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mirror of https://github.com/gnss-sdr/gnss-sdr synced 2024-12-15 20:50:33 +00:00

Apply project's coding style

This commit is contained in:
Carles Fernandez 2018-01-17 19:02:52 +01:00
parent 1b5a3b6fa4
commit 7e97d00a4f

View File

@ -65,49 +65,49 @@ hybrid_observables_cc::hybrid_observables_cc(unsigned int nchannels, bool dump,
T_rx_s = 0.0; T_rx_s = 0.0;
T_rx_step_s = 1e-3; // todo: move to gnss-sdr config T_rx_step_s = 1e-3; // todo: move to gnss-sdr config
for (unsigned int i = 0; i < d_nchannels; i++) for (unsigned int i = 0; i < d_nchannels; i++)
{ {
d_gnss_synchro_history_queue.push_back(std::deque<Gnss_Synchro>()); d_gnss_synchro_history_queue.push_back(std::deque<Gnss_Synchro>());
} }
// ############# ENABLE DATA FILE LOG ################# // ############# ENABLE DATA FILE LOG #################
if (d_dump == true) if (d_dump == true)
{
if (d_dump_file.is_open() == false)
{ {
try if (d_dump_file.is_open() == false)
{ {
d_dump_file.exceptions (std::ifstream::failbit | std::ifstream::badbit ); try
d_dump_file.open(d_dump_filename.c_str(), std::ios::out | std::ios::binary); {
LOG(INFO) << "Observables dump enabled Log file: " << d_dump_filename.c_str(); d_dump_file.exceptions (std::ifstream::failbit | std::ifstream::badbit );
} d_dump_file.open(d_dump_filename.c_str(), std::ios::out | std::ios::binary);
catch (const std::ifstream::failure & e) LOG(INFO) << "Observables dump enabled Log file: " << d_dump_filename.c_str();
{ }
LOG(WARNING) << "Exception opening observables dump file " << e.what(); catch (const std::ifstream::failure & e)
} {
LOG(WARNING) << "Exception opening observables dump file " << e.what();
}
}
} }
}
} }
hybrid_observables_cc::~hybrid_observables_cc() hybrid_observables_cc::~hybrid_observables_cc()
{ {
if (d_dump_file.is_open() == true) if (d_dump_file.is_open() == true)
{
try
{ {
d_dump_file.close(); try
{
d_dump_file.close();
}
catch(const std::exception & ex)
{
LOG(WARNING) << "Exception in destructor closing the dump file " << ex.what();
}
} }
catch(const std::exception & ex)
{
LOG(WARNING) << "Exception in destructor closing the dump file " << ex.what();
}
}
if(d_dump == true) if(d_dump == true)
{ {
std::cout << "Writing observables .mat files ..."; std::cout << "Writing observables .mat files ...";
hybrid_observables_cc::save_matfile(); hybrid_observables_cc::save_matfile();
std::cout << " done." << std::endl; std::cout << " done." << std::endl;
} }
} }
@ -121,25 +121,25 @@ int hybrid_observables_cc::save_matfile()
dump_file.exceptions(std::ifstream::failbit | std::ifstream::badbit); dump_file.exceptions(std::ifstream::failbit | std::ifstream::badbit);
try try
{ {
dump_file.open(d_dump_filename.c_str(), std::ios::binary | std::ios::ate); dump_file.open(d_dump_filename.c_str(), std::ios::binary | std::ios::ate);
} }
catch(const std::ifstream::failure &e) catch(const std::ifstream::failure &e)
{ {
std::cerr << "Problem opening dump file:" << e.what() << std::endl; std::cerr << "Problem opening dump file:" << e.what() << std::endl;
return 1; return 1;
} }
// count number of epochs and rewind // count number of epochs and rewind
long int num_epoch = 0; long int num_epoch = 0;
if (dump_file.is_open()) if (dump_file.is_open())
{ {
size = dump_file.tellg(); size = dump_file.tellg();
num_epoch = static_cast<long int>(size) / static_cast<long int>(epoch_size_bytes); num_epoch = static_cast<long int>(size) / static_cast<long int>(epoch_size_bytes);
dump_file.seekg(0, std::ios::beg); dump_file.seekg(0, std::ios::beg);
} }
else else
{ {
return 1; return 1;
} }
double ** RX_time = new double * [d_nchannels]; double ** RX_time = new double * [d_nchannels];
double ** TOW_at_current_symbol_s = new double * [d_nchannels]; double ** TOW_at_current_symbol_s = new double * [d_nchannels];
double ** Carrier_Doppler_hz = new double * [d_nchannels]; double ** Carrier_Doppler_hz = new double * [d_nchannels];
@ -149,58 +149,58 @@ int hybrid_observables_cc::save_matfile()
double ** Flag_valid_pseudorange = new double * [d_nchannels]; double ** Flag_valid_pseudorange = new double * [d_nchannels];
for(unsigned int i = 0; i < d_nchannels; i++) for(unsigned int i = 0; i < d_nchannels; i++)
{ {
RX_time[i] = new double [num_epoch]; RX_time[i] = new double [num_epoch];
TOW_at_current_symbol_s[i] = new double[num_epoch]; TOW_at_current_symbol_s[i] = new double[num_epoch];
Carrier_Doppler_hz[i] = new double[num_epoch]; Carrier_Doppler_hz[i] = new double[num_epoch];
Carrier_phase_cycles[i] = new double[num_epoch]; Carrier_phase_cycles[i] = new double[num_epoch];
Pseudorange_m[i] = new double[num_epoch]; Pseudorange_m[i] = new double[num_epoch];
PRN[i] = new double[num_epoch]; PRN[i] = new double[num_epoch];
Flag_valid_pseudorange[i] = new double[num_epoch]; Flag_valid_pseudorange[i] = new double[num_epoch];
} }
try try
{ {
if (dump_file.is_open()) if (dump_file.is_open())
{
for(long int i = 0; i < num_epoch; i++)
{
for(unsigned int chan = 0; chan < d_nchannels; chan++)
{ {
dump_file.read(reinterpret_cast<char *>(&RX_time[chan][i]), sizeof(double)); for(long int i = 0; i < num_epoch; i++)
dump_file.read(reinterpret_cast<char *>(&TOW_at_current_symbol_s[chan][i]), sizeof(double)); {
dump_file.read(reinterpret_cast<char *>(&Carrier_Doppler_hz[chan][i]), sizeof(double)); for(unsigned int chan = 0; chan < d_nchannels; chan++)
dump_file.read(reinterpret_cast<char *>(&Carrier_phase_cycles[chan][i]), sizeof(double)); {
dump_file.read(reinterpret_cast<char *>(&Pseudorange_m[chan][i]), sizeof(double)); dump_file.read(reinterpret_cast<char *>(&RX_time[chan][i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&PRN[chan][i]), sizeof(double)); dump_file.read(reinterpret_cast<char *>(&TOW_at_current_symbol_s[chan][i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&Flag_valid_pseudorange[chan][i]), sizeof(double)); dump_file.read(reinterpret_cast<char *>(&Carrier_Doppler_hz[chan][i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&Carrier_phase_cycles[chan][i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&Pseudorange_m[chan][i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&PRN[chan][i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&Flag_valid_pseudorange[chan][i]), sizeof(double));
}
}
} }
} dump_file.close();
}
dump_file.close();
} }
catch (const std::ifstream::failure &e) catch (const std::ifstream::failure &e)
{ {
std::cerr << "Problem reading dump file:" << e.what() << std::endl; std::cerr << "Problem reading dump file:" << e.what() << std::endl;
for(unsigned int i = 0; i < d_nchannels; i++) for(unsigned int i = 0; i < d_nchannels; i++)
{ {
delete[] RX_time[i]; delete[] RX_time[i];
delete[] TOW_at_current_symbol_s[i]; delete[] TOW_at_current_symbol_s[i];
delete[] Carrier_Doppler_hz[i]; delete[] Carrier_Doppler_hz[i];
delete[] Carrier_phase_cycles[i]; delete[] Carrier_phase_cycles[i];
delete[] Pseudorange_m[i]; delete[] Pseudorange_m[i];
delete[] PRN[i]; delete[] PRN[i];
delete[] Flag_valid_pseudorange[i]; delete[] Flag_valid_pseudorange[i];
} }
delete[] RX_time; delete[] RX_time;
delete[] TOW_at_current_symbol_s; delete[] TOW_at_current_symbol_s;
delete[] Carrier_Doppler_hz; delete[] Carrier_Doppler_hz;
delete[] Carrier_phase_cycles; delete[] Carrier_phase_cycles;
delete[] Pseudorange_m; delete[] Pseudorange_m;
delete[] PRN; delete[] PRN;
delete[] Flag_valid_pseudorange; delete[] Flag_valid_pseudorange;
return 1; return 1;
} }
double * RX_time_aux = new double [d_nchannels * num_epoch]; double * RX_time_aux = new double [d_nchannels * num_epoch];
@ -212,19 +212,19 @@ int hybrid_observables_cc::save_matfile()
double * Flag_valid_pseudorange_aux = new double[d_nchannels * num_epoch]; double * Flag_valid_pseudorange_aux = new double[d_nchannels * num_epoch];
unsigned int k = 0; unsigned int k = 0;
for(long int j = 0; j < num_epoch; j++ ) for(long int j = 0; j < num_epoch; j++ )
{
for(unsigned int i = 0; i < d_nchannels; i++ )
{ {
RX_time_aux[k] = RX_time[i][j]; for(unsigned int i = 0; i < d_nchannels; i++ )
TOW_at_current_symbol_s_aux[k] = TOW_at_current_symbol_s[i][j]; {
Carrier_Doppler_hz_aux[k] = Carrier_Doppler_hz[i][j]; RX_time_aux[k] = RX_time[i][j];
Carrier_phase_cycles_aux[k] = Carrier_phase_cycles[i][j]; TOW_at_current_symbol_s_aux[k] = TOW_at_current_symbol_s[i][j];
Pseudorange_m_aux[k] = Pseudorange_m[i][j]; Carrier_Doppler_hz_aux[k] = Carrier_Doppler_hz[i][j];
PRN_aux[k] = PRN[i][j]; Carrier_phase_cycles_aux[k] = Carrier_phase_cycles[i][j];
Flag_valid_pseudorange_aux[k] = Flag_valid_pseudorange[i][j]; Pseudorange_m_aux[k] = Pseudorange_m[i][j];
k++; PRN_aux[k] = PRN[i][j];
Flag_valid_pseudorange_aux[k] = Flag_valid_pseudorange[i][j];
k++;
}
} }
}
// WRITE MAT FILE // WRITE MAT FILE
mat_t *matfp; mat_t *matfp;
@ -234,49 +234,49 @@ int hybrid_observables_cc::save_matfile()
filename.append(".mat"); filename.append(".mat");
matfp = Mat_CreateVer(filename.c_str(), NULL, MAT_FT_MAT73); matfp = Mat_CreateVer(filename.c_str(), NULL, MAT_FT_MAT73);
if(reinterpret_cast<long*>(matfp) != NULL) if(reinterpret_cast<long*>(matfp) != NULL)
{ {
size_t dims[2] = {static_cast<size_t>(d_nchannels), static_cast<size_t>(num_epoch)}; size_t dims[2] = {static_cast<size_t>(d_nchannels), static_cast<size_t>(num_epoch)};
matvar = Mat_VarCreate("RX_time", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, RX_time_aux, MAT_F_DONT_COPY_DATA); matvar = Mat_VarCreate("RX_time", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, RX_time_aux, MAT_F_DONT_COPY_DATA);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar); Mat_VarFree(matvar);
matvar = Mat_VarCreate("TOW_at_current_symbol_s", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, TOW_at_current_symbol_s_aux, MAT_F_DONT_COPY_DATA); matvar = Mat_VarCreate("TOW_at_current_symbol_s", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, TOW_at_current_symbol_s_aux, MAT_F_DONT_COPY_DATA);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar); Mat_VarFree(matvar);
matvar = Mat_VarCreate("Carrier_Doppler_hz", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Carrier_Doppler_hz_aux, MAT_F_DONT_COPY_DATA); matvar = Mat_VarCreate("Carrier_Doppler_hz", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Carrier_Doppler_hz_aux, MAT_F_DONT_COPY_DATA);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar); Mat_VarFree(matvar);
matvar = Mat_VarCreate("Carrier_phase_cycles", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Carrier_phase_cycles_aux, MAT_F_DONT_COPY_DATA); matvar = Mat_VarCreate("Carrier_phase_cycles", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Carrier_phase_cycles_aux, MAT_F_DONT_COPY_DATA);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar); Mat_VarFree(matvar);
matvar = Mat_VarCreate("Pseudorange_m", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Pseudorange_m_aux, MAT_F_DONT_COPY_DATA); matvar = Mat_VarCreate("Pseudorange_m", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Pseudorange_m_aux, MAT_F_DONT_COPY_DATA);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar); Mat_VarFree(matvar);
matvar = Mat_VarCreate("PRN", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, PRN_aux, MAT_F_DONT_COPY_DATA); matvar = Mat_VarCreate("PRN", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, PRN_aux, MAT_F_DONT_COPY_DATA);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar); Mat_VarFree(matvar);
matvar = Mat_VarCreate("Flag_valid_pseudorange", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Flag_valid_pseudorange_aux, MAT_F_DONT_COPY_DATA); matvar = Mat_VarCreate("Flag_valid_pseudorange", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, Flag_valid_pseudorange_aux, MAT_F_DONT_COPY_DATA);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar); Mat_VarFree(matvar);
} }
Mat_Close(matfp); Mat_Close(matfp);
for(unsigned int i = 0; i < d_nchannels; i++) for(unsigned int i = 0; i < d_nchannels; i++)
{ {
delete[] RX_time[i]; delete[] RX_time[i];
delete[] TOW_at_current_symbol_s[i]; delete[] TOW_at_current_symbol_s[i];
delete[] Carrier_Doppler_hz[i]; delete[] Carrier_Doppler_hz[i];
delete[] Carrier_phase_cycles[i]; delete[] Carrier_phase_cycles[i];
delete[] Pseudorange_m[i]; delete[] Pseudorange_m[i];
delete[] PRN[i]; delete[] PRN[i];
delete[] Flag_valid_pseudorange[i]; delete[] Flag_valid_pseudorange[i];
} }
delete[] RX_time; delete[] RX_time;
delete[] TOW_at_current_symbol_s; delete[] TOW_at_current_symbol_s;
delete[] Carrier_Doppler_hz; delete[] Carrier_Doppler_hz;
@ -325,30 +325,32 @@ bool Hybrid_valueCompare_gnss_synchro_d_TOW(const Gnss_Synchro& a, double b)
return (a.TOW_at_current_symbol_s) < (b); return (a.TOW_at_current_symbol_s) < (b);
} }
void hybrid_observables_cc::forecast (int noutput_items __attribute__((unused)), gr_vector_int &ninput_items_required) void hybrid_observables_cc::forecast (int noutput_items __attribute__((unused)), gr_vector_int &ninput_items_required)
{ {
bool zero_samples=true; bool zero_samples = true;
for(unsigned int i = 0; i < d_nchannels; i++) for(unsigned int i = 0; i < d_nchannels; i++)
{
int items=detail()->input(i)->items_available();
if (items>0) zero_samples=false;
ninput_items_required[i] = items; //set the required available samples in each call
}
if (zero_samples==true)
{
for(unsigned int i = 0; i < d_nchannels; i++)
{ {
ninput_items_required[i] = 1; //set the required available samples in each call int items=detail()->input(i)->items_available();
if (items>0) zero_samples = false;
ninput_items_required[i] = items; // set the required available samples in each call
}
if (zero_samples == true)
{
for(unsigned int i = 0; i < d_nchannels; i++)
{
ninput_items_required[i] = 1; // set the required available samples in each call
}
} }
}
} }
int hybrid_observables_cc::general_work (int noutput_items , int hybrid_observables_cc::general_work (int noutput_items ,
gr_vector_int &ninput_items, gr_vector_int &ninput_items,
gr_vector_const_void_star &input_items, gr_vector_const_void_star &input_items,
gr_vector_void_star &output_items) gr_vector_void_star &output_items)
{ {
const Gnss_Synchro **in = reinterpret_cast<const Gnss_Synchro **>(&input_items[0]); // Get the input buffer pointer const Gnss_Synchro **in = reinterpret_cast<const Gnss_Synchro **>(&input_items[0]); // Get the input buffer pointer
Gnss_Synchro **out = reinterpret_cast<Gnss_Synchro **>(&output_items[0]); // Get the output buffer pointer Gnss_Synchro **out = reinterpret_cast<Gnss_Synchro **>(&output_items[0]); // Get the output buffer pointer
@ -359,231 +361,231 @@ int hybrid_observables_cc::general_work (int noutput_items ,
Gnss_Synchro current_gnss_synchro[d_nchannels]; Gnss_Synchro current_gnss_synchro[d_nchannels];
Gnss_Synchro aux = Gnss_Synchro(); Gnss_Synchro aux = Gnss_Synchro();
for(unsigned int i = 0; i < d_nchannels; i++) for(unsigned int i = 0; i < d_nchannels; i++)
{ {
current_gnss_synchro[i] = aux; current_gnss_synchro[i] = aux;
} }
/* /*
* 1. Read the GNSS SYNCHRO objects from available channels. * 1. Read the GNSS SYNCHRO objects from available channels.
* Multi-rate GNURADIO Block. Read how many input items are avaliable in each channel * Multi-rate GNURADIO Block. Read how many input items are avaliable in each channel
* Record all synchronization data into queues * Record all synchronization data into queues
*/ */
for (unsigned int i = 0; i < d_nchannels; i++) for (unsigned int i = 0; i < d_nchannels; i++)
{
n_consume[i] = ninput_items[i];// full throttle
for (int j = 0; j < n_consume[i]; j++)
{ {
d_gnss_synchro_history_queue[i].push_back(in[i][j]); n_consume[i] = ninput_items[i]; // full throttle
for (int j = 0; j < n_consume[i]; j++)
{
d_gnss_synchro_history_queue[i].push_back(in[i][j]);
}
} }
}
bool channel_history_ok; bool channel_history_ok;
do do
{
channel_history_ok = true;
for (unsigned int i = 0; i < d_nchannels; i++)
{ {
if (d_gnss_synchro_history_queue[i].size() < history_deep) channel_history_ok = true;
{
channel_history_ok = false;
}
}
if (channel_history_ok == true)
{
std::map<int,Gnss_Synchro>::const_iterator gnss_synchro_map_iter;
std::deque<Gnss_Synchro>::const_iterator gnss_synchro_deque_iter;
// 1. If the RX time is not set, set the Rx time
if (T_rx_s == 0)
{
// 0. Read a gnss_synchro snapshot from the queue and store it in a map
std::map<int,Gnss_Synchro> gnss_synchro_map;
for (unsigned int i = 0; i < d_nchannels; i++)
{
gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(d_gnss_synchro_history_queue[i].front().Channel_ID,
d_gnss_synchro_history_queue[i].front()));
}
gnss_synchro_map_iter = min_element(gnss_synchro_map.cbegin(),
gnss_synchro_map.cend(),
Hybrid_pairCompare_gnss_synchro_sample_counter);
T_rx_s = static_cast<double>(gnss_synchro_map_iter->second.Tracking_sample_counter) / static_cast<double>(gnss_synchro_map_iter->second.fs);
T_rx_s = floor(T_rx_s * 1000.0) / 1000.0; // truncate to ms
T_rx_s += past_history_s; // increase T_rx to have a minimum past history to interpolate
}
// 2. Realign RX time in all valid channels
std::map<int,Gnss_Synchro> realigned_gnss_synchro_map; // container for the aligned set of observables for the selected T_rx
std::map<int,Gnss_Synchro> adjacent_gnss_synchro_map; // container for the previous observable values to interpolate
// shift channels history to match the reference TOW
for (unsigned int i = 0; i < d_nchannels; i++) for (unsigned int i = 0; i < d_nchannels; i++)
{
gnss_synchro_deque_iter = std::lower_bound(d_gnss_synchro_history_queue[i].cbegin(),
d_gnss_synchro_history_queue[i].cend(),
T_rx_s,
Hybrid_valueCompare_gnss_synchro_receiver_time);
if (gnss_synchro_deque_iter != d_gnss_synchro_history_queue[i].cend())
{ {
if (gnss_synchro_deque_iter->Flag_valid_word == true) if (d_gnss_synchro_history_queue[i].size() < history_deep)
{
double T_rx_channel = static_cast<double>(gnss_synchro_deque_iter->Tracking_sample_counter) / static_cast<double>(gnss_synchro_deque_iter->fs);
double delta_T_rx_s = T_rx_channel - T_rx_s;
// check that T_rx difference is less than a threshold (the correlation interval)
if (delta_T_rx_s * 1000.0 < static_cast<double>(gnss_synchro_deque_iter->correlation_length_ms))
{ {
// record the word structure in a map for pseudorange computation channel_history_ok = false;
// save the previous observable }
int distance = std::distance(d_gnss_synchro_history_queue[i].cbegin(), gnss_synchro_deque_iter); }
if (distance > 0) if (channel_history_ok == true)
{ {
if (d_gnss_synchro_history_queue[i].at(distance - 1).Flag_valid_word) std::map<int,Gnss_Synchro>::const_iterator gnss_synchro_map_iter;
std::deque<Gnss_Synchro>::const_iterator gnss_synchro_deque_iter;
// 1. If the RX time is not set, set the Rx time
if (T_rx_s == 0)
{
// 0. Read a gnss_synchro snapshot from the queue and store it in a map
std::map<int,Gnss_Synchro> gnss_synchro_map;
for (unsigned int i = 0; i < d_nchannels; i++)
{ {
double T_rx_channel_prev = static_cast<double>(d_gnss_synchro_history_queue[i].at(distance - 1).Tracking_sample_counter) / static_cast<double>(gnss_synchro_deque_iter->fs); gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(d_gnss_synchro_history_queue[i].front().Channel_ID,
double delta_T_rx_s_prev = T_rx_channel_prev - T_rx_s; d_gnss_synchro_history_queue[i].front()));
if (fabs(delta_T_rx_s_prev) < fabs(delta_T_rx_s)) }
gnss_synchro_map_iter = min_element(gnss_synchro_map.cbegin(),
gnss_synchro_map.cend(),
Hybrid_pairCompare_gnss_synchro_sample_counter);
T_rx_s = static_cast<double>(gnss_synchro_map_iter->second.Tracking_sample_counter) / static_cast<double>(gnss_synchro_map_iter->second.fs);
T_rx_s = floor(T_rx_s * 1000.0) / 1000.0; // truncate to ms
T_rx_s += past_history_s; // increase T_rx to have a minimum past history to interpolate
}
// 2. Realign RX time in all valid channels
std::map<int,Gnss_Synchro> realigned_gnss_synchro_map; // container for the aligned set of observables for the selected T_rx
std::map<int,Gnss_Synchro> adjacent_gnss_synchro_map; // container for the previous observable values to interpolate
// shift channels history to match the reference TOW
for (unsigned int i = 0; i < d_nchannels; i++)
{
gnss_synchro_deque_iter = std::lower_bound(d_gnss_synchro_history_queue[i].cbegin(),
d_gnss_synchro_history_queue[i].cend(),
T_rx_s,
Hybrid_valueCompare_gnss_synchro_receiver_time);
if (gnss_synchro_deque_iter != d_gnss_synchro_history_queue[i].cend())
{
if (gnss_synchro_deque_iter->Flag_valid_word == true)
{
double T_rx_channel = static_cast<double>(gnss_synchro_deque_iter->Tracking_sample_counter) / static_cast<double>(gnss_synchro_deque_iter->fs);
double delta_T_rx_s = T_rx_channel - T_rx_s;
// check that T_rx difference is less than a threshold (the correlation interval)
if (delta_T_rx_s * 1000.0 < static_cast<double>(gnss_synchro_deque_iter->correlation_length_ms))
{
// record the word structure in a map for pseudorange computation
// save the previous observable
int distance = std::distance(d_gnss_synchro_history_queue[i].cbegin(), gnss_synchro_deque_iter);
if (distance > 0)
{
if (d_gnss_synchro_history_queue[i].at(distance - 1).Flag_valid_word)
{
double T_rx_channel_prev = static_cast<double>(d_gnss_synchro_history_queue[i].at(distance - 1).Tracking_sample_counter) / static_cast<double>(gnss_synchro_deque_iter->fs);
double delta_T_rx_s_prev = T_rx_channel_prev - T_rx_s;
if (fabs(delta_T_rx_s_prev) < fabs(delta_T_rx_s))
{
realigned_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(d_gnss_synchro_history_queue[i].at(distance - 1).Channel_ID,
d_gnss_synchro_history_queue[i].at(distance - 1)));
adjacent_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(gnss_synchro_deque_iter->Channel_ID, *gnss_synchro_deque_iter));
}
else
{
realigned_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(gnss_synchro_deque_iter->Channel_ID, *gnss_synchro_deque_iter));
adjacent_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(d_gnss_synchro_history_queue[i].at(distance - 1).Channel_ID,
d_gnss_synchro_history_queue[i].at(distance - 1)));
}
}
}
else
{
realigned_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(gnss_synchro_deque_iter->Channel_ID, *gnss_synchro_deque_iter));
}
}
}
}
}
if(!realigned_gnss_synchro_map.empty())
{
/*
* 2.1 Use CURRENT set of measurements and find the nearest satellite
* common RX time algorithm
*/
// what is the most recent symbol TOW in the current set? -> this will be the reference symbol
gnss_synchro_map_iter = max_element(realigned_gnss_synchro_map.cbegin(),
realigned_gnss_synchro_map.cend(),
Hybrid_pairCompare_gnss_synchro_d_TOW);
double ref_fs_hz = static_cast<double>(gnss_synchro_map_iter->second.fs);
// compute interpolated TOW value at T_rx_s
int ref_channel_key = gnss_synchro_map_iter->second.Channel_ID;
Gnss_Synchro adj_obs = adjacent_gnss_synchro_map.at(ref_channel_key);
double ref_adj_T_rx_s = static_cast<double>(adj_obs.Tracking_sample_counter) / ref_fs_hz + adj_obs.Code_phase_samples / ref_fs_hz;
double d_TOW_reference = gnss_synchro_map_iter->second.TOW_at_current_symbol_s;
double d_ref_T_rx_s = static_cast<double>(gnss_synchro_map_iter->second.Tracking_sample_counter) / ref_fs_hz + gnss_synchro_map_iter->second.Code_phase_samples / ref_fs_hz;
double selected_T_rx_s = T_rx_s;
// two points linear interpolation using adjacent (adj) values: y=y1+(x-x1)*(y2-y1)/(x2-x1)
double ref_TOW_at_T_rx_s = adj_obs.TOW_at_current_symbol_s +
(selected_T_rx_s - ref_adj_T_rx_s) * (d_TOW_reference - adj_obs.TOW_at_current_symbol_s) / (d_ref_T_rx_s - ref_adj_T_rx_s);
// Now compute RX time differences due to the PRN alignment in the correlators
double traveltime_ms;
double pseudorange_m;
double channel_T_rx_s;
double channel_fs_hz;
double channel_TOW_s;
for(gnss_synchro_map_iter = realigned_gnss_synchro_map.cbegin(); gnss_synchro_map_iter != realigned_gnss_synchro_map.cend(); gnss_synchro_map_iter++)
{
channel_fs_hz = static_cast<double>(gnss_synchro_map_iter->second.fs);
channel_TOW_s = gnss_synchro_map_iter->second.TOW_at_current_symbol_s;
channel_T_rx_s = static_cast<double>(gnss_synchro_map_iter->second.Tracking_sample_counter) / channel_fs_hz + gnss_synchro_map_iter->second.Code_phase_samples / channel_fs_hz;
// compute interpolated observation values
// two points linear interpolation using adjacent (adj) values: y=y1+(x-x1)*(y2-y1)/(x2-x1)
// TOW at the selected receiver time T_rx_s
int element_key = gnss_synchro_map_iter->second.Channel_ID;
adj_obs = adjacent_gnss_synchro_map.at(element_key);
double adj_T_rx_s = static_cast<double>(adj_obs.Tracking_sample_counter) / channel_fs_hz + adj_obs.Code_phase_samples / channel_fs_hz;
double channel_TOW_at_T_rx_s = adj_obs.TOW_at_current_symbol_s + (selected_T_rx_s - adj_T_rx_s) * (channel_TOW_s - adj_obs.TOW_at_current_symbol_s) / (channel_T_rx_s - adj_T_rx_s);
// Doppler and Accumulated carrier phase
double Carrier_phase_lin_rads = adj_obs.Carrier_phase_rads + (selected_T_rx_s - adj_T_rx_s) * (gnss_synchro_map_iter->second.Carrier_phase_rads - adj_obs.Carrier_phase_rads) / (channel_T_rx_s - adj_T_rx_s);
double Carrier_Doppler_lin_hz = adj_obs.Carrier_Doppler_hz + (selected_T_rx_s - adj_T_rx_s) * (gnss_synchro_map_iter->second.Carrier_Doppler_hz - adj_obs.Carrier_Doppler_hz) / (channel_T_rx_s - adj_T_rx_s);
// compute the pseudorange (no rx time offset correction)
traveltime_ms = (ref_TOW_at_T_rx_s - channel_TOW_at_T_rx_s) * 1000.0 + GPS_STARTOFFSET_ms;
// convert to meters
pseudorange_m = traveltime_ms * GPS_C_m_ms; // [m]
// update the pseudorange object
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID] = gnss_synchro_map_iter->second;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Pseudorange_m = pseudorange_m;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Flag_valid_pseudorange = true;
// Save the estimated RX time (no RX clock offset correction yet!)
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].RX_time = ref_TOW_at_T_rx_s + GPS_STARTOFFSET_ms / 1000.0;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Carrier_phase_rads = Carrier_phase_lin_rads;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Carrier_Doppler_hz = Carrier_Doppler_lin_hz;
}
if(d_dump == true)
{
// MULTIPLEXED FILE RECORDING - Record results to file
try
{ {
realigned_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(d_gnss_synchro_history_queue[i].at(distance - 1).Channel_ID, double tmp_double;
d_gnss_synchro_history_queue[i].at(distance - 1))); for (unsigned int i = 0; i < d_nchannels; i++)
adjacent_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(gnss_synchro_deque_iter->Channel_ID, *gnss_synchro_deque_iter)); {
tmp_double = current_gnss_synchro[i].RX_time;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].TOW_at_current_symbol_s;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].Carrier_Doppler_hz;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].Carrier_phase_rads / GPS_TWO_PI;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].Pseudorange_m;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].PRN;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = static_cast<double>(current_gnss_synchro[i].Flag_valid_pseudorange);
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
}
} }
else catch (const std::ifstream::failure& e)
{ {
realigned_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(gnss_synchro_deque_iter->Channel_ID, *gnss_synchro_deque_iter)); LOG(WARNING) << "Exception writing observables dump file " << e.what();
adjacent_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(d_gnss_synchro_history_queue[i].at(distance - 1).Channel_ID,
d_gnss_synchro_history_queue[i].at(distance - 1)));
} }
} }
}
else
{
realigned_gnss_synchro_map.insert(std::pair<int, Gnss_Synchro>(gnss_synchro_deque_iter->Channel_ID, *gnss_synchro_deque_iter));
}
for (unsigned int i = 0; i < d_nchannels; i++)
{
out[i][n_outputs] = current_gnss_synchro[i];
}
n_outputs++;
} }
}
}
}
if(!realigned_gnss_synchro_map.empty()) // Move RX time
{ T_rx_s = T_rx_s + T_rx_step_s;
/* // pop old elements from queue
* 2.1 Use CURRENT set of measurements and find the nearest satellite for (unsigned int i = 0; i < d_nchannels; i++)
* common RX time algorithm
*/
// what is the most recent symbol TOW in the current set? -> this will be the reference symbol
gnss_synchro_map_iter = max_element(realigned_gnss_synchro_map.cbegin(),
realigned_gnss_synchro_map.cend(),
Hybrid_pairCompare_gnss_synchro_d_TOW);
double ref_fs_hz = static_cast<double>(gnss_synchro_map_iter->second.fs);
// compute interpolated TOW value at T_rx_s
int ref_channel_key = gnss_synchro_map_iter->second.Channel_ID;
Gnss_Synchro adj_obs = adjacent_gnss_synchro_map.at(ref_channel_key);
double ref_adj_T_rx_s = static_cast<double>(adj_obs.Tracking_sample_counter) / ref_fs_hz + adj_obs.Code_phase_samples / ref_fs_hz;
double d_TOW_reference = gnss_synchro_map_iter->second.TOW_at_current_symbol_s;
double d_ref_T_rx_s = static_cast<double>(gnss_synchro_map_iter->second.Tracking_sample_counter) / ref_fs_hz + gnss_synchro_map_iter->second.Code_phase_samples / ref_fs_hz;
double selected_T_rx_s = T_rx_s;
// two points linear interpolation using adjacent (adj) values: y=y1+(x-x1)*(y2-y1)/(x2-x1)
double ref_TOW_at_T_rx_s = adj_obs.TOW_at_current_symbol_s +
(selected_T_rx_s - ref_adj_T_rx_s) * (d_TOW_reference - adj_obs.TOW_at_current_symbol_s) / (d_ref_T_rx_s - ref_adj_T_rx_s);
// Now compute RX time differences due to the PRN alignment in the correlators
double traveltime_ms;
double pseudorange_m;
double channel_T_rx_s;
double channel_fs_hz;
double channel_TOW_s;
for(gnss_synchro_map_iter = realigned_gnss_synchro_map.cbegin(); gnss_synchro_map_iter != realigned_gnss_synchro_map.cend(); gnss_synchro_map_iter++)
{
channel_fs_hz = static_cast<double>(gnss_synchro_map_iter->second.fs);
channel_TOW_s = gnss_synchro_map_iter->second.TOW_at_current_symbol_s;
channel_T_rx_s = static_cast<double>(gnss_synchro_map_iter->second.Tracking_sample_counter) / channel_fs_hz + gnss_synchro_map_iter->second.Code_phase_samples / channel_fs_hz;
// compute interpolated observation values
// two points linear interpolation using adjacent (adj) values: y=y1+(x-x1)*(y2-y1)/(x2-x1)
// TOW at the selected receiver time T_rx_s
int element_key = gnss_synchro_map_iter->second.Channel_ID;
adj_obs = adjacent_gnss_synchro_map.at(element_key);
double adj_T_rx_s = static_cast<double>(adj_obs.Tracking_sample_counter) / channel_fs_hz + adj_obs.Code_phase_samples / channel_fs_hz;
double channel_TOW_at_T_rx_s = adj_obs.TOW_at_current_symbol_s + (selected_T_rx_s - adj_T_rx_s) * (channel_TOW_s - adj_obs.TOW_at_current_symbol_s) / (channel_T_rx_s - adj_T_rx_s);
// Doppler and Accumulated carrier phase
double Carrier_phase_lin_rads = adj_obs.Carrier_phase_rads + (selected_T_rx_s - adj_T_rx_s) * (gnss_synchro_map_iter->second.Carrier_phase_rads - adj_obs.Carrier_phase_rads) / (channel_T_rx_s - adj_T_rx_s);
double Carrier_Doppler_lin_hz = adj_obs.Carrier_Doppler_hz + (selected_T_rx_s - adj_T_rx_s) * (gnss_synchro_map_iter->second.Carrier_Doppler_hz - adj_obs.Carrier_Doppler_hz) / (channel_T_rx_s - adj_T_rx_s);
// compute the pseudorange (no rx time offset correction)
traveltime_ms = (ref_TOW_at_T_rx_s - channel_TOW_at_T_rx_s) * 1000.0 + GPS_STARTOFFSET_ms;
// convert to meters
pseudorange_m = traveltime_ms * GPS_C_m_ms; // [m]
// update the pseudorange object
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID] = gnss_synchro_map_iter->second;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Pseudorange_m = pseudorange_m;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Flag_valid_pseudorange = true;
// Save the estimated RX time (no RX clock offset correction yet!)
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].RX_time = ref_TOW_at_T_rx_s + GPS_STARTOFFSET_ms / 1000.0;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Carrier_phase_rads = Carrier_phase_lin_rads;
current_gnss_synchro[gnss_synchro_map_iter->second.Channel_ID].Carrier_Doppler_hz = Carrier_Doppler_lin_hz;
}
if(d_dump == true)
{
// MULTIPLEXED FILE RECORDING - Record results to file
try
{
double tmp_double;
for (unsigned int i = 0; i < d_nchannels; i++)
{ {
tmp_double = current_gnss_synchro[i].RX_time; while (static_cast<double>(d_gnss_synchro_history_queue[i].front().Tracking_sample_counter) / static_cast<double>(d_gnss_synchro_history_queue[i].front().fs) < (T_rx_s - past_history_s))
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double)); {
tmp_double = current_gnss_synchro[i].TOW_at_current_symbol_s; d_gnss_synchro_history_queue[i].pop_front();
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double)); }
tmp_double = current_gnss_synchro[i].Carrier_Doppler_hz;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].Carrier_phase_rads / GPS_TWO_PI;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].Pseudorange_m;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = current_gnss_synchro[i].PRN;
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
tmp_double = static_cast<double>(current_gnss_synchro[i].Flag_valid_pseudorange);
d_dump_file.write(reinterpret_cast<char*>(&tmp_double), sizeof(double));
} }
}
catch (const std::ifstream::failure& e)
{
LOG(WARNING) << "Exception writing observables dump file " << e.what();
}
} }
} while(channel_history_ok == true && noutput_items > n_outputs);
for (unsigned int i = 0; i < d_nchannels; i++)
{
out[i][n_outputs] = current_gnss_synchro[i];
}
n_outputs++;
}
// Move RX time
T_rx_s = T_rx_s + T_rx_step_s;
// pop old elements from queue
for (unsigned int i = 0; i < d_nchannels; i++)
{
while (static_cast<double>(d_gnss_synchro_history_queue[i].front().Tracking_sample_counter) / static_cast<double>(d_gnss_synchro_history_queue[i].front().fs) < (T_rx_s - past_history_s))
{
d_gnss_synchro_history_queue[i].pop_front();
}
}
}
} while(channel_history_ok == true && noutput_items > n_outputs);
// Multi-rate consume! // Multi-rate consume!
for (unsigned int i = 0; i < d_nchannels; i++) for (unsigned int i = 0; i < d_nchannels; i++)
{ {
consume(i, n_consume[i]); // which input, how many items consume(i, n_consume[i]); // which input, how many items
} }
return n_outputs; return n_outputs;
} }