FreeCalypso > hg > fc-rfcal-tools
view autocal/vcxomain.c @ 68:3ec82dc1dbda
fc-cmu200d: implemented reading and parsing of cable config files (-c arg)
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Fri, 14 Jul 2017 04:34:15 +0000 |
parents | 6e8f2728c7f5 |
children | 7ad5836d3b87 |
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/* * This module contains the main() function for fc-rfcal-vcxo. */ #include <math.h> #include <stdio.h> #include <stdint.h> #include <stdlib.h> #include <endian.h> #include <rvinterf/l1tm.h> #include <rvinterf/exitcodes.h> #include "afcparams.h" #include "stdband.h" #define VCXOCAL_BAND 900 #define VCXOCAL_BAND_RFPW RFPW_STD_BAND(6, 0) #define VCXOCAL_ARFCN 40 extern float vcxo_freq_meas(); static float freq_max_neg, freq_max_pos; static float lin_a, lin_b, lin_a2, lin_b2; static int zero_search_dac1, zero_search_dac2, zero_search_incr; static float zero_search_freq1, zero_search_freq2; static float dac_min, dac_max, dac_init; static int dac_init_int; static float Psi_sta, Psi_st; struct afcparams afcparams_host, afcparams_arm; prepare_rf_test_system() { char cmd[80]; printf("Preparing RF test system for VCXO calibration\n"); sprintf(cmd, "vcxo-cal-setup %d %d\n", VCXOCAL_BAND, VCXOCAL_ARFCN); tsid_command(cmd); return(0); } main(argc, argv) char **argv; { socket_pathname_options(argc, argv); connect_rvinterf_socket(); connect_tsid_socket(); setlinebuf(stdout); /* to allow logging with tee */ prepare_rf_test_system(); printf("Putting the DUT into Test Mode\n"); do_tms(1); do_rfpw(STD_BAND_FLAG, VCXOCAL_BAND_RFPW); do_rfpw(TCH_ARFCN, VCXOCAL_ARFCN); do_rfpw(AFC_ENA_FLAG, 0); do_txpw(TX_PWR_LEVEL, 12); printf("Starting RF Tx on the DUT\n"); do_rfe(RX_TX_TCH); /* initial measurements at the DAC extremes */ freq_max_neg = vcxo_freq_meas(-2048, "max-neg"); freq_max_pos = vcxo_freq_meas(2048, "max-pos"); lin_a = (freq_max_pos - freq_max_neg) / 4096.0f; lin_b = freq_max_pos - lin_a * 2048.0f; zero_search_dac1 = -lin_b / lin_a; zero_search_freq1 = vcxo_freq_meas(zero_search_dac1, "zero-search"); /* search for zero crossing */ if (zero_search_freq1 < 0) zero_search_incr = 100; else zero_search_incr = -100; for (;;) { zero_search_dac2 = zero_search_dac1 + zero_search_incr; zero_search_freq2 = vcxo_freq_meas(zero_search_dac2, "zero-search"); if (zero_search_incr > 0 && zero_search_freq2 >= 0) break; if (zero_search_incr < 0 && zero_search_freq2 < 0) break; zero_search_dac1 = zero_search_dac2; zero_search_freq1 = zero_search_freq2; } /* second linear approximation */ lin_a2 = (zero_search_freq2 - zero_search_freq1) / (float)(zero_search_dac2 - zero_search_dac1); lin_b2 = zero_search_freq2 - lin_a2 * zero_search_dac2; /* DAC settings */ dac_min = (-13500.0f - lin_b) / lin_a; dac_max = (13500.0f - lin_b) / lin_a; dac_init = -lin_b2 / lin_a2; dac_init_int = (int) dac_init; /* check the frequency offset at the final DAC value */ vcxo_freq_meas(dac_init_int, "zero-check"); /* done with the measurements and the Tx */ printf("Stopping RF Tx on the DUT\n"); do_rfe(STOP_ALL); /* Psi computations */ Psi_sta = 2.0f * (float)M_PI * lin_a / 270833.0f; Psi_st = Psi_sta * 0.8f; /* compute and fill afcparams */ afcparams_host.psi_sta_inv = (unsigned)(1.0f / Psi_sta); afcparams_host.psi_st = (unsigned)(Psi_st * 65536.0f); afcparams_host.psi_st_32 = (unsigned)(Psi_st * 65536.0f * 65536.0f); afcparams_host.psi_st_inv = (unsigned)(1.0f / Psi_st); afcparams_host.dac_center = (int)(dac_init * 8.0f); afcparams_host.dac_min = (int)(dac_min * 8.0f); afcparams_host.dac_max = (int)(dac_max * 8.0f); afcparams_host.snr_thr = 2560; /* print them out */ printf("afcparams Psi_sta_inv: %u\n", afcparams_host.psi_sta_inv); printf("afcparams Psi_st: %u\n", afcparams_host.psi_st); printf("afcparams Psi_st_32: %u\n", afcparams_host.psi_st_32); printf("afcparams Psi_st_inv: %u\n", afcparams_host.psi_st_inv); printf("afcparams DAC_INIT*8: %d\n", afcparams_host.dac_center); printf("afcparams DAC_MIN*8: %d\n", afcparams_host.dac_min); printf("afcparams DAC_MAX*8: %d\n", afcparams_host.dac_max); printf("afcparams snr_thr: %d\n", afcparams_host.snr_thr); /* convert to LE for upload to the DUT */ afcparams_arm.psi_sta_inv = htole32(afcparams_host.psi_sta_inv); afcparams_arm.psi_st = htole32(afcparams_host.psi_st); afcparams_arm.psi_st_32 = htole32(afcparams_host.psi_st_32); afcparams_arm.psi_st_inv = htole32(afcparams_host.psi_st_inv); afcparams_arm.dac_center = htole16(afcparams_host.dac_center); afcparams_arm.dac_min = htole16(afcparams_host.dac_min); afcparams_arm.dac_max = htole16(afcparams_host.dac_max); afcparams_arm.snr_thr = htole16(afcparams_host.snr_thr); /* send them up */ printf("Uploading afcparams and INITIAL_AFC_DAC to the DUT\n"); do_rftw(AFC_PARAMS, &afcparams_arm, sizeof(struct afcparams)); do_rfpw(INITIAL_AFC_DAC, dac_init_int); printf("Saving rf-cal and rf-cfg in FFS\n"); misc_enable(CFG_WRITE_RF_CAL); misc_enable(CFG_WRITE_RF_CFG); exit(0); }