/*!
* \file pcps_acquisition.cc
* \brief This class implements a Parallel Code Phase Search Acquisition
* \authors
* - Javier Arribas, 2011. jarribas(at)cttc.es
*
- Luis Esteve, 2012. luis(at)epsilon-formacion.com
*
- Marc Molina, 2013. marc.molina.pena@gmail.com
*
- Cillian O'Driscoll, 2017. cillian(at)ieee.org
*
*
* -------------------------------------------------------------------------
*
* Copyright (C) 2010-2018 (see AUTHORS file for a list of contributors)
*
* GNSS-SDR is a software defined Global Navigation
* Satellite Systems receiver
*
* This file is part of GNSS-SDR.
*
* GNSS-SDR is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* GNSS-SDR is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with GNSS-SDR. If not, see .
*
* -------------------------------------------------------------------------
*/
#include "pcps_acquisition.h"
#include "GPS_L1_CA.h" // for GPS_TWO_PI
#include "GLONASS_L1_L2_CA.h" // for GLONASS_TWO_PI"
#include
#include
#include
#include
#include
using google::LogMessage;
pcps_acquisition_sptr pcps_make_acquisition(const Acq_Conf& conf_)
{
return pcps_acquisition_sptr(new pcps_acquisition(conf_));
}
pcps_acquisition::pcps_acquisition(const Acq_Conf& conf_) : gr::block("pcps_acquisition",
gr::io_signature::make(1, 1, conf_.it_size * conf_.sampled_ms * conf_.samples_per_ms * (conf_.bit_transition_flag ? 2 : 1)),
gr::io_signature::make(0, 0, conf_.it_size * conf_.sampled_ms * conf_.samples_per_ms * (conf_.bit_transition_flag ? 2 : 1)))
{
this->message_port_register_out(pmt::mp("events"));
acq_parameters = conf_;
d_sample_counter = 0; // SAMPLE COUNTER
d_active = false;
d_positive_acq = 0;
d_state = 0;
d_old_freq = 0;
d_num_noncoherent_integrations_counter = 0;
d_consumed_samples = acq_parameters.sampled_ms * acq_parameters.samples_per_ms * (acq_parameters.bit_transition_flag ? 2 : 1);
if (acq_parameters.sampled_ms == (acq_parameters.samples_per_code / acq_parameters.samples_per_ms)) //
{
d_fft_size = d_consumed_samples;
}
else
{
d_fft_size = d_consumed_samples * 2;
}
//d_fft_size = next power of two? ////
d_mag = 0;
d_input_power = 0.0;
d_num_doppler_bins = 0;
d_threshold = 0.0;
d_doppler_step = 0;
d_doppler_center_step_two = 0.0;
d_test_statistics = 0.0;
d_channel = 0;
if (conf_.it_size == sizeof(gr_complex))
{
d_cshort = false;
}
else
{
d_cshort = true;
}
// COD:
// Experimenting with the overlap/save technique for handling bit trannsitions
// The problem: Circular correlation is asynchronous with the received code.
// In effect the first code phase used in the correlation is the current
// estimate of the code phase at the start of the input buffer. If this is 1/2
// of the code period a bit transition would move all the signal energy into
// adjacent frequency bands at +/- 1/T where T is the integration time.
//
// We can avoid this by doing linear correlation, effectively doubling the
// size of the input buffer and padding the code with zeros.
if (acq_parameters.bit_transition_flag)
{
d_fft_size = d_consumed_samples * 2;
acq_parameters.max_dwells = 1; // Activation of acq_parameters.bit_transition_flag invalidates the value of acq_parameters.max_dwells
}
d_tmp_buffer = static_cast(volk_gnsssdr_malloc(d_fft_size * sizeof(float), volk_gnsssdr_get_alignment()));
d_fft_codes = static_cast(volk_gnsssdr_malloc(d_fft_size * sizeof(gr_complex), volk_gnsssdr_get_alignment()));
d_magnitude = static_cast(volk_gnsssdr_malloc(d_fft_size * sizeof(float), volk_gnsssdr_get_alignment()));
d_input_signal = static_cast(volk_gnsssdr_malloc(d_fft_size * sizeof(gr_complex), volk_gnsssdr_get_alignment()));
// Direct FFT
d_fft_if = new gr::fft::fft_complex(d_fft_size, true);
// Inverse FFT
d_ifft = new gr::fft::fft_complex(d_fft_size, false);
d_gnss_synchro = 0;
d_grid_doppler_wipeoffs = nullptr;
d_grid_doppler_wipeoffs_step_two = nullptr;
d_magnitude_grid = nullptr;
d_worker_active = false;
d_data_buffer = static_cast(volk_gnsssdr_malloc(d_consumed_samples * sizeof(gr_complex), volk_gnsssdr_get_alignment()));
if (d_cshort)
{
d_data_buffer_sc = static_cast(volk_gnsssdr_malloc(d_consumed_samples * sizeof(lv_16sc_t), volk_gnsssdr_get_alignment()));
}
else
{
d_data_buffer_sc = nullptr;
}
grid_ = arma::fmat();
d_step_two = false;
d_dump_number = 0;
d_dump_channel = acq_parameters.dump_channel;
d_samplesPerChip = acq_parameters.samples_per_chip;
// todo: CFAR statistic not available for non-coherent integration
if (acq_parameters.max_dwells == 1)
{
d_use_CFAR_algorithm_flag = acq_parameters.use_CFAR_algorithm_flag;
}
else
{
d_use_CFAR_algorithm_flag = false;
}
}
pcps_acquisition::~pcps_acquisition()
{
if (d_num_doppler_bins > 0)
{
for (unsigned int i = 0; i < d_num_doppler_bins; i++)
{
volk_gnsssdr_free(d_grid_doppler_wipeoffs[i]);
volk_gnsssdr_free(d_magnitude_grid[i]);
}
delete[] d_grid_doppler_wipeoffs;
delete[] d_magnitude_grid;
}
if (acq_parameters.make_2_steps)
{
for (unsigned int i = 0; i < acq_parameters.num_doppler_bins_step2; i++)
{
volk_gnsssdr_free(d_grid_doppler_wipeoffs_step_two[i]);
}
delete[] d_grid_doppler_wipeoffs_step_two;
}
volk_gnsssdr_free(d_fft_codes);
volk_gnsssdr_free(d_magnitude);
volk_gnsssdr_free(d_tmp_buffer);
volk_gnsssdr_free(d_input_signal);
delete d_ifft;
delete d_fft_if;
volk_gnsssdr_free(d_data_buffer);
if (d_cshort)
{
volk_gnsssdr_free(d_data_buffer_sc);
}
}
void pcps_acquisition::set_local_code(std::complex* code)
{
// reset the intermediate frequency
d_old_freq = 0;
// This will check if it's fdma, if yes will update the intermediate frequency and the doppler grid
if (is_fdma())
{
update_grid_doppler_wipeoffs();
}
// COD
// Here we want to create a buffer that looks like this:
// [ 0 0 0 ... 0 c_0 c_1 ... c_L]
// where c_i is the local code and there are L zeros and L chips
gr::thread::scoped_lock lock(d_setlock); // require mutex with work function called by the scheduler
if (acq_parameters.bit_transition_flag)
{
int offset = d_fft_size / 2;
std::fill_n(d_fft_if->get_inbuf(), offset, gr_complex(0.0, 0.0));
memcpy(d_fft_if->get_inbuf() + offset, code, sizeof(gr_complex) * offset);
}
else
{
if (acq_parameters.sampled_ms == (acq_parameters.samples_per_code / acq_parameters.samples_per_ms))
{
memcpy(d_fft_if->get_inbuf(), code, sizeof(gr_complex) * d_consumed_samples);
}
else
{
std::fill_n(d_fft_if->get_inbuf(), d_fft_size - d_consumed_samples, gr_complex(0.0, 0.0));
memcpy(d_fft_if->get_inbuf() + d_consumed_samples, code, sizeof(gr_complex) * d_consumed_samples);
}
}
d_fft_if->execute(); // We need the FFT of local code
volk_32fc_conjugate_32fc(d_fft_codes, d_fft_if->get_outbuf(), d_fft_size);
}
bool pcps_acquisition::is_fdma()
{
// Dealing with FDMA system
if (strcmp(d_gnss_synchro->Signal, "1G") == 0)
{
d_old_freq += DFRQ1_GLO * GLONASS_PRN.at(d_gnss_synchro->PRN);
LOG(INFO) << "Trying to acquire SV PRN " << d_gnss_synchro->PRN << " with freq " << d_old_freq << " in Glonass Channel " << GLONASS_PRN.at(d_gnss_synchro->PRN) << std::endl;
return true;
}
else if (strcmp(d_gnss_synchro->Signal, "2G") == 0)
{
d_old_freq += DFRQ2_GLO * GLONASS_PRN.at(d_gnss_synchro->PRN);
LOG(INFO) << "Trying to acquire SV PRN " << d_gnss_synchro->PRN << " with freq " << d_old_freq << " in Glonass Channel " << GLONASS_PRN.at(d_gnss_synchro->PRN) << std::endl;
return true;
}
else
{
return false;
}
}
void pcps_acquisition::update_local_carrier(gr_complex* carrier_vector, int correlator_length_samples, float freq)
{
float phase_step_rad = GPS_TWO_PI * freq / static_cast(acq_parameters.fs_in);
float _phase[1];
_phase[0] = 0;
volk_gnsssdr_s32f_sincos_32fc(carrier_vector, -phase_step_rad, _phase, correlator_length_samples);
}
void pcps_acquisition::init()
{
d_gnss_synchro->Flag_valid_acquisition = false;
d_gnss_synchro->Flag_valid_symbol_output = false;
d_gnss_synchro->Flag_valid_pseudorange = false;
d_gnss_synchro->Flag_valid_word = false;
d_gnss_synchro->Acq_delay_samples = 0.0;
d_gnss_synchro->Acq_doppler_hz = 0.0;
d_gnss_synchro->Acq_samplestamp_samples = 0;
d_mag = 0.0;
d_input_power = 0.0;
d_num_doppler_bins = static_cast(std::ceil(static_cast(static_cast(acq_parameters.doppler_max) - static_cast(-acq_parameters.doppler_max)) / static_cast(d_doppler_step)));
// Create the carrier Doppler wipeoff signals
d_grid_doppler_wipeoffs = new gr_complex*[d_num_doppler_bins];
if (acq_parameters.make_2_steps)
{
d_grid_doppler_wipeoffs_step_two = new gr_complex*[acq_parameters.num_doppler_bins_step2];
for (unsigned int doppler_index = 0; doppler_index < acq_parameters.num_doppler_bins_step2; doppler_index++)
{
d_grid_doppler_wipeoffs_step_two[doppler_index] = static_cast(volk_gnsssdr_malloc(d_fft_size * sizeof(gr_complex), volk_gnsssdr_get_alignment()));
}
}
d_magnitude_grid = new float*[d_num_doppler_bins];
for (unsigned int doppler_index = 0; doppler_index < d_num_doppler_bins; doppler_index++)
{
d_grid_doppler_wipeoffs[doppler_index] = static_cast(volk_gnsssdr_malloc(d_fft_size * sizeof(gr_complex), volk_gnsssdr_get_alignment()));
d_magnitude_grid[doppler_index] = static_cast(volk_gnsssdr_malloc(d_fft_size * sizeof(float), volk_gnsssdr_get_alignment()));
for (unsigned k = 0; k < d_fft_size; k++)
{
d_magnitude_grid[doppler_index][k] = 0.0;
}
int doppler = -static_cast(acq_parameters.doppler_max) + d_doppler_step * doppler_index;
update_local_carrier(d_grid_doppler_wipeoffs[doppler_index], d_fft_size, d_old_freq + doppler);
}
d_worker_active = false;
if (acq_parameters.dump)
{
unsigned int effective_fft_size = (acq_parameters.bit_transition_flag ? (d_fft_size / 2) : d_fft_size);
grid_ = arma::fmat(effective_fft_size, d_num_doppler_bins, arma::fill::zeros);
}
}
void pcps_acquisition::update_grid_doppler_wipeoffs()
{
for (unsigned int doppler_index = 0; doppler_index < d_num_doppler_bins; doppler_index++)
{
int doppler = -static_cast(acq_parameters.doppler_max) + d_doppler_step * doppler_index;
update_local_carrier(d_grid_doppler_wipeoffs[doppler_index], d_fft_size, d_old_freq + doppler);
}
}
void pcps_acquisition::update_grid_doppler_wipeoffs_step2()
{
for (unsigned int doppler_index = 0; doppler_index < acq_parameters.num_doppler_bins_step2; doppler_index++)
{
float doppler = (static_cast(doppler_index) - static_cast(acq_parameters.num_doppler_bins_step2) / 2.0) * acq_parameters.doppler_step2;
update_local_carrier(d_grid_doppler_wipeoffs_step_two[doppler_index], d_fft_size, d_doppler_center_step_two + doppler);
}
}
void pcps_acquisition::set_state(int state)
{
gr::thread::scoped_lock lock(d_setlock); // require mutex with work function called by the scheduler
d_state = state;
if (d_state == 1)
{
d_gnss_synchro->Acq_delay_samples = 0.0;
d_gnss_synchro->Acq_doppler_hz = 0.0;
d_gnss_synchro->Acq_samplestamp_samples = 0;
d_mag = 0.0;
d_input_power = 0.0;
d_test_statistics = 0.0;
d_active = true;
}
else if (d_state == 0)
{
}
else
{
LOG(ERROR) << "State can only be set to 0 or 1";
}
}
void pcps_acquisition::send_positive_acquisition()
{
// 6.1- Declare positive acquisition using a message port
//0=STOP_CHANNEL 1=ACQ_SUCCEES 2=ACQ_FAIL
DLOG(INFO) << "positive acquisition"
<< ", satellite " << d_gnss_synchro->System << " " << d_gnss_synchro->PRN
<< ", sample_stamp " << d_sample_counter
<< ", test statistics value " << d_test_statistics
<< ", test statistics threshold " << d_threshold
<< ", code phase " << d_gnss_synchro->Acq_delay_samples
<< ", doppler " << d_gnss_synchro->Acq_doppler_hz
<< ", magnitude " << d_mag
<< ", input signal power " << d_input_power;
d_positive_acq = 1;
this->message_port_pub(pmt::mp("events"), pmt::from_long(1));
}
void pcps_acquisition::send_negative_acquisition()
{
// 6.2- Declare negative acquisition using a message port
//0=STOP_CHANNEL 1=ACQ_SUCCEES 2=ACQ_FAIL
DLOG(INFO) << "negative acquisition"
<< ", satellite " << d_gnss_synchro->System << " " << d_gnss_synchro->PRN
<< ", sample_stamp " << d_sample_counter
<< ", test statistics value " << d_test_statistics
<< ", test statistics threshold " << d_threshold
<< ", code phase " << d_gnss_synchro->Acq_delay_samples
<< ", doppler " << d_gnss_synchro->Acq_doppler_hz
<< ", magnitude " << d_mag
<< ", input signal power " << d_input_power;
d_positive_acq = 0;
this->message_port_pub(pmt::mp("events"), pmt::from_long(2));
}
void pcps_acquisition::dump_results(int effective_fft_size)
{
d_dump_number++;
std::string filename = acq_parameters.dump_filename;
filename.append("_");
filename.append(1, d_gnss_synchro->System);
filename.append("_");
filename.append(1, d_gnss_synchro->Signal[0]);
filename.append(1, d_gnss_synchro->Signal[1]);
filename.append("_ch_");
filename.append(std::to_string(d_channel));
filename.append("_");
filename.append(std::to_string(d_dump_number));
filename.append("_sat_");
filename.append(std::to_string(d_gnss_synchro->PRN));
filename.append(".mat");
mat_t* matfp = Mat_CreateVer(filename.c_str(), NULL, MAT_FT_MAT73);
if (matfp == NULL)
{
std::cout << "Unable to create or open Acquisition dump file" << std::endl;
acq_parameters.dump = false;
}
else
{
size_t dims[2] = {static_cast(effective_fft_size), static_cast(d_num_doppler_bins)};
matvar_t* matvar = Mat_VarCreate("acq_grid", MAT_C_SINGLE, MAT_T_SINGLE, 2, dims, grid_.memptr(), 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
dims[0] = static_cast(1);
dims[1] = static_cast(1);
matvar = Mat_VarCreate("doppler_max", MAT_C_UINT32, MAT_T_UINT32, 1, dims, &acq_parameters.doppler_max, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("doppler_step", MAT_C_UINT32, MAT_T_UINT32, 1, dims, &d_doppler_step, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("d_positive_acq", MAT_C_INT32, MAT_T_INT32, 1, dims, &d_positive_acq, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
float aux = static_cast(d_gnss_synchro->Acq_doppler_hz);
matvar = Mat_VarCreate("acq_doppler_hz", MAT_C_SINGLE, MAT_T_SINGLE, 1, dims, &aux, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
aux = static_cast(d_gnss_synchro->Acq_delay_samples);
matvar = Mat_VarCreate("acq_delay_samples", MAT_C_SINGLE, MAT_T_SINGLE, 1, dims, &aux, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("test_statistic", MAT_C_SINGLE, MAT_T_SINGLE, 1, dims, &d_test_statistics, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("threshold", MAT_C_SINGLE, MAT_T_SINGLE, 1, dims, &d_threshold, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("input_power", MAT_C_SINGLE, MAT_T_SINGLE, 1, dims, &d_input_power, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("sample_counter", MAT_C_UINT64, MAT_T_UINT64, 1, dims, &d_sample_counter, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("PRN", MAT_C_UINT32, MAT_T_UINT32, 1, dims, &d_gnss_synchro->PRN, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
Mat_Close(matfp);
}
}
float pcps_acquisition::max_to_input_power_statistic(uint32_t& indext, int& doppler, float input_power, unsigned int num_doppler_bins, int doppler_max, int doppler_step)
{
float grid_maximum = 0.0;
unsigned int index_doppler = 0;
uint32_t tmp_intex_t = 0;
uint32_t index_time = 0;
float fft_normalization_factor = static_cast(d_fft_size) * static_cast(d_fft_size);
// Find the correlation peak and the carrier frequency
for (unsigned int i = 0; i < num_doppler_bins; i++)
{
volk_gnsssdr_32f_index_max_32u(&tmp_intex_t, d_magnitude_grid[i], d_fft_size);
if (d_magnitude_grid[i][tmp_intex_t] > grid_maximum)
{
grid_maximum = d_magnitude_grid[i][tmp_intex_t];
index_doppler = i;
index_time = tmp_intex_t;
}
}
indext = index_time;
if (!d_step_two)
{
doppler = -static_cast(doppler_max) + doppler_step * static_cast(index_doppler);
}
else
{
doppler = static_cast(d_doppler_center_step_two + (index_doppler - (acq_parameters.num_doppler_bins_step2 / 2.0) * acq_parameters.doppler_step2));
}
float magt = grid_maximum / (fft_normalization_factor * fft_normalization_factor);
return magt / input_power;
}
float pcps_acquisition::first_vs_second_peak_statistic(uint32_t& indext, int& doppler, unsigned int num_doppler_bins, int doppler_max, int doppler_step)
{
// Look for correlation peaks in the results
// Find the highest peak and compare it to the second highest peak
// The second peak is chosen not closer than 1 chip to the highest peak
float firstPeak = 0.0;
unsigned int index_doppler = 0;
uint32_t tmp_intex_t = 0;
uint32_t index_time = 0;
// Find the correlation peak and the carrier frequency
for (unsigned int i = 0; i < num_doppler_bins; i++)
{
volk_gnsssdr_32f_index_max_32u(&tmp_intex_t, d_magnitude_grid[i], d_fft_size);
if (d_magnitude_grid[i][tmp_intex_t] > firstPeak)
{
firstPeak = d_magnitude_grid[i][tmp_intex_t];
index_doppler = i;
index_time = tmp_intex_t;
}
}
indext = index_time;
if (!d_step_two)
{
doppler = -static_cast(doppler_max) + doppler_step * static_cast(index_doppler);
}
else
{
doppler = static_cast(d_doppler_center_step_two + (index_doppler - (acq_parameters.num_doppler_bins_step2 / 2.0) * acq_parameters.doppler_step2));
}
// Find 1 chip wide code phase exclude range around the peak
int32_t excludeRangeIndex1 = index_time - d_samplesPerChip;
int32_t excludeRangeIndex2 = index_time + d_samplesPerChip;
// Correct code phase exclude range if the range includes array boundaries
if (excludeRangeIndex1 < 0)
{
excludeRangeIndex1 = d_fft_size + excludeRangeIndex1;
}
else if (excludeRangeIndex2 >= static_cast(d_fft_size))
{
excludeRangeIndex2 = excludeRangeIndex2 - d_fft_size;
}
int32_t idx = excludeRangeIndex1;
memcpy(d_tmp_buffer, d_magnitude_grid[index_doppler], d_fft_size);
do
{
d_tmp_buffer[idx] = 0.0;
idx++;
if (idx == static_cast(d_fft_size)) idx = 0;
}
while (idx != excludeRangeIndex2);
// Find the second highest correlation peak in the same freq. bin ---
volk_gnsssdr_32f_index_max_32u(&tmp_intex_t, d_tmp_buffer, d_fft_size);
float secondPeak = d_tmp_buffer[tmp_intex_t];
// Compute the test statistics and compare to the threshold
return firstPeak / secondPeak;
}
void pcps_acquisition::acquisition_core(unsigned long int samp_count)
{
gr::thread::scoped_lock lk(d_setlock);
// initialize acquisition algorithm
float magt = 0.0;
int doppler = 0;
uint32_t indext = 0;
int effective_fft_size = (acq_parameters.bit_transition_flag ? d_fft_size / 2 : d_fft_size);
if (d_cshort)
{
volk_gnsssdr_16ic_convert_32fc(d_data_buffer, d_data_buffer_sc, d_consumed_samples);
}
memcpy(d_input_signal, d_data_buffer, d_consumed_samples * sizeof(gr_complex));
if (d_fft_size > d_consumed_samples)
{
for (unsigned int i = d_consumed_samples; i < d_fft_size; i++)
{
d_input_signal[i] = gr_complex(0.0, 0.0);
}
}
const gr_complex* in = d_input_signal; // Get the input samples pointer
float fft_normalization_factor = static_cast(d_fft_size) * static_cast(d_fft_size);
d_input_power = 0.0;
d_mag = 0.0;
d_num_noncoherent_integrations_counter++;
DLOG(INFO) << "Channel: " << d_channel
<< " , doing acquisition of satellite: " << d_gnss_synchro->System << " " << d_gnss_synchro->PRN
<< " ,sample stamp: " << samp_count << ", threshold: "
<< d_threshold << ", doppler_max: " << acq_parameters.doppler_max
<< ", doppler_step: " << d_doppler_step
<< ", use_CFAR_algorithm_flag: " << (d_use_CFAR_algorithm_flag ? "true" : "false");
lk.unlock();
if (d_use_CFAR_algorithm_flag or acq_parameters.bit_transition_flag)
{
// Compute the input signal power estimation
volk_32fc_magnitude_squared_32f(d_tmp_buffer, in, d_fft_size);
volk_32f_accumulator_s32f(&d_input_power, d_tmp_buffer, d_fft_size);
d_input_power /= static_cast(d_fft_size);
}
// Doppler frequency grid loop
if (!d_step_two)
{
for (unsigned int doppler_index = 0; doppler_index < d_num_doppler_bins; doppler_index++)
{
// Remove Doppler
volk_32fc_x2_multiply_32fc(d_fft_if->get_inbuf(), in, d_grid_doppler_wipeoffs[doppler_index], d_fft_size);
// Perform the FFT-based convolution (parallel time search)
// Compute the FFT of the carrier wiped--off incoming signal
d_fft_if->execute();
// Multiply carrier wiped--off, Fourier transformed incoming signal with the local FFT'd code reference
volk_32fc_x2_multiply_32fc(d_ifft->get_inbuf(), d_fft_if->get_outbuf(), d_fft_codes, d_fft_size);
// Compute the inverse FFT
d_ifft->execute();
// Compute squared magnitude (and accumulate in case of non-coherent integration)
size_t offset = (acq_parameters.bit_transition_flag ? effective_fft_size : 0);
if (d_num_noncoherent_integrations_counter == 1)
{
volk_32fc_magnitude_squared_32f(d_magnitude_grid[doppler_index], d_ifft->get_outbuf() + offset, effective_fft_size);
}
else
{
volk_32fc_magnitude_squared_32f(d_tmp_buffer, d_ifft->get_outbuf() + offset, effective_fft_size);
volk_32f_x2_add_32f(d_magnitude_grid[doppler_index], d_magnitude_grid[doppler_index], d_tmp_buffer, effective_fft_size);
}
// Record results to file if required
if (acq_parameters.dump and d_channel == d_dump_channel)
{
memcpy(grid_.colptr(doppler_index), d_magnitude_grid[doppler_index], sizeof(float) * effective_fft_size);
}
}
// Compute the test statistic
if (d_use_CFAR_algorithm_flag)
{
d_test_statistics = max_to_input_power_statistic(indext, doppler, d_input_power, d_num_doppler_bins, acq_parameters.doppler_max, d_doppler_step);
}
else
{
d_test_statistics = first_vs_second_peak_statistic(indext, doppler, d_num_doppler_bins, acq_parameters.doppler_max, d_doppler_step);
}
d_gnss_synchro->Acq_delay_samples = static_cast(indext % acq_parameters.samples_per_code);
d_gnss_synchro->Acq_doppler_hz = static_cast(doppler);
d_gnss_synchro->Acq_samplestamp_samples = samp_count;
}
else
{
for (unsigned int doppler_index = 0; doppler_index < acq_parameters.num_doppler_bins_step2; doppler_index++)
{
volk_32fc_x2_multiply_32fc(d_fft_if->get_inbuf(), in, d_grid_doppler_wipeoffs_step_two[doppler_index], d_fft_size);
// 3- Perform the FFT-based convolution (parallel time search)
// Compute the FFT of the carrier wiped--off incoming signal
d_fft_if->execute();
// Multiply carrier wiped--off, Fourier transformed incoming signal
// with the local FFT'd code reference using SIMD operations with VOLK library
volk_32fc_x2_multiply_32fc(d_ifft->get_inbuf(), d_fft_if->get_outbuf(), d_fft_codes, d_fft_size);
// compute the inverse FFT
d_ifft->execute();
size_t offset = (acq_parameters.bit_transition_flag ? effective_fft_size : 0);
if (d_num_noncoherent_integrations_counter == 1)
{
volk_32fc_magnitude_squared_32f(d_magnitude_grid[doppler_index], d_ifft->get_outbuf() + offset, effective_fft_size);
}
else
{
volk_32fc_magnitude_squared_32f(d_tmp_buffer, d_ifft->get_outbuf() + offset, effective_fft_size);
volk_32f_x2_add_32f(d_magnitude_grid[doppler_index], d_magnitude_grid[doppler_index], d_tmp_buffer, effective_fft_size);
}
}
// Compute the test statistic
if (d_use_CFAR_algorithm_flag)
{
d_test_statistics = max_to_input_power_statistic(indext, doppler, d_input_power, acq_parameters.num_doppler_bins_step2, static_cast(d_doppler_center_step_two - (static_cast(acq_parameters.num_doppler_bins_step2) / 2.0) * acq_parameters.doppler_step2), acq_parameters.doppler_step2);
}
else
{
d_test_statistics = first_vs_second_peak_statistic(indext, doppler, acq_parameters.num_doppler_bins_step2, static_cast(d_doppler_center_step_two - (static_cast(acq_parameters.num_doppler_bins_step2) / 2.0) * acq_parameters.doppler_step2), acq_parameters.doppler_step2);
}
d_gnss_synchro->Acq_delay_samples = static_cast(indext % acq_parameters.samples_per_code);
d_gnss_synchro->Acq_doppler_hz = static_cast(doppler);
d_gnss_synchro->Acq_samplestamp_samples = samp_count;
}
lk.lock();
if (!acq_parameters.bit_transition_flag)
{
if (d_test_statistics > d_threshold)
{
d_active = false;
if (acq_parameters.make_2_steps)
{
if (d_step_two)
{
send_positive_acquisition();
d_step_two = false;
d_state = 0; // Positive acquisition
}
else
{
d_step_two = true; // Clear input buffer and make small grid acquisition
d_state = 0;
}
}
else
{
send_positive_acquisition();
d_state = 0; // Positive acquisition
}
}
if (d_num_noncoherent_integrations_counter == acq_parameters.max_dwells)
{
if (d_state != 0) send_negative_acquisition();
d_state = 0;
d_active = false;
d_step_two = false;
}
}
else
{
d_active = false;
if (d_test_statistics > d_threshold)
{
if (acq_parameters.make_2_steps)
{
if (d_step_two)
{
send_positive_acquisition();
d_step_two = false;
d_state = 0; // Positive acquisition
}
else
{
d_step_two = true; // Clear input buffer and make small grid acquisition
d_state = 0;
}
}
else
{
send_positive_acquisition();
d_state = 0; // Positive acquisition
}
}
else
{
d_state = 0; // Negative acquisition
d_step_two = false;
send_negative_acquisition();
}
}
d_worker_active = false;
if ((d_num_noncoherent_integrations_counter == acq_parameters.max_dwells) or (d_positive_acq == 1))
{
// Record results to file if required
if (acq_parameters.dump and d_channel == d_dump_channel)
{
pcps_acquisition::dump_results(effective_fft_size);
}
d_num_noncoherent_integrations_counter = 0;
d_positive_acq = 0;
// Reset grid
for (unsigned int i = 0; i < d_num_doppler_bins; i++)
{
for (unsigned k = 0; k < d_fft_size; k++)
{
d_magnitude_grid[i][k] = 0.0;
}
}
}
}
int pcps_acquisition::general_work(int noutput_items __attribute__((unused)),
gr_vector_int& ninput_items, gr_vector_const_void_star& input_items,
gr_vector_void_star& output_items __attribute__((unused)))
{
/*
* By J.Arribas, L.Esteve and M.Molina
* Acquisition strategy (Kay Borre book + CFAR threshold):
* 1. Compute the input signal power estimation
* 2. Doppler serial search loop
* 3. Perform the FFT-based circular convolution (parallel time search)
* 4. Record the maximum peak and the associated synchronization parameters
* 5. Compute the test statistics and compare to the threshold
* 6. Declare positive or negative acquisition using a message port
*/
gr::thread::scoped_lock lk(d_setlock);
if (!d_active or d_worker_active)
{
if (!acq_parameters.blocking_on_standby)
{
d_sample_counter += d_consumed_samples * ninput_items[0];
consume_each(ninput_items[0]);
}
if (d_step_two)
{
d_doppler_center_step_two = static_cast(d_gnss_synchro->Acq_doppler_hz);
update_grid_doppler_wipeoffs_step2();
d_state = 0;
d_active = true;
}
return 0;
}
switch (d_state)
{
case 0:
{
//restart acquisition variables
d_gnss_synchro->Acq_delay_samples = 0.0;
d_gnss_synchro->Acq_doppler_hz = 0.0;
d_gnss_synchro->Acq_samplestamp_samples = 0;
d_mag = 0.0;
d_input_power = 0.0;
d_test_statistics = 0.0;
d_state = 1;
if (!acq_parameters.blocking_on_standby)
{
d_sample_counter += d_consumed_samples * ninput_items[0]; // sample counter
consume_each(ninput_items[0]);
}
break;
}
case 1:
{
// Copy the data to the core and let it know that new data is available
if (d_cshort)
{
memcpy(d_data_buffer_sc, input_items[0], d_consumed_samples * sizeof(lv_16sc_t));
}
else
{
memcpy(d_data_buffer, input_items[0], d_consumed_samples * sizeof(gr_complex));
}
if (acq_parameters.blocking)
{
lk.unlock();
acquisition_core(d_sample_counter);
}
else
{
gr::thread::thread d_worker(&pcps_acquisition::acquisition_core, this, d_sample_counter);
d_worker_active = true;
}
d_sample_counter += d_consumed_samples;
consume_each(1);
break;
}
}
return 0;
}