void undo_calibration (GtkWidget *widget, gpointer data) { trx_phase_rotation(dev_dds_master, 0.0); trx_phase_rotation(dev_dds_slave, 0.0); trx_phase_rotation(cf_ad9361_lpc, 0.0); trx_phase_rotation(cf_ad9361_hpc, 0.0); }
void tx_phase_hscale_value_changed (GtkRange *hscale1, gpointer data) { double value = gtk_range_get_value(hscale1); if ((unsigned long)data) trx_phase_rotation(dev_dds_master, value); else trx_phase_rotation(dev_dds_slave, value); }
static void undo_calibration (GtkWidget *widget, gpointer data) { struct osc_plugin *plugin; GSList *node; trx_phase_rotation(dev_dds_master, 0.0); trx_phase_rotation(dev_dds_slave, 0.0); trx_phase_rotation(cf_ad9361_lpc, 0.0); trx_phase_rotation(cf_ad9361_hpc, 0.0); gtk_range_set_value(GTK_RANGE(data), 0); for (node = plugin_list; node; node = g_slist_next(node)) { plugin = node->data; if (plugin && (!strncmp(plugin->name, "FMComms5", 8))) { if (plugin->handle_external_request) plugin->handle_external_request(NULL, "Reload Settings"); } } }
static int default_dds(long long freq, double scale) { int i, j, ret = 0; for (i = 0; i < 2; i++) { for (j = 0; j < 8; j++) { ret |= iio_channel_attr_write_longlong(dds_out[i][j], "frequency", freq); ret |= iio_channel_attr_write_double(dds_out[i][j], "scale", scale); } dds_tx_phase_rotation(i ? dev_dds_slave : dev_dds_master, 0.0); trx_phase_rotation(i ? dev_dds_slave : dev_dds_master, 0.0); } return ret; }
static void calibrate (gpointer button) { GtkProgressBar *calib_progress; double rx_phase_lpc, rx_phase_hpc, tx_phase_hpc; long long cal_tone, cal_freq; int ret, samples; if (!cf_ad9361_lpc || !cf_ad9361_hpc) { printf("could not find capture cores\n"); ret = -ENODEV; auto_calibrate = -1; goto calibrate_fail; } if (!dev_dds_master || !dev_dds_slave) { printf("could not find dds cores\n"); ret = -ENODEV; auto_calibrate = -1; goto calibrate_fail; } calib_progress = GTK_PROGRESS_BAR(gtk_builder_get_object(builder, "progress_calibration")); set_calibration_progress(calib_progress, 0.00); mcs_cb(NULL, NULL); /* * set some logical defaults / assumptions */ ret = default_dds(get_cal_tone(), CAL_SCALE); if (ret < 0) { printf("could not set dds cores\n"); auto_calibrate = -1; goto calibrate_fail; } iio_channel_attr_read_longlong(dds_out[0][0], "frequency", &cal_tone); iio_channel_attr_read_longlong(dds_out[0][0], "sampling_frequency", &cal_freq); samples = get_cal_samples(cal_tone, cal_freq); DBG("cal_tone %u cal_freq %u samples %d", cal_tone, cal_freq, samples); gdk_threads_enter(); osc_plot_set_sample_count(plot_xcorr_4ch, samples); osc_plot_draw_start(plot_xcorr_4ch); gdk_threads_leave(); iio_device_attr_write(dev, "in_voltage_quadrature_tracking_en", "0"); iio_device_attr_write(dev_slave, "in_voltage_quadrature_tracking_en", "0"); trx_phase_rotation(cf_ad9361_lpc, 0.0); trx_phase_rotation(cf_ad9361_hpc, 0.0); set_calibration_progress(calib_progress, 0.16); /* * Calibrate RX: * 1 TX1B_B (HPC) -> RX1C_B (HPC) : BIST_LOOPBACK on A */ osc_plot_xcorr_revert(plot_xcorr_4ch, true); __cal_switch_ports_enable_cb(1); rx_phase_hpc = tune_trx_phase_offset(cf_ad9361_hpc, &ret, cal_freq, cal_tone, 1.0, 0.01, trx_phase_rotation); if (ret < 0) { printf("Failed to tune phase\n"); auto_calibrate = -1; goto calibrate_fail; } set_calibration_progress(calib_progress, 0.40); DBG("rx_phase_hpc %f", rx_phase_hpc); /* * Calibrate RX: * 3 TX1B_B (HPC) -> RX1C_A (LPC) : BIST_LOOPBACK on B */ osc_plot_xcorr_revert(plot_xcorr_4ch, false); trx_phase_rotation(cf_ad9361_hpc, 0.0); __cal_switch_ports_enable_cb(3); rx_phase_lpc = tune_trx_phase_offset(cf_ad9361_lpc, &ret, cal_freq, cal_tone, 1.0, 0.01, trx_phase_rotation); if (ret < 0) { printf("Failed to tune phase\n"); auto_calibrate = -1; goto calibrate_fail; } set_calibration_progress(calib_progress, 0.64); DBG("rx_phase_lpc %f", rx_phase_lpc); /* * Calibrate TX: * 4 TX1B_A (LPC) -> RX1C_A (LPC) : BIST_LOOPBACK on B */ osc_plot_xcorr_revert(plot_xcorr_4ch, false); trx_phase_rotation(cf_ad9361_hpc, 0.0); __cal_switch_ports_enable_cb(4); tx_phase_hpc = tune_trx_phase_offset(dev_dds_slave, &ret, cal_freq, cal_tone, -1.0 , 0.001, trx_phase_rotation); if (ret < 0) { printf("Failed to tune phase\n"); auto_calibrate = -1; goto calibrate_fail; } set_calibration_progress(calib_progress, 0.88); DBG("tx_phase_hpc %f", tx_phase_hpc); trx_phase_rotation(cf_ad9361_hpc, rx_phase_hpc); gtk_range_set_value(GTK_RANGE(GTK_WIDGET(gtk_builder_get_object(builder, "tx_phase"))), scale_phase_0_360(tx_phase_hpc)); ret = 0; set_calibration_progress(calib_progress, 1.0); calibrate_fail: osc_plot_xcorr_revert(plot_xcorr_4ch, false); __cal_switch_ports_enable_cb(0); iio_device_attr_write(dev, "in_voltage_quadrature_tracking_en", "1"); iio_device_attr_write(dev_slave, "in_voltage_quadrature_tracking_en", "1"); gdk_threads_enter(); reload_settings(); create_blocking_popup(GTK_MESSAGE_INFO, GTK_BUTTONS_CLOSE, "FMCOMMS5", "Calibration finished %s", ret ? "with Error" : "Successfully"); auto_calibrate = 1; osc_plot_destroy(plot_xcorr_4ch); if (button) gtk_widget_show(GTK_WIDGET(button)); gdk_threads_leave(); g_thread_exit(NULL); }
static void calibrate (gpointer button) { GtkProgressBar *calib_progress = NULL; double rx_phase_lpc, rx_phase_hpc, tx_phase_hpc; struct iio_channel *in0, *in0_slave; long long cal_tone, cal_freq; int ret, samples; in0 = iio_device_find_channel(dev, "voltage0", false); in0_slave = iio_device_find_channel(dev_slave, "voltage0", false); if (!in0 || !in0_slave) { printf("could not find channels\n"); ret = -ENODEV; goto calibrate_fail; } if (!cf_ad9361_lpc || !cf_ad9361_hpc) { printf("could not find capture cores\n"); ret = -ENODEV; goto calibrate_fail; } if (!dev_dds_master || !dev_dds_slave) { printf("could not find dds cores\n"); ret = -ENODEV; goto calibrate_fail; } calib_progress = GTK_PROGRESS_BAR(gtk_builder_get_object(builder, "progress_calibration")); set_calibration_progress(calib_progress, 0.00); mcs_cb(NULL, NULL); /* * set some logical defaults / assumptions */ ret = default_dds(get_cal_tone(), CAL_SCALE); if (ret < 0) { printf("could not set dds cores\n"); goto calibrate_fail; } iio_channel_attr_read_longlong(dds_out[0][0], "frequency", &cal_tone); iio_channel_attr_read_longlong(dds_out[0][0], "sampling_frequency", &cal_freq); samples = get_cal_samples(cal_tone, cal_freq); DBG("cal_tone %lld cal_freq %lld samples %d", cal_tone, cal_freq, samples); gdk_threads_enter(); osc_plot_set_sample_count(plot_xcorr_4ch, samples); osc_plot_draw_start(plot_xcorr_4ch); gdk_threads_leave(); /* Turn off quadrature tracking while the sync is going on */ iio_channel_attr_write(in0, "quadrature_tracking_en", "0"); iio_channel_attr_write(in0_slave, "quadrature_tracking_en", "0"); /* reset any Tx rotation to zero */ trx_phase_rotation(cf_ad9361_lpc, 0.0); trx_phase_rotation(cf_ad9361_hpc, 0.0); set_calibration_progress(calib_progress, 0.16); /* * Calibrate RX: * 1 TX1B_B (HPC) -> RX1C_B (HPC) : BIST_LOOPBACK on A */ osc_plot_xcorr_revert(plot_xcorr_4ch, true); __cal_switch_ports_enable_cb(1); rx_phase_hpc = tune_trx_phase_offset(cf_ad9361_hpc, &ret, cal_freq, cal_tone, 1.0, 0.01, trx_phase_rotation); if (ret < 0) { printf("Failed to tune phase : %s:%i\n", __func__, __LINE__); goto calibrate_fail; } set_calibration_progress(calib_progress, 0.40); DBG("rx_phase_hpc %f", rx_phase_hpc); /* * Calibrate RX: * 3 TX1B_B (HPC) -> RX1C_A (LPC) : BIST_LOOPBACK on B */ osc_plot_xcorr_revert(plot_xcorr_4ch, false); trx_phase_rotation(cf_ad9361_hpc, 0.0); __cal_switch_ports_enable_cb(3); rx_phase_lpc = tune_trx_phase_offset(cf_ad9361_lpc, &ret, cal_freq, cal_tone, 1.0, 0.01, trx_phase_rotation); if (ret < 0) { printf("Failed to tune phase : %s:%i\n", __func__, __LINE__); goto calibrate_fail; } set_calibration_progress(calib_progress, 0.64); (void) rx_phase_lpc; /* Avoid compiler warnings */ DBG("rx_phase_lpc %f", rx_phase_lpc); /* * Calibrate TX: * 4 TX1B_A (LPC) -> RX1C_A (LPC) : BIST_LOOPBACK on B */ osc_plot_xcorr_revert(plot_xcorr_4ch, false); trx_phase_rotation(cf_ad9361_hpc, 0.0); __cal_switch_ports_enable_cb(4); tx_phase_hpc = tune_trx_phase_offset(dev_dds_slave, &ret, cal_freq, cal_tone, -1.0 , 0.001, trx_phase_rotation); if (ret < 0) { printf("Failed to tune phase : %s:%i\n", __func__, __LINE__); goto calibrate_fail; } set_calibration_progress(calib_progress, 0.88); DBG("tx_phase_hpc %f", tx_phase_hpc); trx_phase_rotation(cf_ad9361_hpc, rx_phase_hpc); gtk_range_set_value(GTK_RANGE(GTK_WIDGET(gtk_builder_get_object(builder, "tx_phase"))), scale_phase_0_360(tx_phase_hpc)); ret = 0; set_calibration_progress(calib_progress, 1.0); calibrate_fail: osc_plot_xcorr_revert(plot_xcorr_4ch, false); __cal_switch_ports_enable_cb(0); if (in0 && in0_slave) { iio_channel_attr_write(in0, "quadrature_tracking_en", "1"); iio_channel_attr_write(in0_slave, "quadrature_tracking_en", "1"); } gdk_threads_enter(); reload_settings(); if (ret) { create_blocking_popup(GTK_MESSAGE_INFO, GTK_BUTTONS_CLOSE, "FMCOMMS5", "Calibration failed"); auto_calibrate = -1; } else { /* set completed flag for testing */ auto_calibrate = 1; } osc_plot_destroy(plot_xcorr_4ch); if (button) gtk_widget_show(GTK_WIDGET(button)); gdk_threads_leave(); /* reset progress bar */ gtk_progress_bar_set_fraction(calib_progress, 0.0); gtk_progress_bar_set_text(calib_progress, "Calibration Progress"); /* Disable the channels that were enabled at the beginning of the calibration */ struct iio_device *iio_dev; iio_dev = iio_context_find_device(get_context_from_osc(), CAP_DEVICE_ALT); if (iio_dev && cap_device_channels_enabled) { iio_channels_change_shadow_of_enabled(iio_dev, false); cap_device_channels_enabled = false; } g_thread_exit(NULL); }