// stm32_mixers_enable level CDC into clk_120m_dac
// ============================================================================
cdc_single_bit #(.STAGES(3)) cdc_mixers_en_120m (
.src_clk(clk_100m), // Treat as pseudo-source (GPIO is async)
.dst_clk(clk_120m_dac),
.reset_n(reset_n),
.src_signal(stm32_mixers_enable),
.dst_signal(mixers_enable_120m)
);
// ============================================================================
// Beam-step CDC + edge detection (clk_100m, unchanged from v1)
// ============================================================================
cdc_single_bit #(.STAGES(2)) cdc_stm32_elevation (
.src_clk(clk_100m),
.dst_clk(clk_100m),
.reset_n(reset_100m_n),
.src_signal(stm32_new_elevation),
.dst_signal(stm32_new_elevation_sync)
);
cdc_single_bit #(.STAGES(2)) cdc_stm32_azimuth (
.src_clk(clk_100m),
.dst_clk(clk_100m),
.reset_n(reset_100m_n),
.src_signal(stm32_new_azimuth),
.dst_signal(stm32_new_azimuth_sync)
);
edge_detector_enhanced elevation_edge (
.clk(clk_100m),
.reset_n(reset_100m_n),
.signal_in(stm32_new_elevation_sync),
.rising_falling_edge(new_elevation_pulse)
);
edge_detector_enhanced azimuth_edge (
.clk(clk_100m),
.reset_n(reset_100m_n),
.signal_in(stm32_new_azimuth_sync),
.rising_falling_edge(new_azimuth_pulse)
);
// ============================================================================
// PLFM Chirp Generator (chirp-v2)
// ============================================================================
plfm_chirp_controller_v2 plfm_chirp_inst (
.clk_120m (clk_120m_dac),
.clk_100m (clk_100m),
.reset_n (reset_n),
.reset_100m_n (reset_100m_n),
.mixers_enable (mixers_enable_120m),
// Scheduler bridge (clk_120m_dac, post-CDC)
.dst_chirp_valid (dst_chirp_valid),
.dst_wave_sel (dst_wave_sel),
.frame_pulse_120m(frame_pulse_120m),
// Beam-step pulses (clk_100m)
.new_elevation (new_elevation_pulse),
.new_azimuth (new_azimuth_pulse),
// DAC outputs
.chirp_data (chirp_data),
.chirp_valid (chirp_valid),
.new_chirp_frame(new_chirp_frame),
.chirp_done (chirp_sequence_done),
.rf_switch_ctrl (fpga_rf_switch),
.rx_mixer_en (rx_mixer_en),
.tx_mixer_en (tx_mixer_en),
// ADAR
.adar_tx_load_1 (adar_tx_load_1),
.adar_rx_load_1 (adar_rx_load_1),
.adar_tx_load_2 (adar_tx_load_2),
.adar_rx_load_2 (adar_rx_load_2),
.adar_tx_load_3 (adar_tx_load_3),
.adar_rx_load_3 (adar_rx_load_3),
.adar_tx_load_4 (adar_tx_load_4),
.adar_rx_load_4 (adar_rx_load_4),
.adar_tr_1 (adar_tr_1),
.adar_tr_2 (adar_tr_2),
.adar_tr_3 (adar_tr_3),
.adar_tr_4 (adar_tr_4),
// Status counters
.chirp_counter (current_chirp),
.elevation_counter(current_elevation),
.azimuth_counter (current_azimuth)
);
// ============================================================================
// DAC Output Interface
// ============================================================================
dac_interface_enhanced dac_interface_inst (
.clk_120m (clk_120m_dac),
.reset_n (reset_n),
.chirp_data (chirp_data),
.chirp_valid(chirp_valid),
.dac_data (dac_data),
.dac_clk (dac_clk),
.dac_sleep (dac_sleep)
);
endmodule
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