// *************************************************************************** // *************************************************************************** // Copyright 2011(c) Analog Devices, Inc. // // All rights reserved. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // - Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // - Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in // the documentation and/or other materials provided with the // distribution. // - Neither the name of Analog Devices, Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // - The use of this software may or may not infringe the patent rights // of one or more patent holders. This license does not release you // from the requirement that you obtain separate licenses from these // patent holders to use this software. // - Use of the software either in source or binary form, must be run // on or directly connected to an Analog Devices Inc. component. // // THIS SOFTWARE IS PROVIDED BY ANALOG DEVICES "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, // INCLUDING, BUT NOT LIMITED TO, NON-INFRINGEMENT, MERCHANTABILITY AND FITNESS FOR A // PARTICULAR PURPOSE ARE DISCLAIMED. // // IN NO EVENT SHALL ANALOG DEVICES BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, INTELLECTUAL PROPERTY // RIGHTS, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR // BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF // THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // *************************************************************************** // *************************************************************************** `timescale 1ns/100ps module axi_ad9361_cmos_if ( // physical interface (receive) rx_clk_in, rx_frame_in, rx_data_in, // physical interface (transmit) tx_clk_out, tx_frame_out, tx_data_out, // ensm control enable, txnrx, // clock (common to both receive and transmit) rst, clk, l_clk, // receive data path interface adc_valid, adc_data, adc_status, adc_r1_mode, adc_ddr_edgesel, // transmit data path interface dac_valid, dac_data, dac_r1_mode, // tdd interface tdd_enable, tdd_txnrx, tdd_mode, // delay interface up_clk, up_enable, up_txnrx, up_adc_dld, up_adc_dwdata, up_adc_drdata, up_dac_dld, up_dac_dwdata, up_dac_drdata, delay_clk, delay_rst, delay_locked); // this parameter controls the buffer type based on the target device. parameter DEVICE_TYPE = 0; parameter DAC_IODELAY_ENABLE = 0; parameter IO_DELAY_GROUP = "dev_if_delay_group"; // physical interface (receive) input rx_clk_in; input rx_frame_in; input [11:0] rx_data_in; // physical interface (transmit) output tx_clk_out; output tx_frame_out; output [11:0] tx_data_out; // ensm control output enable; output txnrx; // clock (common to both receive and transmit) input rst; input clk; output l_clk; // receive data path interface output adc_valid; output [47:0] adc_data; output adc_status; input adc_r1_mode; input adc_ddr_edgesel; // transmit data path interface input dac_valid; input [47:0] dac_data; input dac_r1_mode; // tdd interface input tdd_enable; input tdd_txnrx; input tdd_mode; // delay interface input up_clk; input up_enable; input up_txnrx; input [12:0] up_adc_dld; input [64:0] up_adc_dwdata; output [64:0] up_adc_drdata; input [15:0] up_dac_dld; input [79:0] up_dac_dwdata; output [79:0] up_dac_drdata; input delay_clk; input delay_rst; output delay_locked; // internal registers reg [ 1:0] rx_frame = 0; reg [11:0] rx_data_p = 0; reg rx_error_r1 = 'd0; reg rx_valid_r1 = 'd0; reg [23:0] rx_data_r1 = 'd0; reg rx_error_r2 = 'd0; reg rx_valid_r2 = 'd0; reg [47:0] rx_data_r2 = 'd0; reg adc_p_valid = 'd0; reg [47:0] adc_p_data = 'd0; reg adc_p_status = 'd0; reg adc_n_valid = 'd0; reg [47:0] adc_n_data = 'd0; reg adc_n_status = 'd0; reg adc_valid_int = 'd0; reg [47:0] adc_data_int = 'd0; reg adc_status_int = 'd0; reg adc_valid = 'd0; reg [47:0] adc_data = 'd0; reg adc_status = 'd0; reg [ 1:0] tx_data_cnt = 'd0; reg [47:0] tx_data = 'd0; reg tx_frame_p = 'd0; reg tx_frame_n = 'd0; reg [11:0] tx_data_p = 'd0; reg [11:0] tx_data_n = 'd0; reg tx_n_frame_p = 'd0; reg tx_n_frame_n = 'd0; reg [11:0] tx_n_data_p = 'd0; reg [11:0] tx_n_data_n = 'd0; reg tx_p_frame_p = 'd0; reg tx_p_frame_n = 'd0; reg [11:0] tx_p_data_p = 'd0; reg [11:0] tx_p_data_n = 'd0; reg up_enable_int = 'd0; reg up_txnrx_int = 'd0; reg enable_up_m1 = 'd0; reg txnrx_up_m1 = 'd0; reg enable_up = 'd0; reg txnrx_up = 'd0; reg enable_int = 'd0; reg txnrx_int = 'd0; reg enable_n_int = 'd0; reg txnrx_n_int = 'd0; reg enable_p_int = 'd0; reg txnrx_p_int = 'd0; // internal signals wire [ 1:0] rx_frame_s; wire [ 3:0] rx_frame_4_s; wire [ 2:0] tx_data_sel_s; wire [11:0] rx_data_p_s; wire [11:0] rx_data_n_s; wire rx_frame_p_s; wire rx_frame_n_s; genvar l_inst; // receive data path interface assign rx_frame_s = {rx_frame_p_s, rx_frame_n_s}; assign rx_frame_4_s = {rx_frame_s, rx_frame}; always @(posedge l_clk) begin rx_frame <= rx_frame_s; rx_data_p <= rx_data_p_s; end // receive data path for single rf, frame is expected to qualify i only always @(posedge l_clk) begin rx_error_r1 <= ~^ rx_frame_s; rx_valid_r1 <= ^ rx_frame_s; case (rx_frame_s) 2'b01: rx_data_r1 <= {rx_data_p_s, rx_data_n_s}; 2'b10: rx_data_r1 <= {rx_data_n_s, rx_data_p}; default: rx_data_r1 <= 24'd0; endcase end // receive data path for dual rf, frame is expected to qualify iq for rf-1 only always @(posedge l_clk) begin rx_error_r2 <= ((rx_frame_4_s == 4'b0011) || (rx_frame_4_s == 4'b1001)) ? 1'b0 : 1'b1; rx_valid_r2 <= ((rx_frame_4_s == 4'b0011) || (rx_frame_4_s == 4'b1001)) ? 1'b1 : 1'b0; case (rx_frame_s) 2'b11: rx_data_r2[23: 0] <= {rx_data_p_s, rx_data_n_s}; 2'b01: rx_data_r2[23: 0] <= {rx_data_n_s, rx_data_p}; default: rx_data_r2[23: 0] <= rx_data_r2[23: 0]; endcase case (rx_frame_s) 2'b00: rx_data_r2[47:24] <= {rx_data_p_s, rx_data_n_s}; 2'b10: rx_data_r2[47:24] <= {rx_data_n_s, rx_data_p}; default: rx_data_r2[47:24] <= rx_data_r2[47:24]; endcase end // receive data path mux always @(posedge l_clk) begin if (adc_r1_mode == 1'b1) begin adc_p_valid <= rx_valid_r1; adc_p_data <= {24'd0, rx_data_r1}; adc_p_status <= ~rx_error_r1; end else begin adc_p_valid <= rx_valid_r2; adc_p_data <= rx_data_r2; adc_p_status <= ~rx_error_r2; end end // transfer to a synchronous common clock always @(negedge l_clk) begin adc_n_valid <= adc_p_valid; adc_n_data <= adc_p_data; adc_n_status <= adc_p_status; end always @(posedge clk) begin adc_valid_int <= adc_n_valid; adc_data_int <= adc_n_data; adc_status_int <= adc_n_status; adc_valid <= adc_valid_int; if (adc_valid_int == 1'b1) begin adc_data <= adc_data_int; end adc_status <= adc_status_int; end // transmit data path mux (reverse of what receive does above) // the count simply selets the data muxing on the ddr outputs assign tx_data_sel_s = {tx_data_cnt[1], dac_r1_mode, tx_data_cnt[0]}; always @(posedge clk) begin if (dac_valid == 1'b1) begin tx_data_cnt <= 2'b10; end else if (tx_data_cnt[1] == 1'b1) begin tx_data_cnt <= tx_data_cnt + 1'b1; end if (dac_valid == 1'b1) begin tx_data <= dac_data; end case (tx_data_sel_s) 3'b100: begin tx_frame_p <= 1'b0; tx_frame_n <= 1'b0; tx_data_p <= tx_data[35:24]; tx_data_n <= tx_data[47:36]; end 3'b101: begin tx_frame_p <= 1'b1; tx_frame_n <= 1'b1; tx_data_p <= tx_data[11: 0]; tx_data_n <= tx_data[23:12]; end 3'b110: begin tx_frame_p <= 1'b1; tx_frame_n <= 1'b0; tx_data_p <= tx_data[11: 0]; tx_data_n <= tx_data[23:12]; end default: begin tx_frame_p <= 1'd0; tx_frame_n <= 1'd0; tx_data_p <= 12'd0; tx_data_n <= 12'd0; end endcase end // transfer data from a synchronous clock (skew less than 2ns) always @(negedge clk) begin tx_n_frame_p <= tx_frame_p; tx_n_frame_n <= tx_frame_n; tx_n_data_p <= tx_data_p; tx_n_data_n <= tx_data_n; end always @(posedge l_clk) begin tx_p_frame_p <= tx_n_frame_p; tx_p_frame_n <= tx_n_frame_n; tx_p_data_p <= tx_n_data_p; tx_p_data_n <= tx_n_data_n; end // tdd/ensm control always @(posedge up_clk) begin up_enable_int <= up_enable; up_txnrx_int <= up_txnrx; end always @(posedge clk or posedge rst) begin if (rst == 1'b1) begin enable_up_m1 <= 1'b0; txnrx_up_m1 <= 1'b0; enable_up <= 1'b0; txnrx_up <= 1'b0; end else begin enable_up_m1 <= up_enable_int; txnrx_up_m1 <= up_txnrx_int; enable_up <= enable_up_m1; txnrx_up <= txnrx_up_m1; end end always @(posedge clk) begin if (tdd_mode == 1'b1) begin enable_int <= tdd_enable; txnrx_int <= tdd_txnrx; end else begin enable_int <= enable_up; txnrx_int <= txnrx_up; end end always @(negedge clk) begin enable_n_int <= enable_int; txnrx_n_int <= txnrx_int; end always @(posedge l_clk) begin enable_p_int <= enable_n_int; txnrx_p_int <= txnrx_n_int; end // receive data interface, ibuf -> idelay -> iddr generate for (l_inst = 0; l_inst <= 11; l_inst = l_inst + 1) begin: g_rx_data ad_cmos_in #( .SINGLE_ENDED (1), .DEVICE_TYPE (DEVICE_TYPE), .IODELAY_CTRL (0), .IODELAY_GROUP (IO_DELAY_GROUP)) i_rx_data ( .rx_clk (l_clk), .rx_data_in (rx_data_in[l_inst]), .rx_data_p (rx_data_p_s[l_inst]), .rx_data_n (rx_data_n_s[l_inst]), .up_clk (up_clk), .up_dld (up_adc_dld[l_inst]), .up_dwdata (up_adc_dwdata[((l_inst*5)+4):(l_inst*5)]), .up_drdata (up_adc_drdata[((l_inst*5)+4):(l_inst*5)]), .delay_clk (delay_clk), .delay_rst (delay_rst), .delay_locked ()); end endgenerate // receive frame interface, ibuf -> idelay -> iddr ad_cmos_in #( .SINGLE_ENDED (1), .DEVICE_TYPE (DEVICE_TYPE), .IODELAY_CTRL (1), .IODELAY_GROUP (IO_DELAY_GROUP)) i_rx_frame ( .rx_clk (l_clk), .rx_data_in_p (rx_frame_in), .rx_data_p (rx_frame_p_s), .rx_data_n (rx_frame_n_s), .up_clk (up_clk), .up_dld (up_adc_dld[12]), .up_dwdata (up_adc_dwdata[64:60]), .up_drdata (up_adc_drdata[64:60]), .delay_clk (delay_clk), .delay_rst (delay_rst), .delay_locked (delay_locked)); // transmit data interface, oddr -> obuf generate for (l_inst = 0; l_inst <= 11; l_inst = l_inst + 1) begin: g_tx_data ad_cmos_out #( .DEVICE_TYPE (DEVICE_TYPE), .SINGLE_ENDED (1), .IODELAY_ENABLE (DAC_IODELAY_ENABLE), .IODELAY_CTRL (0), .IODELAY_GROUP (IO_DELAY_GROUP)) i_tx_data ( .tx_clk (l_clk), .tx_data_p (tx_p_data_p[l_inst]), .tx_data_n (tx_p_data_n[l_inst]), .tx_data_out (tx_data_out[l_inst]), .up_clk (up_clk), .up_dld (up_dac_dld[l_inst]), .up_dwdata (up_dac_dwdata[((l_inst*5)+4):(l_inst*5)]), .up_drdata (up_dac_drdata[((l_inst*5)+4):(l_inst*5)]), .delay_clk (delay_clk), .delay_rst (delay_rst), .delay_locked ()); end endgenerate // transmit frame interface, oddr -> obuf ad_cmos_out #( .DEVICE_TYPE (DEVICE_TYPE), .SINGLE_ENDED (1), .IODELAY_ENABLE (DAC_IODELAY_ENABLE), .IODELAY_CTRL (0), .IODELAY_GROUP (IO_DELAY_GROUP)) i_tx_frame ( .tx_clk (l_clk), .tx_data_p (tx_p_frame_p), .tx_data_n (tx_p_frame_n), .tx_data_out (tx_frame_out), .up_clk (up_clk), .up_dld (up_dac_dld[12]), .up_dwdata (up_dac_dwdata[64:60]), .up_drdata (up_dac_drdata[64:60]), .delay_clk (delay_clk), .delay_rst (delay_rst), .delay_locked ()); // transmit clock interface, oddr -> obuf ad_cmos_out #( .DEVICE_TYPE (DEVICE_TYPE), .SINGLE_ENDED (1), .IODELAY_ENABLE (DAC_IODELAY_ENABLE), .IODELAY_CTRL (0), .IODELAY_GROUP (IO_DELAY_GROUP)) i_tx_clk ( .tx_clk (l_clk), .tx_data_p (1'b0), .tx_data_n (1'b1), .tx_data_out (tx_clk_out), .up_clk (up_clk), .up_dld (up_dac_dld[13]), .up_dwdata (up_dac_dwdata[69:65]), .up_drdata (up_dac_drdata[69:65]), .delay_clk (delay_clk), .delay_rst (delay_rst), .delay_locked ()); // enable, oddr -> obuf ad_cmos_out #( .DEVICE_TYPE (DEVICE_TYPE), .SINGLE_ENDED (1), .IODELAY_ENABLE (DAC_IODELAY_ENABLE), .IODELAY_CTRL (0), .IODELAY_GROUP (IO_DELAY_GROUP)) i_enable ( .tx_clk (l_clk), .tx_data_p (enable_p_int), .tx_data_n (enable_p_int), .tx_data_out (enable), .up_clk (up_clk), .up_dld (up_dac_dld[14]), .up_dwdata (up_dac_dwdata[74:70]), .up_drdata (up_dac_drdata[74:70]), .delay_clk (delay_clk), .delay_rst (delay_rst), .delay_locked ()); // txnrx, oddr -> obuf ad_cmos_out #( .DEVICE_TYPE (DEVICE_TYPE), .SINGLE_ENDED (1), .IODELAY_ENABLE (DAC_IODELAY_ENABLE), .IODELAY_CTRL (0), .IODELAY_GROUP (IO_DELAY_GROUP)) i_txnrx ( .tx_clk (l_clk), .tx_data_p (txnrx_p_int), .tx_data_n (txnrx_p_int), .tx_data_out (txnrx), .up_clk (up_clk), .up_dld (up_dac_dld[15]), .up_dwdata (up_dac_dwdata[79:75]), .up_drdata (up_dac_drdata[79:75]), .delay_clk (delay_clk), .delay_rst (delay_rst), .delay_locked ()); // device clock interface (receive clock) ad_cmos_clk #( .DEVICE_TYPE (DEVICE_TYPE)) i_clk ( .clk_in (rx_clk_in), .clk (l_clk)); endmodule // *************************************************************************** // ***************************************************************************