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https://github.com/f4exb/sdrangel.git
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246 lines
6.6 KiB
C++
246 lines
6.6 KiB
C++
/* icfir.c
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This file is part of a program that implements a Software-Defined Radio.
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Copyright (C) 2018 Warren Pratt, NR0V
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Copyright (C) 2024 Edouard Griffiths, F4EXB Adapted to SDRangel
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License
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as published by the Free Software Foundation; either version 2
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of the License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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The author can be reached by email at
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warren@pratt.one
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*/
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#include <vector>
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#include "comm.hpp"
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#include "fircore.hpp"
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#include "fir.hpp"
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#include "icfir.hpp"
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namespace WDSP {
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void ICFIR::calc()
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{
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std::vector<float> impulse;
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scale = 1.0f / (float)(2 * size);
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icfir_impulse (impulse, nc, DD, R, Pairs, (float) runrate, (float) cicrate, cutoff, xtype, xbw, 1, scale, wintype);
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p = new FIRCORE(size, in, out, mp, impulse);
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}
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void ICFIR::decalc()
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{
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delete p;
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}
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ICFIR::ICFIR(
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int _run,
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int _size,
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int _nc,
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int _mp,
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float* _in,
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float* _out,
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int _runrate,
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int _cicrate,
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int _DD,
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int _R,
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int _Pairs,
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float _cutoff,
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int _xtype,
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float _xbw,
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int _wintype
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)
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// run: 0 - no action; 1 - operate
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// size: number of complex samples in an input buffer to the CFIR filter
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// nc: number of filter coefficients
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// mp: minimum phase flag
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// in: pointer to the input buffer
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// out: pointer to the output buffer
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// rate: samplerate
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// DD: differential delay of the CIC to be compensated (usually 1 or 2)
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// R: interpolation factor of CIC
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// Pairs: number of comb-integrator pairs in the CIC
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// cutoff: cutoff frequency
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// xtype: 0 - fourth power transition; 1 - raised cosine transition
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// xbw: width of raised cosine transition
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{
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run = _run;
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size = _size;
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nc = _nc;
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mp = _mp;
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in = _in;
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out = _out;
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runrate = _runrate;
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cicrate = _cicrate;
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DD = _DD;
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R = _R;
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Pairs = _Pairs;
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cutoff = _cutoff;
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xtype = _xtype;
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xbw = _xbw;
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wintype = _wintype;
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calc();
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}
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ICFIR::~ICFIR()
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{
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decalc();
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}
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void ICFIR::flush()
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{
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p->flush();
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}
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void ICFIR::execute()
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{
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if (run)
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p->execute();
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else if (in != out)
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std::copy( in, in + size * 2, out);
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}
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void ICFIR::setBuffers(float* _in, float* _out)
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{
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decalc();
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in = _in;
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out = _out;
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calc();
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}
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void ICFIR::setSamplerate(int _rate)
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{
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decalc();
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runrate = _rate;
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calc();
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}
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void ICFIR::setSize(int _size)
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{
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decalc();
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size = _size;
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calc();
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}
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void ICFIR::setOutRate(int _rate)
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{
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decalc();
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cicrate = _rate;
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calc();
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}
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void ICFIR::icfir_impulse (
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std::vector<float>& _impulse,
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int _N,
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int _DD,
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int _R,
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int _Pairs,
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float _runrate,
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float _cicrate,
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float _cutoff,
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int _xtype,
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float _xbw,
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int _rtype,
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float _scale,
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int _wintype
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)
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{
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// N: number of impulse response samples
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// DD: differential delay used in the CIC filter
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// R: interpolation / decimation factor of the CIC
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// Pairs: number of comb-integrator pairs in the CIC
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// runrate: sample rate at which this filter is to run (assumes there may be flat interp. between this filter and the CIC)
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// cicrate: sample rate at interface to CIC
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// cutoff: cutoff frequency
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// xtype: transition type, 0 for 4th-power rolloff, 1 for raised cosine
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// xbw: transition bandwidth for raised cosine
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// rtype: 0 for real output, 1 for complex output
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// scale: scale factor to be applied to the output
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int i;
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int j;
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double tmp;
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double local_scale;
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double ri;
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double mag = 0;
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double fn;
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std::vector<float> A(_N);
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double ft = _cutoff / _cicrate; // normalized cutoff frequency
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int u_samps = (_N + 1) / 2; // number of unique samples, OK for odd or even N
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int c_samps = (int)(_cutoff / _runrate * _N) + (_N + 1) / 2 - _N / 2; // number of unique samples within bandpass, OK for odd or even N
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auto x_samps = (int)(_xbw / _runrate * _N); // number of unique samples in transition region, OK for odd or even N
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double offset = 0.5f - 0.5f * (float)((_N + 1) / 2 - _N / 2); // sample offset from center, OK for odd or even N
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std::vector<double> xistion(x_samps + 1);
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double delta = PI / (float)x_samps;
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double L = _cicrate / _runrate;
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double phs = 0.0;
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for (i = 0; i <= x_samps; i++)
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{
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xistion[i] = 0.5 * (cos (phs) + 1.0);
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phs += delta;
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}
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if ((tmp = _DD * _R * sin (PI * ft / _R) / sin (PI * _DD * ft)) < 0.0) //normalize by peak gain
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tmp = -tmp;
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local_scale = _scale / pow (tmp, _Pairs);
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if (_xtype == 0)
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{
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for (i = 0, ri = offset; i < u_samps; i++, ri += 1.0)
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{
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fn = ri / (L * (float)_N);
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if (fn <= ft)
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{
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if (fn == 0.0) tmp = 1.0;
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else if ((tmp = sin (PI * _DD * fn) / (_DD * _R * sin (PI * fn / _R))) < 0.0)
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tmp = -tmp;
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mag = pow (tmp, _Pairs) * local_scale;
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}
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else
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mag *= (ft * ft * ft * ft) / (fn * fn * fn * fn);
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A[i] = (float) mag;
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}
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}
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else if (_xtype == 1)
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{
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for (i = 0, ri = offset; i < u_samps; i++, ri += 1.0)
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{
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fn = ri / (L *(float)_N);
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if (i < c_samps)
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{
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if (fn == 0.0) tmp = 1.0;
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else if ((tmp = sin (PI * _DD * fn) / (_DD * _R * sin (PI * fn / _R))) < 0.0)
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tmp = -tmp;
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mag = pow (tmp, _Pairs) * local_scale;
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A[i] = (float) mag;
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}
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else if ( i >= c_samps && i <= c_samps + x_samps)
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A[i] = (float) (mag * xistion[i - c_samps]);
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else
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A[i] = 0.0;
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}
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}
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if (_N & 1)
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for (i = u_samps, j = 2; i < _N; i++, j++)
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A[i] = A[u_samps - j];
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else
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for (i = u_samps, j = 1; i < _N; i++, j++)
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A[i] = A[u_samps - j];
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_impulse.resize(2 * _N);
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FIR::fir_fsamp (_impulse, _N, A.data(), _rtype, 1.0, _wintype);
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}
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} // namespace WDSP
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