// *************************************************************************** // *************************************************************************** // Copyright 2014 - 2020 (c) Analog Devices, Inc. All rights reserved. // // In this HDL repository, there are many different and unique modules, consisting // of various HDL (Verilog or VHDL) components. The individual modules are // developed independently, and may be accompanied by separate and unique license // terms. // // The user should read each of these license terms, and understand the // freedoms and responsibilities that he or she has by using this source/core. // // This core is distributed in the hope that it will be useful, but WITHOUT ANY // WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR // A PARTICULAR PURPOSE. // // Redistribution and use of source or resulting binaries, with or without modification // of this file, are permitted under one of the following two license terms: // // 1. The GNU General Public License version 2 as published by the // Free Software Foundation, which can be found in the top level directory // of this repository (LICENSE_GPL2), and also online at: // // // OR // // 2. An ADI specific BSD license, which can be found in the top level directory // of this repository (LICENSE_ADIBSD), and also on-line at: // https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD // This will allow to generate bit files and not release the source code, // as long as it attaches to an ADI device. // // *************************************************************************** // *************************************************************************** `timescale 1ns/100ps module axi_adrv9001_rx_channel #( parameter Q_OR_I_N = 0, parameter COMMON_ID = 0, parameter CHANNEL_ID = 0, parameter DISABLE = 0, parameter DATAFORMAT_DISABLE = 0, parameter DCFILTER_DISABLE = 0, parameter IQCORRECTION_DISABLE = 0, parameter DATA_WIDTH = 16 ) ( // adc interface input adc_clk, input adc_rst, input adc_valid_in, input [(DATA_WIDTH-1):0] adc_data_in, output adc_valid_out, output [(DATA_WIDTH-1):0] adc_data_out, input [(DATA_WIDTH-1):0] adc_data_iq_in, output [(DATA_WIDTH-1):0] adc_data_iq_out, output adc_enable, input dac_valid_in, input [(DATA_WIDTH-1):0] dac_data_in, // channel interface output up_adc_pn_err, output up_adc_pn_oos, output up_adc_or, // processor interface input up_rstn, input up_clk, input up_wreq, input [13:0] up_waddr, input [31:0] up_wdata, output up_wack, input up_rreq, input [13:0] up_raddr, output [31:0] up_rdata, output up_rack ); localparam NUM_OF_SAMPLES = DATA_WIDTH/16; // internal signals wire [(NUM_OF_SAMPLES-1):0] adc_dfmt_valid_s; wire [(DATA_WIDTH-1):0] adc_dfmt_data_s; wire [(NUM_OF_SAMPLES-1):0] adc_dcfilter_valid_s; wire [(DATA_WIDTH-1):0] adc_dcfilter_data_s; wire [(NUM_OF_SAMPLES-1):0] adc_valid_out_s; wire adc_pn_err_s; wire adc_pn_oos_s; wire [3:0] adc_pnseq_sel; wire adc_dfmt_se_s; wire adc_dfmt_type_s; wire adc_dfmt_enable_s; wire adc_dcfilt_enb_s; wire [15:0] adc_dcfilt_offset_s; wire [15:0] adc_dcfilt_coeff_s; wire adc_iqcor_enb_s; wire [15:0] adc_iqcor_coeff_1_s; wire [15:0] adc_iqcor_coeff_2_s; wire [(DATA_WIDTH-1):0] adc_data_pn; wire [(DATA_WIDTH-1):0] pn7_data; wire [(DATA_WIDTH-1):0] pn15_data; wire [ 3:0] adc_data_sel_s; wire [15:0] adc_data_in_s; wire adc_valid_in_s; reg [15:0] full_ramp_counter = 'd0; reg adc_valid_in_d = 'h0; reg adc_valid_in_2d = 'h0; reg [(DATA_WIDTH-1):0] adc_data_in_d = 'h0; reg [(DATA_WIDTH-1):0] adc_data_in_2d = 'h0; reg dac_valid_in_d = 'h0; reg dac_valid_in_2d = 'h0; reg [(DATA_WIDTH-1):0] dac_data_in_d = 'h0; reg [(DATA_WIDTH-1):0] dac_data_in_2d = 'h0; // variables genvar n; // input pipeline stage to protect logic if data comes from an async clock domain always @(posedge adc_clk) begin adc_valid_in_d <= adc_valid_in; adc_valid_in_2d <= adc_valid_in_d; adc_data_in_d <= adc_data_in; adc_data_in_2d <= adc_data_in_d; end always @(posedge adc_clk) begin dac_valid_in_d <= dac_valid_in; dac_valid_in_2d <= dac_valid_in_d; dac_data_in_d <= dac_data_in; dac_data_in_2d <= dac_data_in_d; end assign adc_data_in_s = (adc_data_sel_s == 4'h0) ? adc_data_in_2d : dac_data_in_2d; assign adc_valid_in_s = (adc_data_sel_s == 4'h0) ? adc_valid_in_2d : dac_valid_in_2d; // iq correction inputs generate for (n = 0; n < NUM_OF_SAMPLES; n = n + 1) begin: g_datafmt if (DISABLE == 1 || DATAFORMAT_DISABLE == 1) begin assign adc_dfmt_valid_s[n] = adc_valid_in_s; assign adc_dfmt_data_s[((16*n)+15):(16*n)] = adc_data_in_s[((16*n)+15):(16*n)]; end else begin ad_datafmt #(.DATA_WIDTH (16)) i_ad_datafmt ( .clk (adc_clk), .valid (adc_valid_in_s), .data (adc_data_in_s[((16*n)+15):(16*n)]), .valid_out (adc_dfmt_valid_s[n]), .data_out (adc_dfmt_data_s[((16*n)+15):(16*n)]), .dfmt_enable (adc_dfmt_enable_s), .dfmt_type (adc_dfmt_type_s), .dfmt_se (adc_dfmt_se_s)); end end for (n = 0; n < NUM_OF_SAMPLES; n = n + 1) begin: g_dcfilter if (DISABLE == 1 || DCFILTER_DISABLE == 1) begin assign adc_dcfilter_valid_s[n] = adc_dfmt_valid_s[n]; assign adc_dcfilter_data_s[((16*n)+15):(16*n)] = adc_dfmt_data_s[((16*n)+15):(16*n)]; end else begin ad_dcfilter i_ad_dcfilter ( .clk (adc_clk), .valid (adc_dfmt_valid_s[n]), .data (adc_dfmt_data_s[((16*n)+15):(16*n)]), .valid_out (adc_dcfilter_valid_s[n]), .data_out (adc_dcfilter_data_s[((16*n)+15):(16*n)]), .dcfilt_enb (adc_dcfilt_enb_s), .dcfilt_coeff (adc_dcfilt_coeff_s), .dcfilt_offset (adc_dcfilt_offset_s)); end end assign adc_valid_out = adc_valid_out_s[0]; assign adc_data_iq_out = adc_dcfilter_data_s; for (n = 0; n < NUM_OF_SAMPLES; n = n + 1) begin: g_iqcor if (DISABLE == 1 || IQCORRECTION_DISABLE == 1) begin assign adc_valid_out_s[n] = adc_dcfilter_valid_s[n]; assign adc_data_out[((16*n)+15):(16*n)] = adc_dcfilter_data_s[((16*n)+15):(16*n)]; end else begin ad_iqcor #(.Q_OR_I_N (Q_OR_I_N)) i_ad_iqcor ( .clk (adc_clk), .valid (adc_dcfilter_valid_s[n]), .data_in (adc_dcfilter_data_s[((16*n)+15):(16*n)]), .data_iq (adc_data_iq_in[((16*n)+15):(16*n)]), .valid_out (adc_valid_out_s[n]), .data_out (adc_data_out[((16*n)+15):(16*n)]), .iqcor_enable (adc_iqcor_enb_s), .iqcor_coeff_1 (adc_iqcor_coeff_1_s), .iqcor_coeff_2 (adc_iqcor_coeff_2_s)); end end if (DISABLE == 1) begin assign adc_enable = 1'b0; assign up_adc_pn_err = 1'b0; assign up_adc_pn_oos = 1'b0; assign up_adc_or = 1'b0; assign up_wack = 1'b0; assign up_rdata = 32'b0; assign up_rack = 1'b0; end else begin // pn oos & pn err // PN7 x^7 + x^6 + 1 ad_pngen #( .POL_MASK ( (1<<7) | (1<<6) ), .POL_W (7), .DW (16) ) PN7_gen ( .clk (adc_clk), .reset (adc_rst), .clk_en (adc_valid_in_s), .pn_init (adc_pn_oos_s), .pn_data_in (adc_data_in_s), .pn_data_out (pn7_data) ); // PN15 x^15 + x^14 + 1 ad_pngen #( .POL_MASK ( (1<<15) | (1<<14) ), .POL_W (15), .DW (16) ) PN15_gen ( .clk (adc_clk), .reset (adc_rst), .clk_en (adc_valid_in_s), .pn_init (adc_pn_oos_s), .pn_data_in (adc_data_in_s), .pn_data_out (pn15_data) ); // reference nibble ramp and full ramp generator always @(posedge adc_clk) begin if (adc_valid_in_s) begin if (adc_pn_oos_s) begin full_ramp_counter <= adc_data_in_s + 16'd1; end else begin full_ramp_counter <= full_ramp_counter + 16'd1; end end end assign adc_data_pn = adc_pnseq_sel == 4'd4 ? pn7_data : adc_pnseq_sel == 4'd5 ? pn15_data : adc_pnseq_sel == 4'd10 ? {4{full_ramp_counter[3:0]}} : adc_pnseq_sel == 4'd11 ? full_ramp_counter : 'h0; ad_pnmon #( .DATA_WIDTH (DATA_WIDTH), .OOS_THRESHOLD (8), .ALLOW_ZERO_MASKING(1) ) i_pnmon ( .adc_clk (adc_clk), .adc_valid_in (adc_valid_in_s), .adc_data_in (adc_data_in_s), .adc_data_pn (adc_data_pn), .adc_pattern_has_zero (adc_pnseq_sel[3]), .adc_pn_oos (adc_pn_oos_s), .adc_pn_err (adc_pn_err_s) ); up_adc_channel #( .COMMON_ID (COMMON_ID), .CHANNEL_ID (CHANNEL_ID), .USERPORTS_DISABLE(1), .DATAFORMAT_DISABLE(DATAFORMAT_DISABLE), .DCFILTER_DISABLE(DCFILTER_DISABLE), .IQCORRECTION_DISABLE(IQCORRECTION_DISABLE)) i_up_adc_channel ( .adc_clk (adc_clk), .adc_rst (adc_rst), .adc_enable (adc_enable), .adc_iqcor_enb (adc_iqcor_enb_s), .adc_dcfilt_enb (adc_dcfilt_enb_s), .adc_dfmt_se (adc_dfmt_se_s), .adc_dfmt_type (adc_dfmt_type_s), .adc_dfmt_enable (adc_dfmt_enable_s), .adc_dcfilt_offset (adc_dcfilt_offset_s), .adc_dcfilt_coeff (adc_dcfilt_coeff_s), .adc_iqcor_coeff_1 (adc_iqcor_coeff_1_s), .adc_iqcor_coeff_2 (adc_iqcor_coeff_2_s), .adc_pnseq_sel (adc_pnseq_sel), .adc_data_sel (adc_data_sel_s), .adc_pn_err (adc_pn_err_s), .adc_pn_oos (adc_pn_oos_s), .adc_or (1'd0), .up_adc_pn_err (up_adc_pn_err), .up_adc_pn_oos (up_adc_pn_oos), .up_adc_or (up_adc_or), .up_usr_datatype_be (), .up_usr_datatype_signed (), .up_usr_datatype_shift (), .up_usr_datatype_total_bits (), .up_usr_datatype_bits (), .up_usr_decimation_m (), .up_usr_decimation_n (), .adc_usr_datatype_be (1'b0), .adc_usr_datatype_signed (1'b1), .adc_usr_datatype_shift (8'd0), .adc_usr_datatype_total_bits (8'd16), .adc_usr_datatype_bits (8'd16), .adc_usr_decimation_m (16'd1), .adc_usr_decimation_n (16'd1), .up_rstn (up_rstn), .up_clk (up_clk), .up_wreq (up_wreq), .up_waddr (up_waddr), .up_wdata (up_wdata), .up_wack (up_wack), .up_rreq (up_rreq), .up_raddr (up_raddr), .up_rdata (up_rdata), .up_rack (up_rack)); end endgenerate endmodule // *************************************************************************** // ***************************************************************************