module io_ctrl ( input i_rst_b, input i_sys_clk, // FPGA Clock input [4:0] i_ioc, input [7:0] i_data_in, output reg [7:0] o_data_out, input i_cs, input i_fetch_cmd, input i_load_cmd, // Digital interfaces input i_button, input [3:0] i_config, output o_led0, output o_led1, output [7:0] o_pmod, // Analog interfaces output o_mixer_fm, output o_rx_h_tx_l, output o_rx_h_tx_l_b, output o_tr_vc1, output o_tr_vc1_b, output o_tr_vc2, output o_shdn_tx_lna, output o_shdn_rx_lna, output o_mixer_en ); //========================================================================= // CONSTANT DEFINITIONS //========================================================================= // MODULE SPECIFIC IOC LIST localparam ioc_module_version = 5'b00000, // read only ioc_mode = 5'b00001, // The functional mode-of-operation of the system. ioc_dig_pin = 5'b00010, // Digital pin control and read ioc_pmod_dir = 5'b00011, // PMOD connector bits IO pin direction ioc_pmod_val = 5'b00100, // PMOD connector bits IO pin value ioc_rf_pin = 5'b00101; // Setting up / reading out the pin values controlling the RF front-end path switches. // MODULE SPECIFIC PARAMS localparam module_version = 8'b00000001; // Debug state definitions localparam debug_mode_none = 2'b00, // No-debug mode - the RFM field describes a set of pre-determines modes of operation debug_mode_debug = 2'b01; // Debug mode - the RFM field directives are ignored and the RF-I/O settings are explicitly set in pin-level // RF-mode states localparam // RF Mode of operation - this setting is active only when DBG='00' rf_mode_low_power = 3'b000, // Low-power / inactive mode - all RF peripherals are turned off (LNAs, Mixer, etc.) rf_mode_bypass = 3'b001, // RF front-end wide-range tuning is turned off, and the modem 2.4GHz rf_mode_rx_lpf = 3'b010, // RX Lowpass mode - tuned to receive high-frequency signals (>2.483 GHz) rf_mode_rx_hpf = 3'b011, // RX Highpass mode - tuned to receive low-frequency signals (<2.4 GHz) rf_mode_tx_lpf = 3'b100, // TX Lowpass mode - tuned to transmit low-frequency signals (<2.4 GHz) rf_mode_tx_hpf = 3'b101; // TX Highpass mode - tuned to transmit high-frequency signals (>2.4 GHz) //========================================================================= // INTERNAL REGISTERS //========================================================================= // Internal registers reg [1:0] debug_mode; reg [2:0] rf_mode; // Digital outputs reg led0_state; reg led1_state; reg [7:0] pmod_dir_state; reg [7:0] pmod_state; reg [7:0] rf_pin_state; reg mixer_en_state; // Analog parts outputs reg lna_rx_shutdown_state; reg lna_tx_shutdown_state; reg rx_h_state; reg rx_h_b_state; reg tr_vc_1_state; reg tr_vc_1_b_state; reg tr_vc_2_state; //========================================================================= // LOGICAL SIGNAL ASSIGNMENTS //========================================================================= assign o_led0 = led0_state; assign o_led1 = led1_state; assign o_pmod = pmod_state; // Analog interfaces assign o_mixer_fm = 1'b0; assign o_rx_h_tx_l = rx_h_state; assign o_rx_h_tx_l_b = rx_h_b_state; assign o_tr_vc1 = tr_vc_1_state; assign o_tr_vc1_b = tr_vc_1_b_state; assign o_tr_vc2 = tr_vc_2_state; assign o_shdn_tx_lna = lna_tx_shutdown_state; assign o_shdn_rx_lna = lna_rx_shutdown_state; //assign o_mixer_en = mixer_en_state; assign o_mixer_en = 1'b1; //========================================================================= // BUS COMMUNICATION LOGIC & RF CONTROL //========================================================================= always @(posedge i_sys_clk or negedge i_rst_b) begin if (i_rst_b == 1'b0) begin debug_mode <= debug_mode_none; rf_mode <= rf_mode_low_power; led0_state <= 1'b0; led1_state <= 1'b0; end else begin if (i_cs == 1'b1) begin //============================================= // READ OPERATIONS //============================================= if (i_fetch_cmd == 1'b1) begin case (i_ioc) //---------------------------------------------- ioc_module_version: o_data_out <= module_version; //---------------------------------------------- ioc_mode: begin o_data_out[1:0] <= debug_mode; o_data_out[4:2] <= rf_mode; end //---------------------------------------------- ioc_dig_pin: begin o_data_out[0] <= led0_state; o_data_out[1] <= led1_state; o_data_out[6:3] <= i_config; o_data_out[7] <= i_button; end //---------------------------------------------- ioc_pmod_dir: begin o_data_out <= pmod_dir_state; end //---------------------------------------------- ioc_pmod_val: begin o_data_out <= pmod_state; end //---------------------------------------------- ioc_rf_pin: begin o_data_out[0] <= mixer_en_state; o_data_out[1] <= lna_rx_shutdown_state; o_data_out[2] <= lna_tx_shutdown_state; o_data_out[3] <= tr_vc_2_state; o_data_out[4] <= tr_vc_1_b_state; o_data_out[5] <= tr_vc_1_state; o_data_out[6] <= rx_h_b_state; o_data_out[7] <= rx_h_state; end endcase end //============================================= // WRITE OPERATIONS //============================================= else if (i_load_cmd == 1'b1) begin case (i_ioc) //---------------------------------------------- ioc_mode: begin debug_mode <= i_data_in[1:0]; rf_mode <= i_data_in[4:2]; if (i_data_in[1:0] == debug_mode_none) begin // TBD move back all the controls to good position // use rf_mode to control everything end end //---------------------------------------------- ioc_dig_pin: begin led0_state <= i_data_in[0]; led1_state <= i_data_in[1]; end //---------------------------------------------- ioc_pmod_dir: begin pmod_dir_state <= i_data_in; end //---------------------------------------------- ioc_pmod_val: begin pmod_state <= i_data_in; end //---------------------------------------------- ioc_rf_pin: begin rf_pin_state <= i_data_in; end //---------------------------------------------- endcase end end end end always @(posedge i_sys_clk or negedge i_rst_b) begin if (i_rst_b == 1'b0) begin end // this is relevant only if the system runs // in an operational mode else if (debug_mode == debug_mode_none) begin case (rf_mode) //-------------------------------------------------- rf_mode_low_power: begin mixer_en_state <= 1'b0; lna_rx_shutdown_state <= 1'b1; lna_tx_shutdown_state <= 1'b1; tr_vc_1_state <= 1'b0; tr_vc_1_b_state <= 1'b1; tr_vc_2_state <= 1'b0; rx_h_state <= 1'b0; rx_h_b_state <= 1'b1; end //-------------------------------------------------- rf_mode_bypass: begin mixer_en_state <= 1'b0; lna_rx_shutdown_state <= 1'b1; lna_tx_shutdown_state <= 1'b1; tr_vc_1_state <= 1'b1; tr_vc_1_b_state <= 1'b0; tr_vc_2_state <= 1'b0; rx_h_state <= 1'b0; rx_h_b_state <= 1'b1; end //-------------------------------------------------- rf_mode_rx_lpf: begin mixer_en_state <= 1'b1; lna_rx_shutdown_state <= 1'b0; lna_tx_shutdown_state <= 1'b1; tr_vc_1_state <= 1'b0; tr_vc_1_b_state <= 1'b1; tr_vc_2_state <= 1'b1; rx_h_state <= 1'b1; rx_h_b_state <= 1'b0; end //-------------------------------------------------- rf_mode_rx_hpf: begin mixer_en_state <= 1'b1; lna_rx_shutdown_state <= 1'b0; lna_tx_shutdown_state <= 1'b1; tr_vc_1_state <= 1'b0; tr_vc_1_b_state <= 1'b1; tr_vc_2_state <= 1'b1; rx_h_state <= 1'b0; rx_h_b_state <= 1'b1; end //-------------------------------------------------- rf_mode_tx_lpf: begin mixer_en_state <= 1'b1; lna_rx_shutdown_state <= 1'b1; lna_tx_shutdown_state <= 1'b0; tr_vc_1_state <= 1'b1; tr_vc_1_b_state <= 1'b0; tr_vc_2_state <= 1'b1; rx_h_state <= 1'b0; rx_h_b_state <= 1'b1; end //-------------------------------------------------- rf_mode_tx_hpf: begin mixer_en_state <= 1'b1; lna_rx_shutdown_state <= 1'b1; lna_tx_shutdown_state <= 1'b0; tr_vc_1_state <= 1'b1; tr_vc_1_b_state <= 1'b0; tr_vc_2_state <= 1'b1; rx_h_state <= 1'b1; rx_h_b_state <= 1'b0; end //-------------------------------------------------- endcase end else if (debug_mode == debug_mode_debug) begin mixer_en_state <= rf_pin_state[0]; lna_rx_shutdown_state <= rf_pin_state[1]; lna_tx_shutdown_state <= rf_pin_state[2]; tr_vc_2_state <= rf_pin_state[3]; tr_vc_1_b_state <= rf_pin_state[4]; tr_vc_1_state <= rf_pin_state[5]; rx_h_b_state <= rf_pin_state[6]; rx_h_state <= rf_pin_state[7]; end end endmodule // io_ctrl