300 lines
11 KiB
Verilog
300 lines
11 KiB
Verilog
// ***************************************************************************
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// ***************************************************************************
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// Copyright 2022 (c) Analog Devices, Inc. All rights reserved.
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//
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// In this HDL repository, there are many different and unique modules, consisting
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// of various HDL (Verilog or VHDL) components. The individual modules are
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// developed independently, and may be accompanied by separate and unique license
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// terms.
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//
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// The user should read each of these license terms, and understand the
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// freedoms and responsibilities that he or she has by using this source/core.
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//
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// This core is distributed in the hope that it will be useful, but WITHOUT ANY
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// WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
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// A PARTICULAR PURPOSE.
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//
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// Redistribution and use of source or resulting binaries, with or without modification
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// of this file, are permitted under one of the following two license terms:
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//
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// 1. The GNU General Public License version 2 as published by the
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// Free Software Foundation, which can be found in the top level directory
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// of this repository (LICENSE_GPL2), and also online at:
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// <https://www.gnu.org/licenses/old-licenses/gpl-2.0.html>
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//
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// OR
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//
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// 2. An ADI specific BSD license, which can be found in the top level directory
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// of this repository (LICENSE_ADIBSD), and also on-line at:
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// https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD
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// This will allow to generate bit files and not release the source code,
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// as long as it attaches to an ADI device.
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//
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// ***************************************************************************
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// ***************************************************************************
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// This is the LVDS/DDR interface, note that overrange is independent of data path,
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// software will not be able to relate overrange to a specific sample!
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`timescale 1ns/100ps
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module axi_adaq8092_if #(
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parameter FPGA_TECHNOLOGY = 0,
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parameter IO_DELAY_GROUP = "adc_if_delay_group",
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parameter DELAY_REFCLK_FREQUENCY = 200,
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parameter [27:0] POLARITY_MASK ='hfffffff,
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parameter OUTPUT_MODE = 0
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) (
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// adc interface (clk, data, over-range)
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// nominal clock 80 MHz, up to 105 MHz
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input adc_clk_in_p,
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input adc_clk_in_n,
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input [13:0] lvds_adc_data_p,
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input [13:0] lvds_adc_data_n,
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input lvds_adc_or_p,
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input lvds_adc_or_n,
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input [27:0] cmos_adc_data,
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input cmos_adc_data_or_1,
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input cmos_adc_data_or_2,
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// up control SDR or DDR
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input sdr_or_ddr,
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// interface outputs
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output adc_clk,
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output reg [27:0] adc_data,
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output reg adc_or,
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output reg adc_status,
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// delay control signals
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input up_clk,
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input [29:0] up_dld,
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input [149:0] up_dwdata,
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output [149:0] up_drdata,
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input delay_clk,
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input delay_rst,
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output delay_locked
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);
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// internal registers
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reg [27:0] adc_data_s='b0;
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// internal signals
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wire [13:0] lvds_adc_data_p_s;
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wire [13:0] lvds_adc_data_n_s;
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wire [27:0] cmos_adc_data_p_s;
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wire [27:0] cmos_adc_data_n_s;
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wire adc_or_s_1;
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wire adc_or_s_2;
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wire adc_or_s_1_p;
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wire adc_or_s_1_n;
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wire adc_or_s_2_p;
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wire adc_or_s_2_n;
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wire [27:0] adc_data_if_out;
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genvar l_inst;
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// LOCAL parameters
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localparam LVDS = 0;
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localparam CMOS = 1;
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always @(posedge adc_clk) begin
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adc_status <= 1'b1;
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if (OUTPUT_MODE == LVDS) begin
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adc_or <= adc_or_s_1 | adc_or_s_2;
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adc_data <= POLARITY_MASK ^ adc_data_s;
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adc_data_s <= { lvds_adc_data_n_s[13], lvds_adc_data_p_s[13],
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lvds_adc_data_n_s[12], lvds_adc_data_p_s[12],
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lvds_adc_data_n_s[11], lvds_adc_data_p_s[11],
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lvds_adc_data_n_s[10], lvds_adc_data_p_s[10],
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lvds_adc_data_n_s[9], lvds_adc_data_p_s[9],
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lvds_adc_data_n_s[8], lvds_adc_data_p_s[8],
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lvds_adc_data_n_s[7], lvds_adc_data_p_s[7],
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lvds_adc_data_n_s[6], lvds_adc_data_p_s[6],
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lvds_adc_data_n_s[5], lvds_adc_data_p_s[5],
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lvds_adc_data_n_s[4], lvds_adc_data_p_s[4],
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lvds_adc_data_n_s[3], lvds_adc_data_p_s[3],
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lvds_adc_data_n_s[2], lvds_adc_data_p_s[2],
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lvds_adc_data_n_s[1], lvds_adc_data_p_s[1],
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lvds_adc_data_n_s[0], lvds_adc_data_p_s[0]};
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end else if (OUTPUT_MODE == CMOS) begin
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adc_data <= adc_data_s;
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if (sdr_or_ddr == 0) begin //DDR_CMOS
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adc_or <= adc_or_s_1_p | adc_or_s_1_n;
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adc_data_s <= { cmos_adc_data_n_s[27], cmos_adc_data_p_s[27],
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cmos_adc_data_n_s[25], cmos_adc_data_p_s[25],
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cmos_adc_data_n_s[23], cmos_adc_data_p_s[23],
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cmos_adc_data_n_s[21], cmos_adc_data_p_s[21],
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cmos_adc_data_n_s[19], cmos_adc_data_p_s[19],
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cmos_adc_data_n_s[17], cmos_adc_data_p_s[17],
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cmos_adc_data_n_s[15], cmos_adc_data_p_s[15],
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cmos_adc_data_n_s[13], cmos_adc_data_p_s[13],
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cmos_adc_data_n_s[11], cmos_adc_data_p_s[11],
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cmos_adc_data_n_s[9], cmos_adc_data_p_s[9],
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cmos_adc_data_n_s[7], cmos_adc_data_p_s[7],
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cmos_adc_data_n_s[5], cmos_adc_data_p_s[5],
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cmos_adc_data_n_s[3], cmos_adc_data_p_s[3],
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cmos_adc_data_n_s[1], cmos_adc_data_p_s[1]};
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end else if (sdr_or_ddr == 1) begin //SDR_CMOS
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adc_or <= adc_or_s_1_p | adc_or_s_2_p;
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adc_data_s <= { cmos_adc_data_p_s[27], cmos_adc_data_p_s[26],
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cmos_adc_data_p_s[25], cmos_adc_data_p_s[24],
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cmos_adc_data_p_s[23], cmos_adc_data_p_s[22],
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cmos_adc_data_p_s[21], cmos_adc_data_p_s[20],
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cmos_adc_data_p_s[19], cmos_adc_data_p_s[18],
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cmos_adc_data_p_s[17], cmos_adc_data_p_s[16],
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cmos_adc_data_p_s[15], cmos_adc_data_p_s[14],
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cmos_adc_data_p_s[13], cmos_adc_data_p_s[12],
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cmos_adc_data_p_s[11], cmos_adc_data_p_s[10],
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cmos_adc_data_p_s[9], cmos_adc_data_p_s[8],
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cmos_adc_data_p_s[7], cmos_adc_data_p_s[6],
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cmos_adc_data_p_s[5], cmos_adc_data_p_s[4],
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cmos_adc_data_p_s[3], cmos_adc_data_p_s[2],
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cmos_adc_data_p_s[1], cmos_adc_data_p_s[0]};
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end
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end
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end
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// data interface
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generate
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if (OUTPUT_MODE == LVDS) begin
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for (l_inst = 0; l_inst <= 13; l_inst = l_inst + 1) begin : lvds_adc_if // DDR LVDS INTERFACE
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ad_data_in #(
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.FPGA_TECHNOLOGY (FPGA_TECHNOLOGY),
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.IODELAY_CTRL (0),
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.IODELAY_GROUP (IO_DELAY_GROUP),
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.REFCLK_FREQUENCY (DELAY_REFCLK_FREQUENCY),
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.IDDR_CLK_EDGE("OPPOSITE_EDGE")
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) i_adc_data (
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.rx_clk (adc_clk),
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.rx_data_in_p (lvds_adc_data_p[l_inst]),
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.rx_data_in_n (lvds_adc_data_n[l_inst]),
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.rx_data_p (lvds_adc_data_p_s[l_inst]),
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.rx_data_n (lvds_adc_data_n_s[l_inst]),
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.up_clk (up_clk),
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.up_dld (up_dld[l_inst]),
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.up_dwdata (up_dwdata[((l_inst*5)+4):(l_inst*5)]),
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.up_drdata (up_drdata[((l_inst*5)+4):(l_inst*5)]),
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.delay_clk (delay_clk),
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.delay_rst (delay_rst),
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.delay_locked ());
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end
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end else if (OUTPUT_MODE == CMOS) begin
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for (l_inst = 0; l_inst <= 27; l_inst = l_inst + 1) begin : cmos_adc_if // CMOS INTERFACE
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ad_data_in #(
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.SINGLE_ENDED(1),
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.FPGA_TECHNOLOGY (FPGA_TECHNOLOGY),
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.IODELAY_CTRL (0),
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.IODELAY_GROUP (IO_DELAY_GROUP),
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.REFCLK_FREQUENCY (DELAY_REFCLK_FREQUENCY),
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.IDDR_CLK_EDGE("OPPOSITE_EDGE")
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) i_adc_data (
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.rx_clk (adc_clk),
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.rx_data_in_p (cmos_adc_data[l_inst]),
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.rx_data_in_n (),
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.rx_data_p (cmos_adc_data_p_s[l_inst]),
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.rx_data_n (cmos_adc_data_n_s[l_inst]),
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.up_clk (up_clk),
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.up_dld (up_dld[l_inst]),
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.up_dwdata (up_dwdata[((l_inst*5)+4):(l_inst*5)]),
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.up_drdata (up_drdata[((l_inst*5)+4):(l_inst*5)]),
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.delay_clk (delay_clk),
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.delay_rst (delay_rst),
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.delay_locked ());
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end
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end
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endgenerate
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// over-range interface
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if (OUTPUT_MODE == LVDS) begin
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ad_data_in #(
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.FPGA_TECHNOLOGY (FPGA_TECHNOLOGY),
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.IODELAY_CTRL (1),
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.IODELAY_GROUP (IO_DELAY_GROUP),
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.REFCLK_FREQUENCY (DELAY_REFCLK_FREQUENCY),
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.IDDR_CLK_EDGE("OPPOSITE_EDGE")
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) i_adc_or_lvds (
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.rx_clk (adc_clk),
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.rx_data_in_p (lvds_adc_or_p),
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.rx_data_in_n (lvds_adc_or_n),
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.rx_data_p (adc_or_s_1),
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.rx_data_n (adc_or_s_2),
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.up_clk (up_clk),
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.up_dld (up_dld[14]),
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.up_dwdata (up_dwdata[74:70]),
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.up_drdata (up_drdata[74:70]),
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.delay_clk (delay_clk),
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.delay_rst (delay_rst),
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.delay_locked (delay_locked));
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end else if (OUTPUT_MODE == CMOS) begin
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ad_data_in #(
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.SINGLE_ENDED(1),
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.FPGA_TECHNOLOGY (FPGA_TECHNOLOGY),
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.IODELAY_CTRL (1),
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.IODELAY_GROUP (IO_DELAY_GROUP),
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.REFCLK_FREQUENCY (DELAY_REFCLK_FREQUENCY),
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.IDDR_CLK_EDGE("OPPOSITE_EDGE")
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) i_adc_or_cmos_1 (
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.rx_clk (adc_clk),
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.rx_data_in_p (cmos_adc_data_or_1),
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.rx_data_in_n (),
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.rx_data_p (adc_or_s_1_p),
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.rx_data_n (adc_or_s_1_n),
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.up_clk (up_clk),
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.up_dld (up_dld[28]),
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.up_dwdata (up_dwdata[144:140]),
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.up_drdata (up_drdata[144:140]),
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.delay_clk (delay_clk),
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.delay_rst (delay_rst),
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.delay_locked ());
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ad_data_in #(
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.SINGLE_ENDED(1),
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.FPGA_TECHNOLOGY (FPGA_TECHNOLOGY),
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.IODELAY_CTRL (1),
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.IODELAY_GROUP (IO_DELAY_GROUP),
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.REFCLK_FREQUENCY (DELAY_REFCLK_FREQUENCY),
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.IDDR_CLK_EDGE("OPPOSITE_EDGE")
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) i_adc_or_cmos_2 (
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.rx_clk (adc_clk),
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.rx_data_in_p (cmos_adc_data_or_2),
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.rx_data_in_n (),
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.rx_data_p (adc_or_s_2_p),
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.rx_data_n (adc_or_s_2_n),
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.up_clk (up_clk),
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.up_dld (up_dld[29]),
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.up_dwdata (up_dwdata[149:145]),
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.up_drdata (up_drdata[149:145]),
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.delay_clk (delay_clk),
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.delay_rst (delay_rst),
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.delay_locked ());
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end
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// clock
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ad_data_clk i_adc_clk (
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.rst (1'b0),
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.locked (),
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.clk_in_p (adc_clk_in_p),
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.clk_in_n (adc_clk_in_n),
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.clk (adc_clk));
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endmodule
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