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Change std::vector<std::deque<Gnss_Synchro>> by gnss_circular_deque

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This commit is contained in:
Antonio Ramos 2018-04-09 16:16:50 +02:00
parent 204aef99d0
commit d42d6b2ed4
5 changed files with 312 additions and 41 deletions
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213
src/algorithms/libs/gnss_circular_deque.h Normal file
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@ -0,0 +1,213 @@
/*!
* \file gnss_circular_deque.h
* \brief This class implements a circular deque for Gnss_Synchro
*
* \author Luis Esteve, 2018. antonio.ramos(at)cttc.es
*
* Detailed description of the file here if needed.
*
* -------------------------------------------------------------------------
*
* 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 <http://www.gnu.org/licenses/>.
*
* -------------------------------------------------------------------------
*/
#ifndef GNSS_SDR_CIRCULAR_DEQUE_H_
#define GNSS_SDR_CIRCULAR_DEQUE_H_
template <class T>
class Gnss_circular_deque
{
public:
Gnss_circular_deque();
Gnss_circular_deque(const unsigned int max_size, const unsigned int nchann);
~Gnss_circular_deque();
unsigned int size(const unsigned int ch);
T& at(const unsigned int ch, const unsigned int pos);
T& front(const unsigned int ch);
T& back(const unsigned int ch);
void push_back(const unsigned int ch, const T& new_data);
T pop_front(const unsigned int ch);
void clear(const unsigned int ch);
T* get_vector(const unsigned int ch);
private:
T** d_history;
T d_return_void; // Void object for avoid compiler errors
unsigned int* d_index_pop;
unsigned int* d_index_push;
unsigned int* d_size;
unsigned int d_max_size;
unsigned int d_nchannels;
};
template <class T>
Gnss_circular_deque<T>::Gnss_circular_deque()
{
d_max_size = 0;
d_nchannels = 0;
d_size = nullptr;
d_index_pop = nullptr;
d_index_push = nullptr;
d_history = nullptr;
}
template <class T>
Gnss_circular_deque<T>::Gnss_circular_deque(const unsigned int max_size, const unsigned int nchann)
{
d_max_size = max_size;
d_nchannels = nchann;
if (d_max_size > 0 and d_nchannels > 0)
{
d_size = new unsigned int[d_nchannels];
d_index_pop = new unsigned int[d_nchannels];
d_index_push = new unsigned int[d_nchannels];
d_history = new T*[d_nchannels];
for (unsigned int i = 0; i < d_nchannels; i++)
{
d_size[i] = 0;
d_index_pop[i] = 0;
d_index_push[i] = 0;
d_history[i] = new T[d_max_size];
}
}
}
template <class T>
Gnss_circular_deque<T>::~Gnss_circular_deque()
{
if (d_max_size > 0 and d_nchannels > 0)
{
delete[] d_size;
delete[] d_index_pop;
delete[] d_index_push;
for (unsigned int i = 0; i < d_nchannels; i++)
{
delete[] d_history[i];
}
delete[] d_history;
}
}
template <class T>
unsigned int Gnss_circular_deque<T>::size(const unsigned int ch)
{
return d_size[ch];
}
template <class T>
T& Gnss_circular_deque<T>::back(const unsigned int ch)
{
if (d_size[ch] > 0)
{
unsigned int index = 0;
if (d_index_push[ch] > 0)
{
index = d_index_push[ch] - 1;
}
else
{
index = d_max_size;
}
return d_history[ch][index];
}
else
{
return d_return_void;
}
}
template <class T>
T& Gnss_circular_deque<T>::front(const unsigned int ch)
{
if (d_size[ch] > 0)
{
return d_history[ch][d_index_pop[ch]];
}
else
{
return d_return_void;
}
}
template <class T>
T& Gnss_circular_deque<T>::at(const unsigned int ch, const unsigned int pos)
{
if (d_size[ch] > 0 and pos < d_size[ch])
{
unsigned int index = (d_index_pop[ch] + pos) % d_max_size;
return d_history[ch][index];
}
else
{
return d_return_void;
}
}
template <class T>
void Gnss_circular_deque<T>::clear(const unsigned int ch)
{
d_size[ch] = 0;
d_index_pop[ch] = 0;
d_index_push[ch] = 0;
}
template <class T>
T Gnss_circular_deque<T>::pop_front(const unsigned int ch)
{
T result;
if (d_size[ch] > 0)
{
d_size[ch]--;
result = d_history[ch][d_index_pop[ch]];
d_index_pop[ch]++;
d_index_pop[ch] %= d_max_size;
}
return result;
}
template <class T>
void Gnss_circular_deque<T>::push_back(const unsigned int ch, const T& new_data)
{
d_history[ch][d_index_push[ch]] = new_data;
d_index_push[ch]++;
d_index_push[ch] %= d_max_size;
if (d_size[ch] < d_max_size)
{
d_size[ch]++;
}
else
{
d_index_pop[ch]++;
d_index_pop[ch] %= d_max_size;
}
}
template <class T>
T* Gnss_circular_deque<T>::get_vector(const unsigned int ch)
{
return d_history[ch];
}
#endif /* GNSS_SDR_CIRCULAR_DEQUE_H_ */

1
src/algorithms/observables/adapters/CMakeLists.txt
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@ -26,6 +26,7 @@ include_directories(
${CMAKE_SOURCE_DIR}/src/core/interfaces
${CMAKE_SOURCE_DIR}/src/core/receiver
${CMAKE_SOURCE_DIR}/src/algorithms/observables/gnuradio_blocks
${CMAKE_SOURCE_DIR}/src/algorithms/libs
${CMAKE_SOURCE_DIR}/src/algorithms/PVT/libs
${GLOG_INCLUDE_DIRS}
${GFlags_INCLUDE_DIRS}

6
src/algorithms/observables/gnuradio_blocks/CMakeLists.txt
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@ -39,8 +39,8 @@ list(SORT OBS_GR_BLOCKS_HEADERS)
add_library(obs_gr_blocks ${OBS_GR_BLOCKS_SOURCES} ${OBS_GR_BLOCKS_HEADERS})
source_group(Headers FILES ${OBS_GR_BLOCKS_HEADERS})
if(MATIO_FOUND)
add_dependencies(obs_gr_blocks glog-${glog_RELEASE} armadillo-${armadillo_RELEASE})
add_dependencies(obs_gr_blocks gnss_sp_libs glog-${glog_RELEASE} armadillo-${armadillo_RELEASE})
else(MATIO_FOUND)
add_dependencies(obs_gr_blocks glog-${glog_RELEASE} armadillo-${armadillo_RELEASE} matio-${GNSSSDR_MATIO_LOCAL_VERSION})
add_dependencies(obs_gr_blocks gnss_sp_libs glog-${glog_RELEASE} armadillo-${armadillo_RELEASE} matio-${GNSSSDR_MATIO_LOCAL_VERSION})
endif(MATIO_FOUND)
target_link_libraries(obs_gr_blocks ${GNURADIO_RUNTIME_LIBRARIES} ${ARMADILLO_LIBRARIES} ${MATIO_LIBRARIES})
target_link_libraries(obs_gr_blocks gnss_sp_libs ${GNURADIO_RUNTIME_LIBRARIES} ${ARMADILLO_LIBRARIES} ${MATIO_LIBRARIES})

122
src/algorithms/observables/gnuradio_blocks/hybrid_observables_cc.cc
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@ -66,11 +66,7 @@ hybrid_observables_cc::hybrid_observables_cc(unsigned int nchannels_in,
max_delta = 0.15; // 150 ms
valid_channels.resize(d_nchannels, false);
d_num_valid_channels = 0;
for (unsigned int i = 0; i < d_nchannels; i++)
{
d_gnss_synchro_history.push_back(std::deque<Gnss_Synchro>());
}
d_gnss_synchro_history = Gnss_circular_deque<Gnss_Synchro>(200, d_nchannels);
// ############# ENABLE DATA FILE LOG #################
if (d_dump)
@ -302,15 +298,37 @@ int hybrid_observables_cc::save_matfile()
}
bool hybrid_observables_cc::interpolate_data(Gnss_Synchro &out, std::deque<Gnss_Synchro> &data, const double &ti)
bool hybrid_observables_cc::interpolate_data(Gnss_Synchro &out, const unsigned int &ch, const double &ti)
{
if ((ti < data.front().RX_time) or (ti > data.back().RX_time))
if ((ti < d_gnss_synchro_history.front(ch).RX_time) or (ti > d_gnss_synchro_history.back(ch).RX_time))
{
return false;
}
std::deque<Gnss_Synchro>::iterator it;
std::pair<unsigned int, unsigned int> ind = find_interp_elements(ch, ti);
arma::vec t = arma::vec(data.size());
double m = 0.0;
double c = 0.0;
// CARRIER PHASE INTERPOLATION
m = (d_gnss_synchro_history.at(ch, ind.first).Carrier_phase_rads - d_gnss_synchro_history.at(ch, ind.second).Carrier_phase_rads) / (d_gnss_synchro_history.at(ch, ind.first).RX_time - d_gnss_synchro_history.at(ch, ind.second).RX_time);
c = d_gnss_synchro_history.at(ch, ind.first).Carrier_phase_rads - m * d_gnss_synchro_history.at(ch, ind.first).RX_time;
out.Carrier_phase_rads = m * ti + c;
// CARRIER DOPPLER INTERPOLATION
m = (d_gnss_synchro_history.at(ch, ind.first).Carrier_Doppler_hz - d_gnss_synchro_history.at(ch, ind.second).Carrier_Doppler_hz) / (d_gnss_synchro_history.at(ch, ind.first).RX_time - d_gnss_synchro_history.at(ch, ind.second).RX_time);
c = d_gnss_synchro_history.at(ch, ind.first).Carrier_Doppler_hz - m * d_gnss_synchro_history.at(ch, ind.first).RX_time;
out.Carrier_Doppler_hz = m * ti + c;
// TOW INTERPOLATION
m = (d_gnss_synchro_history.at(ch, ind.first).TOW_at_current_symbol_s - d_gnss_synchro_history.at(ch, ind.second).TOW_at_current_symbol_s) / (d_gnss_synchro_history.at(ch, ind.first).RX_time - d_gnss_synchro_history.at(ch, ind.second).RX_time);
c = d_gnss_synchro_history.at(ch, ind.first).TOW_at_current_symbol_s - m * d_gnss_synchro_history.at(ch, ind.first).RX_time;
out.TOW_at_current_symbol_s = m * ti + c;
return true;
/*
arma::vec t = arma::vec(d_gnss_synchro_history.size(ch));
arma::vec dop = t;
arma::vec cph = t;
arma::vec tow = t;
@ -336,6 +354,7 @@ bool hybrid_observables_cc::interpolate_data(Gnss_Synchro &out, std::deque<Gnss_
out.TOW_at_current_symbol_s = result(0);
return result.is_finite();
*/
}
@ -351,6 +370,48 @@ double hybrid_observables_cc::compute_T_rx_s(const Gnss_Synchro &a)
}
}
std::pair<unsigned int, unsigned int> hybrid_observables_cc::find_interp_elements(const unsigned int &ch, const double &ti)
{
unsigned int closest = 0;
double dif = std::numeric_limits<double>::max();
double dt = 0.0;
for (unsigned int i = 0; i < d_gnss_synchro_history.size(ch); i++)
{
dt = std::fabs(ti - d_gnss_synchro_history.at(ch, i).RX_time);
if (dt < dif)
{
dif = dt;
closest = i;
}
}
unsigned int index1;
unsigned int index2;
if (closest == 0)
{
index1 = 0;
index2 = 1;
}
else if (closest == (d_gnss_synchro_history.size(ch) - 1))
{
index1 = d_gnss_synchro_history.size(ch) - 2;
index2 = d_gnss_synchro_history.size(ch) - 1;
}
else
{
if (d_gnss_synchro_history.at(ch, closest).RX_time < ti)
{
index1 = closest;
index2 = closest + 1;
}
else
{
index1 = closest - 1;
index2 = closest;
}
}
return std::pair<unsigned int, unsigned int>(index1, index2);
}
void hybrid_observables_cc::forecast(int noutput_items __attribute__((unused)),
gr_vector_int &ninput_items_required)
@ -363,13 +424,13 @@ void hybrid_observables_cc::forecast(int noutput_items __attribute__((unused)),
}
void hybrid_observables_cc::clean_history(std::deque<Gnss_Synchro> &data)
void hybrid_observables_cc::clean_history(Gnss_circular_deque<Gnss_Synchro> &data, unsigned int pos)
{
while (data.size() > 0)
while (data.size(pos) > 0)
{
if ((T_rx_s - data.front().RX_time) > max_delta)
if ((T_rx_s - data.front(pos).RX_time) > max_delta)
{
data.pop_front();
data.pop_front(pos);
}
else
{
@ -454,11 +515,9 @@ int hybrid_observables_cc::general_work(int noutput_items __attribute__((unused)
}
//////////////////////////////////////////////////////////////////////////
std::vector<std::deque<Gnss_Synchro>>::iterator it;
if (total_input_items > 0)
{
i = 0;
for (it = d_gnss_synchro_history.begin(); it != d_gnss_synchro_history.end(); it++)
for (unsigned int i = 0; i < d_nchannels; i++)
{
if (ninput_items[i] > 0)
{
@ -467,26 +526,25 @@ int hybrid_observables_cc::general_work(int noutput_items __attribute__((unused)
{
if (in[i][aux].Flag_valid_word)
{
it->push_back(in[i][aux]);
it->back().RX_time = compute_T_rx_s(in[i][aux]);
d_gnss_synchro_history.push_back(i, in[i][aux]);
d_gnss_synchro_history.back(i).RX_time = compute_T_rx_s(in[i][aux]);
// Check if the last Gnss_Synchro comes from the same satellite as the previous ones
if (it->size() > 1)
if (d_gnss_synchro_history.size(i) > 1)
{
if (it->front().PRN != it->back().PRN)
if (d_gnss_synchro_history.front(i).PRN != d_gnss_synchro_history.back(i).PRN)
{
it->clear();
d_gnss_synchro_history.clear(i);
}
}
}
}
consume(i, ninput_items[i]);
}
i++;
}
}
for (i = 0; i < d_nchannels; i++)
{
if (d_gnss_synchro_history.at(i).size() > 2)
if (d_gnss_synchro_history.size(i) > 2)
{
valid_channels[i] = true;
}
@ -506,8 +564,8 @@ int hybrid_observables_cc::general_work(int noutput_items __attribute__((unused)
{
if (valid_channels[i])
{
clean_history(d_gnss_synchro_history.at(i));
if (d_gnss_synchro_history.at(i).size() < 2)
clean_history(d_gnss_synchro_history, i);
if (d_gnss_synchro_history.size(i) < 2)
{
valid_channels[i] = false;
}
@ -523,13 +581,12 @@ int hybrid_observables_cc::general_work(int noutput_items __attribute__((unused)
}
std::vector<Gnss_Synchro> epoch_data;
i = 0;
for (it = d_gnss_synchro_history.begin(); it != d_gnss_synchro_history.end(); it++)
for (unsigned int i = 0; i < d_nchannels; i++)
{
if (valid_channels[i])
{
Gnss_Synchro interpolated_gnss_synchro = it->back();
if (interpolate_data(interpolated_gnss_synchro, *it, T_rx_s_out))
Gnss_Synchro interpolated_gnss_synchro = d_gnss_synchro_history.back(i);
if (interpolate_data(interpolated_gnss_synchro, i, T_rx_s_out))
{
epoch_data.push_back(interpolated_gnss_synchro);
}
@ -538,7 +595,6 @@ int hybrid_observables_cc::general_work(int noutput_items __attribute__((unused)
valid_channels[i] = false;
}
}
i++;
}
d_num_valid_channels = valid_channels.count();
if (d_num_valid_channels == 0)
@ -546,14 +602,14 @@ int hybrid_observables_cc::general_work(int noutput_items __attribute__((unused)
return 0;
}
correct_TOW_and_compute_prange(epoch_data);
std::vector<Gnss_Synchro>::iterator it2 = epoch_data.begin();
std::vector<Gnss_Synchro>::iterator it = epoch_data.begin();
for (i = 0; i < d_nchannels; i++)
{
if (valid_channels[i])
{
out[i][0] = (*it2);
out[i][0] = (*it);
out[i][0].Flag_valid_pseudorange = true;
it2++;
it++;
}
else
{

11
src/algorithms/observables/gnuradio_blocks/hybrid_observables_cc.h
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@ -35,12 +35,12 @@
#define GNSS_SDR_HYBRID_OBSERVABLES_CC_H
#include "gnss_synchro.h"
#include "gnss_circular_deque.h"
#include <gnuradio/block.h>
#include <boost/dynamic_bitset.hpp>
#include <fstream>
#include <string>
#include <vector>
#include <deque>
#include <utility>
class hybrid_observables_cc;
@ -65,14 +65,15 @@ private:
friend hybrid_observables_cc_sptr
hybrid_make_observables_cc(unsigned int nchannels_in, unsigned int nchannels_out, bool dump, std::string dump_filename);
hybrid_observables_cc(unsigned int nchannels_in, unsigned int nchannels_out, bool dump, std::string dump_filename);
void clean_history(std::deque<Gnss_Synchro>& data);
void clean_history(Gnss_circular_deque<Gnss_Synchro>& data, unsigned int pos);
double compute_T_rx_s(const Gnss_Synchro& a);
bool interpolate_data(Gnss_Synchro& out, std::deque<Gnss_Synchro>& data, const double& ti);
bool interpolate_data(Gnss_Synchro& out, const unsigned int& ch, const double& ti);
std::pair<unsigned int, unsigned int> find_interp_elements(const unsigned int& ch, const double& ti);
void correct_TOW_and_compute_prange(std::vector<Gnss_Synchro>& data);
int save_matfile();
//Tracking observable history
std::vector<std::deque<Gnss_Synchro>> d_gnss_synchro_history;
Gnss_circular_deque<Gnss_Synchro> d_gnss_synchro_history;
boost::dynamic_bitset<> valid_channels;
double T_rx_s;
double T_rx_step_s;