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Bug correction for acquisition and tracking: acquisition Doppler sign were inverted and this issue caused several wrong interpretations in tracking algorithms, resulting in a swap in I/Q components. Now the bug was corrected in all tracking algorithms.

Browse Source 
git-svn-id: https://svn.code.sf.net/p/gnss-sdr/code/trunk@249 64b25241-fba3-4117-9849-534c7e92360d
This commit is contained in:
Javier Arribas
2012-10-18 10:24:41 +00:00
parent 4859faa245
commit a25e712be6
13 changed files with 94 additions and 80 deletions
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2
src/algorithms/acquisition/gnuradio_blocks/pcps_acquisition_cc.cc
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@@ -198,7 +198,7 @@ int pcps_acquisition_cc::general_work(int noutput_items,
{
//doppler search steps
//Perform the carrier wipe-off
complex_exp_gen(d_carrier, d_freq + doppler, d_fs_in, d_fft_size);
complex_exp_gen_conj(d_carrier, d_freq + doppler, d_fs_in, d_fft_size);
if (is_unaligned()==true)
{

26
src/algorithms/libs/gnss_signal_processing.cc
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@@ -61,6 +61,32 @@ void complex_exp_gen(std::complex<float>* _dest, double _f, double _fs, unsigned
}
}
void complex_exp_gen_conj(std::complex<float>* _dest, double _f, double _fs, unsigned int _samps)
{
//old
//double phase = 0;
//const double phase_step = (GPS_TWO_PI * _f) / _fs;
//new Fixed Point NCO (faster)
int phase_i=0;
int phase_step_i;
float phase_step_f =(float)((GPS_TWO_PI * _f) / _fs);
phase_step_i=gr_fxpt::float_to_fixed(phase_step_f);
float sin_f,cos_f;
for(unsigned int i = 0; i < _samps; i++)
{
//old
//_dest[i] = std::complex<float>(cos(phase), sin(phase));
//phase += phase_step;
//new Fixed Point NCO (faster)
gr_fxpt::sincos(phase_i,&sin_f,&cos_f);
_dest[i] = std::complex<float>(cos_f, -sin_f);
phase_i += phase_step_i;
}
}
void hex_to_binary_converter(int * _dest, char _from)
{

8
src/algorithms/libs/gnss_signal_processing.h
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@@ -46,6 +46,14 @@
void complex_exp_gen(std::complex<float>* _dest, double _f, double _fs,
unsigned int _samps);
/*!
* \brief This function generates a conjugate complex exponential in _dest.
*
*/
void complex_exp_gen_conj(std::complex<float>* _dest, double _f, double _fs,
unsigned int _samps);
/*!
* \brief This function makes a conversion from hex (the input is a char)
* to binary (the output are 4 ints with +1 or -1 values).

10
src/algorithms/tracking/gnuradio_blocks/galileo_e1_dll_pll_veml_tracking_cc.cc
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@@ -286,7 +286,7 @@ void galileo_e1_dll_pll_veml_tracking_cc::update_local_carrier()
phase_rad = d_rem_carr_phase_rad;
for(int i = 0; i < d_current_prn_length_samples; i++)
{
d_carr_sign[i] = gr_complex(cos(phase_rad), sin(phase_rad));
d_carr_sign[i] = gr_complex(cos(phase_rad), -sin(phase_rad));
phase_rad += phase_step_rad;
}
d_rem_carr_phase_rad = fmod(phase_rad, GPS_TWO_PI);
@@ -460,8 +460,8 @@ int galileo_e1_dll_pll_veml_tracking_cc::general_work (int noutput_items,gr_vect
// ########### Output the tracking results to Telemetry block ##########
current_synchro_data.Prompt_I = (double)(*d_Prompt).imag(); // ???????
current_synchro_data.Prompt_Q = (double)(*d_Prompt).real(); // ???????
current_synchro_data.Prompt_I = (double)(*d_Prompt).real();
current_synchro_data.Prompt_Q = (double)(*d_Prompt).imag();
// Tracking_timestamp_secs is aligned with the PRN start sample
current_synchro_data.Tracking_timestamp_secs = ((double)d_sample_counter +
(double)d_next_prn_length_samples + (double)d_next_rem_code_phase_samples) / (double)d_fs_in;
@@ -517,8 +517,8 @@ int galileo_e1_dll_pll_veml_tracking_cc::general_work (int noutput_items,gr_vect
float tmp_VE, tmp_E, tmp_P, tmp_L, tmp_VL;
float tmp_float;
double tmp_double;
prompt_I = (*d_Prompt).imag();
prompt_Q = (*d_Prompt).real();
prompt_I = (*d_Prompt).real();
prompt_Q = (*d_Prompt).imag();
tmp_VE = std::abs<float>(*d_Very_Early);
tmp_E = std::abs<float>(*d_Early);
tmp_P = std::abs<float>(*d_Prompt);

21
src/algorithms/tracking/gnuradio_blocks/gps_l1_ca_dll_fll_pll_tracking_cc.cc
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@@ -310,7 +310,7 @@ void Gps_L1_Ca_Dll_Fll_Pll_Tracking_cc::update_local_carrier()
phase = d_rem_carr_phase;
for(int i = 0; i < d_current_prn_length_samples; i++)
{
d_carr_sign[i] = gr_complex(cos(phase), sin(phase));
d_carr_sign[i] = gr_complex(cos(phase), -sin(phase));
phase += phase_step;
}
d_rem_carr_phase = fmod(phase, GPS_TWO_PI);
@@ -319,8 +319,6 @@ void Gps_L1_Ca_Dll_Fll_Pll_Tracking_cc::update_local_carrier()
Gps_L1_Ca_Dll_Fll_Pll_Tracking_cc::~Gps_L1_Ca_Dll_Fll_Pll_Tracking_cc()
{
d_dump_file.close();
@@ -452,19 +450,12 @@ int Gps_L1_Ca_Dll_Fll_Pll_Tracking_cc::general_work (int noutput_items, gr_vecto
// Compute PLL error
PLL_discriminator_hz = pll_cloop_two_quadrant_atan(*d_Prompt) / GPS_TWO_PI;
/*
* \todo Update FLL assistance algorithm!
*/
if ((((double)d_sample_counter - (double)d_acq_sample_stamp) / d_fs_in) > 3)
{
d_FLL_discriminator_hz = 0; //disconnect the FLL after the initial lock
}
/*
* DLL and FLL+PLL filter and get current carrier Doppler and code frequency
*/
carr_nco_hz = d_carrier_loop_filter.get_carrier_error(d_FLL_discriminator_hz, PLL_discriminator_hz, correlation_time_s);
d_carrier_doppler_hz = d_if_freq + carr_nco_hz;
d_code_freq_hz = GPS_L1_CA_CODE_RATE_HZ - (((d_carrier_doppler_hz - d_if_freq) * GPS_L1_CA_CODE_RATE_HZ) / GPS_L1_FREQ_HZ) - code_error_chips;
d_code_freq_hz = GPS_L1_CA_CODE_RATE_HZ + (((d_carrier_doppler_hz + d_if_freq) * GPS_L1_CA_CODE_RATE_HZ) / GPS_L1_FREQ_HZ) - code_error_chips;
/*!
* \todo Improve the lock detection algorithm!
@@ -539,8 +530,8 @@ int Gps_L1_Ca_Dll_Fll_Pll_Tracking_cc::general_work (int noutput_items, gr_vecto
d_rem_code_phase_samples = K_blk_samples - d_current_prn_length_samples; //rounding error
// ########### Output the tracking data to navigation and PVT ##########
current_synchro_data.Prompt_I=(double)(*d_Prompt).imag();
current_synchro_data.Prompt_Q=(double)(*d_Prompt).real();
current_synchro_data.Prompt_I=(double)(*d_Prompt).real();
current_synchro_data.Prompt_Q=(double)(*d_Prompt).imag();
// Tracking_timestamp_secs is aligned with the PRN start sample
current_synchro_data.Tracking_timestamp_secs=((double)d_sample_counter+(double)d_current_prn_length_samples+d_rem_code_phase_samples)/d_fs_in;
// This tracking block aligns the Tracking_timestamp_secs with the start sample of the PRN, Code_phase_secs=0
@@ -568,8 +559,8 @@ int Gps_L1_Ca_Dll_Fll_Pll_Tracking_cc::general_work (int noutput_items, gr_vecto
float tmp_E, tmp_P, tmp_L;
float tmp_float;
double tmp_double;
prompt_I = (*d_Prompt).imag();
prompt_Q = (*d_Prompt).real();
prompt_I = (*d_Prompt).real();
prompt_Q = (*d_Prompt).imag();
tmp_E=std::abs<float>(*d_Early);
tmp_P=std::abs<float>(*d_Prompt);
tmp_L=std::abs<float>(*d_Late);

17
src/algorithms/tracking/gnuradio_blocks/gps_l1_ca_dll_pll_optim_tracking_cc.cc
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@@ -82,7 +82,7 @@ gps_l1_ca_dll_pll_make_optim_tracking_cc(
void Gps_L1_Ca_Dll_Pll_Optim_Tracking_cc::forecast (int noutput_items,
gr_vector_int &ninput_items_required)
{
ninput_items_required[0] = (int)d_vector_length*2; //set the required available samples in each call
ninput_items_required[0] = d_gnuradio_forecast_samples ; //set the required available samples in each call
}
@@ -109,6 +109,7 @@ Gps_L1_Ca_Dll_Pll_Optim_Tracking_cc::Gps_L1_Ca_Dll_Pll_Optim_Tracking_cc(
d_if_freq = if_freq;
d_fs_in = fs_in;
d_vector_length = vector_length;
d_gnuradio_forecast_samples=(int)d_vector_length*2;
d_dump_filename = dump_filename;
// Initialize tracking ==========================================
@@ -339,14 +340,14 @@ void Gps_L1_Ca_Dll_Pll_Optim_Tracking_cc::update_local_carrier()
{
//using temp variables
gr_fxpt::sincos(phase_rad_i,&sin_f,&cos_f);
d_carr_sign[i] = gr_complex(cos_f, sin_f);
d_carr_sign[i] = gr_complex(cos_f, -sin_f);
//using references (may be it can be a problem for c++11 standard
//gr_fxpt::sincos(phase_rad_i,&d_carr_sign[i].imag(),&d_carr_sign[i].real());
phase_rad_i += phase_step_rad_i;
// Using std::cos and std::sin
//d_carr_sign[i] = gr_complex(cos(phase_rad), sin(phase_rad));
//d_carr_sign[i] = gr_complex(cos(phase_rad), -sin(phase_rad));
}
d_rem_carr_phase_rad = fmod(gr_fxpt::fixed_to_float(phase_rad_i), GPS_TWO_PI);
@@ -425,7 +426,7 @@ int Gps_L1_Ca_Dll_Pll_Optim_Tracking_cc::general_work (int noutput_items, gr_vec
// variable code PRN sample block size
d_current_prn_length_samples = d_next_prn_length_samples;
//update_local_code();
update_local_code();
update_local_carrier();
// perform Early, Prompt and Late correlation
@@ -535,8 +536,8 @@ int Gps_L1_Ca_Dll_Pll_Optim_Tracking_cc::general_work (int noutput_items, gr_vec
// ########### Output the tracking data to navigation and PVT ##########
current_synchro_data.Prompt_I = (double)(*d_Prompt).imag();
current_synchro_data.Prompt_Q = (double)(*d_Prompt).real();
current_synchro_data.Prompt_I = (double)(*d_Prompt).real();
current_synchro_data.Prompt_Q = (double)(*d_Prompt).imag();
// Tracking_timestamp_secs is aligned with the PRN start sample
current_synchro_data.Tracking_timestamp_secs=((double)d_sample_counter+(double)d_next_prn_length_samples+(double)d_next_rem_code_phase_samples)/(double)d_fs_in;
// This tracking block aligns the Tracking_timestamp_secs with the start sample of the PRN, thus, Code_phase_secs=0
@@ -593,8 +594,8 @@ int Gps_L1_Ca_Dll_Pll_Optim_Tracking_cc::general_work (int noutput_items, gr_vec
float tmp_E, tmp_P, tmp_L;
float tmp_float;
double tmp_double;
prompt_I = (*d_Prompt).imag();
prompt_Q = (*d_Prompt).real();
prompt_I = (*d_Prompt).real();
prompt_Q = (*d_Prompt).imag();
tmp_E = std::abs<float>(*d_Early);
tmp_P = std::abs<float>(*d_Prompt);
tmp_L = std::abs<float>(*d_Late);

2
src/algorithms/tracking/gnuradio_blocks/gps_l1_ca_dll_pll_optim_tracking_cc.h
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@@ -135,7 +135,6 @@ private:
long d_fs_in;
double d_early_late_spc_chips;
double d_code_phase_step_chips;
gr_complex* d_ca_code;
@@ -190,6 +189,7 @@ private:
// control vars
bool d_enable_tracking;
bool d_pull_in;
int d_gnuradio_forecast_samples;
// file dump
std::string d_dump_filename;

10
src/algorithms/tracking/gnuradio_blocks/gps_l1_ca_dll_pll_tracking_cc.cc
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@@ -307,7 +307,7 @@ void Gps_L1_Ca_Dll_Pll_Tracking_cc::update_local_carrier()
phase_rad = d_rem_carr_phase_rad;
for(int i = 0; i < d_current_prn_length_samples; i++)
{
d_carr_sign[i] = gr_complex(cos(phase_rad), sin(phase_rad));
d_carr_sign[i] = gr_complex(cos(phase_rad), -sin(phase_rad));
phase_rad += phase_step_rad;
}
d_rem_carr_phase_rad = fmod(phase_rad, GPS_TWO_PI);
@@ -496,8 +496,8 @@ int Gps_L1_Ca_Dll_Pll_Tracking_cc::general_work (int noutput_items, gr_vector_in
// ########### Output the tracking data to navigation and PVT ##########
current_synchro_data.Prompt_I = (double)(*d_Prompt).imag();
current_synchro_data.Prompt_Q = (double)(*d_Prompt).real();
current_synchro_data.Prompt_I = (double)(*d_Prompt).real();
current_synchro_data.Prompt_Q = (double)(*d_Prompt).imag();
// Tracking_timestamp_secs is aligned with the PRN start sample
current_synchro_data.Tracking_timestamp_secs=((double)d_sample_counter+(double)d_next_prn_length_samples+(double)d_next_rem_code_phase_samples)/(double)d_fs_in;
// This tracking block aligns the Tracking_timestamp_secs with the start sample of the PRN, thus, Code_phase_secs=0
@@ -554,8 +554,8 @@ int Gps_L1_Ca_Dll_Pll_Tracking_cc::general_work (int noutput_items, gr_vector_in
float tmp_E, tmp_P, tmp_L;
float tmp_float;
double tmp_double;
prompt_I = (*d_Prompt).imag();
prompt_Q = (*d_Prompt).real();
prompt_I = (*d_Prompt).real();
prompt_Q = (*d_Prompt).imag();
tmp_E = std::abs<float>(*d_Early);
tmp_P = std::abs<float>(*d_Prompt);
tmp_L = std::abs<float>(*d_Late);

16
src/algorithms/tracking/gnuradio_blocks/gps_l1_ca_tcp_connector_tracking_cc.cc
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@@ -310,10 +310,6 @@ void Gps_L1_Ca_Tcp_Connector_Tracking_cc::update_local_code()
{
associated_chip_index = 1 + round(fmod(tcode_chips - d_early_late_spc_chips, code_length_chips));
d_early_code[i] = d_ca_code[associated_chip_index];
//associated_chip_index = 1 + round(fmod(tcode_chips, code_length_chips));
//d_prompt_code[i] = d_ca_code[associated_chip_index];
//associated_chip_index = 1 + round(fmod(tcode_chips+d_early_late_spc_chips, code_length_chips));
//d_late_code[i] = d_ca_code[associated_chip_index];
tcode_chips = tcode_chips + d_code_phase_step_chips;
}
@@ -332,7 +328,7 @@ void Gps_L1_Ca_Tcp_Connector_Tracking_cc::update_local_carrier()
phase_rad = d_rem_carr_phase_rad;
for(int i = 0; i < d_current_prn_length_samples; i++)
{
d_carr_sign[i] = gr_complex(cos(phase_rad), sin(phase_rad));
d_carr_sign[i] = gr_complex(cos(phase_rad), -sin(phase_rad));
phase_rad += phase_step_rad;
}
d_rem_carr_phase_rad = fmod(phase_rad, GPS_TWO_PI);
@@ -466,7 +462,7 @@ int Gps_L1_Ca_Tcp_Connector_Tracking_cc::general_work (int noutput_items, gr_vec
d_control_id++;
//! Send and receive a TCP packet
boost::array<float, NUM_TX_VARIABLES> tx_variables_array = {{d_control_id,(*d_Early).imag(),(*d_Early).real(),(*d_Late).imag(),(*d_Late).real(),(*d_Prompt).imag(),(*d_Prompt).real(),d_acq_carrier_doppler_hz,1}};
boost::array<float, NUM_TX_VARIABLES> tx_variables_array = {{d_control_id,(*d_Early).real(),(*d_Early).imag(),(*d_Late).real(),(*d_Late).imag(),(*d_Prompt).real(),(*d_Prompt).imag(),d_acq_carrier_doppler_hz,1}};
d_tcp_com.send_receive_tcp_packet(tx_variables_array, &tcp_data);
//! Recover the tracking data
@@ -545,8 +541,8 @@ int Gps_L1_Ca_Tcp_Connector_Tracking_cc::general_work (int noutput_items, gr_vec
// ########### Output the tracking data to navigation and PVT ##########
current_synchro_data.Prompt_I = (double)(*d_Prompt).imag();
current_synchro_data.Prompt_Q = (double)(*d_Prompt).real();
current_synchro_data.Prompt_I = (double)(*d_Prompt).real();
current_synchro_data.Prompt_Q = (double)(*d_Prompt).imag();
current_synchro_data.Tracking_timestamp_secs = d_sample_counter_seconds;
current_synchro_data.Carrier_phase_rads = (double)d_acc_carrier_phase_rad;
current_synchro_data.Code_phase_secs = (double)d_code_phase_samples * (1/(float)d_fs_in);
@@ -600,8 +596,8 @@ int Gps_L1_Ca_Tcp_Connector_Tracking_cc::general_work (int noutput_items, gr_vec
float prompt_Q;
float tmp_E, tmp_P, tmp_L;
float tmp_float;
prompt_I = (*d_Prompt).imag();
prompt_Q = (*d_Prompt).real();
prompt_I = (*d_Prompt).real();
prompt_Q = (*d_Prompt).imag();
tmp_E = std::abs<float>(*d_Early);
tmp_P = std::abs<float>(*d_Prompt);
tmp_L = std::abs<float>(*d_Late);

29
src/algorithms/tracking/libs/CN_estimators.cc
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@@ -72,19 +72,17 @@ float gps_l1_ca_CN0_SNV(gr_complex* Prompt_buffer, int length, long fs_in)
{
// estimate CN0 using buffered values
// MATLAB CODE
// Psig=((1/N)*sum(abs(imag(x((n-N+1):n)))))^2;
// Ptot=(1/N)*sum(abs(x((n-N+1):n)).^2);
// SNR_SNV(count)=Psig/(Ptot-Psig);
// CN0_SNV_dB=10*log10(SNR_SNV)+10*log10(BW)-10*log10(PRN_length);
float SNR, SNR_dB_Hz;
float tmp_abs_imag;
float tmp_abs_real;
float Psig, Ptot;
Psig = 0;
Ptot = 0;
for (int i=0; i<length; i++)
{
tmp_abs_imag = std::abs(Prompt_buffer[i].imag());
Psig += tmp_abs_imag;
tmp_abs_real = std::abs(Prompt_buffer[i].real());
Psig += tmp_abs_real;
Ptot += Prompt_buffer[i].imag() * Prompt_buffer[i].imag() + Prompt_buffer[i].real() * Prompt_buffer[i].real();
}
Psig = Psig / (float)length;
@@ -114,19 +112,17 @@ float galileo_e1_CN0_SNV(gr_complex* Prompt_buffer, int length, long fs_in)
{
// estimate CN0 using buffered values
// MATLAB CODE
// Psig=((1/N)*sum(abs(imag(x((n-N+1):n)))))^2;
// Ptot=(1/N)*sum(abs(x((n-N+1):n)).^2);
// SNR_SNV(count)=Psig/(Ptot-Psig);
// CN0_SNV_dB=10*log10(SNR_SNV)+10*log10(BW)-10*log10(PRN_length);
float SNR, SNR_dB_Hz;
float tmp_abs_imag;
float tmp_abs_real;
float Psig, Ptot;
Psig = 0;
Ptot = 0;
for (int i=0; i<length; i++)
{
tmp_abs_imag = std::abs(Prompt_buffer[i].imag());
Psig += tmp_abs_imag;
tmp_abs_real= std::abs(Prompt_buffer[i].real());
Psig += tmp_abs_real;
Ptot += Prompt_buffer[i].imag() * Prompt_buffer[i].imag() + Prompt_buffer[i].real() * Prompt_buffer[i].real();
}
Psig = Psig / (float)length;
@@ -150,11 +146,6 @@ float carrier_lock_detector(gr_complex* Prompt_buffer, int length)
* Code lock detector
*/
// estimate using buffered values
// MATLAB CODE
// lock detector operation
// NBD=sum(abs(imag(x((n-N+1):n))))^2 + sum(abs(real(x((n-N+1):n))))^2;
// NBP=sum(imag(x((n-N+1):n)).^2) - sum(real(x((n-N+1):n)).^2);
// LOCK(count)=NBD/NBP;
float tmp_abs_I, tmp_abs_Q;
float tmp_sum_abs_I, tmp_sum_abs_Q;
float tmp_sum_sqr_I, tmp_sum_sqr_Q;
@@ -165,12 +156,12 @@ float carrier_lock_detector(gr_complex* Prompt_buffer, int length)
float NBD,NBP;
for (int i=0; i<length; i++)
{
tmp_abs_I = std::abs(Prompt_buffer[i].imag());
tmp_abs_Q = std::abs(Prompt_buffer[i].real());
tmp_abs_I = std::abs(Prompt_buffer[i].real());
tmp_abs_Q = std::abs(Prompt_buffer[i].imag());
tmp_sum_abs_I += tmp_abs_I;
tmp_sum_abs_Q += tmp_abs_Q;
tmp_sum_sqr_I += (Prompt_buffer[i].imag() * Prompt_buffer[i].imag());
tmp_sum_sqr_Q += (Prompt_buffer[i].real() * Prompt_buffer[i].real());
tmp_sum_sqr_I += (Prompt_buffer[i].real() * Prompt_buffer[i].real());
tmp_sum_sqr_Q += (Prompt_buffer[i].imag() * Prompt_buffer[i].imag());
}
NBD = tmp_sum_abs_I * tmp_sum_abs_I + tmp_sum_abs_Q * tmp_sum_abs_Q;
NBP = tmp_sum_sqr_I - tmp_sum_sqr_Q;

21
src/algorithms/tracking/libs/correlator.cc
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@@ -74,7 +74,7 @@ void Correlator::Carrier_wipeoff_and_EPL_generic(int signal_length_samples,const
void Correlator::Carrier_wipeoff_and_EPL_volk(int signal_length_samples,const gr_complex* input, gr_complex* carrier,gr_complex* E_code, gr_complex* P_code, gr_complex* L_code,gr_complex* E_out, gr_complex* P_out, gr_complex* L_out, bool input_vector_aligned)
void Correlator::Carrier_wipeoff_and_EPL_volk(int signal_length_samples,const gr_complex* input, gr_complex* carrier,gr_complex* E_code, gr_complex* P_code, gr_complex* L_code,gr_complex* E_out, gr_complex* P_out, gr_complex* L_out, bool input_vector_unaligned)
{
gr_complex* bb_signal;
gr_complex* input_aligned;
@@ -82,21 +82,22 @@ void Correlator::Carrier_wipeoff_and_EPL_volk(int signal_length_samples,const gr
//todo: do something if posix_memalign fails
if (posix_memalign((void**)&bb_signal, 16, signal_length_samples * sizeof(gr_complex)) == 0) {};
if (input_vector_aligned==false)
//todo: There is an issue with the aligned version of volk_32fc_x2_multiply_32fc, even if the is_unaligned()==false
if (input_vector_unaligned==true)
{
//todo: do something if posix_memalign fails
if (posix_memalign((void**)&input_aligned, 16, signal_length_samples * sizeof(gr_complex)) == 0){};
memcpy(input_aligned,input,signal_length_samples * sizeof(gr_complex));
//if (posix_memalign((void**)&input_aligned, 16, signal_length_samples * sizeof(gr_complex)) == 0){};
//memcpy(input_aligned,input,signal_length_samples * sizeof(gr_complex));
//volk_32fc_x2_multiply_32fc_a_manual(bb_signal, input_aligned, carrier, signal_length_samples, volk_32fc_x2_multiply_32fc_a_best_arch.c_str());
//volk_32fc_x2_dot_prod_32fc_a_manual(E_out, bb_signal, E_code, signal_length_samples * sizeof(gr_complex), volk_32fc_x2_dot_prod_32fc_a_best_arch.c_str());
//volk_32fc_x2_dot_prod_32fc_a_manual(P_out, bb_signal, P_code, signal_length_samples * sizeof(gr_complex), volk_32fc_x2_dot_prod_32fc_a_best_arch.c_str());
//volk_32fc_x2_dot_prod_32fc_a_manual(L_out, bb_signal, L_code, signal_length_samples * sizeof(gr_complex), volk_32fc_x2_dot_prod_32fc_a_best_arch.c_str());
volk_32fc_x2_multiply_32fc_a(bb_signal, input_aligned, carrier, signal_length_samples);
volk_32fc_x2_multiply_32fc_u(bb_signal, input, carrier, signal_length_samples);
}else{
//use directly the input vector
volk_32fc_x2_multiply_32fc_a(bb_signal, input, carrier, signal_length_samples);
volk_32fc_x2_multiply_32fc_u(bb_signal, input, carrier, signal_length_samples);
}
volk_32fc_x2_dot_prod_32fc_a(E_out, bb_signal, E_code, signal_length_samples * sizeof(gr_complex));
@@ -104,10 +105,10 @@ void Correlator::Carrier_wipeoff_and_EPL_volk(int signal_length_samples,const gr
volk_32fc_x2_dot_prod_32fc_a(L_out, bb_signal, L_code, signal_length_samples * sizeof(gr_complex));
free(bb_signal);
if (input_vector_aligned==false)
{
free(input_aligned);
}
//if (input_vector_unaligned==false)
//{
// free(input_aligned);
//}
}
void Correlator::Carrier_wipeoff_and_VEPL_volk(int signal_length_samples,const gr_complex* input, gr_complex* carrier,gr_complex* VE_code,gr_complex* E_code, gr_complex* P_code, gr_complex* L_code,gr_complex* VL_code,gr_complex* VE_out,gr_complex* E_out, gr_complex* P_out, gr_complex* L_out,gr_complex* VL_out,bool input_vector_aligned)

2
src/algorithms/tracking/libs/correlator.h
View File

@@ -54,7 +54,7 @@ class Correlator
public:
void Carrier_wipeoff_and_EPL_generic(int signal_length_samples,const gr_complex* input, gr_complex* carrier,gr_complex* E_code, gr_complex* P_code, gr_complex* L_code,gr_complex* E_out, gr_complex* P_out, gr_complex* L_out);
void Carrier_wipeoff_and_EPL_volk(int signal_length_samples,const gr_complex* input, gr_complex* carrier,gr_complex* E_code, gr_complex* P_code, gr_complex* L_code,gr_complex* E_out, gr_complex* P_out, gr_complex* L_out,bool input_vector_aligned);
void Carrier_wipeoff_and_VEPL_volk(int signal_length_samples,const gr_complex* input, gr_complex* carrier,gr_complex* VE_code,gr_complex* E_code, gr_complex* P_code, gr_complex* L_code,gr_complex* VL_code,gr_complex* VE_out,gr_complex* E_out, gr_complex* P_out, gr_complex* L_out,gr_complex* VL_out,bool input_vector_aligned);
void Carrier_wipeoff_and_VEPL_volk(int signal_length_samples,const gr_complex* input, gr_complex* carrier,gr_complex* VE_code,gr_complex* E_code, gr_complex* P_code, gr_complex* L_code,gr_complex* VL_code,gr_complex* VE_out,gr_complex* E_out, gr_complex* P_out, gr_complex* L_out,gr_complex* VL_out,bool input_vector_unaligned);
Correlator();
~Correlator();
private:

10
src/algorithms/tracking/libs/tracking_discriminators.cc
View File

@@ -49,8 +49,8 @@
float fll_four_quadrant_atan(gr_complex prompt_s1, gr_complex prompt_s2,float t1, float t2)
{
float cross,dot;
dot = prompt_s1.imag()*prompt_s2.imag() + prompt_s1.real()*prompt_s2.real();
cross = prompt_s1.imag()*prompt_s2.real() - prompt_s2.imag()*prompt_s1.real();
dot = prompt_s1.real()*prompt_s2.real() + prompt_s1.imag()*prompt_s2.imag();
cross = prompt_s1.real()*prompt_s2.imag() - prompt_s2.real()*prompt_s1.imag();
return atan2(cross, dot) / (t2-t1);
}
@@ -64,7 +64,7 @@ float fll_four_quadrant_atan(gr_complex prompt_s1, gr_complex prompt_s2,float t1
*/
float pll_four_quadrant_atan(gr_complex prompt_s1)
{
return atan2(prompt_s1.real(), prompt_s1.imag());
return atan2(prompt_s1.imag(), prompt_s1.real());
}
@@ -77,9 +77,9 @@ float pll_four_quadrant_atan(gr_complex prompt_s1)
*/
float pll_cloop_two_quadrant_atan(gr_complex prompt_s1)
{
if (prompt_s1.imag() != 0.0)
if (prompt_s1.real() != 0.0)
{
return atan(prompt_s1.real() / prompt_s1.imag());
return atan(prompt_s1.imag() / prompt_s1.real());
}
else
{