/*! * \file gnss_signal_processing.cc * \brief This library gathers a few functions used by the algorithms of gnss-sdr, * regardless of system used * \author Luis Esteve, 2012. luis(at)epsilon-formacion.com * * * ----------------------------------------------------------------------------- * * Copyright (C) 2010-2020 (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. * * SPDX-License-Identifier: GPL-3.0-or-later * * ----------------------------------------------------------------------------- */ #include "gnss_signal_processing.h" #include "MATH_CONSTANTS.h" #include #include // for size_t const auto AUX_CEIL2 = [](float x) { return static_cast(static_cast((x) + 1)); }; void complex_exp_gen(own::span> _dest, double _f, double _fs) { gr::fxpt_nco d_nco; d_nco.set_freq(static_cast((TWO_PI * _f) / _fs)); d_nco.sincos(_dest.data(), _dest.size(), 1); } void complex_exp_gen_conj(own::span> _dest, double _f, double _fs) { gr::fxpt_nco d_nco; d_nco.set_freq(-static_cast((TWO_PI * _f) / _fs)); d_nco.sincos(_dest.data(), _dest.size(), 1); } void hex_to_binary_converter(own::span _dest, char _from) { switch (_from) { case '0': _dest[0] = 1; _dest[1] = 1; _dest[2] = 1; _dest[3] = 1; break; case '1': _dest[0] = 1; _dest[1] = 1; _dest[2] = 1; _dest[3] = -1; break; case '2': _dest[0] = 1; _dest[1] = 1; _dest[2] = -1; _dest[3] = 1; break; case '3': _dest[0] = 1; _dest[1] = 1; _dest[2] = -1; _dest[3] = -1; break; case '4': _dest[0] = 1; _dest[1] = -1; _dest[2] = 1; _dest[3] = 1; break; case '5': _dest[0] = 1; _dest[1] = -1; _dest[2] = 1; _dest[3] = -1; break; case '6': _dest[0] = 1; _dest[1] = -1; _dest[2] = -1; _dest[3] = 1; break; case '7': _dest[0] = 1; _dest[1] = -1; _dest[2] = -1; _dest[3] = -1; break; case '8': _dest[0] = -1; _dest[1] = 1; _dest[2] = 1; _dest[3] = 1; break; case '9': _dest[0] = -1; _dest[1] = 1; _dest[2] = 1; _dest[3] = -1; break; case 'A': _dest[0] = -1; _dest[1] = 1; _dest[2] = -1; _dest[3] = 1; break; case 'B': _dest[0] = -1; _dest[1] = 1; _dest[2] = -1; _dest[3] = -1; break; case 'C': _dest[0] = -1; _dest[1] = -1; _dest[2] = 1; _dest[3] = 1; break; case 'D': _dest[0] = -1; _dest[1] = -1; _dest[2] = 1; _dest[3] = -1; break; case 'E': _dest[0] = -1; _dest[1] = -1; _dest[2] = -1; _dest[3] = 1; break; case 'F': _dest[0] = -1; _dest[1] = -1; _dest[2] = -1; _dest[3] = -1; break; default: break; } } void resampler(const own::span _from, own::span _dest, float _fs_in, float _fs_out) { uint32_t _codeValueIndex; float aux; const float _t_out = 1.0F / _fs_out; // Output sampling period for (size_t i = 0; i < _dest.size() - 1; i++) { aux = (_t_out * (static_cast(i) + 1.0F)) * _fs_in; _codeValueIndex = AUX_CEIL2(aux) - 1; _dest[i] = _from[_codeValueIndex]; } // Correct the last index (due to number rounding issues) _dest[_dest.size() - 1] = _from[_from.size() - 1]; } void resampler(own::span> _from, own::span> _dest, float _fs_in, float _fs_out) { uint32_t _codeValueIndex; float aux; const float _t_out = 1.0F / _fs_out; // Output sampling period for (size_t i = 0; i < _dest.size() - 1; i++) { aux = (_t_out * (static_cast(i) + 1.0F)) * _fs_in; _codeValueIndex = AUX_CEIL2(aux) - 1; _dest[i] = _from[_codeValueIndex]; } // Correct the last index (due to number rounding issues) _dest[_dest.size() - 1] = _from[_from.size() - 1]; }