/*! * \file tracking_pull-in_test_fpga.cc * \brief This class implements a tracking Pull-In test for FPGA HW accelerator * implementations based on some input parameters. * \authors * * * ----------------------------------------------------------------------------- * * GNSS-SDR is a Global Navigation Satellite System software-defined receiver. * This file is part of GNSS-SDR. * * Copyright (C) 2012-2020 (see AUTHORS file for a list of contributors) * SPDX-License-Identifier: GPL-3.0-or-later * * ----------------------------------------------------------------------------- */ #include "GPS_L1_CA.h" #include "GPS_L5.h" #include "Galileo_E1.h" #include "Galileo_E5a.h" #include "acquisition_msg_rx.h" #include "concurrent_queue.h" #include "galileo_e1_pcps_ambiguous_acquisition_fpga.h" #include "galileo_e5a_pcps_acquisition_fpga.h" #include "gnss_block_factory.h" #include "gnss_block_interface.h" #include "gnss_sdr_filesystem.h" #include "gnuplot_i.h" #include "gps_l1_ca_pcps_acquisition_fpga.h" #include "gps_l5i_pcps_acquisition_fpga.h" #include "in_memory_configuration.h" #include "signal_generator_flags.h" #include "test_flags.h" #include "tracking_dump_reader.h" #include "tracking_interface.h" #include "tracking_tests_flags.h" #include "tracking_true_obs_reader.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if HAS_GENERIC_LAMBDA #else #include #endif #ifdef GR_GREATER_38 #include #else #include #endif #if PMT_USES_BOOST_ANY namespace wht = boost; #else namespace wht = std; #endif // ######## GNURADIO TRACKING BLOCK MESSAGE RECEVER ######### class TrackingPullInTest_msg_rx_Fpga; using TrackingPullInTest_msg_rx_Fpga_sptr = gnss_shared_ptr; TrackingPullInTest_msg_rx_Fpga_sptr TrackingPullInTest_msg_rx_Fpga_make(); class TrackingPullInTest_msg_rx_Fpga : public gr::block { private: friend TrackingPullInTest_msg_rx_Fpga_sptr TrackingPullInTest_msg_rx_Fpga_make(); void msg_handler_channel_events(const pmt::pmt_t msg); TrackingPullInTest_msg_rx_Fpga(); public: int rx_message; ~TrackingPullInTest_msg_rx_Fpga(); //!< Default destructor }; TrackingPullInTest_msg_rx_Fpga_sptr TrackingPullInTest_msg_rx_Fpga_make() { return TrackingPullInTest_msg_rx_Fpga_sptr(new TrackingPullInTest_msg_rx_Fpga()); } void TrackingPullInTest_msg_rx_Fpga::msg_handler_channel_events(const pmt::pmt_t msg) { try { int64_t message = pmt::to_long(std::move(msg)); rx_message = message; // 3 -> loss of lock } catch (const wht::bad_any_cast& e) { LOG(WARNING) << "msg_handler_tracking Bad cast!"; rx_message = 0; } } TrackingPullInTest_msg_rx_Fpga::TrackingPullInTest_msg_rx_Fpga() : gr::block("TrackingPullInTest_msg_rx_Fpga", gr::io_signature::make(0, 0, 0), gr::io_signature::make(0, 0, 0)) { this->message_port_register_in(pmt::mp("events")); this->set_msg_handler(pmt::mp("events"), #if HAS_GENERIC_LAMBDA [this](auto&& PH1) { msg_handler_channel_events(PH1); }); #else #if USE_BOOST_BIND_PLACEHOLDERS boost::bind(&TrackingPullInTest_msg_rx_Fpga::msg_handler_channel_events, this, boost::placeholders::_1)); #else boost::bind(&TrackingPullInTest_msg_rx_Fpga::msg_handler_channel_events, this, _1)); #endif #endif rx_message = 0; } TrackingPullInTest_msg_rx_Fpga::~TrackingPullInTest_msg_rx_Fpga() = default; struct DMA_handler_args_trk_pull_in_test { std::string file; int32_t nsamples_tx; int32_t skip_used_samples; unsigned int freq_band; // 0 for GPS L1/ Galileo E1, 1 for GPS L5/Galileo E5 float scaling_factor; }; struct acquisition_handler_args_trk_pull_in_test { std::shared_ptr acquisition; }; void* handler_acquisition_trk_pull_in_test(void* arguments) { // the acquisition is a blocking function so we have to // create a thread auto* args = (struct acquisition_handler_args_trk_pull_in_test*)arguments; args->acquisition->reset(); return nullptr; } void* handler_DMA_trk_pull_in_test(void* arguments) { const int MAX_INPUT_SAMPLES_TOTAL = 16384; auto* args = (struct DMA_handler_args_trk_pull_in_test*)arguments; std::string Filename = args->file; // input filename int32_t skip_used_samples = args->skip_used_samples; int32_t nsamples_tx = args->nsamples_tx; std::vector input_samples(MAX_INPUT_SAMPLES_TOTAL * 2); std::vector input_samples_dma(MAX_INPUT_SAMPLES_TOTAL * 2 * 2); bool file_completed = false; int32_t nsamples_remaining; int32_t nsamples_block_size; unsigned int dma_index; int tx_fd; // DMA descriptor std::ifstream infile; infile.exceptions(std::ifstream::failbit | std::ifstream::badbit); try { infile.open(Filename, std::ios::binary); } catch (const std::ifstream::failure& e) { std::cerr << "Exception opening file " << Filename << '\n'; return nullptr; } // ************************************************************************* // Open DMA device // ************************************************************************* tx_fd = open("/dev/loop_tx", O_WRONLY); if (tx_fd < 0) { std::cout << "Cannot open loop device\n"; return nullptr; } // ************************************************************************* // Open input file // ************************************************************************* #if USE_GLOG_AND_GFLAGS uint32_t skip_samples = static_cast(FLAGS_skip_samples); #else uint32_t skip_samples = static_cast(absl::GetFlag(FLAGS_skip_samples)); #endif if (skip_samples + skip_used_samples > 0) { try { infile.ignore((skip_samples + skip_used_samples) * 2); } catch (const std::ifstream::failure& e) { std::cerr << "Exception reading file " << Filename << '\n'; } } nsamples_remaining = nsamples_tx; nsamples_block_size = 0; while (file_completed == false) { dma_index = 0; if (nsamples_remaining > MAX_INPUT_SAMPLES_TOTAL) { nsamples_block_size = MAX_INPUT_SAMPLES_TOTAL; } else { nsamples_block_size = nsamples_remaining; } try { // 2 bytes per complex sample infile.read(reinterpret_cast(input_samples.data()), nsamples_block_size * 2); } catch (const std::ifstream::failure& e) { std::cerr << "Exception reading file " << Filename << '\n'; } for (int index0 = 0; index0 < (nsamples_block_size * 2); index0 += 2) { if (args->freq_band == 0) { // channel 1 (queue 1) -> E5/L5 input_samples_dma[dma_index] = 0; input_samples_dma[dma_index + 1] = 0; // channel 0 (queue 0) -> E1/L1 input_samples_dma[dma_index + 2] = static_cast(input_samples[index0] * args->scaling_factor); input_samples_dma[dma_index + 3] = static_cast(input_samples[index0 + 1] * args->scaling_factor); } else { // channel 1 (queue 1) -> E5/L5 input_samples_dma[dma_index] = static_cast(input_samples[index0] * args->scaling_factor); input_samples_dma[dma_index + 1] = static_cast(input_samples[index0 + 1] * args->scaling_factor); // channel 0 (queue 0) -> E1/L1 input_samples_dma[dma_index + 2] = 0; input_samples_dma[dma_index + 3] = 0; } dma_index += 4; } if (write(tx_fd, input_samples_dma.data(), nsamples_block_size * 2 * 2) != nsamples_block_size * 2 * 2) { std::cerr << "Error: DMA could not send all the required samples \n"; } // Throttle the DMA std::this_thread::sleep_for(std::chrono::milliseconds(1)); nsamples_remaining -= nsamples_block_size; if (nsamples_remaining == 0) { file_completed = true; } } try { infile.close(); } catch (const std::ifstream::failure& e) { std::cerr << "Exception closing files " << Filename << '\n'; } try { close(tx_fd); } catch (const std::ifstream::failure& e) { std::cerr << "Exception closing loop device \n"; } return nullptr; } class TrackingPullInTestFpga : public ::testing::Test { public: enum StringValue { evGPS_1C, evGPS_2S, evGPS_L5, evSBAS_1C, evGAL_1B, evGAL_5X, evGLO_1G, evGLO_2G }; std::string generator_binary; std::string p1; std::string p2; std::string p3; std::string p4; std::string p5; std::string p6; #if USE_GLOG_AND_GFLAGS std::string implementation = FLAGS_trk_test_implementation; const int baseband_sampling_freq = FLAGS_fs_gen_sps; std::string filename_rinex_obs = FLAGS_filename_rinex_obs; std::string filename_raw_data = FLAGS_signal_file; #else std::string implementation = absl::GetFlag(FLAGS_trk_test_implementation); const int baseband_sampling_freq = absl::GetFlag(FLAGS_fs_gen_sps); std::string filename_rinex_obs = absl::GetFlag(FLAGS_filename_rinex_obs); std::string filename_raw_data = absl::GetFlag(FLAGS_signal_file); #endif std::map doppler_measurements_map; std::map code_delay_measurements_map; std::map acq_samplestamp_map; int configure_generator(double CN0_dBHz, int file_idx); int generate_signal(); std::vector check_results_doppler(arma::vec& true_time_s, arma::vec& true_value, arma::vec& meas_time_s, arma::vec& meas_value, double& mean_error, double& std_dev_error); std::vector check_results_acc_carrier_phase(arma::vec& true_time_s, arma::vec& true_value, arma::vec& meas_time_s, arma::vec& meas_value, double& mean_error, double& std_dev_error); std::vector check_results_codephase(arma::vec& true_time_s, arma::vec& true_value, arma::vec& meas_time_s, arma::vec& meas_value, double& mean_error, double& std_dev_error); TrackingPullInTestFpga() { factory = std::make_shared(); config = std::make_shared(); item_size = sizeof(gr_complex); gnss_synchro = Gnss_Synchro(); } ~TrackingPullInTestFpga() = default; void configure_receiver(double PLL_wide_bw_hz, double DLL_wide_bw_hz, double PLL_narrow_bw_hz, double DLL_narrow_bw_hz, int extend_correlation_symbols); bool acquire_signal(int SV_ID); gr::top_block_sptr top_block; std::shared_ptr factory; std::shared_ptr config; Gnss_Synchro gnss_synchro; size_t item_size; std::shared_ptr> queue; static const int32_t TEST_TRK_PULL_IN_TEST_SKIP_SAMPLES = 1024; // 48 static constexpr float DMA_SIGNAL_SCALING_FACTOR = 8.0; }; int TrackingPullInTestFpga::configure_generator(double CN0_dBHz, int file_idx) { #if USE_GLOG_AND_GFLAGS // Configure signal generator generator_binary = FLAGS_generator_binary; p1 = std::string("-rinex_nav_file=") + FLAGS_rinex_nav_file; if (FLAGS_dynamic_position.empty()) { p2 = std::string("-static_position=") + FLAGS_static_position + std::string(",") + std::to_string(FLAGS_duration * 10); } else { p2 = std::string("-obs_pos_file=") + std::string(FLAGS_dynamic_position); } p3 = std::string("-rinex_obs_file=") + FLAGS_filename_rinex_obs; // RINEX 2.10 observation file output p4 = std::string("-sig_out_file=") + FLAGS_signal_file + std::to_string(file_idx); // Baseband signal output file. Will be stored in int8_t IQ multiplexed samples p5 = std::string("-sampling_freq=") + std::to_string(baseband_sampling_freq); // Baseband sampling frequency [MSps] p6 = std::string("-CN0_dBHz=") + std::to_string(CN0_dBHz); // Signal generator CN0 #else // Configure signal generator generator_binary = absl::GetFlag(FLAGS_generator_binary); p1 = std::string("-rinex_nav_file=") + absl::GetFlag(FLAGS_rinex_nav_file); if (absl::GetFlag(FLAGS_dynamic_position).empty()) { p2 = std::string("-static_position=") + absl::GetFlag(FLAGS_static_position) + std::string(",") + std::to_string(absl::GetFlag(FLAGS_duration) * 10); } else { p2 = std::string("-obs_pos_file=") + std::string(absl::GetFlag(FLAGS_dynamic_position)); } p3 = std::string("-rinex_obs_file=") + absl::GetFlag(FLAGS_filename_rinex_obs); // RINEX 2.10 observation file output p4 = std::string("-sig_out_file=") + absl::GetFlag(FLAGS_signal_file) + std::to_string(file_idx); // Baseband signal output file. Will be stored in int8_t IQ multiplexed samples p5 = std::string("-sampling_freq=") + std::to_string(baseband_sampling_freq); // Baseband sampling frequency [MSps] p6 = std::string("-CN0_dBHz=") + std::to_string(CN0_dBHz); // Signal generator CN0 #endif return 0; } int TrackingPullInTestFpga::generate_signal() { int child_status; char* const parmList[] = {&generator_binary[0], &generator_binary[0], &p1[0], &p2[0], &p3[0], &p4[0], &p5[0], &p6[0], nullptr}; int pid; if ((pid = fork()) == -1) { perror("fork err"); } else if (pid == 0) { execv(&generator_binary[0], parmList); std::cout << "Return not expected. Must be an execv err.\n"; std::terminate(); } waitpid(pid, &child_status, 0); std::cout << "Signal and Observables RINEX and RAW files created.\n"; return 0; } // When using the FPGA the acquisition class calls the states // of the channel finite state machine directly. This is done // in order to reduce the latency of the receiver when going // from acquisition to tracking. In order to execute the // acquisition in the unit tests we need to create a derived // class of the channel finite state machine. Some of the states // of the channel state machine are modified here, in order to // simplify the instantiation of the acquisition class in the // unit test. class ChannelFsm_trk_pull_in_test : public ChannelFsm { public: bool Event_valid_acquisition() override { acquisition_successful = true; return true; } bool Event_failed_acquisition_repeat() override { acquisition_successful = false; return true; } bool Event_failed_acquisition_no_repeat() override { acquisition_successful = false; return true; } bool Event_check_test_result() { return acquisition_successful; } void Event_clear_test_result() { acquisition_successful = false; } private: bool acquisition_successful; }; void TrackingPullInTestFpga::configure_receiver( double PLL_wide_bw_hz, double DLL_wide_bw_hz, double PLL_narrow_bw_hz, double DLL_narrow_bw_hz, int extend_correlation_symbols) { config = std::make_shared(); config->set_property("Tracking.dump", "true"); config->set_property("Tracking.dump_filename", "./tracking_ch_"); config->set_property("Tracking.implementation", implementation); config->set_property("Tracking.pll_bw_hz", std::to_string(PLL_wide_bw_hz)); config->set_property("Tracking.dll_bw_hz", std::to_string(DLL_wide_bw_hz)); config->set_property("Tracking.extend_correlation_symbols", std::to_string(extend_correlation_symbols)); config->set_property("Tracking.pll_bw_narrow_hz", std::to_string(PLL_narrow_bw_hz)); config->set_property("Tracking.dll_bw_narrow_hz", std::to_string(DLL_narrow_bw_hz)); #if USE_GLOG_AND_GFLAGS gnss_synchro.PRN = FLAGS_test_satellite_PRN; #else gnss_synchro.PRN = absl::GetFlag(FLAGS_test_satellite_PRN); #endif gnss_synchro.Channel_ID = 0; config->set_property("GNSS-SDR.internal_fs_sps", std::to_string(baseband_sampling_freq)); std::string System_and_Signal; if (implementation == "GPS_L1_CA_DLL_PLL_Tracking_FPGA") { gnss_synchro.System = 'G'; std::string signal = "1C"; System_and_Signal = "GPS L1 CA"; signal.copy(gnss_synchro.Signal, 2, 0); config->set_property("Tracking.early_late_space_chips", "0.5"); config->set_property("Tracking.early_late_space_narrow_chips", "0.5"); } else if (implementation == "Galileo_E1_DLL_PLL_VEML_Tracking_FPGA") { gnss_synchro.System = 'E'; std::string signal = "1B"; System_and_Signal = "Galileo E1B"; signal.copy(gnss_synchro.Signal, 2, 0); config->set_property("Tracking.early_late_space_chips", "0.15"); config->set_property("Tracking.very_early_late_space_chips", "0.6"); config->set_property("Tracking.early_late_space_narrow_chips", "0.15"); config->set_property("Tracking.very_early_late_space_narrow_chips", "0.6"); config->set_property("Tracking.track_pilot", "true"); } else if (implementation == "Galileo_E5a_DLL_PLL_Tracking_FPGA" or implementation == "Galileo_E5a_DLL_PLL_Tracking_b_Fpga") { gnss_synchro.System = 'E'; std::string signal = "5X"; System_and_Signal = "Galileo E5a"; signal.copy(gnss_synchro.Signal, 2, 0); if (implementation == "Galileo_E5a_DLL_PLL_Tracking_b") { config->supersede_property("Tracking.implementation", std::string("Galileo_E5a_DLL_PLL_Tracking_FPGA")); } config->set_property("Tracking.early_late_space_chips", "0.5"); config->set_property("Tracking.track_pilot", "true"); config->set_property("Tracking.order", "2"); } else if (implementation == "GPS_L5_DLL_PLL_Tracking_FPGA") { gnss_synchro.System = 'G'; std::string signal = "L5"; System_and_Signal = "GPS L5I"; signal.copy(gnss_synchro.Signal, 2, 0); config->set_property("Tracking.early_late_space_chips", "0.5"); config->set_property("Tracking.track_pilot", "true"); config->set_property("Tracking.order", "2"); } else { std::cout << "The test can not run with the selected tracking implementation\n "; throw(std::exception()); } std::cout << "*****************************************\n"; std::cout << "*** Tracking configuration parameters ***\n"; std::cout << "*****************************************\n"; std::cout << "Signal: " << System_and_Signal << "\n"; std::cout << "implementation: " << config->property("Tracking.implementation", std::string("undefined")) << " \n"; std::cout << "pll_bw_hz: " << config->property("Tracking.pll_bw_hz", 0.0) << " Hz\n"; std::cout << "dll_bw_hz: " << config->property("Tracking.dll_bw_hz", 0.0) << " Hz\n"; std::cout << "pll_bw_narrow_hz: " << config->property("Tracking.pll_bw_narrow_hz", 0.0) << " Hz\n"; std::cout << "dll_bw_narrow_hz: " << config->property("Tracking.dll_bw_narrow_hz", 0.0) << " Hz\n"; std::cout << "extend_correlation_symbols: " << config->property("Tracking.extend_correlation_symbols", 0) << " Symbols\n"; std::cout << "*****************************************\n"; std::cout << "*****************************************\n"; } bool TrackingPullInTestFpga::acquire_signal(int SV_ID) { pthread_t thread_DMA, thread_acquisition; // fsm std::shared_ptr channel_fsm_; channel_fsm_ = std::make_shared(); bool acquisition_successful; // Satellite signal definition Gnss_Synchro tmp_gnss_synchro; tmp_gnss_synchro.Channel_ID = 0; // config = std::make_shared(); config->set_property("GNSS-SDR.internal_fs_sps", std::to_string(baseband_sampling_freq)); std::shared_ptr acquisition; std::string System_and_Signal; std::string signal; struct DMA_handler_args_trk_pull_in_test args; struct acquisition_handler_args_trk_pull_in_test args_acq; #if USE_GLOG_AND_GFLAGS std::string file = FLAGS_signal_file; #else std::string file = absl::GetFlag(FLAGS_signal_file); #endif args.file = file; // DMA file configuration // instantiate the FPGA switch and set the // switch position to DMA. std::shared_ptr switch_fpga; switch_fpga = std::make_shared(); switch_fpga->set_switch_position(0); // set switch position to DMA // create the correspondign acquisition block according to the desired tracking signal if (implementation == "GPS_L1_CA_DLL_PLL_Tracking_FPGA") { tmp_gnss_synchro.System = 'G'; signal = "1C"; const char* str = signal.c_str(); // get a C style null terminated string std::memcpy(static_cast(tmp_gnss_synchro.Signal), str, 3); // copy string into synchro char array: 2 char + null tmp_gnss_synchro.PRN = SV_ID; System_and_Signal = "GPS L1 CA"; acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 0; // frequency band on which the DMA has to transfer the samples } else if (implementation == "Galileo_E1_DLL_PLL_VEML_Tracking_FPGA") { tmp_gnss_synchro.System = 'E'; signal = "1B"; const char* str = signal.c_str(); // get a C style null terminated string std::memcpy(static_cast(tmp_gnss_synchro.Signal), str, 3); // copy string into synchro char array: 2 char + null tmp_gnss_synchro.PRN = SV_ID; System_and_Signal = "Galileo E1B"; acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 0; // frequency band on which the DMA has to transfer the samples } else if (implementation == "Galileo_E5a_DLL_PLL_Tracking_FPGA") { tmp_gnss_synchro.System = 'E'; signal = "5X"; const char* str = signal.c_str(); // get a C style null terminated string std::memcpy(static_cast(tmp_gnss_synchro.Signal), str, 3); // copy string into synchro char array: 2 char + null tmp_gnss_synchro.PRN = SV_ID; System_and_Signal = "Galileo E5a"; acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 1; // frequency band on which the DMA has to transfer the samples } else if (implementation == "GPS_L5_DLL_PLL_Tracking_FPGA") { tmp_gnss_synchro.System = 'G'; signal = "L5"; const char* str = signal.c_str(); // get a C style null terminated string std::memcpy(static_cast(tmp_gnss_synchro.Signal), str, 3); // copy string into synchro char array: 2 char + null tmp_gnss_synchro.PRN = SV_ID; System_and_Signal = "GPS L5I"; acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 1; // frequency band on which the DMA has to transfer the samples } else { std::cout << "The test can not run with the selected tracking implementation\n "; throw(std::exception()); } acquisition->set_gnss_synchro(&tmp_gnss_synchro); acquisition->set_channel_fsm(channel_fsm_); acquisition->set_channel(0); #if USE_GLOG_AND_GFLAGS acquisition->set_doppler_max(config->property("Acquisition.doppler_max", FLAGS_external_signal_acquisition_doppler_max_hz)); acquisition->set_doppler_step(config->property("Acquisition.doppler_step", FLAGS_external_signal_acquisition_doppler_step_hz)); acquisition->set_doppler_center(0); acquisition->set_threshold(config->property("Acquisition.threshold", FLAGS_external_signal_acquisition_threshold)); #else acquisition->set_doppler_max(config->property("Acquisition.doppler_max", absl::GetFlag(FLAGS_external_signal_acquisition_doppler_max_hz))); acquisition->set_doppler_step(config->property("Acquisition.doppler_step", absl::GetFlag(FLAGS_external_signal_acquisition_doppler_step_hz))); acquisition->set_doppler_center(0); acquisition->set_threshold(config->property("Acquisition.threshold", absl::GetFlag(FLAGS_external_signal_acquisition_threshold))); #endif std::chrono::time_point start, end; std::chrono::duration elapsed_seconds; start = std::chrono::system_clock::now(); bool start_msg = true; doppler_measurements_map.clear(); code_delay_measurements_map.clear(); acq_samplestamp_map.clear(); unsigned int MAX_PRN_IDX = 0; switch (tmp_gnss_synchro.System) { case 'G': MAX_PRN_IDX = 33; break; case 'E': MAX_PRN_IDX = 37; break; default: MAX_PRN_IDX = 33; } // number of samples that the DMA has to transfer unsigned int nsamples_to_transfer; if (implementation == "GPS_L1_CA_DLL_PLL_Tracking_FPGA") { nsamples_to_transfer = static_cast(std::round(static_cast(baseband_sampling_freq) / (GPS_L1_CA_CODE_RATE_CPS / GPS_L1_CA_CODE_LENGTH_CHIPS))); } else if (implementation == "Galileo_E1_DLL_PLL_VEML_Tracking_FPGA") { nsamples_to_transfer = static_cast(std::round(static_cast(baseband_sampling_freq) / (GALILEO_E1_CODE_CHIP_RATE_CPS / GALILEO_E1_B_CODE_LENGTH_CHIPS))); } else if (implementation == "Galileo_E5a_DLL_PLL_Tracking_FPGA") { nsamples_to_transfer = static_cast(std::round(static_cast(baseband_sampling_freq) / (GALILEO_E5A_CODE_CHIP_RATE_CPS / GALILEO_E5A_CODE_LENGTH_CHIPS))); } else // (if (implementation.compare("GPS_L5_DLL_PLL_Tracking_FPGA") == 0)) { nsamples_to_transfer = static_cast(std::round(static_cast(baseband_sampling_freq) / (GPS_L5I_CODE_RATE_CPS / GPS_L5I_CODE_LENGTH_CHIPS))); } // set the scaling factor args.scaling_factor = DMA_SIGNAL_SCALING_FACTOR; for (unsigned int PRN = 1; PRN < MAX_PRN_IDX; PRN++) { tmp_gnss_synchro.PRN = PRN; channel_fsm_->Event_clear_test_result(); acquisition->stop_acquisition(); // reset the whole system including the sample counters acquisition->init(); acquisition->set_local_code(); if ((implementation == "GPS_L1_CA_DLL_PLL_Tracking_FPGA") or (implementation == "Galileo_E1_DLL_PLL_VEML_Tracking_FPGA")) { // Configure the DMA to send TEST_TRK_PULL_IN_TEST_SKIP_SAMPLES in order to initialize the internal // states of the downsampling filter in the FPGA args.skip_used_samples = 0; args.nsamples_tx = TEST_TRK_PULL_IN_TEST_SKIP_SAMPLES; // create DMA child process if (pthread_create(&thread_DMA, nullptr, handler_DMA_trk_pull_in_test, reinterpret_cast(&args)) < 0) { std::cout << "ERROR cannot create DMA Process\n"; } pthread_join(thread_DMA, nullptr); // Configure the DMA to skip the samples that were used to initialize the internal states of the // downsampling filter in the FPGA args.skip_used_samples = TEST_TRK_PULL_IN_TEST_SKIP_SAMPLES; } else { args.skip_used_samples = 0; } // Configure the DMA to send the required samples to perform an acquisition args.nsamples_tx = nsamples_to_transfer; // run the acquisition. The acquisition must run in a separate thread because it is a blocking function args_acq.acquisition = acquisition; if (pthread_create(&thread_acquisition, nullptr, handler_acquisition_trk_pull_in_test, reinterpret_cast(&args_acq)) < 0) { std::cout << "ERROR cannot create acquisition Process\n"; } if (start_msg == true) { #if USE_GLOG_AND_GFLAGS std::cout << "Reading external signal file: " << FLAGS_signal_file << '\n'; #else std::cout << "Reading external signal file: " << absl::GetFlag(FLAGS_signal_file) << '\n'; #endif std::cout << "Searching for " << System_and_Signal << " Satellites...\n"; std::cout << "["; start_msg = false; } // wait to give time for the acquisition thread to set up the acquisition HW accelerator in the FPGA usleep(1000000); // create DMA child process if (pthread_create(&thread_DMA, nullptr, handler_DMA_trk_pull_in_test, reinterpret_cast(&args)) < 0) { std::cout << "ERROR cannot create DMA Process\n"; } // wait until the acquisition is finished pthread_join(thread_acquisition, nullptr); // wait for the child DMA process to finish pthread_join(thread_DMA, nullptr); acquisition_successful = channel_fsm_->Event_check_test_result(); if (acquisition_successful) { std::cout << " " << PRN << " "; doppler_measurements_map.insert(std::pair(PRN, tmp_gnss_synchro.Acq_doppler_hz)); code_delay_measurements_map.insert(std::pair(PRN, tmp_gnss_synchro.Acq_delay_samples)); acq_samplestamp_map.insert(std::pair(PRN, tmp_gnss_synchro.Acq_samplestamp_samples)); } else { std::cout << " . "; } std::cout.flush(); } std::cout << "]\n"; std::cout << "-------------------------------------------\n"; for (auto& x : doppler_measurements_map) { std::cout << "DETECTED SATELLITE " << System_and_Signal << " PRN: " << x.first << " with Doppler: " << x.second << " [Hz], code phase: " << code_delay_measurements_map.at(x.first) << " [samples] at signal SampleStamp " << acq_samplestamp_map.at(x.first) << "\n"; } // report the elapsed time end = std::chrono::system_clock::now(); elapsed_seconds = end - start; std::cout << "Total signal acquisition run time " << elapsed_seconds.count() << " [seconds]\n"; return true; } TEST_F(TrackingPullInTestFpga, ValidationOfResults) { // pointer to the DMA thread that sends the samples to the acquisition engine pthread_t thread_DMA; struct DMA_handler_args_trk_pull_in_test args; // ************************************************* // ***** STEP 1: Prepare the parameters sweep ****** // ************************************************* std::vector acq_doppler_error_hz_values; std::vector> acq_delay_error_chips_values; // vector of vector #if USE_GLOG_AND_GFLAGS for (double doppler_hz = FLAGS_acq_Doppler_error_hz_start; doppler_hz >= FLAGS_acq_Doppler_error_hz_stop; doppler_hz = doppler_hz + FLAGS_acq_Doppler_error_hz_step) #else for (double doppler_hz = absl::GetFlag(FLAGS_acq_Doppler_error_hz_start); doppler_hz >= absl::GetFlag(FLAGS_acq_Doppler_error_hz_stop); doppler_hz = doppler_hz + absl::GetFlag(FLAGS_acq_Doppler_error_hz_step)) #endif { acq_doppler_error_hz_values.push_back(doppler_hz); std::vector tmp_vector; // Code Delay Sweep #if USE_GLOG_AND_GFLAGS for (double code_delay_chips = FLAGS_acq_Delay_error_chips_start; code_delay_chips >= FLAGS_acq_Delay_error_chips_stop; code_delay_chips = code_delay_chips + FLAGS_acq_Delay_error_chips_step) #else for (double code_delay_chips = absl::GetFlag(FLAGS_acq_Delay_error_chips_start); code_delay_chips >= absl::GetFlag(FLAGS_acq_Delay_error_chips_stop); code_delay_chips = code_delay_chips + absl::GetFlag(FLAGS_acq_Delay_error_chips_step)) #endif { tmp_vector.push_back(code_delay_chips); } acq_delay_error_chips_values.push_back(tmp_vector); } // *********************************************************** // ***** STEP 2: Generate the input signal (if required) ***** // *********************************************************** std::vector generator_CN0_values; #if USE_GLOG_AND_GFLAGS if (FLAGS_enable_external_signal_file) { generator_CN0_values.push_back(999); // an external input signal capture is selected, no CN0 information available } else { if (FLAGS_CN0_dBHz_start == FLAGS_CN0_dBHz_stop) { generator_CN0_values.push_back(FLAGS_CN0_dBHz_start); } else { for (double cn0 = FLAGS_CN0_dBHz_start; cn0 > FLAGS_CN0_dBHz_stop; cn0 = cn0 - FLAGS_CN0_dB_step) { generator_CN0_values.push_back(cn0); } } } #else if (absl::GetFlag(FLAGS_enable_external_signal_file)) { generator_CN0_values.push_back(999); // an external input signal capture is selected, no CN0 information available } else { if (absl::GetFlag(FLAGS_CN0_dBHz_start) == absl::GetFlag(FLAGS_CN0_dBHz_stop)) { generator_CN0_values.push_back(absl::GetFlag(FLAGS_CN0_dBHz_start)); } else { for (double cn0 = absl::GetFlag(FLAGS_CN0_dBHz_start); cn0 > absl::GetFlag(FLAGS_CN0_dBHz_stop); cn0 = cn0 - absl::GetFlag(FLAGS_CN0_dB_step)) { generator_CN0_values.push_back(cn0); } } } #endif // use generator or use an external capture file #if USE_GLOG_AND_GFLAGS if (FLAGS_enable_external_signal_file) { // create and configure an acquisition block and perform an acquisition to obtain the synchronization parameters ASSERT_EQ(acquire_signal(FLAGS_test_satellite_PRN), true); bool found_satellite = doppler_measurements_map.find(FLAGS_test_satellite_PRN) != doppler_measurements_map.end(); EXPECT_TRUE(found_satellite) << "Error: satellite SV: " << FLAGS_test_satellite_PRN << " is not acquired"; #else if (absl::GetFlag(FLAGS_enable_external_signal_file)) { // create and configure an acquisition block and perform an acquisition to obtain the synchronization parameters ASSERT_EQ(acquire_signal(absl::GetFlag(FLAGS_test_satellite_PRN)), true); bool found_satellite = doppler_measurements_map.find(absl::GetFlag(FLAGS_test_satellite_PRN)) != doppler_measurements_map.end(); EXPECT_TRUE(found_satellite) << "Error: satellite SV: " << absl::GetFlag(FLAGS_test_satellite_PRN) << " is not acquired"; #endif if (!found_satellite) { return; } } else { for (unsigned int current_cn0_idx = 0; current_cn0_idx < generator_CN0_values.size(); current_cn0_idx++) { // Configure the signal generator configure_generator(generator_CN0_values.at(current_cn0_idx), current_cn0_idx); // Generate signal raw signal samples and observations RINEX file #if USE_GLOG_AND_GFLAGS if (FLAGS_disable_generator == false) #else if (absl::GetFlag(FLAGS_disable_generator) == false) #endif { generate_signal(); } } } #if USE_GLOG_AND_GFLAGS configure_receiver(FLAGS_PLL_bw_hz_start, FLAGS_DLL_bw_hz_start, FLAGS_PLL_narrow_bw_hz, FLAGS_DLL_narrow_bw_hz, FLAGS_extend_correlation_symbols); #else configure_receiver(absl::GetFlag(FLAGS_PLL_bw_hz_start), absl::GetFlag(FLAGS_DLL_bw_hz_start), absl::GetFlag(FLAGS_PLL_narrow_bw_hz), absl::GetFlag(FLAGS_DLL_narrow_bw_hz), absl::GetFlag(FLAGS_extend_correlation_symbols)); #endif // ****************************************************************************************** // ***** Obtain the initial signal sinchronization parameters (emulating an acquisition) **** // ****************************************************************************************** int test_satellite_PRN = 0; double true_acq_doppler_hz = 0.0; double true_acq_delay_samples = 0.0; uint64_t acq_samplestamp_samples = 0; Tracking_True_Obs_Reader true_obs_data; #if USE_GLOG_AND_GFLAGS if (!FLAGS_enable_external_signal_file) { test_satellite_PRN = FLAGS_test_satellite_PRN; #else if (!absl::GetFlag(FLAGS_enable_external_signal_file)) { test_satellite_PRN = absl::GetFlag(FLAGS_test_satellite_PRN); #endif std::string true_obs_file = std::string("./gps_l1_ca_obs_prn"); true_obs_file.append(std::to_string(test_satellite_PRN)); true_obs_file.append(".dat"); true_obs_data.close_obs_file(); ASSERT_EQ(true_obs_data.open_obs_file(true_obs_file), true) << "Failure opening true observables file"; // load acquisition data based on the first epoch of the true observations ASSERT_EQ(true_obs_data.read_binary_obs(), true) << "Failure reading true tracking dump file.\n" #if USE_GLOG_AND_GFLAGS << "Maybe sat PRN #" + std::to_string(FLAGS_test_satellite_PRN) + #else << "Maybe sat PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + #endif " is not available?"; std::cout << "Testing satellite PRN=" << test_satellite_PRN << '\n'; std::cout << "True Initial Doppler " << true_obs_data.doppler_l1_hz << " [Hz], true Initial code delay [Chips]=" << true_obs_data.prn_delay_chips << "[Chips]\n"; true_acq_doppler_hz = true_obs_data.doppler_l1_hz; true_acq_delay_samples = (GPS_L1_CA_CODE_LENGTH_CHIPS - true_obs_data.prn_delay_chips / GPS_L1_CA_CODE_LENGTH_CHIPS) * static_cast(baseband_sampling_freq) * GPS_L1_CA_CODE_PERIOD_S; acq_samplestamp_samples = 0; } else { #if USE_GLOG_AND_GFLAGS true_acq_doppler_hz = doppler_measurements_map.find(FLAGS_test_satellite_PRN)->second; true_acq_delay_samples = code_delay_measurements_map.find(FLAGS_test_satellite_PRN)->second; acq_samplestamp_samples = acq_samplestamp_map.find(FLAGS_test_satellite_PRN)->second; #else true_acq_doppler_hz = doppler_measurements_map.find(absl::GetFlag(FLAGS_test_satellite_PRN))->second; true_acq_delay_samples = code_delay_measurements_map.find(absl::GetFlag(FLAGS_test_satellite_PRN))->second; acq_samplestamp_samples = acq_samplestamp_map.find(absl::GetFlag(FLAGS_test_satellite_PRN))->second; #endif std::cout << "Estimated Initial Doppler " << true_acq_doppler_hz << " [Hz], estimated Initial code delay " << true_acq_delay_samples << " [Samples]" #if USE_GLOG_AND_GFLAGS << " Acquisition SampleStamp is " << acq_samplestamp_map.find(FLAGS_test_satellite_PRN)->second << '\n'; #else << " Acquisition SampleStamp is " << acq_samplestamp_map.find(absl::GetFlag(FLAGS_test_satellite_PRN))->second << '\n'; #endif } #if USE_GLOG_AND_GFLAGS int64_t acq_to_trk_delay_samples = ceil(static_cast(FLAGS_fs_gen_sps) * FLAGS_acq_to_trk_delay_s); #else int64_t acq_to_trk_delay_samples = ceil(static_cast(absl::GetFlag(FLAGS_fs_gen_sps)) * absl::GetFlag(FLAGS_acq_to_trk_delay_s)); #endif // set the scaling factor args.scaling_factor = DMA_SIGNAL_SCALING_FACTOR; // CN0 LOOP std::vector> pull_in_results_v_v; for (unsigned int current_cn0_idx = 0; current_cn0_idx < generator_CN0_values.size(); current_cn0_idx++) { std::vector pull_in_results_v; for (unsigned int current_acq_doppler_error_idx = 0; current_acq_doppler_error_idx < acq_doppler_error_hz_values.size(); current_acq_doppler_error_idx++) { for (unsigned int current_acq_code_error_idx = 0; current_acq_code_error_idx < acq_delay_error_chips_values.at(current_acq_doppler_error_idx).size(); current_acq_code_error_idx++) { gnss_synchro.Acq_samplestamp_samples = acq_samplestamp_samples; // simulate a Doppler error in acquisition gnss_synchro.Acq_doppler_hz = true_acq_doppler_hz + acq_doppler_error_hz_values.at(current_acq_doppler_error_idx); // simulate Code Delay error in acquisition gnss_synchro.Acq_delay_samples = true_acq_delay_samples + (acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx) / GPS_L1_CA_CODE_RATE_CPS) * static_cast(baseband_sampling_freq); // We need to reset the HW again in order to reset the sample counter. // The HW is reset by sending a command to the acquisition HW accelerator // In order to send the reset command to the HW we instantiate the acquisition module. std::shared_ptr acquisition; // reset the HW to clear the sample counters: the acquisition constructor generates a reset if (implementation == "GPS_L1_CA_DLL_PLL_Tracking_FPGA") { acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 0; } else if (implementation == "Galileo_E1_DLL_PLL_VEML_Tracking_FPGA") { acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 0; } else if (implementation == "Galileo_E5a_DLL_PLL_Tracking_FPGA") { acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 1; } else if (implementation == "GPS_L5_DLL_PLL_Tracking_FPGA") { acquisition = std::make_shared(config.get(), "Acquisition", 0, 0); args.freq_band = 1; } else { std::cout << "The test can not run with the selected tracking implementation\n "; throw(std::exception()); } acquisition->stop_acquisition(); // reset the whole system including the sample counters // create flowgraph top_block = gr::make_top_block("Tracking test"); std::shared_ptr trk_ = factory->GetBlock(config.get(), "Tracking", 1, 1); std::shared_ptr tracking = std::dynamic_pointer_cast(trk_); auto msg_rx = TrackingPullInTest_msg_rx_Fpga_make(); ASSERT_NO_THROW({ tracking->set_channel(gnss_synchro.Channel_ID); }) << "Failure setting channel."; ASSERT_NO_THROW({ tracking->set_gnss_synchro(&gnss_synchro); }) << "Failure setting gnss_synchro."; ASSERT_NO_THROW({ tracking->connect(top_block); }) << "Failure connecting tracking to the top_block."; std::string file; ASSERT_NO_THROW({ #if USE_GLOG_AND_GFLAGS if (!FLAGS_enable_external_signal_file) #else if (!absl::GetFlag(FLAGS_enable_external_signal_file)) #endif { file = "./" + filename_raw_data + std::to_string(current_cn0_idx); } else { #if USE_GLOG_AND_GFLAGS file = FLAGS_signal_file; #else file = absl::GetFlag(FLAGS_signal_file); #endif } gr::blocks::null_sink::sptr sink = gr::blocks::null_sink::make(sizeof(Gnss_Synchro)); top_block->connect(tracking->get_right_block(), 0, sink, 0); top_block->msg_connect(tracking->get_right_block(), pmt::mp("events"), msg_rx, pmt::mp("events")); }) << "Failure connecting the blocks of tracking test."; // initialize the internal status of the LPF in the FPGA in the L1/E1 frequency band // ******************************************************************** // ***** STEP 5: Perform the signal tracking and read the results ***** // ******************************************************************** std::cout << "--- START TRACKING WITH PULL-IN ERROR: " << acq_doppler_error_hz_values.at(current_acq_doppler_error_idx) << " [Hz] and " << acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx) << " [Chips] ---\n"; std::chrono::time_point start, end; top_block->start(); usleep(1000000); // give time for the system to start before receiving the start tracking command. if (acq_to_trk_delay_samples > 0) { #if USE_GLOG_AND_GFLAGS std::cout << "--- SIMULATING A PULL-IN DELAY OF " << FLAGS_acq_to_trk_delay_s << " SECONDS ---\n"; #else std::cout << "--- SIMULATING A PULL-IN DELAY OF " << absl::GetFlag(FLAGS_acq_to_trk_delay_s) << " SECONDS ---\n"; #endif args.file = file; args.nsamples_tx = acq_to_trk_delay_samples; // 150 s for now but will be all file args.skip_used_samples = 0; if (pthread_create(&thread_DMA, nullptr, handler_DMA_trk_pull_in_test, reinterpret_cast(&args)) < 0) { std::cout << "ERROR cannot create DMA Process\n"; } } std::cout << " Starting tracking...\n"; tracking->start_tracking(); std::cout << " Waiting flowgraph..\n"; args.file = file; #if USE_GLOG_AND_GFLAGS args.nsamples_tx = baseband_sampling_freq * FLAGS_duration; #else args.nsamples_tx = baseband_sampling_freq * absl::GetFlag(FLAGS_duration); #endif args.skip_used_samples = acq_to_trk_delay_samples; if (pthread_create(&thread_DMA, nullptr, handler_DMA_trk_pull_in_test, reinterpret_cast(&args)) < 0) { std::cout << "ERROR cannot create DMA Process\n"; } // wait for the child DMA process to finish pthread_join(thread_DMA, nullptr); // stop the top block top_block->stop(); tracking->stop_tracking(); // reset the HW in order to produce an interrupt to the tracking // modules that are in a waiting state acquisition->stop_acquisition(); std::chrono::duration elapsed_seconds = end - start; std::cout << "Signal tracking completed in " << elapsed_seconds.count() << " seconds\n"; pull_in_results_v.push_back(msg_rx->rx_message != 3); // save last asynchronous tracking message in order to detect a loss of lock // ******************************** // ***** STEP 7: Plot results ***** // ******************************** #if USE_GLOG_AND_GFLAGS if (FLAGS_plot_detail_level >= 2 and FLAGS_show_plots) #else if (absl::GetFlag(FLAGS_plot_detail_level) >= 2 and absl::GetFlag(FLAGS_show_plots)) #endif { // load the measured values Tracking_Dump_Reader trk_dump; ASSERT_EQ(trk_dump.open_obs_file(std::string("./tracking_ch_0.dat")), true) << "Failure opening tracking dump file"; int64_t n_measured_epochs = trk_dump.num_epochs(); // todo: use vectors instead arma::vec trk_timestamp_s = arma::zeros(n_measured_epochs, 1); arma::vec trk_acc_carrier_phase_cycles = arma::zeros(n_measured_epochs, 1); arma::vec trk_Doppler_Hz = arma::zeros(n_measured_epochs, 1); arma::vec trk_prn_delay_chips = arma::zeros(n_measured_epochs, 1); std::vector timestamp_s; std::vector prompt; std::vector early; std::vector late; std::vector v_early; std::vector v_late; std::vector promptI; std::vector promptQ; std::vector CN0_dBHz; std::vector Doppler; int64_t epoch_counter = 0; while (trk_dump.read_binary_obs()) { trk_timestamp_s(epoch_counter) = static_cast(trk_dump.PRN_start_sample_count) / static_cast(baseband_sampling_freq); trk_acc_carrier_phase_cycles(epoch_counter) = trk_dump.acc_carrier_phase_rad / TWO_PI; trk_Doppler_Hz(epoch_counter) = trk_dump.carrier_doppler_hz; double delay_chips = GPS_L1_CA_CODE_LENGTH_CHIPS - GPS_L1_CA_CODE_LENGTH_CHIPS * (fmod((static_cast(trk_dump.PRN_start_sample_count) + trk_dump.aux1) / static_cast(baseband_sampling_freq), 1.0e-3) / 1.0e-3); trk_prn_delay_chips(epoch_counter) = delay_chips; timestamp_s.push_back(trk_timestamp_s(epoch_counter)); prompt.push_back(trk_dump.abs_P); early.push_back(trk_dump.abs_E); late.push_back(trk_dump.abs_L); v_early.push_back(trk_dump.abs_VE); v_late.push_back(trk_dump.abs_VL); promptI.push_back(trk_dump.prompt_I); promptQ.push_back(trk_dump.prompt_Q); CN0_dBHz.push_back(trk_dump.CN0_SNV_dB_Hz); Doppler.push_back(trk_dump.carrier_doppler_hz); epoch_counter++; } #if USE_GLOG_AND_GFLAGS const std::string gnuplot_executable(FLAGS_gnuplot_executable); #else const std::string gnuplot_executable(absl::GetFlag(FLAGS_gnuplot_executable)); #endif if (gnuplot_executable.empty()) { std::cout << "WARNING: Although the flag show_plots has been set to TRUE,\n"; std::cout << "gnuplot has not been found in your system.\n"; std::cout << "Test results will not be plotted.\n"; } else { try { fs::path p(gnuplot_executable); fs::path dir = p.parent_path(); const std::string& gnuplot_path = dir.native(); Gnuplot::set_GNUPlotPath(gnuplot_path); #if USE_GLOG_AND_GFLAGS auto decimate = static_cast(FLAGS_plot_decimate); if (FLAGS_plot_detail_level >= 2 and FLAGS_show_plots) { Gnuplot g1("linespoints"); g1.showonscreen(); // window output if (!FLAGS_enable_external_signal_file) { g1.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz, " + "PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz], GPS L1 C/A (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } else { g1.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips], PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz], (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } #else auto decimate = static_cast(absl::GetFlag(FLAGS_plot_decimate)); if (absl::GetFlag(FLAGS_plot_detail_level) >= 2 and absl::GetFlag(FLAGS_show_plots)) { Gnuplot g1("linespoints"); g1.showonscreen(); // window output if (!absl::GetFlag(FLAGS_enable_external_signal_file)) { g1.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz, " + "PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz], GPS L1 C/A (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } else { g1.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips], PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz], (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } #endif g1.set_grid(); g1.set_xlabel("Time [s]"); g1.set_ylabel("Correlators' output"); // g1.cmd("set key box opaque"); g1.plot_xy(trk_timestamp_s, prompt, "Prompt", decimate); g1.plot_xy(trk_timestamp_s, early, "Early", decimate); g1.plot_xy(trk_timestamp_s, late, "Late", decimate); if (implementation == "Galileo_E1_DLL_PLL_VEML_Tracking") { g1.plot_xy(trk_timestamp_s, v_early, "Very Early", decimate); g1.plot_xy(trk_timestamp_s, v_late, "Very Late", decimate); } g1.set_legend(); g1.savetops("Correlators_outputs"); Gnuplot g2("points"); g2.showonscreen(); // window output #if USE_GLOG_AND_GFLAGS if (!FLAGS_enable_external_signal_file) { g2.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz Constellation " + "PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz], (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } else { g2.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips], PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz], (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } #else if (!absl::GetFlag(FLAGS_enable_external_signal_file)) { g2.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz Constellation " + "PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz], (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } else { g2.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips], PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz], (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } #endif g2.set_grid(); g2.set_xlabel("Inphase"); g2.set_ylabel("Quadrature"); // g2.cmd("set size ratio -1"); g2.plot_xy(promptI, promptQ); g2.savetops("Constellation"); Gnuplot g3("linespoints"); #if USE_GLOG_AND_GFLAGS if (!FLAGS_enable_external_signal_file) { g3.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz, GPS L1 C/A tracking CN0 output (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } else { g3.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips] PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz], (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } #else if (!absl::GetFlag(FLAGS_enable_external_signal_file)) { g3.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz, GPS L1 C/A tracking CN0 output (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } else { g3.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips] PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz], (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } #endif g3.set_grid(); g3.set_xlabel("Time [s]"); g3.set_ylabel("Reported CN0 [dB-Hz]"); g3.cmd("set key box opaque"); g3.plot_xy(trk_timestamp_s, CN0_dBHz, std::to_string(static_cast(round(generator_CN0_values.at(current_cn0_idx)))) + "[dB-Hz]", decimate); g3.set_legend(); g3.savetops("CN0_output"); g3.showonscreen(); // window output Gnuplot g4("linespoints"); #if USE_GLOG_AND_GFLAGS if (!FLAGS_enable_external_signal_file) { g4.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz, GPS L1 C/A tracking CN0 output (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } else { g4.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips] PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz], (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } #else if (!absl::GetFlag(FLAGS_enable_external_signal_file)) { g4.set_title(std::to_string(generator_CN0_values.at(current_cn0_idx)) + " dB-Hz, GPS L1 C/A tracking CN0 output (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } else { g4.set_title("D_e=" + std::to_string(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)) + " [Hz] " + "T_e= " + std::to_string(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)) + " [Chips] PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz], (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } #endif g4.set_grid(); g4.set_xlabel("Time [s]"); g4.set_ylabel("Estimated Doppler [Hz]"); g4.cmd("set key box opaque"); g4.plot_xy(trk_timestamp_s, Doppler, std::to_string(static_cast(round(generator_CN0_values.at(current_cn0_idx)))) + "[dB-Hz]", decimate); g4.set_legend(); g4.savetops("Doppler"); g4.showonscreen(); // window output } } catch (const GnuplotException& ge) { std::cout << ge.what() << '\n'; } } } // end plot } // end acquisition Delay errors loop } // end acquisition Doppler errors loop pull_in_results_v_v.push_back(pull_in_results_v); } // end CN0 LOOP // build the mesh grid std::vector doppler_error_mesh; std::vector code_delay_error_mesh; for (unsigned int current_acq_doppler_error_idx = 0; current_acq_doppler_error_idx < acq_doppler_error_hz_values.size(); current_acq_doppler_error_idx++) { for (unsigned int current_acq_code_error_idx = 0; current_acq_code_error_idx < acq_delay_error_chips_values.at(current_acq_doppler_error_idx).size(); current_acq_code_error_idx++) { doppler_error_mesh.push_back(acq_doppler_error_hz_values.at(current_acq_doppler_error_idx)); code_delay_error_mesh.push_back(acq_delay_error_chips_values.at(current_acq_doppler_error_idx).at(current_acq_code_error_idx)); } } for (unsigned int current_cn0_idx = 0; current_cn0_idx < generator_CN0_values.size(); current_cn0_idx++) { std::vector pull_in_result_mesh; pull_in_result_mesh = pull_in_results_v_v.at(current_cn0_idx); // plot grid Gnuplot g4("points palette pointsize 2 pointtype 7"); #if USE_GLOG_AND_GFLAGS if (FLAGS_show_plots) #else if (absl::GetFlag(FLAGS_show_plots)) #endif { g4.showonscreen(); // window output } else { g4.disablescreen(); } g4.cmd(R"(set palette defined ( 0 "black", 1 "green" ))"); g4.cmd("set key off"); g4.cmd("set view map"); std::string title; #if USE_GLOG_AND_GFLAGS if (!FLAGS_enable_external_signal_file) { title = std::string("Tracking Pull-in result grid at CN0:" + std::to_string(static_cast(round(generator_CN0_values.at(current_cn0_idx)))) + " [dB-Hz], PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz]."); } else { title = std::string("Tracking Pull-in result grid, PLL/DLL BW: " + std::to_string(FLAGS_PLL_bw_hz_start) + "," + std::to_string(FLAGS_DLL_bw_hz_start) + " [Hz], GPS L1 C/A (PRN #" + std::to_string(FLAGS_test_satellite_PRN) + ")"); } #else if (!absl::GetFlag(FLAGS_enable_external_signal_file)) { title = std::string("Tracking Pull-in result grid at CN0:" + std::to_string(static_cast(round(generator_CN0_values.at(current_cn0_idx)))) + " [dB-Hz], PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz]."); } else { title = std::string("Tracking Pull-in result grid, PLL/DLL BW: " + std::to_string(absl::GetFlag(FLAGS_PLL_bw_hz_start)) + "," + std::to_string(absl::GetFlag(FLAGS_DLL_bw_hz_start)) + " [Hz], GPS L1 C/A (PRN #" + std::to_string(absl::GetFlag(FLAGS_test_satellite_PRN)) + ")"); } #endif g4.set_title(title); g4.set_grid(); g4.set_xlabel("Acquisition Doppler error [Hz]"); g4.set_ylabel("Acquisition Code Delay error [Chips]"); g4.cmd("set cbrange[0:1]"); g4.plot_xyz(doppler_error_mesh, code_delay_error_mesh, pull_in_result_mesh); g4.set_legend(); #if USE_GLOG_AND_GFLAGS if (!FLAGS_enable_external_signal_file) #else if (!absl::GetFlag(FLAGS_enable_external_signal_file)) #endif { g4.savetops("trk_pull_in_grid_" + std::to_string(static_cast(round(generator_CN0_values.at(current_cn0_idx))))); g4.savetopdf("trk_pull_in_grid_" + std::to_string(static_cast(round(generator_CN0_values.at(current_cn0_idx)))), 12); } else { g4.savetops("trk_pull_in_grid_external_file"); g4.savetopdf("trk_pull_in_grid_external_file", 12); } } }