/* -*- c++ -*- */ /* * Copyright 2009 Free Software Foundation, Inc. * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program 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. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include #include #include #include #include #include #include #define min(X,Y) ((X) < (Y) ? (X) : (Y)) #define max(X,Y) ((X) > (Y) ? (X) : (Y)) #define abs(X) ((X) < (0) ? ((-1)*(X)) : (X)) #define I2C_ADDR 0x67 #define REFCLK_DIVISOR 25 // Gives a 4 MHz clock #define REFCLK_FREQ U2_DOUBLE_TO_FXPT_FREQ(MASTER_CLK_RATE/REFCLK_DIVISOR) #define REFCLK_FREQ_INT u2_fxpt_freq_round_to_int(REFCLK_FREQ) #define VMAXGAIN .75 #define VMINGAIN 2.6 #define RFGAINMAX 60 #define BBGAINMAX 24 #define DACFULLSCALE 3.3 bool db_dbsrx_init(struct db_base *db); bool db_dbsrx_set_freq(struct db_base *db, u2_fxpt_freq_t freq, u2_fxpt_freq_t *dc); bool db_dbsrx_set_gain(struct db_base *db, u2_fxpt_gain_t gain); struct db_dbsrx_common { int d_n; int d_div2; int d_osc; int d_cp; int d_r_reg; int d_fdac; int d_m; int d_dl; int d_ade; int d_adl; int d_gc2; int d_diag; }; struct db_dbsrx_dummy { struct db_base base; struct db_dbsrx_common common; }; struct db_dbsrx { struct db_base base; struct db_dbsrx_common common; }; struct db_dbsrx db_dbsrx = { .base.dbid = 0x000d, .base.is_tx = false, .base.output_enables = 0x0000, .base.used_pins = 0x0000, .base.freq_min = U2_DOUBLE_TO_FXPT_FREQ(500e6), .base.freq_max = U2_DOUBLE_TO_FXPT_FREQ(2.6e9), .base.gain_min = U2_DOUBLE_TO_FXPT_GAIN(0), .base.gain_max = U2_DOUBLE_TO_FXPT_GAIN(RFGAINMAX+BBGAINMAX), .base.gain_step_size = U2_DOUBLE_TO_FXPT_GAIN(1), .base.is_quadrature = true, .base.i_and_q_swapped = false, .base.spectrum_inverted = false, .base.default_lo_offset = U2_DOUBLE_TO_FXPT_FREQ(0), .base.init = db_dbsrx_init, .base.set_freq = db_dbsrx_set_freq, .base.set_gain = db_dbsrx_set_gain, .base.set_tx_enable = 0, .base.atr_mask = 0x0000, .base.atr_txval = 0, .base.atr_rxval = 0, //.base.atr_tx_delay = //.base.atr_rx_delay = .common.d_n = 950, .common.d_div2 = 0, .common.d_osc = 5, .common.d_cp = 3, .common.d_r_reg = 1, .common.d_fdac = 127, .common.d_m = 2, .common.d_dl = 1, .common.d_ade = 0, .common.d_adl = 0, .common.d_gc2 = 31, .common.d_diag = 0, .base.set_antenna = 0, }; bool db_dbsrx_init(struct db_base *dbb){ struct db_dbsrx_dummy *db = (struct db_dbsrx_dummy *) dbb; db->base.set_gain(dbb, (db->base.gain_max + db->base.gain_min)/2); clocks_enable_rx_dboard(true, REFCLK_DIVISOR); // Gives 4 MHz clock return true; } /************************************************** * Registers **************************************************/ static int _read_adc (void){ unsigned char readback[2]; i2c_read(I2C_ADDR, readback, 2*sizeof(unsigned char)); int adc_val = (readback[0] >> 2)&7; //printf("READBACK[0] %d, [1] %d\n",readback[0],readback[1]); //printf("ADC: %d\n",adc_val); return adc_val; } static void _write_reg (int regno, int v){ //regno is in [0,5], v is value to write to register""" unsigned char args[2]; args[0] = (unsigned char)regno; args[1] = (unsigned char)v; i2c_write(I2C_ADDR, args, 2*sizeof(unsigned char)); //printf("Reg %d, Val %x\n",regno,v); } static void _send_reg_0(struct db_dbsrx_dummy *db){ _write_reg(0,(db->common.d_div2<<7) + (db->common.d_n>>8)); } static void _send_reg_1(struct db_dbsrx_dummy *db){ _write_reg(1,db->common.d_n & 255); } static void _send_reg_2(struct db_dbsrx_dummy *db){ _write_reg(2,db->common.d_osc + (db->common.d_cp<<3) + (db->common.d_r_reg<<5)); } static void _send_reg_3(struct db_dbsrx_dummy *db){ _write_reg(3,db->common.d_fdac); } static void _send_reg_4(struct db_dbsrx_dummy *db){ _write_reg(4,db->common.d_m + (db->common.d_dl<<5) + (db->common.d_ade<<6) + (db->common.d_adl<<7)); } static void _send_reg_5(struct db_dbsrx_dummy *db){ _write_reg(5,db->common.d_gc2 + (db->common.d_diag<<5)); } /************************************************** * Helpers for setting the freq **************************************************/ static void _set_div2(struct db_dbsrx_dummy *db, int div2){ db->common.d_div2 = div2; _send_reg_0(db); } // FIXME How do we handle ADE and ADL properly? static void _set_ade(struct db_dbsrx_dummy *db, int ade){ db->common.d_ade = ade; _send_reg_4(db); } static void _set_r(struct db_dbsrx_dummy *db, int r){ db->common.d_r_reg = r; _send_reg_2(db); } static void _set_n(struct db_dbsrx_dummy *db, int n){ db->common.d_n = n; _send_reg_0(db); _send_reg_1(db); } static void _set_osc(struct db_dbsrx_dummy *db, int osc){ db->common.d_osc = osc; _send_reg_2(db); } static void _set_cp(struct db_dbsrx_dummy *db, int cp){ db->common.d_cp = cp; _send_reg_2(db); } /************************************************** * Set the freq **************************************************/ bool db_dbsrx_set_freq(struct db_base *dbb, u2_fxpt_freq_t freq, u2_fxpt_freq_t *dc){ struct db_dbsrx_dummy *db = (struct db_dbsrx_dummy *) dbb; if(!(freq>=db->base.freq_min && freq<=db->base.freq_max)) { return false; } u2_fxpt_freq_t vcofreq; if(freq < U2_DOUBLE_TO_FXPT_FREQ(1150e6)) { _set_div2(db, 0); vcofreq = 4 * freq; } else { _set_div2(db, 1); vcofreq = 2 * freq; } _set_ade(db, 1); int rmin = max(2, u2_fxpt_freq_round_to_int(REFCLK_FREQ/2e6)); //TODO? remove max() //int rmax = min(128, u2_fxpt_freq_round_to_int(REFCLK_FREQ/500e3)); //TODO? remove min() int n = 0; u2_fxpt_freq_t best_delta = U2_DOUBLE_TO_FXPT_FREQ(10e6); u2_fxpt_freq_t delta; int r_reg = 0; while ((r_reg<7) && ((2<= 7) { return false; } else { vco = vco + 1; } } _set_osc(db, vco); } if(adc_val == 1 || adc_val == 2) { _set_cp(db, 1); } else if(adc_val == 3 || adc_val == 4) { _set_cp(db, 2); } else { _set_cp(db, 3); } //printf("Final VCO choice %d\n",vco); *dc = db->common.d_n * REFCLK_FREQ / (2<common.d_r_reg); return true; } /************************************************** * Helpers for setting the gain **************************************************/ static void _set_gc2(struct db_dbsrx_dummy *db, int gc2){ db->common.d_gc2 = gc2; _send_reg_5(db); } /************************************************** * Set the gain **************************************************/ bool db_dbsrx_set_gain(struct db_base *dbb, u2_fxpt_gain_t gain){ struct db_dbsrx_dummy *db = (struct db_dbsrx_dummy *) dbb; u2_fxpt_gain_t rfgain, bbgain; if(!(gain >= db->base.gain_min && gain <= db->base.gain_max)) { return false; } if(gain < U2_DOUBLE_TO_FXPT_GAIN(RFGAINMAX)) { rfgain = gain; bbgain = 0; } else { rfgain = U2_DOUBLE_TO_FXPT_GAIN(RFGAINMAX); bbgain = gain - U2_DOUBLE_TO_FXPT_GAIN(RFGAINMAX); } int rf_gain_slope_q8 = 256 * 4096 * (VMAXGAIN-VMINGAIN) / RFGAINMAX / DACFULLSCALE; int rf_gain_offset_q8 = 128 * 256 * 4096 * VMINGAIN / DACFULLSCALE; int rfdac = (rfgain*rf_gain_slope_q8 + rf_gain_offset_q8)>>15; //printf("Set RF Gain %d, %d\n",rfgain,rfdac); lsdac_write_rx(1,rfdac); // Set GC2 int bb_gain_slope_q8 = 256*(0-31)/(BBGAINMAX-0); int gc2 = u2_fxpt_gain_round_to_int((bb_gain_slope_q8 * bbgain)>>8) + 31; //printf("Set BB Gain: %d, gc2 %d\n",bbgain,gc2); _set_gc2(db, gc2); return true; } /************************************************** * Helpers for setting the bw **************************************************/ static void _set_m(struct db_dbsrx_dummy *db, int m){ db->common.d_m = m; _send_reg_4(db); } static void _set_fdac(struct db_dbsrx_dummy *db, int fdac){ db->common.d_fdac = fdac; _send_reg_3(db); }