mirror of
https://github.com/gnss-sdr/gnss-sdr
synced 2024-12-14 12:10:34 +00:00
Replace some C-style cast by static_cast<>()
See https://stackoverflow.com/questions/1609163/what-is-the-difference-between-static-cast-and-c-style-casting
This commit is contained in:
parent
f71933e938
commit
61f8df3586
@ -280,7 +280,7 @@ rtklib_pvt_cc::rtklib_pvt_cc(unsigned int nchannels, bool dump, std::string dump
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d_dump_filename.append("_raw.dat");
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dump_ls_pvt_filename.append("_ls_pvt.dat");
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d_ls_pvt = std::make_shared<rtklib_solver>((int)nchannels, dump_ls_pvt_filename, d_dump, rtk);
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d_ls_pvt = std::make_shared<rtklib_solver>(static_cast<int>(nchannels), dump_ls_pvt_filename, d_dump, rtk);
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d_ls_pvt->set_averaging_depth(1);
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d_rx_time = 0.0;
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@ -505,7 +505,7 @@ void Pvt_Solution::perform_pos_averaging()
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bool avg = d_flag_averaging;
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if (avg == true)
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{
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if (d_hist_longitude_d.size() == (unsigned int)d_averaging_depth)
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if (d_hist_longitude_d.size() == static_cast<unsigned int>(d_averaging_depth))
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{
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// Pop oldest value
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d_hist_longitude_d.pop_back();
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@ -1133,7 +1133,7 @@ void Rinex_Printer::update_nav_header(std::fstream& out, const Galileo_Iono& gal
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out.close();
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out.open(navGalfilename, std::ios::out | std::ios::trunc);
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out.seekp(0);
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for (int i = 0; i < (int) data.size() - 1; i++)
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for (int i = 0; i < static_cast<int>(data.size()) - 1; i++)
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{
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out << data[i] << std::endl;
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}
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@ -1284,7 +1284,7 @@ void Rinex_Printer::update_nav_header(std::fstream& out, const Gps_Utc_Model& ut
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out.close();
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out.open(navfilename, std::ios::out | std::ios::trunc);
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out.seekp(0);
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for (int i = 0; i < (int) data.size() - 1; i++)
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for (int i = 0; i < static_cast<int>(data.size()) - 1; i++)
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{
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out << data[i] << std::endl;
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}
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@ -1379,7 +1379,7 @@ void Rinex_Printer::update_nav_header(std::fstream & out, const Gps_CNAV_Utc_Mod
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out.close();
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out.open(navfilename, std::ios::out | std::ios::trunc);
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out.seekp(0);
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for (int i = 0; i < (int) data.size() - 1; i++)
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for (int i = 0; i < static_cast<int>(data.size()) - 1; i++)
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{
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out << data[i] << std::endl;
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}
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@ -1510,7 +1510,7 @@ void Rinex_Printer::update_nav_header(std::fstream& out, const Gps_Iono& gps_ion
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out.close();
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out.open(navMixfilename, std::ios::out | std::ios::trunc);
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out.seekp(0);
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for (int i = 0; i < (int) data.size() - 1; i++)
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for (int i = 0; i < static_cast<int>(data.size()) - 1; i++)
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{
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out << data[i] << std::endl;
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}
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@ -3522,7 +3522,7 @@ void Rinex_Printer::update_obs_header(std::fstream& out, const Gps_Utc_Model& ut
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out.close();
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out.open(obsfilename, std::ios::out | std::ios::trunc);
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out.seekp(0);
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for (int i = 0; i < (int) data.size() - 1; i++)
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for (int i = 0; i < static_cast<int>( data.size()) - 1; i++)
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{
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out << data[i] << std::endl;
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}
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@ -3581,7 +3581,7 @@ void Rinex_Printer::update_obs_header(std::fstream& out, const Gps_CNAV_Utc_Mode
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out.close();
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out.open(obsfilename, std::ios::out | std::ios::trunc);
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out.seekp(0);
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for (int i = 0; i < (int) data.size() - 1; i++)
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for (int i = 0; i < static_cast<int>(data.size()) - 1; i++)
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{
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out << data[i] << std::endl;
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}
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@ -3641,7 +3641,7 @@ void Rinex_Printer::update_obs_header(std::fstream& out, const Galileo_Utc_Model
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out.close();
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out.open(obsfilename, std::ios::out | std::ios::trunc);
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out.seekp(0);
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for (int i = 0; i < (int) data.size() - 1; i++)
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for (int i = 0; i < static_cast<int>(data.size()) - 1; i++)
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{
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out << data[i] << std::endl;
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}
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@ -61,7 +61,7 @@ GalileoE1Pcps8msAmbiguousAcquisition::GalileoE1Pcps8msAmbiguousAcquisition(
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if (sampled_ms_ % 4 != 0)
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{
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sampled_ms_ = (int)(sampled_ms_/4) * 4;
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sampled_ms_ = static_cast<int>(sampled_ms_ / 4) * 4;
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LOG(WARNING) << "coherent_integration_time should be multiple of "
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<< "Galileo code length (4 ms). coherent_integration_time = "
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<< sampled_ms_ << " ms will be used.";
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@ -73,13 +73,12 @@ GalileoE1Pcps8msAmbiguousAcquisition::GalileoE1Pcps8msAmbiguousAcquisition(
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default_dump_filename);
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//--- Find number of samples per spreading code (4 ms) -----------------
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code_length_ = round(
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fs_in_
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/ (Galileo_E1_CODE_CHIP_RATE_HZ
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/ Galileo_E1_B_CODE_LENGTH_CHIPS));
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vector_length_ = code_length_ * (int)(sampled_ms_/4);
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vector_length_ = code_length_ * static_cast<int>(sampled_ms_ / 4);
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int samples_per_ms = code_length_ / 4;
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@ -239,7 +238,7 @@ void GalileoE1Pcps8msAmbiguousAcquisition::reset()
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float GalileoE1Pcps8msAmbiguousAcquisition::calculate_threshold(float pfa)
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{
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
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@ -251,7 +250,7 @@ float GalileoE1Pcps8msAmbiguousAcquisition::calculate_threshold(float pfa)
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double val = pow(1.0 - pfa,exponent);
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double lambda = double(vector_length_);
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boost::math::exponential_distribution<double> mydist (lambda);
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float threshold = (float)quantile(mydist,val);
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float threshold = static_cast<float>(quantile(mydist,val));
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return threshold;
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}
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@ -60,7 +60,7 @@ GalileoE1PcpsAmbiguousAcquisition::GalileoE1PcpsAmbiguousAcquisition(
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if (sampled_ms_ % 4 != 0)
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{
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sampled_ms_ = (int)(sampled_ms_ / 4) * 4;
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sampled_ms_ = static_cast<int>(sampled_ms_ / 4) * 4;
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LOG(WARNING) << "coherent_integration_time should be multiple of "
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<< "Galileo code length (4 ms). coherent_integration_time = "
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<< sampled_ms_ << " ms will be used.";
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@ -93,7 +93,9 @@ GalileoE1PcpsAmbiguousAcquisition::GalileoE1PcpsAmbiguousAcquisition(
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bit_transition_flag_, use_CFAR_algorithm_flag_, dump_, dump_filename_);
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DLOG(INFO) << "acquisition(" << acquisition_sc_->unique_id() << ")";
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}else{
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}
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else
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{
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item_size_ = sizeof(gr_complex);
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acquisition_cc_ = pcps_make_acquisition_cc(sampled_ms_, max_dwells_,
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doppler_max_, if_, fs_in_, samples_per_ms, code_length_,
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@ -296,7 +298,7 @@ void GalileoE1PcpsAmbiguousAcquisition::set_state(int state)
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float GalileoE1PcpsAmbiguousAcquisition::calculate_threshold(float pfa)
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{
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
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@ -308,7 +310,7 @@ float GalileoE1PcpsAmbiguousAcquisition::calculate_threshold(float pfa)
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double val = pow(1.0 - pfa,exponent);
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double lambda = double(vector_length_);
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boost::math::exponential_distribution<double> mydist (lambda);
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float threshold = (float)quantile(mydist,val);
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float threshold = static_cast<float>(quantile(mydist,val));
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return threshold;
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}
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@ -67,14 +67,13 @@ GalileoE1PcpsQuickSyncAmbiguousAcquisition::GalileoE1PcpsQuickSyncAmbiguousAcqui
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int samples_per_ms = round(code_length_ / 4.0);
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/*Calculate the folding factor value based on the formula described in the paper.
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This may be a bug, but acquisition also work by variying the folding factor at va-
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lues different that the expressed in the paper. In adition, it is important to point
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out that by making the folding factor smaller we were able to get QuickSync work with
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Galileo. Future work should be directed to test this asumption statistically.*/
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//folding_factor_ = (unsigned int)ceil(sqrt(log2(code_length_)));
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//folding_factor_ = static_cast<unsigned int>(ceil(sqrt(log2(code_length_))));
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folding_factor_ = configuration_->property(role + ".folding_factor", 2);
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if (sampled_ms_ % (folding_factor_*4) != 0)
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@ -85,11 +84,11 @@ GalileoE1PcpsQuickSyncAmbiguousAcquisition::GalileoE1PcpsQuickSyncAmbiguousAcqui
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if(sampled_ms_ < (folding_factor_*4))
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{
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sampled_ms_ = (int) (folding_factor_*4);
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sampled_ms_ = static_cast<int>(folding_factor_ * 4);
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}
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else
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{
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sampled_ms_ = (int)(sampled_ms_/(folding_factor_*4)) * (folding_factor_*4);
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sampled_ms_ = static_cast<int>(sampled_ms_/(folding_factor_*4)) * (folding_factor_*4);
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}
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LOG(WARNING) << "coherent_integration_time should be multiple of "
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<< "Galileo code length (4 ms). coherent_integration_time = "
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@ -296,7 +295,7 @@ void GalileoE1PcpsQuickSyncAmbiguousAcquisition::set_state(int state)
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float GalileoE1PcpsQuickSyncAmbiguousAcquisition::calculate_threshold(float pfa)
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{
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
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@ -61,11 +61,10 @@ GalileoE1PcpsTongAmbiguousAcquisition::GalileoE1PcpsTongAmbiguousAcquisition(
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if (sampled_ms_ % 4 != 0)
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{
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sampled_ms_ = (int)(sampled_ms_/4) * 4;
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sampled_ms_ = static_cast<int>(sampled_ms_ / 4) * 4;
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LOG(WARNING) << "coherent_integration_time should be multiple of "
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<< "Galileo code length (4 ms). coherent_integration_time = "
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<< sampled_ms_ << " ms will be used.";
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}
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tong_init_val_ = configuration->property(role + ".tong_init_val", 1);
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@ -82,7 +81,7 @@ GalileoE1PcpsTongAmbiguousAcquisition::GalileoE1PcpsTongAmbiguousAcquisition(
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/ (Galileo_E1_CODE_CHIP_RATE_HZ
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/ Galileo_E1_B_CODE_LENGTH_CHIPS));
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vector_length_ = code_length_ * (int)(sampled_ms_/4);
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vector_length_ = code_length_ * static_cast<int>(sampled_ms_ / 4);
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int samples_per_ms = code_length_ / 4;
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@ -251,7 +250,7 @@ void GalileoE1PcpsTongAmbiguousAcquisition::set_state(int state)
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float GalileoE1PcpsTongAmbiguousAcquisition::calculate_threshold(float pfa)
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{
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
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@ -263,7 +262,7 @@ float GalileoE1PcpsTongAmbiguousAcquisition::calculate_threshold(float pfa)
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double val = pow(1.0-pfa,exponent);
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double lambda = double(vector_length_);
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boost::math::exponential_distribution<double> mydist (lambda);
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float threshold = (float)quantile(mydist,val);
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float threshold = static_cast<float>(quantile(mydist,val));
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return threshold;
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}
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@ -282,7 +282,7 @@ float GalileoE5aNoncoherentIQAcquisitionCaf::calculate_threshold(float pfa)
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{
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//Calculate the threshold
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
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@ -292,7 +292,7 @@ float GalileoE5aNoncoherentIQAcquisitionCaf::calculate_threshold(float pfa)
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double val = pow(1.0 - pfa, exponent);
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double lambda = double(vector_length_);
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boost::math::exponential_distribution<double> mydist (lambda);
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float threshold = (float)quantile(mydist,val);
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float threshold = static_cast<float>(quantile(mydist,val));
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return threshold;
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}
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@ -89,7 +89,9 @@ GpsL1CaPcpsAcquisition::GpsL1CaPcpsAcquisition(
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bit_transition_flag_, use_CFAR_algorithm_flag_, dump_, dump_filename_);
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DLOG(INFO) << "acquisition(" << acquisition_sc_->unique_id() << ")";
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}else{
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}
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else
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{
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item_size_ = sizeof(gr_complex);
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acquisition_cc_ = pcps_make_acquisition_cc(sampled_ms_, max_dwells_,
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doppler_max_, if_, fs_in_, code_length_, code_length_,
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@ -130,7 +132,6 @@ void GpsL1CaPcpsAcquisition::set_channel(unsigned int channel)
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{
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acquisition_cc_->set_channel(channel_);
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}
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}
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@ -188,9 +189,9 @@ void GpsL1CaPcpsAcquisition::set_doppler_step(unsigned int doppler_step)
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{
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acquisition_cc_->set_doppler_step(doppler_step_);
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}
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}
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void GpsL1CaPcpsAcquisition::set_gnss_synchro(Gnss_Synchro* gnss_synchro)
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{
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gnss_synchro_ = gnss_synchro;
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@ -236,7 +237,6 @@ void GpsL1CaPcpsAcquisition::init()
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void GpsL1CaPcpsAcquisition::set_local_code()
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{
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std::complex<float>* code = new std::complex<float>[code_length_];
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gps_l1_ca_code_gen_complex_sampled(code, gnss_synchro_->PRN, fs_in_, 0);
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@ -291,7 +291,7 @@ float GpsL1CaPcpsAcquisition::calculate_threshold(float pfa)
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{
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//Calculate the threshold
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
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@ -301,7 +301,7 @@ float GpsL1CaPcpsAcquisition::calculate_threshold(float pfa)
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double val = pow(1.0 - pfa, exponent);
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double lambda = double(vector_length_);
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boost::math::exponential_distribution<double> mydist (lambda);
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float threshold = (float)quantile(mydist,val);
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float threshold = static_cast<float>(quantile(mydist,val));
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return threshold;
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}
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@ -220,7 +220,7 @@ float GpsL1CaPcpsAcquisitionFpga::calculate_threshold(float pfa)
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{
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//Calculate the threshold
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unsigned int frequency_bins = 0;
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for (int doppler = (int) (-doppler_max_); doppler <= (int) doppler_max_;
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_);
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doppler += doppler_step_)
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{
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frequency_bins++;
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@ -231,7 +231,7 @@ float GpsL1CaPcpsAcquisitionFpga::calculate_threshold(float pfa)
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double val = pow(1.0 - pfa, exponent);
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double lambda = double(vector_length_);
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boost::math::exponential_distribution<double> mydist(lambda);
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float threshold = (float) quantile(mydist, val);
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float threshold = static_cast<float>(quantile(mydist, val));
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return threshold;
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}
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@ -236,7 +236,7 @@ float GpsL1CaPcpsMultithreadAcquisition::calculate_threshold(float pfa)
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//Calculate the threshold
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
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@ -248,7 +248,7 @@ float GpsL1CaPcpsMultithreadAcquisition::calculate_threshold(float pfa)
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double val = pow(1.0 - pfa, exponent);
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double lambda = double(vector_length_);
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boost::math::exponential_distribution<double> mydist (lambda);
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float threshold = (float)quantile(mydist,val);
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float threshold = static_cast<float>(quantile(mydist,val));
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return threshold;
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}
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@ -233,7 +233,7 @@ float GpsL1CaPcpsOpenClAcquisition::calculate_threshold(float pfa)
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//Calculate the threshold
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unsigned int frequency_bins = 0;
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for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
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for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
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{
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frequency_bins++;
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}
|
||||
@ -245,7 +245,7 @@ float GpsL1CaPcpsOpenClAcquisition::calculate_threshold(float pfa)
|
||||
double val = pow(1.0 - pfa, exponent);
|
||||
double lambda = double(vector_length_);
|
||||
boost::math::exponential_distribution<double> mydist (lambda);
|
||||
float threshold = (float)quantile(mydist,val);
|
||||
float threshold = static_cast<float>(quantile(mydist,val));
|
||||
|
||||
return threshold;
|
||||
}
|
||||
|
@ -59,14 +59,12 @@ GpsL1CaPcpsQuickSyncAcquisition::GpsL1CaPcpsQuickSyncAcquisition(
|
||||
doppler_max_ = configuration->property(role + ".doppler_max", 5000);
|
||||
sampled_ms_ = configuration_->property(role + ".coherent_integration_time_ms", 4);
|
||||
|
||||
|
||||
//--- Find number of samples per spreading code -------------------------
|
||||
code_length_ = round(fs_in_
|
||||
/ (GPS_L1_CA_CODE_RATE_HZ / GPS_L1_CA_CODE_LENGTH_CHIPS));
|
||||
|
||||
|
||||
/*Calculate the folding factor value based on the calculations*/
|
||||
unsigned int temp = (unsigned int)ceil(sqrt(log2(code_length_)));
|
||||
unsigned int temp = static_cast<unsigned int>(ceil(sqrt(log2(code_length_))));
|
||||
folding_factor_ = configuration_->property(role + ".folding_factor", temp);
|
||||
|
||||
if ( sampled_ms_ % folding_factor_ != 0)
|
||||
@ -76,17 +74,17 @@ GpsL1CaPcpsQuickSyncAcquisition::GpsL1CaPcpsQuickSyncAcquisition(
|
||||
<< sampled_ms_ << " ms";
|
||||
if(sampled_ms_ < folding_factor_)
|
||||
{
|
||||
sampled_ms_ = (int) folding_factor_;
|
||||
sampled_ms_ = static_cast<int>(folding_factor_);
|
||||
}
|
||||
else
|
||||
{
|
||||
sampled_ms_ = (int)(sampled_ms_/folding_factor_) * folding_factor_;
|
||||
sampled_ms_ = static_cast<int>(sampled_ms_ / folding_factor_) * folding_factor_;
|
||||
}
|
||||
|
||||
LOG(WARNING) <<" Coherent_integration_time of "
|
||||
LOG(WARNING) << " Coherent_integration_time of "
|
||||
<< sampled_ms_ << " ms will be used instead.";
|
||||
|
||||
}
|
||||
|
||||
vector_length_ = code_length_ * sampled_ms_;
|
||||
bit_transition_flag_ = configuration_->property(role + ".bit_transition_flag", false);
|
||||
|
||||
@ -276,7 +274,7 @@ float GpsL1CaPcpsQuickSyncAcquisition::calculate_threshold(float pfa)
|
||||
{
|
||||
//Calculate the threshold
|
||||
unsigned int frequency_bins = 0;
|
||||
for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
|
||||
for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
|
||||
{
|
||||
frequency_bins++;
|
||||
}
|
||||
@ -298,7 +296,6 @@ void GpsL1CaPcpsQuickSyncAcquisition::connect(gr::top_block_sptr top_block)
|
||||
{
|
||||
top_block->connect(stream_to_vector_, 0, acquisition_cc_, 0);
|
||||
}
|
||||
|
||||
}
|
||||
|
||||
|
||||
|
@ -232,7 +232,7 @@ float GpsL1CaPcpsTongAcquisition::calculate_threshold(float pfa)
|
||||
{
|
||||
//Calculate the threshold
|
||||
unsigned int frequency_bins = 0;
|
||||
for (int doppler = (int)(-doppler_max_); doppler <= (int)doppler_max_; doppler += doppler_step_)
|
||||
for (int doppler = static_cast<int>(-doppler_max_); doppler <= static_cast<int>(doppler_max_); doppler += doppler_step_)
|
||||
{
|
||||
frequency_bins++;
|
||||
}
|
||||
@ -244,7 +244,7 @@ float GpsL1CaPcpsTongAcquisition::calculate_threshold(float pfa)
|
||||
double val = pow(1.0 - pfa,exponent);
|
||||
double lambda = double(vector_length_);
|
||||
boost::math::exponential_distribution<double> mydist (lambda);
|
||||
float threshold = (float)quantile(mydist, val);
|
||||
float threshold = static_cast<float>(quantile(mydist, val));
|
||||
|
||||
return threshold;
|
||||
}
|
||||
|
@ -88,7 +88,9 @@ GpsL2MPcpsAcquisition::GpsL2MPcpsAcquisition(
|
||||
bit_transition_flag_, use_CFAR_algorithm_flag_, dump_, dump_filename_);
|
||||
DLOG(INFO) << "acquisition(" << acquisition_sc_->unique_id() << ")";
|
||||
|
||||
}else{
|
||||
}
|
||||
else
|
||||
{
|
||||
item_size_ = sizeof(gr_complex);
|
||||
acquisition_cc_ = pcps_make_acquisition_cc(1, max_dwells_,
|
||||
doppler_max_, if_, fs_in_, code_length_, code_length_,
|
||||
@ -305,7 +307,7 @@ float GpsL2MPcpsAcquisition::calculate_threshold(float pfa)
|
||||
double val = pow(1.0 - pfa, exponent);
|
||||
double lambda = double(vector_length_);
|
||||
boost::math::exponential_distribution<double> mydist (lambda);
|
||||
float threshold = (float)quantile(mydist,val);
|
||||
float threshold = static_cast<float>(quantile(mydist,val));
|
||||
|
||||
return threshold;
|
||||
}
|
||||
|
@ -218,7 +218,7 @@ void gps_pcps_acquisition_fpga_sc::set_active(bool active)
|
||||
|
||||
d_sample_counter = initial_sample;
|
||||
|
||||
temp_peak_to_noise_level = (float) (magt / input_power);
|
||||
temp_peak_to_noise_level = static_cast<float>(magt) / static_cast<float>(input_power);
|
||||
if (peak_to_noise_level < temp_peak_to_noise_level)
|
||||
{
|
||||
peak_to_noise_level = temp_peak_to_noise_level;
|
||||
|
@ -165,8 +165,8 @@ void pcps_multithread_acquisition_cc::init()
|
||||
|
||||
// Count the number of bins
|
||||
d_num_doppler_bins = 0;
|
||||
for (int doppler = (int)(-d_doppler_max);
|
||||
doppler <= (int)d_doppler_max;
|
||||
for (int doppler = static_cast<int>(-d_doppler_max);
|
||||
doppler <= static_cast<int>(d_doppler_max);
|
||||
doppler += d_doppler_step)
|
||||
{
|
||||
d_num_doppler_bins++;
|
||||
@ -177,7 +177,7 @@ void pcps_multithread_acquisition_cc::init()
|
||||
for (unsigned int doppler_index = 0; doppler_index < d_num_doppler_bins; doppler_index++)
|
||||
{
|
||||
d_grid_doppler_wipeoffs[doppler_index] = static_cast<gr_complex*>(volk_malloc(d_fft_size * sizeof(gr_complex), volk_get_alignment()));
|
||||
int doppler = -(int)d_doppler_max + d_doppler_step * doppler_index;
|
||||
int doppler = -static_cast<int>(d_doppler_max) + d_doppler_step * doppler_index;
|
||||
float phase_step_rad = static_cast<float>(GPS_TWO_PI) * (d_freq + doppler) / static_cast<float>(d_fs_in);
|
||||
float _phase[1];
|
||||
_phase[0] = 0;
|
||||
@ -201,7 +201,7 @@ void pcps_multithread_acquisition_cc::acquisition_core()
|
||||
int doppler;
|
||||
uint32_t indext = 0;
|
||||
float magt = 0.0;
|
||||
float fft_normalization_factor = (float)d_fft_size * (float)d_fft_size;
|
||||
float fft_normalization_factor = static_cast<float>(d_fft_size) * static_cast<float>(d_fft_size);
|
||||
gr_complex* in = d_in_buffer[d_well_count];
|
||||
unsigned long int samplestamp = d_sample_counter_buffer[d_well_count];
|
||||
|
||||
@ -219,14 +219,14 @@ void pcps_multithread_acquisition_cc::acquisition_core()
|
||||
// 1- Compute the input signal power estimation
|
||||
volk_32fc_magnitude_squared_32f(d_magnitude, in, d_fft_size);
|
||||
volk_32f_accumulator_s32f(&d_input_power, d_magnitude, d_fft_size);
|
||||
d_input_power /= (float)d_fft_size;
|
||||
d_input_power /= static_cast<float>(d_fft_size);
|
||||
|
||||
// 2- Doppler frequency search loop
|
||||
for (unsigned int doppler_index = 0; doppler_index < d_num_doppler_bins; doppler_index++)
|
||||
{
|
||||
// doppler search steps
|
||||
|
||||
doppler = -(int)d_doppler_max + d_doppler_step*doppler_index;
|
||||
doppler = -static_cast<int>(d_doppler_max) + d_doppler_step * doppler_index;
|
||||
|
||||
volk_32fc_x2_multiply_32fc(d_fft_if->get_inbuf(), in,
|
||||
d_grid_doppler_wipeoffs[doppler_index], d_fft_size);
|
||||
@ -264,8 +264,8 @@ void pcps_multithread_acquisition_cc::acquisition_core()
|
||||
// restarted between consecutive dwells in multidwell operation.
|
||||
if (d_test_statistics < (d_mag / d_input_power) || !d_bit_transition_flag)
|
||||
{
|
||||
d_gnss_synchro->Acq_delay_samples = (double)(indext % d_samples_per_code);
|
||||
d_gnss_synchro->Acq_doppler_hz = (double)doppler;
|
||||
d_gnss_synchro->Acq_delay_samples = static_cast<double>(indext % d_samples_per_code);
|
||||
d_gnss_synchro->Acq_doppler_hz = static_cast<double>(doppler);
|
||||
d_gnss_synchro->Acq_samplestamp_samples = samplestamp;
|
||||
|
||||
// 5- Compute the test statistics and compare to the threshold
|
||||
@ -384,7 +384,7 @@ int pcps_multithread_acquisition_cc::general_work(int noutput_items,
|
||||
// Fill internal buffer with d_max_dwells signal blocks. This step ensures that
|
||||
// consecutive signal blocks will be processed in multi-dwell operation. This is
|
||||
// essential when d_bit_transition_flag = true.
|
||||
unsigned int num_dwells = std::min((int)(d_max_dwells-d_in_dwell_count),ninput_items[0]);
|
||||
unsigned int num_dwells = std::min(static_cast<int>(d_max_dwells - d_in_dwell_count), ninput_items[0]);
|
||||
for (unsigned int i = 0; i < num_dwells; i++)
|
||||
{
|
||||
memcpy(d_in_buffer[d_in_dwell_count++], (gr_complex*)input_items[i],
|
||||
@ -393,7 +393,7 @@ int pcps_multithread_acquisition_cc::general_work(int noutput_items,
|
||||
d_sample_counter_buffer.push_back(d_sample_counter);
|
||||
}
|
||||
|
||||
if (ninput_items[0] > (int)num_dwells)
|
||||
if (ninput_items[0] > static_cast<int>(num_dwells))
|
||||
{
|
||||
d_sample_counter += d_fft_size * (ninput_items[0]-num_dwells);
|
||||
}
|
||||
|
@ -90,9 +90,7 @@ gps_fpga_acquisition_8sc::gps_fpga_acquisition_8sc(std::string device_name,
|
||||
unsigned int nsamples_total, long fs_in, long freq,
|
||||
unsigned int sampled_ms, unsigned select_queue)
|
||||
{
|
||||
|
||||
// initial values
|
||||
|
||||
d_device_name = device_name;
|
||||
d_freq = freq;
|
||||
d_fs_in = fs_in;
|
||||
@ -115,10 +113,7 @@ gps_fpga_acquisition_8sc::gps_fpga_acquisition_8sc(std::string device_name,
|
||||
std::complex<float>* code = new std::complex<float>[nsamples_total]; // buffer for the local code
|
||||
std::complex<float> * code_total = new gr_complex[vector_length]; // buffer for the local code repeate every number of ms
|
||||
|
||||
gr_complex* d_fft_codes_padded =
|
||||
static_cast<gr_complex*>(volk_gnsssdr_malloc(
|
||||
vector_length * sizeof(gr_complex),
|
||||
volk_gnsssdr_get_alignment()));
|
||||
gr_complex* d_fft_codes_padded = static_cast<gr_complex*>(volk_gnsssdr_malloc(vector_length * sizeof(gr_complex), volk_gnsssdr_get_alignment()));
|
||||
|
||||
d_all_fft_codes = new lv_16sc_t[vector_length * NUM_PRNs]; // memory containing all the possible fft codes for PRN 0 to 32
|
||||
|
||||
@ -130,19 +125,16 @@ gps_fpga_acquisition_8sc::gps_fpga_acquisition_8sc(std::string device_name,
|
||||
|
||||
for (unsigned int i = 0; i < sampled_ms; i++)
|
||||
{
|
||||
memcpy(&(code_total[i * nsamples_total]), code,
|
||||
sizeof(gr_complex) * nsamples_total); // repeat for each ms
|
||||
memcpy(&(code_total[i * nsamples_total]), code, sizeof(gr_complex) * nsamples_total); // repeat for each ms
|
||||
}
|
||||
|
||||
int offset = 0;
|
||||
|
||||
memcpy(d_fft_if->get_inbuf() + offset, code_total,
|
||||
sizeof(gr_complex) * vector_length); // copy to FFT buffer
|
||||
memcpy(d_fft_if->get_inbuf() + offset, code_total, sizeof(gr_complex) * vector_length); // copy to FFT buffer
|
||||
|
||||
d_fft_if->execute(); // Run the FFT of local code
|
||||
|
||||
volk_32fc_conjugate_32fc(d_fft_codes_padded, d_fft_if->get_outbuf(),
|
||||
vector_length); // conjugate values
|
||||
volk_32fc_conjugate_32fc(d_fft_codes_padded, d_fft_if->get_outbuf(), vector_length); // conjugate values
|
||||
|
||||
max = 0; // initialize maximum value
|
||||
|
||||
@ -160,11 +152,8 @@ gps_fpga_acquisition_8sc::gps_fpga_acquisition_8sc(std::string device_name,
|
||||
|
||||
for (unsigned int i = 0; i < vector_length; i++) // map the FFT to the dynamic range of the fixed point values an copy to buffer containing all FFTs
|
||||
{
|
||||
d_all_fft_codes[i + vector_length * PRN] = lv_16sc_t(
|
||||
(int) (d_fft_codes_padded[i].real()
|
||||
* (pow(2, 7) - 1) / max),
|
||||
(int) (d_fft_codes_padded[i].imag()
|
||||
* (pow(2, 7) - 1) / max));
|
||||
d_all_fft_codes[i + vector_length * PRN] = lv_16sc_t(static_cast<int>(d_fft_codes_padded[i].real() * (pow(2, 7) - 1) / max),
|
||||
static_cast<int>(d_fft_codes_padded[i].imag() * (pow(2, 7) - 1) / max));
|
||||
}
|
||||
|
||||
}
|
||||
@ -174,21 +163,22 @@ gps_fpga_acquisition_8sc::gps_fpga_acquisition_8sc(std::string device_name,
|
||||
delete[] code_total;
|
||||
delete d_fft_if;
|
||||
delete[] d_fft_codes_padded;
|
||||
|
||||
}
|
||||
|
||||
|
||||
gps_fpga_acquisition_8sc::~gps_fpga_acquisition_8sc()
|
||||
{
|
||||
delete[] d_all_fft_codes;
|
||||
}
|
||||
|
||||
|
||||
bool gps_fpga_acquisition_8sc::free()
|
||||
{
|
||||
return true;
|
||||
}
|
||||
|
||||
unsigned gps_fpga_acquisition_8sc::fpga_acquisition_test_register(
|
||||
unsigned writeval)
|
||||
|
||||
unsigned gps_fpga_acquisition_8sc::fpga_acquisition_test_register(unsigned writeval)
|
||||
{
|
||||
unsigned readval;
|
||||
// write value to test register
|
||||
@ -199,8 +189,8 @@ unsigned gps_fpga_acquisition_8sc::fpga_acquisition_test_register(
|
||||
return readval;
|
||||
}
|
||||
|
||||
void gps_fpga_acquisition_8sc::fpga_configure_acquisition_local_code(
|
||||
lv_16sc_t fft_local_code[])
|
||||
|
||||
void gps_fpga_acquisition_8sc::fpga_configure_acquisition_local_code(lv_16sc_t fft_local_code[])
|
||||
{
|
||||
short int local_code;
|
||||
unsigned int k, tmp, tmp2;
|
||||
@ -216,6 +206,7 @@ void gps_fpga_acquisition_8sc::fpga_configure_acquisition_local_code(
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::run_acquisition(void)
|
||||
{
|
||||
// enable interrupts
|
||||
@ -235,6 +226,7 @@ void gps_fpga_acquisition_8sc::run_acquisition(void)
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::configure_acquisition()
|
||||
{
|
||||
d_map_base[0] = d_select_queue;
|
||||
@ -242,16 +234,15 @@ void gps_fpga_acquisition_8sc::configure_acquisition()
|
||||
d_map_base[2] = d_nsamples;
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::set_phase_step(unsigned int doppler_index)
|
||||
{
|
||||
float phase_step_rad_real;
|
||||
float phase_step_rad_int_temp;
|
||||
int32_t phase_step_rad_int;
|
||||
|
||||
int doppler = -static_cast<int>(d_doppler_max)
|
||||
+ d_doppler_step * doppler_index;
|
||||
float phase_step_rad = GPS_TWO_PI * (d_freq + doppler)
|
||||
/ static_cast<float>(d_fs_in);
|
||||
int doppler = -static_cast<int>(d_doppler_max) + d_doppler_step * doppler_index;
|
||||
float phase_step_rad = GPS_TWO_PI * (d_freq + doppler) / static_cast<float>(d_fs_in);
|
||||
// The doppler step can never be outside the range -pi to +pi, otherwise there would be aliasing
|
||||
// The FPGA expects phase_step_rad between -1 (-pi) to +1 (+pi)
|
||||
// The FPGA also expects the phase to be negative since it produces cos(x) -j*sin(x)
|
||||
@ -269,6 +260,7 @@ void gps_fpga_acquisition_8sc::set_phase_step(unsigned int doppler_index)
|
||||
d_map_base[3] = phase_step_rad_int;
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::read_acquisition_results(uint32_t* max_index,
|
||||
float* max_magnitude, unsigned *initial_sample, float *power_sum)
|
||||
{
|
||||
@ -277,24 +269,26 @@ void gps_fpga_acquisition_8sc::read_acquisition_results(uint32_t* max_index,
|
||||
readval = d_map_base[1];
|
||||
*initial_sample = readval;
|
||||
readval = d_map_base[2];
|
||||
*max_magnitude = (float) readval;
|
||||
*max_magnitude = static_cast<float>(readval);
|
||||
readval = d_map_base[4];
|
||||
*power_sum = (float) readval;
|
||||
*power_sum = static_cast<float>(readval);
|
||||
readval = d_map_base[3];
|
||||
*max_index = readval;
|
||||
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::block_samples()
|
||||
{
|
||||
d_map_base[14] = 1; // block the samples
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::unblock_samples()
|
||||
{
|
||||
d_map_base[14] = 0; // unblock the samples
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::open_device()
|
||||
{
|
||||
|
||||
@ -302,13 +296,13 @@ void gps_fpga_acquisition_8sc::open_device()
|
||||
{
|
||||
LOG(WARNING) << "Cannot open deviceio" << d_device_name;
|
||||
}
|
||||
|
||||
d_map_base = (volatile unsigned *) mmap(NULL, PAGE_SIZE,
|
||||
PROT_READ | PROT_WRITE, MAP_SHARED, d_fd, 0);
|
||||
|
||||
if (d_map_base == (void *) -1)
|
||||
{
|
||||
LOG(WARNING)
|
||||
<< "Cannot map the FPGA acquisition module into user memory";
|
||||
LOG(WARNING) << "Cannot map the FPGA acquisition module into user memory";
|
||||
}
|
||||
|
||||
// sanity check : check test register
|
||||
@ -319,8 +313,8 @@ void gps_fpga_acquisition_8sc::open_device()
|
||||
// acquisition, etc ..)
|
||||
unsigned writeval = TEST_REGISTER_ACQ_WRITEVAL;
|
||||
unsigned readval;
|
||||
readval = gps_fpga_acquisition_8sc::fpga_acquisition_test_register(
|
||||
writeval);
|
||||
readval = gps_fpga_acquisition_8sc::fpga_acquisition_test_register(writeval);
|
||||
|
||||
if (writeval != readval)
|
||||
{
|
||||
LOG(WARNING) << "Acquisition test register sanity check failed";
|
||||
@ -329,8 +323,9 @@ void gps_fpga_acquisition_8sc::open_device()
|
||||
{
|
||||
LOG(INFO) << "Acquisition test register sanity check success !";
|
||||
}
|
||||
|
||||
}
|
||||
|
||||
|
||||
void gps_fpga_acquisition_8sc::close_device()
|
||||
{
|
||||
if (munmap((void*) d_map_base, PAGE_SIZE) == -1)
|
||||
@ -338,6 +333,5 @@ void gps_fpga_acquisition_8sc::close_device()
|
||||
printf("Failed to unmap memory uio\n");
|
||||
}
|
||||
close(d_fd);
|
||||
|
||||
}
|
||||
|
||||
|
@ -57,7 +57,7 @@ int gnss_sdr_sample_counter::work (int noutput_items,
|
||||
{
|
||||
const Gnss_Synchro *in = (const Gnss_Synchro *) input_items[0]; // input
|
||||
|
||||
double current_T_rx_s = in[noutput_items-1].Tracking_sample_counter / (double)in[noutput_items-1].fs;
|
||||
double current_T_rx_s = in[noutput_items-1].Tracking_sample_counter / static_cast<double>(in[noutput_items-1].fs);
|
||||
if ((current_T_rx_s - last_T_rx_s) > report_interval_s)
|
||||
{
|
||||
std::cout << "Current receiver time: " << floor(current_T_rx_s) << " [s]" << std::endl;
|
||||
|
@ -51,7 +51,7 @@ DirectResamplerConditioner::DirectResamplerConditioner(
|
||||
std::string default_dump_file = "./data/signal_conditioner.dat";
|
||||
double fs_in;
|
||||
fs_in = configuration->property("GNSS-SDR.internal_fs_hz", 2048000.0);
|
||||
sample_freq_in_ = configuration->property(role_ + ".sample_freq_in", (double)4000000.0);
|
||||
sample_freq_in_ = configuration->property(role_ + ".sample_freq_in", 4000000.0);
|
||||
sample_freq_out_ = configuration->property(role_ + ".sample_freq_out", fs_in);
|
||||
if(std::fabs(fs_in - sample_freq_out_) > std::numeric_limits<double>::epsilon())
|
||||
{
|
||||
|
@ -87,19 +87,19 @@ SignalGenerator::SignalGenerator(ConfigurationInterface* configuration,
|
||||
{
|
||||
if (signal1[0].at(0)=='5')
|
||||
{
|
||||
vector_length = round((float) fs_in / (Galileo_E5a_CODE_CHIP_RATE_HZ
|
||||
vector_length = round(static_cast<float>(fs_in) / (Galileo_E5a_CODE_CHIP_RATE_HZ
|
||||
/ Galileo_E5a_CODE_LENGTH_CHIPS));
|
||||
}
|
||||
else
|
||||
{
|
||||
vector_length = round((float)fs_in / (Galileo_E1_CODE_CHIP_RATE_HZ
|
||||
vector_length = round(static_cast<float>(fs_in) / (Galileo_E1_CODE_CHIP_RATE_HZ
|
||||
/ Galileo_E1_B_CODE_LENGTH_CHIPS))
|
||||
* Galileo_E1_C_SECONDARY_CODE_LENGTH;
|
||||
}
|
||||
}
|
||||
else if (std::find(system.begin(), system.end(), "G") != system.end())
|
||||
{
|
||||
vector_length = round((float)fs_in
|
||||
vector_length = round(static_cast<float>(fs_in)
|
||||
/ (GPS_L1_CA_CODE_RATE_HZ / GPS_L1_CA_CODE_LENGTH_CHIPS));
|
||||
}
|
||||
|
||||
|
@ -122,7 +122,7 @@ NsrFileSignalSource::NsrFileSignalSource(ConfigurationInterface* configuration,
|
||||
if (file.is_open())
|
||||
{
|
||||
size = file.tellg();
|
||||
LOG(INFO) << "Total samples in the file= " << floor((double)size / (double)item_size());
|
||||
LOG(INFO) << "Total samples in the file= " << floor(static_cast<double>(size) / static_cast<double>(item_size()));
|
||||
}
|
||||
else
|
||||
{
|
||||
@ -131,20 +131,20 @@ NsrFileSignalSource::NsrFileSignalSource(ConfigurationInterface* configuration,
|
||||
}
|
||||
std::streamsize ss = std::cout.precision();
|
||||
std::cout << std::setprecision(16);
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << (double)size << " [bytes]" << std::endl;
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << size << " [bytes]" << std::endl;
|
||||
std::cout.precision (ss);
|
||||
|
||||
if (size > 0)
|
||||
{
|
||||
int sample_packet_factor = 4; // 1 byte -> 4 samples
|
||||
samples_ = floor((double)size / (double)item_size())*sample_packet_factor;
|
||||
samples_ = samples_- ceil(0.002 * (double)sampling_frequency_); //process all the samples available in the file excluding the last 2 ms
|
||||
samples_ = floor(static_cast<double>(size) / static_cast<double>(item_size())) * sample_packet_factor;
|
||||
samples_ = samples_- ceil(0.002 * static_cast<double>(sampling_frequency_)); //process all the samples available in the file excluding the last 2 ms
|
||||
}
|
||||
}
|
||||
|
||||
CHECK(samples_ > 0) << "File does not contain enough samples to process.";
|
||||
double signal_duration_s;
|
||||
signal_duration_s = (double)samples_ * ( 1 /(double)sampling_frequency_);
|
||||
signal_duration_s = static_cast<double>(samples_) * ( 1 /static_cast<double>(sampling_frequency_));
|
||||
LOG(INFO) << "Total number samples to be processed= " << samples_ << " GNSS signal duration= " << signal_duration_s << " [s]";
|
||||
std::cout << "GNSS signal recorded time to be processed: " << signal_duration_s << " [s]" << std::endl;
|
||||
|
||||
|
@ -60,10 +60,10 @@ OsmosdrSignalSource::OsmosdrSignalSource(ConfigurationInterface* configuration,
|
||||
// OSMOSDR Driver parameters
|
||||
AGC_enabled_ = configuration->property(role + ".AGC_enabled", true);
|
||||
freq_ = configuration->property(role + ".freq", GPS_L1_FREQ_HZ);
|
||||
gain_ = configuration->property(role + ".gain", (double)40.0);
|
||||
rf_gain_ = configuration->property(role + ".rf_gain", (double)40.0);
|
||||
if_gain_ = configuration->property(role + ".if_gain", (double)40.0);
|
||||
sample_rate_ = configuration->property(role + ".sampling_frequency", (double)2.0e6);
|
||||
gain_ = configuration->property(role + ".gain", 40.0);
|
||||
rf_gain_ = configuration->property(role + ".rf_gain", 40.0);
|
||||
if_gain_ = configuration->property(role + ".if_gain", 40.0);
|
||||
sample_rate_ = configuration->property(role + ".sampling_frequency", 2.0e6);
|
||||
item_type_ = configuration->property(role + ".item_type", default_item_type);
|
||||
osmosdr_args_ = configuration->property(role + ".osmosdr_args", std::string( ));
|
||||
|
||||
|
@ -61,10 +61,10 @@ RtlTcpSignalSource::RtlTcpSignalSource(ConfigurationInterface* configuration,
|
||||
short default_port = 1234;
|
||||
AGC_enabled_ = configuration->property(role + ".AGC_enabled", true);
|
||||
freq_ = configuration->property(role + ".freq", GPS_L1_FREQ_HZ);
|
||||
gain_ = configuration->property(role + ".gain", (double)40.0);
|
||||
rf_gain_ = configuration->property(role + ".rf_gain", (double)40.0);
|
||||
if_gain_ = configuration->property(role + ".if_gain", (double)40.0);
|
||||
sample_rate_ = configuration->property(role + ".sampling_frequency", (double)2.0e6);
|
||||
gain_ = configuration->property(role + ".gain", 40.0);
|
||||
rf_gain_ = configuration->property(role + ".rf_gain", 40.0);
|
||||
if_gain_ = configuration->property(role + ".if_gain", 40.0);
|
||||
sample_rate_ = configuration->property(role + ".sampling_frequency", 2.0e6);
|
||||
item_type_ = configuration->property(role + ".item_type", default_item_type);
|
||||
address_ = configuration->property(role + ".address", default_address);
|
||||
port_ = configuration->property(role + ".port", default_port);
|
||||
|
@ -121,7 +121,7 @@ SpirFileSignalSource::SpirFileSignalSource(ConfigurationInterface* configuration
|
||||
if (file.is_open())
|
||||
{
|
||||
size = file.tellg();
|
||||
LOG(INFO) << "Total samples in the file= " << floor((double)size / (double)item_size());
|
||||
LOG(INFO) << "Total samples in the file= " << floor(static_cast<double>(size) / static_cast<double>(item_size()));
|
||||
}
|
||||
else
|
||||
{
|
||||
@ -130,20 +130,20 @@ SpirFileSignalSource::SpirFileSignalSource(ConfigurationInterface* configuration
|
||||
}
|
||||
std::streamsize ss = std::cout.precision();
|
||||
std::cout << std::setprecision(16);
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << (double)size << " [bytes]" << std::endl;
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << size << " [bytes]" << std::endl;
|
||||
std::cout.precision (ss);
|
||||
|
||||
if (size > 0)
|
||||
{
|
||||
int sample_packet_factor = 1; // 1 int -> 1 complex sample (I&Q from 1 channel)
|
||||
samples_ = floor((double)size / (double)item_size())*sample_packet_factor;
|
||||
samples_ = samples_- ceil(0.002 * (double)sampling_frequency_); //process all the samples available in the file excluding the last 2 ms
|
||||
samples_ = floor(static_cast<double>(size) / static_cast<double>(item_size())) * sample_packet_factor;
|
||||
samples_ = samples_- ceil(0.002 * static_cast<double>(sampling_frequency_)); //process all the samples available in the file excluding the last 2 ms
|
||||
}
|
||||
}
|
||||
|
||||
CHECK(samples_ > 0) << "File does not contain enough samples to process.";
|
||||
double signal_duration_s;
|
||||
signal_duration_s = (double)samples_ * ( 1 /(double)sampling_frequency_);
|
||||
signal_duration_s = static_cast<double>(samples_) * ( 1 /static_cast<double>(sampling_frequency_));
|
||||
LOG(INFO) << "Total number samples to be processed= " << samples_ << " GNSS signal duration= " << signal_duration_s << " [s]";
|
||||
std::cout << "GNSS signal recorded time to be processed: " << signal_duration_s << " [s]" << std::endl;
|
||||
|
||||
|
@ -119,7 +119,7 @@ TwoBitCpxFileSignalSource::TwoBitCpxFileSignalSource(ConfigurationInterface* con
|
||||
if (file.is_open())
|
||||
{
|
||||
size = file.tellg();
|
||||
LOG(INFO) << "Total samples in the file= " << floor((double)size / (double)item_size());
|
||||
LOG(INFO) << "Total samples in the file= " << floor(static_cast<double>(size) / static_cast<double>(item_size()));
|
||||
}
|
||||
else
|
||||
{
|
||||
@ -128,20 +128,20 @@ TwoBitCpxFileSignalSource::TwoBitCpxFileSignalSource(ConfigurationInterface* con
|
||||
}
|
||||
std::streamsize ss = std::cout.precision();
|
||||
std::cout << std::setprecision(16);
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << (double)size << " [bytes]" << std::endl;
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << size << " [bytes]" << std::endl;
|
||||
std::cout.precision (ss);
|
||||
|
||||
if (size > 0)
|
||||
{
|
||||
int sample_packet_factor = 2; // 1 byte -> 2 samples
|
||||
samples_ = floor((double)size / (double)item_size())*sample_packet_factor;
|
||||
samples_ = samples_- ceil(0.002 * (double)sampling_frequency_); //process all the samples available in the file excluding the last 2 ms
|
||||
samples_ = floor(static_cast<double>(size) / static_cast<double>(item_size())) * sample_packet_factor;
|
||||
samples_ = samples_- ceil(0.002 * static_cast<double>(sampling_frequency_)); //process all the samples available in the file excluding the last 2 ms
|
||||
}
|
||||
}
|
||||
|
||||
CHECK(samples_ > 0) << "File does not contain enough samples to process.";
|
||||
double signal_duration_s;
|
||||
signal_duration_s = (double)samples_ * ( 1 /(double)sampling_frequency_);
|
||||
signal_duration_s = static_cast<double>(samples_) * ( 1 /static_cast<double>(sampling_frequency_));
|
||||
LOG(INFO) << "Total number samples to be processed= " << samples_ << " GNSS signal duration= " << signal_duration_s << " [s]";
|
||||
std::cout << "GNSS signal recorded time to be processed: " << signal_duration_s << " [s]" << std::endl;
|
||||
|
||||
|
@ -185,7 +185,7 @@ TwoBitPackedFileSignalSource::TwoBitPackedFileSignalSource(ConfigurationInterfac
|
||||
if (file.is_open())
|
||||
{
|
||||
size = file.tellg();
|
||||
samples_ = floor((double)size * ( is_complex_ ? 2.0 : 4.0 ) );
|
||||
samples_ = floor(static_cast<double>(size) * ( is_complex_ ? 2.0 : 4.0 ) );
|
||||
LOG(INFO) << "Total samples in the file= " << samples_; // 4 samples per byte
|
||||
samples_ -= bytes_to_skip;
|
||||
|
||||
@ -199,13 +199,13 @@ TwoBitPackedFileSignalSource::TwoBitPackedFileSignalSource(ConfigurationInterfac
|
||||
}
|
||||
std::streamsize ss = std::cout.precision();
|
||||
std::cout << std::setprecision(16);
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << (double)size << " [bytes]" << std::endl;
|
||||
std::cout << "Processing file " << filename_ << ", which contains " << size << " [bytes]" << std::endl;
|
||||
std::cout.precision (ss);
|
||||
}
|
||||
|
||||
CHECK(samples_ > 0) << "File does not contain enough samples to process.";
|
||||
double signal_duration_s;
|
||||
signal_duration_s = (double)samples_ * ( 1 /(double)sampling_frequency_);
|
||||
signal_duration_s = static_cast<double>(samples_) * ( 1 /static_cast<double>(sampling_frequency_));
|
||||
LOG(INFO) << "Total number samples to be processed= " << samples_ << " GNSS signal duration= " << signal_duration_s << " [s]";
|
||||
std::cout << "GNSS signal recorded time to be processed: " << signal_duration_s << " [s]" << std::endl;
|
||||
|
||||
|
@ -71,7 +71,7 @@ UhdSignalSource::UhdSignalSource(ConfigurationInterface* configuration,
|
||||
subdevice_ = configuration->property(role + ".subdevice", empty);
|
||||
clock_source_ = configuration->property(role + ".clock_source", std::string("internal"));
|
||||
RF_channels_ = configuration->property(role + ".RF_channels", 1);
|
||||
sample_rate_ = configuration->property(role + ".sampling_frequency", (double)4.0e6);
|
||||
sample_rate_ = configuration->property(role + ".sampling_frequency", 4.0e6);
|
||||
item_type_ = configuration->property(role + ".item_type", default_item_type);
|
||||
|
||||
if (RF_channels_ == 1)
|
||||
@ -82,7 +82,7 @@ UhdSignalSource::UhdSignalSource(ConfigurationInterface* configuration,
|
||||
dump_filename_.push_back(configuration->property(role + ".dump_filename", default_dump_file));
|
||||
|
||||
freq_.push_back(configuration->property(role + ".freq", GPS_L1_FREQ_HZ));
|
||||
gain_.push_back(configuration->property(role + ".gain", (double)50.0));
|
||||
gain_.push_back(configuration->property(role + ".gain", 50.0));
|
||||
|
||||
IF_bandwidth_hz_.push_back(configuration->property(role + ".IF_bandwidth_hz", sample_rate_/2));
|
||||
|
||||
@ -98,7 +98,7 @@ UhdSignalSource::UhdSignalSource(ConfigurationInterface* configuration,
|
||||
dump_filename_.push_back(configuration->property(role + ".dump_filename" + boost::lexical_cast<std::string>(i), default_dump_file));
|
||||
|
||||
freq_.push_back(configuration->property(role + ".freq" + boost::lexical_cast<std::string>(i), GPS_L1_FREQ_HZ));
|
||||
gain_.push_back(configuration->property(role + ".gain" + boost::lexical_cast<std::string>(i), (double)50.0));
|
||||
gain_.push_back(configuration->property(role + ".gain" + boost::lexical_cast<std::string>(i), 50.0));
|
||||
|
||||
IF_bandwidth_hz_.push_back(configuration->property(role + ".IF_bandwidth_hz" + boost::lexical_cast<std::string>(i), sample_rate_/2));
|
||||
}
|
||||
|
@ -69,16 +69,16 @@ int unpack_byte_2bit_samples::work(int noutput_items,
|
||||
// Read packed input sample (1 byte = 4 samples)
|
||||
signed char c = in[i];
|
||||
sample.two_bit_sample = c & 3;
|
||||
out[n++] = (float)sample.two_bit_sample;
|
||||
out[n++] = static_cast<float>(sample.two_bit_sample);
|
||||
|
||||
sample.two_bit_sample = (c>>2) & 3;
|
||||
out[n++] = (float)sample.two_bit_sample;
|
||||
out[n++] = static_cast<float>(sample.two_bit_sample);
|
||||
|
||||
sample.two_bit_sample = (c>>4) & 3;
|
||||
out[n++] = (float)sample.two_bit_sample;
|
||||
out[n++] = static_cast<float>(sample.two_bit_sample);
|
||||
|
||||
sample.two_bit_sample = (c>>6) & 3;
|
||||
out[n++] = (float)sample.two_bit_sample;
|
||||
out[n++] = static_cast<float>(sample.two_bit_sample);
|
||||
}
|
||||
return noutput_items;
|
||||
}
|
||||
|
@ -70,10 +70,10 @@ void galileo_e1b_telemetry_decoder_cc::viterbi_decoder(double *page_part_symbols
|
||||
|
||||
/* create appropriate transition matrices */
|
||||
int *out0, *out1, *state0, *state1;
|
||||
out0 = (int*)calloc( max_states, sizeof(int) );
|
||||
out1 = (int*)calloc( max_states, sizeof(int) );
|
||||
state0 = (int*)calloc( max_states, sizeof(int) );
|
||||
state1 = (int*)calloc( max_states, sizeof(int) );
|
||||
out0 = static_cast<int*>(calloc( max_states, sizeof(int) ));
|
||||
out1 = static_cast<int*>(calloc( max_states, sizeof(int) ));
|
||||
state0 = static_cast<int*>(calloc( max_states, sizeof(int) ));
|
||||
state1 = static_cast<int*>(calloc( max_states, sizeof(int) ));
|
||||
|
||||
nsc_transit( out0, state0, 0, g_encoder, KK, nn );
|
||||
nsc_transit( out1, state1, 1, g_encoder, KK, nn );
|
||||
@ -404,14 +404,14 @@ int galileo_e1b_telemetry_decoder_cc::general_work (int noutput_items __attribut
|
||||
if(d_nav.flag_TOW_5 == true) //page 5 arrived and decoded, so we are in the odd page (since Tow refers to the even page, we have to add 1 sec)
|
||||
{
|
||||
//TOW_5 refers to the even preamble, but when we decode it we are in the odd part, so 1 second later plus the decoding delay
|
||||
d_TOW_at_current_symbol = d_nav.TOW_5 + GALILEO_INAV_PAGE_PART_SECONDS+((double)required_symbols)*GALILEO_E1_CODE_PERIOD; //-GALILEO_E1_CODE_PERIOD;//+ (double)GALILEO_INAV_PREAMBLE_LENGTH_BITS/(double)GALILEO_TELEMETRY_RATE_BITS_SECOND;
|
||||
d_TOW_at_current_symbol = d_nav.TOW_5 + GALILEO_INAV_PAGE_PART_SECONDS + (static_cast<double>(required_symbols)) * GALILEO_E1_CODE_PERIOD; //-GALILEO_E1_CODE_PERIOD;//+ (double)GALILEO_INAV_PREAMBLE_LENGTH_BITS/(double)GALILEO_TELEMETRY_RATE_BITS_SECOND;
|
||||
d_nav.flag_TOW_5 = false;
|
||||
}
|
||||
|
||||
else if(d_nav.flag_TOW_6 == true) //page 6 arrived and decoded, so we are in the odd page (since Tow refers to the even page, we have to add 1 sec)
|
||||
{
|
||||
//TOW_6 refers to the even preamble, but when we decode it we are in the odd part, so 1 second later plus the decoding delay
|
||||
d_TOW_at_current_symbol = d_nav.TOW_6 + GALILEO_INAV_PAGE_PART_SECONDS+((double)required_symbols)*GALILEO_E1_CODE_PERIOD;//-GALILEO_E1_CODE_PERIOD;//+ (double)GALILEO_INAV_PREAMBLE_LENGTH_BITS/(double)GALILEO_TELEMETRY_RATE_BITS_SECOND;
|
||||
d_TOW_at_current_symbol = d_nav.TOW_6 + GALILEO_INAV_PAGE_PART_SECONDS + (static_cast<double>(required_symbols)) * GALILEO_E1_CODE_PERIOD;//-GALILEO_E1_CODE_PERIOD;//+ (double)GALILEO_INAV_PREAMBLE_LENGTH_BITS/(double)GALILEO_TELEMETRY_RATE_BITS_SECOND;
|
||||
d_nav.flag_TOW_6 = false;
|
||||
}
|
||||
else
|
||||
|
@ -206,7 +206,7 @@ int gps_l1_ca_telemetry_decoder_cc::general_work (int noutput_items __attribute_
|
||||
}
|
||||
else if (d_stat == 1) //check 6 seconds of preamble separation
|
||||
{
|
||||
preamble_diff_ms = round((((double)d_symbol_history.at(0).Tracking_sample_counter - d_preamble_time_samples)/(double)d_symbol_history.at(0).fs) * 1000.0);
|
||||
preamble_diff_ms = round(((static_cast<double>(d_symbol_history.at(0).Tracking_sample_counter) - d_preamble_time_samples) / static_cast<double>(d_symbol_history.at(0).fs)) * 1000.0);
|
||||
if (abs(preamble_diff_ms - GPS_SUBFRAME_MS) < 1)
|
||||
{
|
||||
DLOG(INFO) << "Preamble confirmation for SAT " << this->d_satellite;
|
||||
@ -216,7 +216,7 @@ int gps_l1_ca_telemetry_decoder_cc::general_work (int noutput_items __attribute_
|
||||
if (!d_flag_frame_sync)
|
||||
{
|
||||
// send asynchronous message to tracking to inform of frame sync and extend correlation time
|
||||
pmt::pmt_t value = pmt::from_double((double)d_preamble_time_samples/(double)d_symbol_history.at(0).fs - 0.001);
|
||||
pmt::pmt_t value = pmt::from_double(static_cast<double>(d_preamble_time_samples) / static_cast<double>(d_symbol_history.at(0).fs) - 0.001);
|
||||
this->message_port_pub(pmt::mp("preamble_timestamp_s"), value);
|
||||
d_flag_frame_sync = true;
|
||||
if (corr_value < 0)
|
||||
@ -228,7 +228,8 @@ int gps_l1_ca_telemetry_decoder_cc::general_work (int noutput_items __attribute_
|
||||
{
|
||||
flag_PLL_180_deg_phase_locked = false;
|
||||
}
|
||||
DLOG(INFO) << " Frame sync SAT " << this->d_satellite << " with preamble start at " << (double)d_preamble_time_samples/(double)d_symbol_history.at(0).fs << " [s]";
|
||||
DLOG(INFO) << " Frame sync SAT " << this->d_satellite << " with preamble start at "
|
||||
<< static_cast<double>(d_preamble_time_samples) / static_cast<double>(d_symbol_history.at(0).fs) << " [s]";
|
||||
}
|
||||
}
|
||||
}
|
||||
@ -237,7 +238,7 @@ int gps_l1_ca_telemetry_decoder_cc::general_work (int noutput_items __attribute_
|
||||
{
|
||||
if (d_stat == 1)
|
||||
{
|
||||
preamble_diff_ms = round((((double)d_symbol_history.at(0).Tracking_sample_counter - (double)d_preamble_time_samples)/(double)d_symbol_history.at(0).fs) * 1000.0);
|
||||
preamble_diff_ms = round(((static_cast<double>(d_symbol_history.at(0).Tracking_sample_counter) - static_cast<double>(d_preamble_time_samples)) / static_cast<double>(d_symbol_history.at(0).fs)) * 1000.0);
|
||||
if (preamble_diff_ms > GPS_SUBFRAME_MS+1)
|
||||
{
|
||||
DLOG(INFO) << "Lost of frame sync SAT " << this->d_satellite << " preamble_diff= " << preamble_diff_ms;
|
||||
|
@ -149,13 +149,13 @@ int gps_l2c_telemetry_decoder_cc::general_work (int noutput_items __attribute__(
|
||||
}
|
||||
|
||||
//update TOW at the preamble instant
|
||||
d_TOW_at_Preamble = (int)msg.tow;
|
||||
d_TOW_at_Preamble = static_cast<int>(msg.tow);
|
||||
//std::cout<<"["<<(int)msg.prn<<"] deco delay: "<<delay<<"[symbols]"<<std::endl;
|
||||
//* The time of the last input symbol can be computed from the message ToW and
|
||||
//* delay by the formulae:
|
||||
//* \code
|
||||
//* symbolTime_ms = msg->tow * 6000 + *pdelay * 20
|
||||
d_TOW_at_current_symbol = ((double)msg.tow) * 6.0 + ((double)delay) * GPS_L2_M_PERIOD + 12 * GPS_L2_M_PERIOD;
|
||||
d_TOW_at_current_symbol = static_cast<double>(msg.tow) * 6.0 + static_cast<double>(delay) * GPS_L2_M_PERIOD + 12 * GPS_L2_M_PERIOD;
|
||||
d_TOW_at_current_symbol = floor(d_TOW_at_current_symbol * 1000.0) / 1000.0;
|
||||
d_flag_valid_word = true;
|
||||
}
|
||||
|
@ -143,7 +143,7 @@ int sbas_l1_telemetry_decoder_cc::general_work (int noutput_items __attribute__(
|
||||
(sample_alignment ? 0 : -1)
|
||||
+ d_samples_per_symbol*(symbol_alignment ? -1 : 0)
|
||||
+ d_samples_per_symbol * d_symbols_per_bit * it->first;
|
||||
double message_sample_stamp = sample_stamp + ((double)message_sample_offset)/1000;
|
||||
double message_sample_stamp = sample_stamp + static_cast<double>(message_sample_offset) / 1000.0;
|
||||
VLOG(EVENT) << "message_sample_stamp=" << message_sample_stamp
|
||||
<< " (sample_stamp=" << sample_stamp
|
||||
<< " sample_alignment=" << sample_alignment
|
||||
@ -446,7 +446,7 @@ void sbas_l1_telemetry_decoder_cc::crc_verifier::get_valid_frames(const std::vec
|
||||
ss << " Relbitoffset=" << candidate_it->first << " content=";
|
||||
for (std::vector<unsigned char>::iterator byte_it = candidate_bytes.begin(); byte_it < candidate_bytes.end(); ++byte_it)
|
||||
{
|
||||
ss << std::setw(2) << std::setfill('0') << std::hex << (unsigned int)(*byte_it);
|
||||
ss << std::setw(2) << std::setfill('0') << std::hex << static_cast<unsigned int>((*byte_it));
|
||||
}
|
||||
VLOG(SAMP_SYNC) << ss.str() << std::setfill(' ') << std::resetiosflags(std::ios::hex) << std::endl;
|
||||
}
|
||||
@ -471,13 +471,13 @@ void sbas_l1_telemetry_decoder_cc::crc_verifier::zerropad_back_and_convert_to_by
|
||||
if (idx_bit % bits_per_byte == bits_per_byte - 1)
|
||||
{
|
||||
bytes.push_back(byte);
|
||||
VLOG(LMORE) << ss.str() << " -> byte=" << std::setw(2) << std::setfill('0') << std::hex << (unsigned int)byte; ss.str("");
|
||||
VLOG(LMORE) << ss.str() << " -> byte=" << std::setw(2) << std::setfill('0') << std::hex << static_cast<unsigned int>(byte); ss.str("");
|
||||
byte = 0;
|
||||
}
|
||||
}
|
||||
bytes.push_back(byte); // implies: insert 6 zeros at the end to fit the 250bits into a multiple of bytes
|
||||
VLOG(LMORE) << " -> byte=" << std::setw(2)
|
||||
<< std::setfill('0') << std::hex << (unsigned int)byte
|
||||
<< std::setfill('0') << std::hex << static_cast<unsigned int>(byte)
|
||||
<< std::setfill(' ') << std::resetiosflags(std::ios::hex);
|
||||
}
|
||||
|
||||
@ -499,12 +499,12 @@ void sbas_l1_telemetry_decoder_cc::crc_verifier::zerropad_front_and_convert_to_b
|
||||
{
|
||||
bytes.push_back(byte);
|
||||
VLOG(LMORE) << ss.str() << " -> byte=" << std::setw(2)
|
||||
<< std::setfill('0') << std::hex << (unsigned int)byte; ss.str("");
|
||||
<< std::setfill('0') << std::hex << static_cast<unsigned int>(byte); ss.str("");
|
||||
byte = 0;
|
||||
}
|
||||
idx_bit++;
|
||||
}
|
||||
VLOG(LMORE) << " -> byte=" << std::setw(2)
|
||||
<< std::setfill('0') << std::hex << (unsigned int)byte
|
||||
<< std::setfill('0') << std::hex << static_cast<unsigned int>(byte)
|
||||
<< std::setfill(' ') << std::resetiosflags(std::ios::hex);
|
||||
}
|
||||
|
@ -70,7 +70,7 @@ GpsL2MDllPllTracking::GpsL2MDllPllTracking(
|
||||
std::string default_dump_filename = "./track_ch";
|
||||
dump_filename = configuration->property(role + ".dump_filename",
|
||||
default_dump_filename); //unused!
|
||||
vector_length = std::round((double)fs_in / ((double)GPS_L2_M_CODE_RATE_HZ / (double)GPS_L2_M_CODE_LENGTH_CHIPS));
|
||||
vector_length = std::round(static_cast<double>(fs_in) / (static_cast<double>(GPS_L2_M_CODE_RATE_HZ) / static_cast<double>(GPS_L2_M_CODE_LENGTH_CHIPS)));
|
||||
|
||||
//################# MAKE TRACKING GNURadio object ###################
|
||||
if (item_type.compare("gr_complex") == 0)
|
||||
|
@ -297,7 +297,7 @@ int Galileo_E1_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attr
|
||||
float acq_trk_shif_correction_samples;
|
||||
int acq_to_trk_delay_samples;
|
||||
acq_to_trk_delay_samples = d_sample_counter - d_acq_sample_stamp;
|
||||
acq_trk_shif_correction_samples = d_current_prn_length_samples - fmod((float)acq_to_trk_delay_samples, (float)d_current_prn_length_samples);
|
||||
acq_trk_shif_correction_samples = d_current_prn_length_samples - fmod(static_cast<float>(acq_to_trk_delay_samples), static_cast<float>(d_current_prn_length_samples));
|
||||
samples_offset = round(d_acq_code_phase_samples + acq_trk_shif_correction_samples);
|
||||
current_synchro_data.Tracking_sample_counter = d_sample_counter + samples_offset;
|
||||
current_synchro_data.fs = d_fs_in;
|
||||
@ -370,10 +370,10 @@ int Galileo_E1_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attr
|
||||
double T_prn_samples;
|
||||
double K_blk_samples;
|
||||
// Compute the next buffer lenght based in the new period of the PRN sequence and the code phase error estimation
|
||||
T_chip_seconds = 1 / (double)d_code_freq_chips;
|
||||
T_chip_seconds = 1 / static_cast<double>(d_code_freq_chips);
|
||||
T_prn_seconds = T_chip_seconds * Galileo_E1_B_CODE_LENGTH_CHIPS;
|
||||
T_prn_samples = T_prn_seconds * (double)d_fs_in;
|
||||
K_blk_samples = T_prn_samples + d_rem_code_phase_samples + code_error_filt_secs * (double)d_fs_in;
|
||||
T_prn_samples = T_prn_seconds * static_cast<double>(d_fs_in);
|
||||
K_blk_samples = T_prn_samples + d_rem_code_phase_samples + code_error_filt_secs * static_cast<double>(d_fs_in);
|
||||
d_current_prn_length_samples = round(K_blk_samples); //round to a discrete samples
|
||||
//d_rem_code_phase_samples = K_blk_samples - d_current_prn_length_samples; //rounding error < 1 sample
|
||||
|
||||
@ -415,15 +415,15 @@ int Galileo_E1_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attr
|
||||
}
|
||||
|
||||
// ########### Output the tracking data to navigation and PVT ##########
|
||||
current_synchro_data.Prompt_I = (double)(*d_Prompt).real();
|
||||
current_synchro_data.Prompt_Q = (double)(*d_Prompt).imag();
|
||||
current_synchro_data.Prompt_I = static_cast<double>((*d_Prompt).real());
|
||||
current_synchro_data.Prompt_Q = static_cast<double>((*d_Prompt).imag());
|
||||
// Tracking_timestamp_secs is aligned with the PRN start sample
|
||||
current_synchro_data.Tracking_sample_counter = d_sample_counter + d_current_prn_length_samples;
|
||||
current_synchro_data.Code_phase_samples = d_rem_code_phase_samples;
|
||||
d_rem_code_phase_samples = K_blk_samples - d_current_prn_length_samples; //rounding error < 1 sample
|
||||
current_synchro_data.Carrier_phase_rads = (double)d_acc_carrier_phase_rad;
|
||||
current_synchro_data.Carrier_Doppler_hz = (double)d_carrier_doppler_hz;
|
||||
current_synchro_data.CN0_dB_hz = (double)d_CN0_SNV_dB_Hz;
|
||||
current_synchro_data.Carrier_phase_rads = static_cast<double>(d_acc_carrier_phase_rad);
|
||||
current_synchro_data.Carrier_Doppler_hz = static_cast<double>(d_carrier_doppler_hz);
|
||||
current_synchro_data.CN0_dB_hz = static_cast<double>(d_CN0_SNV_dB_Hz);
|
||||
current_synchro_data.Flag_valid_symbol_output = true;
|
||||
current_synchro_data.correlation_length_ms = 4;
|
||||
}
|
||||
@ -498,7 +498,7 @@ int Galileo_E1_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attr
|
||||
// AUX vars (for debug purposes)
|
||||
tmp_float = d_rem_code_phase_samples;
|
||||
d_dump_file.write((char*)&tmp_float, sizeof(float));
|
||||
tmp_double = (double)(d_sample_counter+d_current_prn_length_samples);
|
||||
tmp_double = static_cast<double>(d_sample_counter + d_current_prn_length_samples);
|
||||
d_dump_file.write((char*)&tmp_double, sizeof(double));
|
||||
|
||||
// PRN
|
||||
|
@ -83,7 +83,7 @@ void Gps_L1_Ca_Tcp_Connector_Tracking_cc::forecast (int noutput_items,
|
||||
{
|
||||
if (noutput_items != 0)
|
||||
{
|
||||
ninput_items_required[0] = (int)d_vector_length*2; //set the required available samples in each call
|
||||
ninput_items_required[0] = static_cast<int>(d_vector_length) * 2; //set the required available samples in each call
|
||||
}
|
||||
}
|
||||
|
||||
@ -125,7 +125,7 @@ Gps_L1_Ca_Tcp_Connector_Tracking_cc::Gps_L1_Ca_Tcp_Connector_Tracking_cc(
|
||||
|
||||
// correlator outputs (scalar)
|
||||
d_n_correlator_taps = 3; // Very-Early, Early, Prompt, Late, Very-Late
|
||||
d_correlator_outs = static_cast<gr_complex*>(volk_gnsssdr_malloc(d_n_correlator_taps*sizeof(gr_complex), volk_gnsssdr_get_alignment()));
|
||||
d_correlator_outs = static_cast<gr_complex*>(volk_gnsssdr_malloc(d_n_correlator_taps * sizeof(gr_complex), volk_gnsssdr_get_alignment()));
|
||||
for (int n = 0; n < d_n_correlator_taps; n++)
|
||||
{
|
||||
d_correlator_outs[n] = gr_complex(0,0);
|
||||
@ -141,7 +141,7 @@ Gps_L1_Ca_Tcp_Connector_Tracking_cc::Gps_L1_Ca_Tcp_Connector_Tracking_cc(
|
||||
d_local_code_shift_chips[1] = 0.0;
|
||||
d_local_code_shift_chips[2] = d_early_late_spc_chips;
|
||||
|
||||
d_correlation_length_samples=d_vector_length;
|
||||
d_correlation_length_samples = d_vector_length;
|
||||
|
||||
multicorrelator_cpu.init(2 * d_correlation_length_samples, d_n_correlator_taps);
|
||||
|
||||
@ -161,7 +161,7 @@ Gps_L1_Ca_Tcp_Connector_Tracking_cc::Gps_L1_Ca_Tcp_Connector_Tracking_cc(
|
||||
d_enable_tracking = false;
|
||||
d_pull_in = false;
|
||||
|
||||
d_current_prn_length_samples = (int)d_vector_length;
|
||||
d_current_prn_length_samples = static_cast<int>(d_vector_length);
|
||||
|
||||
// CN0 estimation and lock detector buffers
|
||||
d_cn0_estimation_counter = 0;
|
||||
@ -201,9 +201,9 @@ void Gps_L1_Ca_Tcp_Connector_Tracking_cc::start_tracking()
|
||||
|
||||
long int acq_trk_diff_samples;
|
||||
float acq_trk_diff_seconds;
|
||||
acq_trk_diff_samples = (long int)d_sample_counter - (long int)d_acq_sample_stamp;
|
||||
acq_trk_diff_samples = static_cast<long int>(d_sample_counter) - static_cast<long int>(d_acq_sample_stamp);
|
||||
std::cout << "acq_trk_diff_samples=" << acq_trk_diff_samples << std::endl;
|
||||
acq_trk_diff_seconds = (float)acq_trk_diff_samples / (float)d_fs_in;
|
||||
acq_trk_diff_seconds = static_cast<float>(acq_trk_diff_samples) / static_cast<float>(d_fs_in);
|
||||
//doppler effect
|
||||
// Fd=(C/(C+Vr))*F
|
||||
float radial_velocity;
|
||||
@ -216,18 +216,18 @@ void Gps_L1_Ca_Tcp_Connector_Tracking_cc::start_tracking()
|
||||
d_code_phase_step_chips = static_cast<double>(d_code_freq_hz) / static_cast<double>(d_fs_in);
|
||||
T_chip_mod_seconds = 1/d_code_freq_hz;
|
||||
T_prn_mod_seconds = T_chip_mod_seconds * GPS_L1_CA_CODE_LENGTH_CHIPS;
|
||||
T_prn_mod_samples = T_prn_mod_seconds * (float)d_fs_in;
|
||||
T_prn_mod_samples = T_prn_mod_seconds * static_cast<float>(d_fs_in);
|
||||
|
||||
d_next_prn_length_samples = round(T_prn_mod_samples);
|
||||
|
||||
float T_prn_true_seconds = GPS_L1_CA_CODE_LENGTH_CHIPS / GPS_L1_CA_CODE_RATE_HZ;
|
||||
float T_prn_true_samples = T_prn_true_seconds * (float)d_fs_in;
|
||||
float T_prn_true_samples = T_prn_true_seconds * static_cast<float>(d_fs_in);
|
||||
float T_prn_diff_seconds;
|
||||
T_prn_diff_seconds = T_prn_true_seconds - T_prn_mod_seconds;
|
||||
float N_prn_diff;
|
||||
N_prn_diff = acq_trk_diff_seconds / T_prn_true_seconds;
|
||||
float corrected_acq_phase_samples, delay_correction_samples;
|
||||
corrected_acq_phase_samples = fmod((d_acq_code_phase_samples + T_prn_diff_seconds * N_prn_diff * (float)d_fs_in), T_prn_true_samples);
|
||||
corrected_acq_phase_samples = fmod((d_acq_code_phase_samples + T_prn_diff_seconds * N_prn_diff * static_cast<float>(d_fs_in)), T_prn_true_samples);
|
||||
if (corrected_acq_phase_samples < 0)
|
||||
{
|
||||
corrected_acq_phase_samples = T_prn_mod_samples + corrected_acq_phase_samples;
|
||||
@ -333,12 +333,12 @@ int Gps_L1_Ca_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attri
|
||||
float acq_trk_shif_correction_samples;
|
||||
int acq_to_trk_delay_samples;
|
||||
acq_to_trk_delay_samples = d_sample_counter - d_acq_sample_stamp;
|
||||
acq_trk_shif_correction_samples = d_next_prn_length_samples - fmod((float)acq_to_trk_delay_samples, (float)d_next_prn_length_samples);
|
||||
acq_trk_shif_correction_samples = d_next_prn_length_samples - fmod(static_cast<float>(acq_to_trk_delay_samples), static_cast<float>(d_next_prn_length_samples));
|
||||
samples_offset = round(d_acq_code_phase_samples + acq_trk_shif_correction_samples);
|
||||
current_synchro_data.Tracking_sample_counter = d_sample_counter + samples_offset;
|
||||
current_synchro_data.fs = d_fs_in;
|
||||
*out[0] = current_synchro_data;
|
||||
d_sample_counter_seconds = d_sample_counter_seconds + (((double)samples_offset) / (double)d_fs_in);
|
||||
d_sample_counter_seconds = d_sample_counter_seconds + (static_cast<double>(samples_offset) / static_cast<double>(d_fs_in));
|
||||
d_sample_counter = d_sample_counter + samples_offset; //count for the processed samples
|
||||
d_pull_in = false;
|
||||
consume_each(samples_offset); //shift input to perform alignement with local replica
|
||||
@ -390,21 +390,21 @@ int Gps_L1_Ca_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attri
|
||||
|
||||
// Update the phasestep based on code freq (variable) and
|
||||
// sampling frequency (fixed)
|
||||
d_code_phase_step_chips = d_code_freq_hz / (float)d_fs_in; //[chips]
|
||||
d_code_phase_step_chips = d_code_freq_hz / static_cast<float>(d_fs_in); //[chips]
|
||||
// variable code PRN sample block size
|
||||
double T_chip_seconds;
|
||||
double T_prn_seconds;
|
||||
double T_prn_samples;
|
||||
double K_blk_samples;
|
||||
T_chip_seconds = 1 / (double)d_code_freq_hz;
|
||||
T_chip_seconds = 1.0 / static_cast<double>(d_code_freq_hz);
|
||||
T_prn_seconds = T_chip_seconds * GPS_L1_CA_CODE_LENGTH_CHIPS;
|
||||
T_prn_samples = T_prn_seconds * (double)d_fs_in;
|
||||
T_prn_samples = T_prn_seconds * static_cast<double>(d_fs_in);
|
||||
d_rem_code_phase_samples = d_next_rem_code_phase_samples;
|
||||
K_blk_samples = T_prn_samples + d_rem_code_phase_samples;//-code_error*(double)d_fs_in;
|
||||
|
||||
// Update the current PRN delay (code phase in samples)
|
||||
double T_prn_true_seconds = GPS_L1_CA_CODE_LENGTH_CHIPS / GPS_L1_CA_CODE_RATE_HZ;
|
||||
double T_prn_true_samples = T_prn_true_seconds * (double)d_fs_in;
|
||||
double T_prn_true_samples = T_prn_true_seconds * static_cast<double>(d_fs_in);
|
||||
d_code_phase_samples = d_code_phase_samples + T_prn_samples - T_prn_true_samples;
|
||||
if (d_code_phase_samples < 0)
|
||||
{
|
||||
@ -453,15 +453,15 @@ int Gps_L1_Ca_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attri
|
||||
|
||||
// ########### Output the tracking data to navigation and PVT ##########
|
||||
|
||||
current_synchro_data.Prompt_I = (double)(*d_Prompt).real();
|
||||
current_synchro_data.Prompt_Q = (double)(*d_Prompt).imag();
|
||||
current_synchro_data.Prompt_I = static_cast<double>((*d_Prompt).real());
|
||||
current_synchro_data.Prompt_Q = static_cast<double>((*d_Prompt).imag());
|
||||
//compute remnant code phase samples AFTER the Tracking timestamp
|
||||
d_rem_code_phase_samples = K_blk_samples - d_current_prn_length_samples; //rounding error < 1 sample
|
||||
current_synchro_data.Tracking_sample_counter = d_sample_counter + d_current_prn_length_samples;
|
||||
current_synchro_data.Code_phase_samples = d_rem_code_phase_samples;
|
||||
current_synchro_data.Carrier_phase_rads = (double)d_acc_carrier_phase_rad;
|
||||
current_synchro_data.Carrier_Doppler_hz = (double)d_carrier_doppler_hz;
|
||||
current_synchro_data.CN0_dB_hz = (double)d_CN0_SNV_dB_Hz;
|
||||
current_synchro_data.Carrier_phase_rads = static_cast<double>(d_acc_carrier_phase_rad);
|
||||
current_synchro_data.Carrier_Doppler_hz = static_cast<double>(d_carrier_doppler_hz);
|
||||
current_synchro_data.CN0_dB_hz = static_cast<double>(d_CN0_SNV_dB_Hz);
|
||||
current_synchro_data.Flag_valid_symbol_output = true;
|
||||
current_synchro_data.correlation_length_ms=1;
|
||||
}
|
||||
@ -546,7 +546,7 @@ int Gps_L1_Ca_Tcp_Connector_Tracking_cc::general_work (int noutput_items __attri
|
||||
}
|
||||
|
||||
consume_each(d_current_prn_length_samples); // this is necessary in gr::block derivates
|
||||
d_sample_counter_seconds = d_sample_counter_seconds + ( ((double)d_current_prn_length_samples) / (double)d_fs_in );
|
||||
d_sample_counter_seconds = d_sample_counter_seconds + ( static_cast<double>(d_current_prn_length_samples) / static_cast<double>(d_fs_in) );
|
||||
d_sample_counter += d_current_prn_length_samples; //count for the processed samples
|
||||
|
||||
return 1; //output tracking result ALWAYS even in the case of d_enable_tracking==false
|
||||
|
@ -82,6 +82,7 @@ void fpga_multicorrelator_8sc::set_initial_sample(int samples_offset)
|
||||
d_initial_sample_counter = samples_offset;
|
||||
}
|
||||
|
||||
|
||||
bool fpga_multicorrelator_8sc::set_local_code_and_taps(int code_length_chips,
|
||||
const lv_16sc_t* local_code_in, float *shifts_chips)
|
||||
{
|
||||
@ -94,6 +95,7 @@ bool fpga_multicorrelator_8sc::set_local_code_and_taps(int code_length_chips,
|
||||
return true;
|
||||
}
|
||||
|
||||
|
||||
bool fpga_multicorrelator_8sc::set_output_vectors(lv_16sc_t* corr_out)
|
||||
{
|
||||
// Save CPU pointers
|
||||
@ -102,6 +104,7 @@ bool fpga_multicorrelator_8sc::set_output_vectors(lv_16sc_t* corr_out)
|
||||
return true;
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::update_local_code(float rem_code_phase_chips)
|
||||
{
|
||||
d_rem_code_phase_chips = rem_code_phase_chips;
|
||||
@ -110,6 +113,7 @@ void fpga_multicorrelator_8sc::update_local_code(float rem_code_phase_chips)
|
||||
fpga_multicorrelator_8sc::fpga_configure_code_parameters_in_fpga();
|
||||
}
|
||||
|
||||
|
||||
bool fpga_multicorrelator_8sc::Carrier_wipeoff_multicorrelator_resampler(
|
||||
float rem_carrier_phase_in_rad, float phase_step_rad,
|
||||
float rem_code_phase_chips, float code_phase_step_chips,
|
||||
@ -141,6 +145,7 @@ bool fpga_multicorrelator_8sc::Carrier_wipeoff_multicorrelator_resampler(
|
||||
return true;
|
||||
}
|
||||
|
||||
|
||||
fpga_multicorrelator_8sc::fpga_multicorrelator_8sc(int n_correlators,
|
||||
std::string device_name, unsigned int device_base)
|
||||
{
|
||||
@ -173,11 +178,13 @@ fpga_multicorrelator_8sc::fpga_multicorrelator_8sc(int n_correlators,
|
||||
d_correlator_length_samples = 0;
|
||||
}
|
||||
|
||||
|
||||
fpga_multicorrelator_8sc::~fpga_multicorrelator_8sc()
|
||||
{
|
||||
close(d_device_descriptor);
|
||||
}
|
||||
|
||||
|
||||
bool fpga_multicorrelator_8sc::free()
|
||||
{
|
||||
// unlock the hardware
|
||||
@ -200,6 +207,7 @@ bool fpga_multicorrelator_8sc::free()
|
||||
return true;
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::set_channel(unsigned int channel)
|
||||
{
|
||||
char device_io_name[MAX_LENGTH_DEVICEIO_NAME]; // driver io name
|
||||
@ -245,6 +253,7 @@ void fpga_multicorrelator_8sc::set_channel(unsigned int channel)
|
||||
|
||||
}
|
||||
|
||||
|
||||
unsigned fpga_multicorrelator_8sc::fpga_acquisition_test_register(
|
||||
unsigned writeval)
|
||||
{
|
||||
@ -257,6 +266,7 @@ unsigned fpga_multicorrelator_8sc::fpga_acquisition_test_register(
|
||||
return readval;
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::fpga_configure_tracking_gps_local_code(void)
|
||||
{
|
||||
|
||||
@ -289,6 +299,7 @@ void fpga_multicorrelator_8sc::fpga_configure_tracking_gps_local_code(void)
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::fpga_compute_code_shift_parameters(void)
|
||||
{
|
||||
float temp_calculation;
|
||||
@ -303,8 +314,7 @@ void fpga_multicorrelator_8sc::fpga_compute_code_shift_parameters(void)
|
||||
{
|
||||
temp_calculation = temp_calculation + d_code_length_chips; // % operator does not work as in Matlab with negative numbers
|
||||
}
|
||||
d_initial_index[i] = (unsigned) ((int) temp_calculation)
|
||||
% d_code_length_chips;
|
||||
d_initial_index[i] = static_cast<unsigned>( (static_cast<int>(temp_calculation)) % d_code_length_chips);
|
||||
|
||||
// initial interpolator counter calculation
|
||||
temp_calculation = fmod(d_shifts_chips[i] + d_rem_code_phase_chips,
|
||||
@ -313,11 +323,11 @@ void fpga_multicorrelator_8sc::fpga_compute_code_shift_parameters(void)
|
||||
{
|
||||
temp_calculation = temp_calculation + 1.0; // fmod operator does not work as in Matlab with negative numbers
|
||||
}
|
||||
d_initial_interp_counter[i] = (unsigned) floor(
|
||||
MAX_CODE_RESAMPLER_COUNTER * temp_calculation);
|
||||
d_initial_interp_counter[i] = static_cast<unsigned>( floor( MAX_CODE_RESAMPLER_COUNTER * temp_calculation));
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::fpga_configure_code_parameters_in_fpga(void)
|
||||
{
|
||||
int i;
|
||||
@ -329,12 +339,12 @@ void fpga_multicorrelator_8sc::fpga_configure_code_parameters_in_fpga(void)
|
||||
d_map_base[8] = d_code_length_chips - 1; // number of samples - 1
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::fpga_compute_signal_parameters_in_fpga(void)
|
||||
{
|
||||
float d_rem_carrier_phase_in_rad_temp;
|
||||
|
||||
d_code_phase_step_chips_num = (unsigned) roundf(
|
||||
MAX_CODE_RESAMPLER_COUNTER * d_code_phase_step_chips);
|
||||
d_code_phase_step_chips_num = static_cast<unsigned>( roundf(MAX_CODE_RESAMPLER_COUNTER * d_code_phase_step_chips));
|
||||
|
||||
if (d_rem_carrier_phase_in_rad > M_PI)
|
||||
{
|
||||
@ -351,16 +361,16 @@ void fpga_multicorrelator_8sc::fpga_compute_signal_parameters_in_fpga(void)
|
||||
d_rem_carrier_phase_in_rad_temp = d_rem_carrier_phase_in_rad;
|
||||
}
|
||||
|
||||
d_rem_carr_phase_rad_int = (int) roundf(
|
||||
d_rem_carr_phase_rad_int = static_cast<int>( roundf(
|
||||
(fabs(d_rem_carrier_phase_in_rad_temp) / M_PI)
|
||||
* pow(2, PHASE_CARR_NBITS_FRAC));
|
||||
* pow(2, PHASE_CARR_NBITS_FRAC)));
|
||||
|
||||
if (d_rem_carrier_phase_in_rad_temp < 0)
|
||||
{
|
||||
d_rem_carr_phase_rad_int = -d_rem_carr_phase_rad_int;
|
||||
}
|
||||
d_phase_step_rad_int = (int) roundf(
|
||||
(fabs(d_phase_step_rad) / M_PI) * pow(2, PHASE_CARR_NBITS_FRAC)); // the FPGA accepts a range for the phase step between -pi and +pi
|
||||
d_phase_step_rad_int = static_cast<int>( roundf(
|
||||
(fabs(d_phase_step_rad) / M_PI) * pow(2, PHASE_CARR_NBITS_FRAC))); // the FPGA accepts a range for the phase step between -pi and +pi
|
||||
|
||||
if (d_phase_step_rad < 0)
|
||||
{
|
||||
@ -368,6 +378,7 @@ void fpga_multicorrelator_8sc::fpga_compute_signal_parameters_in_fpga(void)
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::fpga_configure_signal_parameters_in_fpga(void)
|
||||
{
|
||||
d_map_base[0] = d_code_phase_step_chips_num;
|
||||
@ -377,6 +388,7 @@ void fpga_multicorrelator_8sc::fpga_configure_signal_parameters_in_fpga(void)
|
||||
d_map_base[13] = d_initial_sample_counter;
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::fpga_launch_multicorrelator_fpga(void)
|
||||
{
|
||||
// enable interrupts
|
||||
@ -386,6 +398,7 @@ void fpga_multicorrelator_8sc::fpga_launch_multicorrelator_fpga(void)
|
||||
d_map_base[14] = 0; // writing anything to reg 14 launches the tracking
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::read_tracking_gps_results(void)
|
||||
{
|
||||
int readval_real;
|
||||
@ -413,12 +426,14 @@ void fpga_multicorrelator_8sc::read_tracking_gps_results(void)
|
||||
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::unlock_channel(void)
|
||||
{
|
||||
// unlock the channel to let the next samples go through
|
||||
d_map_base[12] = 1; // unlock the channel
|
||||
}
|
||||
|
||||
|
||||
void fpga_multicorrelator_8sc::lock_channel(void)
|
||||
{
|
||||
// lock the channel for processing
|
||||
|
@ -201,39 +201,39 @@ void gnss_sdr_supl_client::read_supl_data()
|
||||
if (assist.set & SUPL_RRLP_ASSIST_REFTIME)
|
||||
{
|
||||
/* TS 44.031: GPSTOW, range 0-604799.92, resolution 0.08 sec, 23-bit presentation */
|
||||
gps_time.d_TOW = ((double)assist.time.gps_tow)*0.08;
|
||||
gps_time.d_Week = (double)assist.time.gps_week;
|
||||
gps_time.d_tv_sec = (double)assist.time.stamp.tv_sec;
|
||||
gps_time.d_tv_usec = (double)assist.time.stamp.tv_usec;
|
||||
gps_time.d_TOW = static_cast<double>(assist.time.gps_tow) * 0.08;
|
||||
gps_time.d_Week = static_cast<double>(assist.time.gps_week);
|
||||
gps_time.d_tv_sec = static_cast<double>(assist.time.stamp.tv_sec);
|
||||
gps_time.d_tv_usec = static_cast<double>(assist.time.stamp.tv_usec);
|
||||
gps_time.valid = true;
|
||||
}
|
||||
|
||||
// READ UTC MODEL
|
||||
if (assist.set & SUPL_RRLP_ASSIST_UTC)
|
||||
{
|
||||
gps_utc.d_A0 = ((double)assist.utc.a0)*pow(2.0, -30);
|
||||
gps_utc.d_A1 = ((double)assist.utc.a1)*pow(2.0, -50);
|
||||
gps_utc.d_DeltaT_LS = ((double)assist.utc.delta_tls);
|
||||
gps_utc.d_DeltaT_LSF = ((double)assist.utc.delta_tlsf);
|
||||
gps_utc.d_t_OT = ((double)assist.utc.tot)*pow(2.0,12);
|
||||
gps_utc.i_DN = ((double)assist.utc.dn);
|
||||
gps_utc.i_WN_T = ((double)assist.utc.wnt);
|
||||
gps_utc.i_WN_LSF = ((double)assist.utc.wnlsf);
|
||||
gps_utc.d_A0 = static_cast<double>(assist.utc.a0) * pow(2.0, -30);
|
||||
gps_utc.d_A1 = static_cast<double>(assist.utc.a1) * pow(2.0, -50);
|
||||
gps_utc.d_DeltaT_LS = static_cast<double>(assist.utc.delta_tls);
|
||||
gps_utc.d_DeltaT_LSF = static_cast<double>(assist.utc.delta_tlsf);
|
||||
gps_utc.d_t_OT = static_cast<double>(assist.utc.tot) * pow(2.0,12);
|
||||
gps_utc.i_DN = static_cast<double>(assist.utc.dn);
|
||||
gps_utc.i_WN_T = static_cast<double>(assist.utc.wnt);
|
||||
gps_utc.i_WN_LSF = static_cast<double>(assist.utc.wnlsf);
|
||||
gps_utc.valid = true;
|
||||
}
|
||||
|
||||
// READ IONOSPHERIC MODEL
|
||||
if (assist.set & SUPL_RRLP_ASSIST_IONO)
|
||||
{
|
||||
gps_iono.d_alpha0 = (double)assist.iono.a0 * ALPHA_0_LSB;
|
||||
gps_iono.d_alpha1 = (double)assist.iono.a1 * ALPHA_1_LSB;
|
||||
gps_iono.d_alpha2 = (double)assist.iono.a2 * ALPHA_2_LSB;
|
||||
gps_iono.d_alpha3 = (double)assist.iono.a3 * ALPHA_3_LSB;
|
||||
gps_iono.d_alpha0 = static_cast<double>(assist.iono.a0) * ALPHA_0_LSB;
|
||||
gps_iono.d_alpha1 = static_cast<double>(assist.iono.a1) * ALPHA_1_LSB;
|
||||
gps_iono.d_alpha2 = static_cast<double>(assist.iono.a2) * ALPHA_2_LSB;
|
||||
gps_iono.d_alpha3 = static_cast<double>(assist.iono.a3) * ALPHA_3_LSB;
|
||||
|
||||
gps_iono.d_beta0 = (double)assist.iono.b0 * BETA_0_LSB;
|
||||
gps_iono.d_beta1 = (double)assist.iono.b1 * BETA_1_LSB;
|
||||
gps_iono.d_beta2 = (double)assist.iono.b2 * BETA_2_LSB;
|
||||
gps_iono.d_beta3 = (double)assist.iono.b3 * BETA_3_LSB;
|
||||
gps_iono.d_beta0 = static_cast<double>(assist.iono.b0) * BETA_0_LSB;
|
||||
gps_iono.d_beta1 = static_cast<double>(assist.iono.b1) * BETA_1_LSB;
|
||||
gps_iono.d_beta2 = static_cast<double>(assist.iono.b2) * BETA_2_LSB;
|
||||
gps_iono.d_beta3 = static_cast<double>(assist.iono.b3) * BETA_3_LSB;
|
||||
gps_iono.valid = true;
|
||||
}
|
||||
|
||||
@ -254,16 +254,16 @@ void gnss_sdr_supl_client::read_supl_data()
|
||||
gps_almanac_iterator = this->gps_almanac_map.find(a->prn);
|
||||
}
|
||||
gps_almanac_iterator->second.i_satellite_PRN = a->prn;
|
||||
gps_almanac_iterator->second.d_A_f0 = ((double)a->AF0)*pow(2.0, -20);
|
||||
gps_almanac_iterator->second.d_A_f1 = ((double)a->AF1)*pow(2.0, -38);
|
||||
gps_almanac_iterator->second.d_Delta_i = ((double)a->Ksii)*pow(2.0, -19);
|
||||
gps_almanac_iterator->second.d_OMEGA = ((double)a->w)*pow(2.0, -23);
|
||||
gps_almanac_iterator->second.d_OMEGA0 = ((double)a->OMEGA_0)*pow(2.0, -23);
|
||||
gps_almanac_iterator->second.d_sqrt_A = ((double)a->A_sqrt)*pow(2.0, -11);
|
||||
gps_almanac_iterator->second.d_OMEGA_DOT = ((double)a->OMEGA_dot)*pow(2.0, -38);
|
||||
gps_almanac_iterator->second.d_Toa = ((double)a->toa)*pow(2.0, 12);
|
||||
gps_almanac_iterator->second.d_e_eccentricity = ((double)a->toa)*pow(2.0, -21);
|
||||
gps_almanac_iterator->second.d_M_0 = ((double)a->M0)*pow(2.0, -23);
|
||||
gps_almanac_iterator->second.d_A_f0 = static_cast<double>(a->AF0) * pow(2.0, -20);
|
||||
gps_almanac_iterator->second.d_A_f1 = static_cast<double>(a->AF1) * pow(2.0, -38);
|
||||
gps_almanac_iterator->second.d_Delta_i = static_cast<double>(a->Ksii) * pow(2.0, -19);
|
||||
gps_almanac_iterator->second.d_OMEGA = static_cast<double>(a->w) * pow(2.0, -23);
|
||||
gps_almanac_iterator->second.d_OMEGA0 = static_cast<double>(a->OMEGA_0) * pow(2.0, -23);
|
||||
gps_almanac_iterator->second.d_sqrt_A = static_cast<double>(a->A_sqrt) * pow(2.0, -11);
|
||||
gps_almanac_iterator->second.d_OMEGA_DOT = static_cast<double>(a->OMEGA_dot) * pow(2.0, -38);
|
||||
gps_almanac_iterator->second.d_Toa = static_cast<double>(a->toa) * pow(2.0, 12);
|
||||
gps_almanac_iterator->second.d_e_eccentricity = static_cast<double>(a->toa) * pow(2.0, -21);
|
||||
gps_almanac_iterator->second.d_M_0 = static_cast<double>(a->M0) * pow(2.0, -23);
|
||||
}
|
||||
}
|
||||
|
||||
@ -288,7 +288,7 @@ void gnss_sdr_supl_client::read_supl_data()
|
||||
{
|
||||
gps_eph_iterator->second.i_GPS_week = assist.time.gps_week;
|
||||
/* TS 44.031: GPSTOW, range 0-604799.92, resolution 0.08 sec, 23-bit presentation */
|
||||
gps_eph_iterator->second.d_TOW = ((double)assist.time.gps_tow)*0.08;
|
||||
gps_eph_iterator->second.d_TOW = static_cast<double>(assist.time.gps_tow) * 0.08;
|
||||
}
|
||||
else
|
||||
{
|
||||
@ -300,32 +300,32 @@ void gnss_sdr_supl_client::read_supl_data()
|
||||
gps_eph_iterator->second.i_code_on_L2 = e->bits;
|
||||
gps_eph_iterator->second.i_SV_accuracy = e->ura; //User Range Accuracy (URA)
|
||||
gps_eph_iterator->second.i_SV_health = e->health;
|
||||
gps_eph_iterator->second.d_IODC = (double)e->IODC;
|
||||
gps_eph_iterator->second.d_IODC = static_cast<double>(e->IODC);
|
||||
//miss P flag (1 bit)
|
||||
//miss SF1 Reserved (87 bits)
|
||||
gps_eph_iterator->second.d_TGD = ((double)e->tgd)*T_GD_LSB;
|
||||
gps_eph_iterator->second.d_Toc = ((double)e->toc)*T_OC_LSB;
|
||||
gps_eph_iterator->second.d_A_f0 = ((double)e->AF0)*A_F0_LSB;
|
||||
gps_eph_iterator->second.d_A_f1 = ((double)e->AF1)*A_F1_LSB;
|
||||
gps_eph_iterator->second.d_A_f2 = ((double)e->AF2)*A_F2_LSB;
|
||||
gps_eph_iterator->second.d_Crc = ((double)e->Crc)*C_RC_LSB;
|
||||
gps_eph_iterator->second.d_Delta_n = ((double)e->delta_n)*DELTA_N_LSB;
|
||||
gps_eph_iterator->second.d_M_0 = ((double)e->M0)*M_0_LSB;
|
||||
gps_eph_iterator->second.d_Cuc = ((double)e->Cuc)*C_UC_LSB;
|
||||
gps_eph_iterator->second.d_e_eccentricity = ((double)e->e)*E_LSB;
|
||||
gps_eph_iterator->second.d_Cus = ((double)e->Cus)*C_US_LSB;
|
||||
gps_eph_iterator->second.d_sqrt_A = ((double)e->A_sqrt)*SQRT_A_LSB;
|
||||
gps_eph_iterator->second.d_Toe = ((double)e->toe)*T_OE_LSB;
|
||||
gps_eph_iterator->second.d_TGD = static_cast<double>(e->tgd) * T_GD_LSB;
|
||||
gps_eph_iterator->second.d_Toc = static_cast<double>(e->toc) * T_OC_LSB;
|
||||
gps_eph_iterator->second.d_A_f0 = static_cast<double>(e->AF0) * A_F0_LSB;
|
||||
gps_eph_iterator->second.d_A_f1 = static_cast<double>(e->AF1) * A_F1_LSB;
|
||||
gps_eph_iterator->second.d_A_f2 = static_cast<double>(e->AF2) * A_F2_LSB;
|
||||
gps_eph_iterator->second.d_Crc = static_cast<double>(e->Crc) * C_RC_LSB;
|
||||
gps_eph_iterator->second.d_Delta_n = static_cast<double>(e->delta_n) * DELTA_N_LSB;
|
||||
gps_eph_iterator->second.d_M_0 = static_cast<double>(e->M0) * M_0_LSB;
|
||||
gps_eph_iterator->second.d_Cuc = static_cast<double>(e->Cuc) * C_UC_LSB;
|
||||
gps_eph_iterator->second.d_e_eccentricity = static_cast<double>(e->e) * E_LSB;
|
||||
gps_eph_iterator->second.d_Cus = static_cast<double>(e->Cus) * C_US_LSB;
|
||||
gps_eph_iterator->second.d_sqrt_A = static_cast<double>(e->A_sqrt) * SQRT_A_LSB;
|
||||
gps_eph_iterator->second.d_Toe = static_cast<double>(e->toe) * T_OE_LSB;
|
||||
//miss fit interval flag (1 bit)
|
||||
gps_eph_iterator->second.i_AODO = e->AODA * AODO_LSB;
|
||||
gps_eph_iterator->second.d_Cic = ((double)e->Cic)*C_IC_LSB;
|
||||
gps_eph_iterator->second.d_OMEGA0 = ((double)e->OMEGA_0)*OMEGA_0_LSB;
|
||||
gps_eph_iterator->second.d_Cis = ((double)e->Cis)*C_IS_LSB;
|
||||
gps_eph_iterator->second.d_i_0 = ((double)e->i0)*I_0_LSB;
|
||||
gps_eph_iterator->second.d_Crs = ((double)e->Crs)*C_RS_LSB;
|
||||
gps_eph_iterator->second.d_OMEGA = ((double)e->w)*OMEGA_LSB;
|
||||
gps_eph_iterator->second.d_OMEGA_DOT = (double)e->OMEGA_dot*OMEGA_DOT_LSB;
|
||||
gps_eph_iterator->second.d_IDOT = ((double)e->i_dot)*I_DOT_LSB;
|
||||
gps_eph_iterator->second.d_Cic = static_cast<double>(e->Cic) * C_IC_LSB;
|
||||
gps_eph_iterator->second.d_OMEGA0 = static_cast<double>(e->OMEGA_0) * OMEGA_0_LSB;
|
||||
gps_eph_iterator->second.d_Cis = static_cast<double>(e->Cis) * C_IS_LSB;
|
||||
gps_eph_iterator->second.d_i_0 = static_cast<double>(e->i0) * I_0_LSB;
|
||||
gps_eph_iterator->second.d_Crs = static_cast<double>(e->Crs) * C_RS_LSB;
|
||||
gps_eph_iterator->second.d_OMEGA = static_cast<double>(e->w) * OMEGA_LSB;
|
||||
gps_eph_iterator->second.d_OMEGA_DOT = static_cast<double>(e->OMEGA_dot) * OMEGA_DOT_LSB;
|
||||
gps_eph_iterator->second.d_IDOT = static_cast<double>(e->i_dot) * I_DOT_LSB;
|
||||
}
|
||||
}
|
||||
|
||||
@ -348,16 +348,16 @@ void gnss_sdr_supl_client::read_supl_data()
|
||||
}
|
||||
// fill the acquisition assistance structure
|
||||
gps_acq_iterator->second.i_satellite_PRN = e->prn;
|
||||
gps_acq_iterator->second.d_TOW = (double)assist.acq_time;
|
||||
gps_acq_iterator->second.d_Doppler0 = (double)e->doppler0;
|
||||
gps_acq_iterator->second.d_Doppler1 = (double)e->doppler1;
|
||||
gps_acq_iterator->second.dopplerUncertainty = (double)e->d_win;
|
||||
gps_acq_iterator->second.Code_Phase = (double)e->code_ph;
|
||||
gps_acq_iterator->second.Code_Phase_int = (double)e->code_ph_int;
|
||||
gps_acq_iterator->second.Code_Phase_window = (double)e->code_ph_win;
|
||||
gps_acq_iterator->second.Azimuth = (double)e->az;
|
||||
gps_acq_iterator->second.Elevation = (double)e->el;
|
||||
gps_acq_iterator->second.GPS_Bit_Number = (double)e->bit_num;
|
||||
gps_acq_iterator->second.d_TOW = static_cast<double>(assist.acq_time);
|
||||
gps_acq_iterator->second.d_Doppler0 = static_cast<double>(e->doppler0);
|
||||
gps_acq_iterator->second.d_Doppler1 = static_cast<double>(e->doppler1);
|
||||
gps_acq_iterator->second.dopplerUncertainty = static_cast<double>(e->d_win);
|
||||
gps_acq_iterator->second.Code_Phase = static_cast<double>(e->code_ph);
|
||||
gps_acq_iterator->second.Code_Phase_int = static_cast<double>(e->code_ph_int);
|
||||
gps_acq_iterator->second.Code_Phase_window = static_cast<double>(e->code_ph_win);
|
||||
gps_acq_iterator->second.Azimuth = static_cast<double>(e->az);
|
||||
gps_acq_iterator->second.Elevation = static_cast<double>(e->el);
|
||||
gps_acq_iterator->second.GPS_Bit_Number = static_cast<double>(e->bit_num);
|
||||
}
|
||||
}
|
||||
}
|
||||
|
@ -65,10 +65,10 @@ TEST(CodeGenerationTest, CodeGenGPSL1SampledTest)
|
||||
{
|
||||
signed int _prn = 1;
|
||||
unsigned int _chip_shift = 4;
|
||||
double _fs = 8000000;
|
||||
double _fs = 8000000.0;
|
||||
const signed int _codeFreqBasis = 1023000; //Hz
|
||||
const signed int _codeLength = 1023;
|
||||
int _samplesPerCode = round(_fs / (double)(_codeFreqBasis / _codeLength));
|
||||
int _samplesPerCode = round(_fs / static_cast<double>(_codeFreqBasis / _codeLength));
|
||||
std::complex<float>* _dest = new std::complex<float>[_samplesPerCode];
|
||||
|
||||
int iterations = 1000;
|
||||
@ -92,11 +92,11 @@ TEST(CodeGenerationTest, CodeGenGPSL1SampledTest)
|
||||
|
||||
TEST(CodeGenerationTest, ComplexConjugateTest)
|
||||
{
|
||||
double _fs = 8000000;
|
||||
double _f = 4000;
|
||||
double _fs = 8000000.0;
|
||||
double _f = 4000.0;
|
||||
const signed int _codeFreqBasis = 1023000; //Hz
|
||||
const signed int _codeLength = 1023;
|
||||
int _samplesPerCode = round(_fs / (double)(_codeFreqBasis / _codeLength));
|
||||
int _samplesPerCode = round(_fs / static_cast<double>(_codeFreqBasis / _codeLength));
|
||||
std::complex<float>* _dest = new std::complex<float>[_samplesPerCode];
|
||||
|
||||
int iterations = 1000;
|
||||
|
@ -42,10 +42,10 @@ TEST(ComplexCarrierTest, StandardComplexImplementation)
|
||||
// Dynamic allocation creates new usable space on the program STACK
|
||||
// (an area of RAM specifically allocated to the program)
|
||||
std::complex<float>* output = new std::complex<float>[FLAGS_size_carrier_test];
|
||||
const double _f = 2000;
|
||||
const double _fs = 2000000;
|
||||
const double phase_step = (double)((GPS_TWO_PI * _f) / _fs);
|
||||
double phase = 0;
|
||||
const double _f = 2000.0;
|
||||
const double _fs = 2000000.0;
|
||||
const double phase_step = static_cast<double>((GPS_TWO_PI * _f) / _fs);
|
||||
double phase = 0.0;
|
||||
|
||||
std::chrono::time_point<std::chrono::system_clock> start, end;
|
||||
start = std::chrono::system_clock::now();
|
||||
@ -82,10 +82,10 @@ TEST(ComplexCarrierTest, C11ComplexImplementation)
|
||||
{
|
||||
// declaration: load data onto the program data segment
|
||||
std::vector<std::complex<float>> output(FLAGS_size_carrier_test);
|
||||
const double _f = 2000;
|
||||
const double _fs = 2000000;
|
||||
const double phase_step = (double)((GPS_TWO_PI * _f) / _fs);
|
||||
double phase = 0;
|
||||
const double _f = 2000.0;
|
||||
const double _fs = 2000000.0;
|
||||
const double phase_step = static_cast<double>((GPS_TWO_PI * _f) / _fs);
|
||||
double phase = 0.0;
|
||||
|
||||
std::chrono::time_point<std::chrono::system_clock> start, end;
|
||||
start = std::chrono::system_clock::now();
|
||||
@ -116,12 +116,12 @@ TEST(ComplexCarrierTest, C11ComplexImplementation)
|
||||
TEST(ComplexCarrierTest, OwnComplexImplementation)
|
||||
{
|
||||
std::complex<float>* output = new std::complex<float>[FLAGS_size_carrier_test];
|
||||
double _f = 2000;
|
||||
double _fs = 2000000;
|
||||
double _f = 2000.0;
|
||||
double _fs = 2000000.0;
|
||||
std::chrono::time_point<std::chrono::system_clock> start, end;
|
||||
start = std::chrono::system_clock::now();
|
||||
|
||||
complex_exp_gen(output, _f, _fs, (unsigned int)FLAGS_size_carrier_test);
|
||||
complex_exp_gen(output, _f, _fs, static_cast<unsigned int>(FLAGS_size_carrier_test));
|
||||
|
||||
end = std::chrono::system_clock::now();
|
||||
std::chrono::duration<double> elapsed_seconds = end - start;
|
||||
|
@ -48,7 +48,7 @@ TEST(MagnitudeSquaredTest, StandardCComplexImplementation)
|
||||
std::chrono::time_point<std::chrono::system_clock> start, end;
|
||||
start = std::chrono::system_clock::now();
|
||||
|
||||
for(number = 0; number < (unsigned int)FLAGS_size_magnitude_test; number++)
|
||||
for(number = 0; number < static_cast<unsigned int>(FLAGS_size_magnitude_test); number++)
|
||||
{
|
||||
output[number] = (input[number].real() * input[number].real()) + (input[number].imag() * input[number].imag());
|
||||
}
|
||||
|
@ -285,7 +285,7 @@ TEST(GNSSBlockFactoryTest, InstantiateChannels)
|
||||
gr::msg_queue::sptr queue = gr::msg_queue::make(0);
|
||||
std::unique_ptr<GNSSBlockFactory> factory;
|
||||
std::unique_ptr<std::vector<std::unique_ptr<GNSSBlockInterface>>> channels = std::move(factory->GetChannels(configuration, queue));
|
||||
EXPECT_EQ((unsigned int) 2, channels->size());
|
||||
EXPECT_EQ(2U, channels->size());
|
||||
channels->erase(channels->begin(), channels->end());
|
||||
}
|
||||
|
||||
|
@ -379,7 +379,7 @@ void GalileoE1Pcps8msAmbiguousAcquisitionGSoC2013Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - (static_cast<double>(gnss_synchro.Acq_delay_samples) - 5) * 1023.0 / (static_cast<double>(fs_in)*1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -393,16 +393,16 @@ void GalileoE1Pcps8msAmbiguousAcquisitionGSoC2013Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -555,7 +555,7 @@ TEST_F(GalileoE1Pcps8msAmbiguousAcquisitionGSoC2013Test, ValidationOfResults)
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
|
||||
}
|
||||
|
@ -382,7 +382,7 @@ void GalileoE1PcpsAmbiguousAcquisitionGSoC2013Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - (static_cast<double>(gnss_synchro.Acq_delay_samples)- 5 ) * 1023.0 / static_cast<double>(fs_in*1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -396,18 +396,18 @@ void GalileoE1PcpsAmbiguousAcquisitionGSoC2013Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= (double)num_of_realizations;
|
||||
mse_doppler /= (double)num_of_realizations;
|
||||
mse_delay /= static_cast<double>(num_of_realizations);
|
||||
mse_doppler /= static_cast<double>(num_of_realizations);
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter-correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= (double)num_of_realizations;
|
||||
mean_acq_time_us /= static_cast<double>(num_of_realizations);
|
||||
|
||||
stop_queue();
|
||||
top_block->stop();
|
||||
@ -535,7 +535,7 @@ TEST_F(GalileoE1PcpsAmbiguousAcquisitionGSoC2013Test, ValidationOfResults)
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
}
|
||||
else if (i == 1)
|
||||
|
@ -258,7 +258,7 @@ TEST_F(GalileoE1PcpsAmbiguousAcquisitionTest, ValidationOfResults)
|
||||
std::cout << "Doppler: " << gnss_synchro.Acq_doppler_hz << std::endl;
|
||||
|
||||
double delay_error_samples = std::abs(expected_delay_samples - gnss_synchro.Acq_delay_samples);
|
||||
float delay_error_chips = (float)(delay_error_samples * 1023 / 4000000);
|
||||
float delay_error_chips = static_cast<float>(delay_error_samples * 1023 / 4000000);
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
EXPECT_LE(doppler_error_hz, 166) << "Doppler error exceeds the expected value: 166 Hz = 2/(3*integration period)";
|
||||
|
@ -381,7 +381,7 @@ void GalileoE1PcpsCccwsrAmbiguousAcquisitionTest::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -395,16 +395,16 @@ void GalileoE1PcpsCccwsrAmbiguousAcquisitionTest::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter-correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -542,7 +542,7 @@ TEST_F(GalileoE1PcpsCccwsrAmbiguousAcquisitionTest, ValidationOfResults)
|
||||
//EXPECT_EQ(2, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
}
|
||||
else if (i == 1)
|
||||
|
@ -494,7 +494,7 @@ void GalileoE1PcpsQuickSyncAmbiguousAcquisitionGSoC2014Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / ((double)fs_in * 1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -518,19 +518,19 @@ void GalileoE1PcpsQuickSyncAmbiguousAcquisitionGSoC2014Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter / num_of_realizations * 100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= (double)num_of_realizations;
|
||||
mse_doppler /= (double)num_of_realizations;
|
||||
mse_delay /= static_cast<double>(num_of_realizations);
|
||||
mse_doppler /= static_cast<double>(num_of_realizations);
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter - correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pmd = (double)miss_detection_counter / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pmd = static_cast<double>(miss_detection_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= (double)num_of_realizations;
|
||||
mean_acq_time_us /= static_cast<double>(num_of_realizations);
|
||||
|
||||
stop_queue();
|
||||
top_block->stop();
|
||||
@ -669,7 +669,7 @@ TEST_F(GalileoE1PcpsQuickSyncAmbiguousAcquisitionGSoC2014Test, ValidationOfResul
|
||||
if (i == 0)
|
||||
{
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
else if (i == 1)
|
||||
{
|
||||
@ -759,7 +759,7 @@ TEST_F(GalileoE1PcpsQuickSyncAmbiguousAcquisitionGSoC2014Test, ValidationOfResul
|
||||
if (i == 0)
|
||||
{
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
else if (i == 1)
|
||||
{
|
||||
|
@ -387,7 +387,7 @@ void GalileoE1PcpsTongAmbiguousAcquisitionGSoC2013Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -401,16 +401,16 @@ void GalileoE1PcpsTongAmbiguousAcquisitionGSoC2013Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -541,7 +541,7 @@ TEST_F(GalileoE1PcpsTongAmbiguousAcquisitionGSoC2013Test, ValidationOfResults)
|
||||
if (i == 0)
|
||||
{
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
else if (i == 1)
|
||||
{
|
||||
|
@ -205,7 +205,7 @@ void GalileoE5aPcpsAcquisitionGSoC2014GensourceTest::config_1()
|
||||
integration_time_ms = 1;
|
||||
fs_in = 32e6;
|
||||
|
||||
expected_delay_chips = round(14000*((double)10230000/(double)fs_in));
|
||||
expected_delay_chips = round(14000.0 * 10230000.0 / static_cast<double>(fs_in));
|
||||
expected_doppler_hz = 2800;
|
||||
expected_delay_sec = 94;
|
||||
CAF_window_hz = 0;
|
||||
@ -464,19 +464,19 @@ void GalileoE5aPcpsAcquisitionGSoC2014GensourceTest::process_message()
|
||||
switch (sat)
|
||||
{
|
||||
case 0:
|
||||
delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*10230.0/((double)fs_in*1e-3));
|
||||
delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 10230.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
break;
|
||||
case 1:
|
||||
delay_error_chips = std::abs((double)expected_delay_chips1 - (double)(gnss_synchro.Acq_delay_samples-5)*10230.0/((double)fs_in*1e-3));
|
||||
delay_error_chips = std::abs(static_cast<double>(expected_delay_chips1) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 10230.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
doppler_error_hz = std::abs(expected_doppler_hz1 - gnss_synchro.Acq_doppler_hz);
|
||||
break;
|
||||
case 2:
|
||||
delay_error_chips = std::abs((double)expected_delay_chips2 - (double)(gnss_synchro.Acq_delay_samples-5)*10230.0/((double)fs_in*1e-3));
|
||||
delay_error_chips = std::abs(static_cast<double>(expected_delay_chips2) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 10230.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
doppler_error_hz = std::abs(expected_doppler_hz2 - gnss_synchro.Acq_doppler_hz);
|
||||
break;
|
||||
case 3:
|
||||
delay_error_chips = std::abs((double)expected_delay_chips3 - (double)(gnss_synchro.Acq_delay_samples-5)*10230.0/((double)fs_in*1e-3));
|
||||
delay_error_chips = std::abs(static_cast<double>(expected_delay_chips3) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 10230.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
doppler_error_hz = std::abs(expected_doppler_hz3 - gnss_synchro.Acq_doppler_hz);
|
||||
break;
|
||||
default: // case 3
|
||||
@ -502,16 +502,16 @@ void GalileoE5aPcpsAcquisitionGSoC2014GensourceTest::process_message()
|
||||
realization_counter++;
|
||||
|
||||
//std::cout << correct_estimation_counter << "correct estimation counter" << std::endl;
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter / num_of_realizations * 100)) << "% \r" << std::flush;
|
||||
//std::cout << message << "message" <<std::endl;
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter - correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -654,7 +654,7 @@ TEST_F(GalileoE5aPcpsAcquisitionGSoC2014GensourceTest, ValidationOfSIM)
|
||||
{
|
||||
// std::cout << gnss_synchro.Acq_delay_samples << "acq delay" <<std::endl;
|
||||
// std::cout << gnss_synchro.Acq_doppler_hz << "acq doppler" <<std::endl;
|
||||
EXPECT_EQ((unsigned int) 1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
}
|
||||
else if (i == 1)
|
||||
|
@ -383,7 +383,7 @@ void GpsL1CaPcpsAcquisitionGSoC2013Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) *1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -397,16 +397,16 @@ void GpsL1CaPcpsAcquisitionGSoC2013Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter - correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -537,7 +537,7 @@ TEST_F(GpsL1CaPcpsAcquisitionGSoC2013Test, ValidationOfResults)
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int) 1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
|
||||
}
|
||||
|
@ -254,7 +254,7 @@ TEST_F(GpsL1CaPcpsAcquisitionTest, ValidationOfResults)
|
||||
ASSERT_EQ(1, msg_rx->rx_message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
|
||||
double delay_error_samples = std::abs(expected_delay_samples - gnss_synchro.Acq_delay_samples);
|
||||
float delay_error_chips = (float)(delay_error_samples * 1023 / 4000);
|
||||
float delay_error_chips = static_cast<float>(delay_error_samples * 1023 / 4000);
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
EXPECT_LE(doppler_error_hz, 666) << "Doppler error exceeds the expected value: 666 Hz = 2/(3*integration period)";
|
||||
|
@ -134,7 +134,7 @@ void thread_acquisition_send_rx_samples(gr::top_block_sptr top_block,
|
||||
|
||||
int transfer_size;
|
||||
int num_transferred_samples = 0;
|
||||
while (num_transferred_samples < (int) (file_length / FLOAT_SIZE))
|
||||
while (num_transferred_samples < static_cast<int>((file_length / FLOAT_SIZE)))
|
||||
{
|
||||
if (((file_length / FLOAT_SIZE) - num_transferred_samples) > DMA_ACQ_TRANSFER_SIZE)
|
||||
{
|
||||
@ -152,7 +152,7 @@ void thread_acquisition_send_rx_samples(gr::top_block_sptr top_block,
|
||||
fread(buffer_float, FLOAT_SIZE, 1, rx_signal_file);
|
||||
|
||||
// specify (float) (int) for a quantization maximizing the dynamic range
|
||||
buffer_DMA[t] = (signed char) ((pointer_float[0] * (RX_SIGNAL_MAX_VALUE - 1)) / max);
|
||||
buffer_DMA[t] = static_cast<signed char>((pointer_float[0] * (RX_SIGNAL_MAX_VALUE - 1) / max));
|
||||
}
|
||||
|
||||
//send_acquisition_gps_input_samples(buffer_DMA, transfer_size, dma_descr);
|
||||
@ -376,7 +376,7 @@ TEST_F(GpsL1CaPcpsAcquisitionTestFpga, ValidationOfResults)
|
||||
ASSERT_EQ(1, msg_rx->rx_message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
|
||||
double delay_error_samples = std::abs(expected_delay_samples - gnss_synchro.Acq_delay_samples);
|
||||
float delay_error_chips = (float) (delay_error_samples * 1023 / 4000);
|
||||
float delay_error_chips = static_cast<float>(delay_error_samples * 1023 / 4000);
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
EXPECT_LE(doppler_error_hz, 666) << "Doppler error exceeds the expected value: 666 Hz = 2/(3*integration period)";
|
||||
|
@ -322,7 +322,7 @@ void GpsL1CaPcpsMultithreadAcquisitionGSoC2013Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -336,16 +336,16 @@ void GpsL1CaPcpsMultithreadAcquisitionGSoC2013Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -471,7 +471,7 @@ TEST_F(GpsL1CaPcpsMultithreadAcquisitionGSoC2013Test, ValidationOfResults)
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
|
||||
}
|
||||
|
@ -379,7 +379,7 @@ void GpsL1CaPcpsOpenClAcquisitionGSoC2013Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples- 5 )*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -393,16 +393,16 @@ void GpsL1CaPcpsOpenClAcquisitionGSoC2013Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -528,7 +528,7 @@ TEST_F(GpsL1CaPcpsOpenClAcquisitionGSoC2013Test, ValidationOfResults)
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ((1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
|
||||
}
|
||||
|
@ -490,7 +490,7 @@ void GpsL1CaPcpsQuickSyncAcquisitionGSoC2014Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples - 5) * 1023.0/ ((double)fs_in * 1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -508,17 +508,17 @@ void GpsL1CaPcpsQuickSyncAcquisitionGSoC2014Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter / num_of_realizations * 100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pmd = (double)miss_detection_counter / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pmd = static_cast<double>(miss_detection_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -651,7 +651,7 @@ TEST_F(GpsL1CaPcpsQuickSyncAcquisitionGSoC2014Test, ValidationOfResults)
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter)
|
||||
EXPECT_EQ(1U, correct_estimation_counter)
|
||||
<< "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
}
|
||||
@ -745,7 +745,7 @@ TEST_F(GpsL1CaPcpsQuickSyncAcquisitionGSoC2014Test, ValidationOfResultsWithNoise
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
|
||||
}
|
||||
|
@ -378,7 +378,7 @@ void GpsL1CaPcpsTongAcquisitionGSoC2013Test::process_message()
|
||||
detection_counter++;
|
||||
|
||||
// The term -5 is here to correct the additional delay introduced by the FIR filter
|
||||
double delay_error_chips = std::abs((double)expected_delay_chips - (double)(gnss_synchro.Acq_delay_samples-5)*1023.0/((double)fs_in*1e-3));
|
||||
double delay_error_chips = std::abs(static_cast<double>(expected_delay_chips) - static_cast<double>(gnss_synchro.Acq_delay_samples - 5) * 1023.0 / (static_cast<double>(fs_in) * 1e-3));
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
mse_delay += std::pow(delay_error_chips, 2);
|
||||
@ -392,16 +392,16 @@ void GpsL1CaPcpsTongAcquisitionGSoC2013Test::process_message()
|
||||
|
||||
realization_counter++;
|
||||
|
||||
std::cout << "Progress: " << round((float)realization_counter/num_of_realizations*100) << "% \r" << std::flush;
|
||||
std::cout << "Progress: " << round(static_cast<float>(realization_counter) / static_cast<float>(num_of_realizations) * 100.0) << "% \r" << std::flush;
|
||||
|
||||
if (realization_counter == num_of_realizations)
|
||||
{
|
||||
mse_delay /= num_of_realizations;
|
||||
mse_doppler /= num_of_realizations;
|
||||
|
||||
Pd = (double)correct_estimation_counter / (double)num_of_realizations;
|
||||
Pfa_a = (double)detection_counter / (double)num_of_realizations;
|
||||
Pfa_p = (double)(detection_counter-correct_estimation_counter) / (double)num_of_realizations;
|
||||
Pd = static_cast<double>(correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_a = static_cast<double>(detection_counter) / static_cast<double>(num_of_realizations);
|
||||
Pfa_p = static_cast<double>(detection_counter - correct_estimation_counter) / static_cast<double>(num_of_realizations);
|
||||
|
||||
mean_acq_time_us /= num_of_realizations;
|
||||
|
||||
@ -534,7 +534,7 @@ TEST_F(GpsL1CaPcpsTongAcquisitionGSoC2013Test, ValidationOfResults)
|
||||
EXPECT_EQ(1, message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
if (message == 1)
|
||||
{
|
||||
EXPECT_EQ((unsigned int)1, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
EXPECT_EQ(1U, correct_estimation_counter) << "Acquisition failure. Incorrect parameters estimation.";
|
||||
}
|
||||
}
|
||||
else if (i == 1)
|
||||
|
@ -146,7 +146,7 @@ void GpsL2MPcpsAcquisitionTest::init()
|
||||
gnss_synchro.PRN = 7;
|
||||
|
||||
sampling_freqeuncy_hz = 5000000;
|
||||
nsamples = round((double)sampling_freqeuncy_hz*GPS_L2_M_PERIOD)*2;
|
||||
nsamples = round(static_cast<double>(sampling_freqeuncy_hz) * GPS_L2_M_PERIOD) * 2;
|
||||
config->set_property("GNSS-SDR.internal_fs_hz", std::to_string(sampling_freqeuncy_hz));
|
||||
config->set_property("Acquisition.item_type", "gr_complex");
|
||||
config->set_property("Acquisition.if", "0");
|
||||
@ -273,7 +273,7 @@ TEST_F(GpsL2MPcpsAcquisitionTest, ValidationOfResults)
|
||||
ASSERT_EQ(1, msg_rx->rx_message) << "Acquisition failure. Expected message: 1=ACQ SUCCESS.";
|
||||
|
||||
double delay_error_samples = std::abs(expected_delay_samples - gnss_synchro.Acq_delay_samples);
|
||||
float delay_error_chips = (float)(delay_error_samples * 1023 / 4000);
|
||||
float delay_error_chips = static_cast<float>(delay_error_samples * 1023 / 4000);
|
||||
double doppler_error_hz = std::abs(expected_doppler_hz - gnss_synchro.Acq_doppler_hz);
|
||||
|
||||
EXPECT_LE(doppler_error_hz, 200) << "Doppler error exceeds the expected value: 666 Hz = 2/(3*integration period)";
|
||||
|
@ -461,7 +461,7 @@ TEST_F(GpsL1CATelemetryDecoderTest, ValidationOfResults)
|
||||
epoch_counter = 0;
|
||||
while(tlm_dump.read_binary_obs())
|
||||
{
|
||||
tlm_timestamp_s(epoch_counter) = (double)tlm_dump.Tracking_sample_counter/(double)baseband_sampling_freq;
|
||||
tlm_timestamp_s(epoch_counter) = static_cast<double>(tlm_dump.Tracking_sample_counter) / static_cast<double>(baseband_sampling_freq);
|
||||
tlm_TOW_at_Preamble(epoch_counter) = tlm_dump.d_TOW_at_Preamble;
|
||||
tlm_tow_s(epoch_counter) = tlm_dump.TOW_at_current_symbol;
|
||||
epoch_counter++;
|
||||
|
Loading…
Reference in New Issue
Block a user