[91] | 1 | //#---------------------------------------------------------------------------
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[890] | 2 | //# Fitter.cc: A Fitter class for spectra
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[91] | 3 | //#--------------------------------------------------------------------------
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| 4 | //# Copyright (C) 2004
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[125] | 5 | //# ATNF
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[91] | 6 | //#
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| 7 | //# This program is free software; you can redistribute it and/or modify it
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| 8 | //# under the terms of the GNU General Public License as published by the Free
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| 9 | //# Software Foundation; either version 2 of the License, or (at your option)
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| 10 | //# any later version.
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| 11 | //#
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| 12 | //# This program is distributed in the hope that it will be useful, but
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| 13 | //# WITHOUT ANY WARRANTY; without even the implied warranty of
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| 14 | //# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General
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| 15 | //# Public License for more details.
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| 16 | //#
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| 17 | //# You should have received a copy of the GNU General Public License along
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| 18 | //# with this program; if not, write to the Free Software Foundation, Inc.,
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| 19 | //# 675 Massachusetts Ave, Cambridge, MA 02139, USA.
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| 20 | //#
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| 21 | //# Correspondence concerning this software should be addressed as follows:
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| 22 | //# Internet email: Malte.Marquarding@csiro.au
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| 23 | //# Postal address: Malte Marquarding,
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| 24 | //# Australia Telescope National Facility,
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| 25 | //# P.O. Box 76,
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| 26 | //# Epping, NSW, 2121,
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| 27 | //# AUSTRALIA
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| 28 | //#
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[891] | 29 | //# $Id: STFitter.cpp 1819 2010-08-02 07:28:20Z KanaSugimoto $
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[91] | 30 | //#---------------------------------------------------------------------------
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[125] | 31 | #include <casa/aips.h>
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[91] | 32 | #include <casa/Arrays/ArrayMath.h>
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| 33 | #include <casa/Arrays/ArrayLogical.h>
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[1819] | 34 | #include <casa/Logging/LogIO.h>
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[91] | 35 | #include <scimath/Fitting.h>
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| 36 | #include <scimath/Fitting/LinearFit.h>
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| 37 | #include <scimath/Functionals/CompiledFunction.h>
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| 38 | #include <scimath/Functionals/CompoundFunction.h>
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| 39 | #include <scimath/Functionals/Gaussian1D.h>
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[1819] | 40 | #include "Lorentzian1D.h"
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[91] | 41 | #include <scimath/Functionals/Polynomial.h>
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| 42 | #include <scimath/Mathematics/AutoDiff.h>
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| 43 | #include <scimath/Mathematics/AutoDiffMath.h>
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| 44 | #include <scimath/Fitting/NonLinearFitLM.h>
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| 45 | #include <components/SpectralComponents/SpectralEstimate.h>
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| 46 |
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[894] | 47 | #include "STFitter.h"
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| 48 |
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[91] | 49 | using namespace asap;
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[125] | 50 | using namespace casa;
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[91] | 51 |
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[890] | 52 | Fitter::Fitter()
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[91] | 53 | {
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| 54 | }
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| 55 |
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[890] | 56 | Fitter::~Fitter()
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[91] | 57 | {
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[517] | 58 | reset();
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[91] | 59 | }
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| 60 |
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[890] | 61 | void Fitter::clear()
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[91] | 62 | {
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[517] | 63 | for (uInt i=0;i< funcs_.nelements();++i) {
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| 64 | delete funcs_[i]; funcs_[i] = 0;
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| 65 | }
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[612] | 66 | funcs_.resize(0,True);
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[517] | 67 | parameters_.resize();
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[1232] | 68 | fixedpar_.resize();
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[517] | 69 | error_.resize();
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| 70 | thefit_.resize();
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| 71 | estimate_.resize();
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| 72 | chisquared_ = 0.0;
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[91] | 73 | }
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[517] | 74 |
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[890] | 75 | void Fitter::reset()
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[91] | 76 | {
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[517] | 77 | clear();
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| 78 | x_.resize();
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| 79 | y_.resize();
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| 80 | m_.resize();
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[91] | 81 | }
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| 82 |
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| 83 |
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[890] | 84 | bool Fitter::computeEstimate() {
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[517] | 85 | if (x_.nelements() == 0 || y_.nelements() == 0)
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| 86 | throw (AipsError("No x/y data specified."));
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[91] | 87 |
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[517] | 88 | if (dynamic_cast<Gaussian1D<Float>* >(funcs_[0]) == 0)
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| 89 | return false;
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| 90 | uInt n = funcs_.nelements();
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| 91 | SpectralEstimate estimator(n);
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| 92 | estimator.setQ(5);
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| 93 | Int mn,mx;
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| 94 | mn = 0;
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| 95 | mx = m_.nelements()-1;
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| 96 | for (uInt i=0; i<m_.nelements();++i) {
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| 97 | if (m_[i]) {
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| 98 | mn = i;
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| 99 | break;
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[108] | 100 | }
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[517] | 101 | }
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| 102 | for (uInt j=m_.nelements()-1; j>=0;--j) {
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| 103 | if (m_[j]) {
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| 104 | mx = j;
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| 105 | break;
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[108] | 106 | }
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[517] | 107 | }
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[1067] | 108 | //mn = 0+x_.nelements()/10;
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| 109 | //mx = x_.nelements()-x_.nelements()/10;
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[517] | 110 | estimator.setRegion(mn,mx);
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| 111 | //estimator.setWindowing(True);
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| 112 | SpectralList listGauss = estimator.estimate(x_, y_);
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| 113 | parameters_.resize(n*3);
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| 114 | Gaussian1D<Float>* g = 0;
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| 115 | for (uInt i=0; i<n;i++) {
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| 116 | g = dynamic_cast<Gaussian1D<Float>* >(funcs_[i]);
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| 117 | if (g) {
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| 118 | (*g)[0] = listGauss[i].getAmpl();
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| 119 | (*g)[1] = listGauss[i].getCenter();
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| 120 | (*g)[2] = listGauss[i].getFWHM();
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[91] | 121 | }
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[517] | 122 | }
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| 123 | estimate_.resize();
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| 124 | listGauss.evaluate(estimate_,x_);
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| 125 | return true;
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[91] | 126 | }
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| 127 |
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[890] | 128 | std::vector<float> Fitter::getEstimate() const
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[91] | 129 | {
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[517] | 130 | if (estimate_.nelements() == 0)
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| 131 | throw (AipsError("No estimate set."));
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| 132 | std::vector<float> stlout;
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| 133 | estimate_.tovector(stlout);
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| 134 | return stlout;
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[91] | 135 | }
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| 136 |
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| 137 |
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[890] | 138 | bool Fitter::setExpression(const std::string& expr, int ncomp)
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[91] | 139 | {
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[517] | 140 | clear();
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| 141 | if (expr == "gauss") {
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| 142 | if (ncomp < 1) throw (AipsError("Need at least one gaussian to fit."));
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| 143 | funcs_.resize(ncomp);
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| 144 | for (Int k=0; k<ncomp; ++k) {
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| 145 | funcs_[k] = new Gaussian1D<Float>();
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| 146 | }
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| 147 | } else if (expr == "poly") {
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| 148 | funcs_.resize(1);
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| 149 | funcs_[0] = new Polynomial<Float>(ncomp);
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[1819] | 150 | } else if (expr == "lorentz") {
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| 151 | if (ncomp < 1) throw (AipsError("Need at least one lorentzian to fit."));
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| 152 | funcs_.resize(ncomp);
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| 153 | for (Int k=0; k<ncomp; ++k) {
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| 154 | funcs_[k] = new Lorentzian1D<Float>();
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| 155 | }
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[517] | 156 | } else {
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[1819] | 157 | //cerr << " compiled functions not yet implemented" << endl;
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| 158 | LogIO os( LogOrigin( "Fitter", "setExpression()", WHERE ) ) ;
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| 159 | os << LogIO::WARN << " compiled functions not yet implemented" << LogIO::POST;
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[517] | 160 | //funcs_.resize(1);
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| 161 | //funcs_[0] = new CompiledFunction<Float>();
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| 162 | //funcs_[0]->setFunction(String(expr));
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| 163 | return false;
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| 164 | }
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| 165 | return true;
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[91] | 166 | }
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| 167 |
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[890] | 168 | bool Fitter::setData(std::vector<float> absc, std::vector<float> spec,
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[91] | 169 | std::vector<bool> mask)
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| 170 | {
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| 171 | x_.resize();
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| 172 | y_.resize();
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| 173 | m_.resize();
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| 174 | // convert std::vector to casa Vector
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| 175 | Vector<Float> tmpx(absc);
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| 176 | Vector<Float> tmpy(spec);
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| 177 | Vector<Bool> tmpm(mask);
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| 178 | AlwaysAssert(tmpx.nelements() == tmpy.nelements(), AipsError);
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| 179 | x_ = tmpx;
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| 180 | y_ = tmpy;
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| 181 | m_ = tmpm;
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| 182 | return true;
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| 183 | }
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| 184 |
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[890] | 185 | std::vector<float> Fitter::getResidual() const
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[91] | 186 | {
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| 187 | if (residual_.nelements() == 0)
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| 188 | throw (AipsError("Function not yet fitted."));
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| 189 | std::vector<float> stlout;
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| 190 | residual_.tovector(stlout);
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| 191 | return stlout;
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| 192 | }
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| 193 |
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[890] | 194 | std::vector<float> Fitter::getFit() const
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[91] | 195 | {
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| 196 | Vector<Float> out = thefit_;
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| 197 | std::vector<float> stlout;
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| 198 | out.tovector(stlout);
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| 199 | return stlout;
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| 200 |
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| 201 | }
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| 202 |
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[890] | 203 | std::vector<float> Fitter::getErrors() const
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[91] | 204 | {
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| 205 | Vector<Float> out = error_;
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| 206 | std::vector<float> stlout;
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| 207 | out.tovector(stlout);
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| 208 | return stlout;
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| 209 | }
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| 210 |
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[890] | 211 | bool Fitter::setParameters(std::vector<float> params)
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[91] | 212 | {
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| 213 | Vector<Float> tmppar(params);
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| 214 | if (funcs_.nelements() == 0)
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| 215 | throw (AipsError("Function not yet set."));
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| 216 | if (parameters_.nelements() > 0 && tmppar.nelements() != parameters_.nelements())
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| 217 | throw (AipsError("Number of parameters inconsistent with function."));
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[1232] | 218 | if (parameters_.nelements() == 0) {
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[91] | 219 | parameters_.resize(tmppar.nelements());
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[1232] | 220 | if (tmppar.nelements() != fixedpar_.nelements()) {
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| 221 | fixedpar_.resize(tmppar.nelements());
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| 222 | fixedpar_ = False;
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| 223 | }
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| 224 | }
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[91] | 225 | if (dynamic_cast<Gaussian1D<Float>* >(funcs_[0]) != 0) {
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| 226 | uInt count = 0;
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| 227 | for (uInt j=0; j < funcs_.nelements(); ++j) {
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| 228 | for (uInt i=0; i < funcs_[j]->nparameters(); ++i) {
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| 229 | (funcs_[j]->parameters())[i] = tmppar[count];
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| 230 | parameters_[count] = tmppar[count];
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| 231 | ++count;
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| 232 | }
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| 233 | }
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| 234 | } else if (dynamic_cast<Polynomial<Float>* >(funcs_[0]) != 0) {
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| 235 | for (uInt i=0; i < funcs_[0]->nparameters(); ++i) {
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| 236 | parameters_[i] = tmppar[i];
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| 237 | (funcs_[0]->parameters())[i] = tmppar[i];
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| 238 | }
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[1819] | 239 | } else if (dynamic_cast<Lorentzian1D<Float>* >(funcs_[0]) != 0) {
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| 240 | uInt count = 0;
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| 241 | for (uInt j=0; j < funcs_.nelements(); ++j) {
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| 242 | for (uInt i=0; i < funcs_[j]->nparameters(); ++i) {
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| 243 | (funcs_[j]->parameters())[i] = tmppar[count];
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| 244 | parameters_[count] = tmppar[count];
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| 245 | ++count;
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| 246 | }
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| 247 | }
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[91] | 248 | }
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[1232] | 249 | // reset
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| 250 | if (params.size() == 0) {
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| 251 | parameters_.resize();
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| 252 | fixedpar_.resize();
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| 253 | }
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[91] | 254 | return true;
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| 255 | }
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| 256 |
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[890] | 257 | bool Fitter::setFixedParameters(std::vector<bool> fixed)
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[91] | 258 | {
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| 259 | if (funcs_.nelements() == 0)
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| 260 | throw (AipsError("Function not yet set."));
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[1232] | 261 | if (fixedpar_.nelements() > 0 && fixed.size() != fixedpar_.nelements())
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[91] | 262 | throw (AipsError("Number of mask elements inconsistent with function."));
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[1232] | 263 | if (fixedpar_.nelements() == 0) {
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| 264 | fixedpar_.resize(parameters_.nelements());
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| 265 | fixedpar_ = False;
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| 266 | }
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[91] | 267 | if (dynamic_cast<Gaussian1D<Float>* >(funcs_[0]) != 0) {
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| 268 | uInt count = 0;
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| 269 | for (uInt j=0; j < funcs_.nelements(); ++j) {
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| 270 | for (uInt i=0; i < funcs_[j]->nparameters(); ++i) {
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[1232] | 271 | funcs_[j]->mask(i) = !fixed[count];
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| 272 | fixedpar_[count] = fixed[count];
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[91] | 273 | ++count;
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| 274 | }
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| 275 | }
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| 276 | } else if (dynamic_cast<Polynomial<Float>* >(funcs_[0]) != 0) {
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| 277 | for (uInt i=0; i < funcs_[0]->nparameters(); ++i) {
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[1232] | 278 | fixedpar_[i] = fixed[i];
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| 279 | funcs_[0]->mask(i) = !fixed[i];
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[91] | 280 | }
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[1819] | 281 | } else if (dynamic_cast<Lorentzian1D<Float>* >(funcs_[0]) != 0) {
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| 282 | uInt count = 0;
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| 283 | for (uInt j=0; j < funcs_.nelements(); ++j) {
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| 284 | for (uInt i=0; i < funcs_[j]->nparameters(); ++i) {
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| 285 | funcs_[j]->mask(i) = !fixed[count];
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| 286 | fixedpar_[count] = fixed[count];
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| 287 | ++count;
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| 288 | }
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| 289 | }
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[91] | 290 | }
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| 291 | return true;
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| 292 | }
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| 293 |
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[890] | 294 | std::vector<float> Fitter::getParameters() const {
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[91] | 295 | Vector<Float> out = parameters_;
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| 296 | std::vector<float> stlout;
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| 297 | out.tovector(stlout);
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| 298 | return stlout;
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| 299 | }
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| 300 |
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[890] | 301 | std::vector<bool> Fitter::getFixedParameters() const {
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[108] | 302 | Vector<Bool> out(parameters_.nelements());
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| 303 | if (fixedpar_.nelements() == 0) {
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[1232] | 304 | return std::vector<bool>();
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[108] | 305 | //throw (AipsError("No parameter mask set."));
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| 306 | } else {
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| 307 | out = fixedpar_;
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| 308 | }
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| 309 | std::vector<bool> stlout;
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| 310 | out.tovector(stlout);
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| 311 | return stlout;
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[91] | 312 | }
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| 313 |
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[890] | 314 | float Fitter::getChisquared() const {
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[91] | 315 | return chisquared_;
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| 316 | }
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| 317 |
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[890] | 318 | bool Fitter::fit() {
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[517] | 319 | NonLinearFitLM<Float> fitter;
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| 320 | CompoundFunction<Float> func;
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[612] | 321 |
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| 322 | uInt n = funcs_.nelements();
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[517] | 323 | for (uInt i=0; i<n; ++i) {
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| 324 | func.addFunction(*funcs_[i]);
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| 325 | }
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[612] | 326 |
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[517] | 327 | fitter.setFunction(func);
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| 328 | fitter.setMaxIter(50+n*10);
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| 329 | // Convergence criterium
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| 330 | fitter.setCriteria(0.001);
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[612] | 331 |
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[517] | 332 | // Fit
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| 333 | Vector<Float> sigma(x_.nelements());
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| 334 | sigma = 1.0;
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[890] | 335 |
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[517] | 336 | parameters_.resize();
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| 337 | parameters_ = fitter.fit(x_, y_, sigma, &m_);
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[1067] | 338 | if ( !fitter.converged() ) {
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| 339 | return false;
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| 340 | }
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[517] | 341 | std::vector<float> ps;
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| 342 | parameters_.tovector(ps);
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| 343 | setParameters(ps);
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[612] | 344 |
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[517] | 345 | error_.resize();
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| 346 | error_ = fitter.errors();
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[612] | 347 |
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[517] | 348 | chisquared_ = fitter.getChi2();
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[890] | 349 |
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[517] | 350 | residual_.resize();
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| 351 | residual_ = y_;
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| 352 | fitter.residual(residual_,x_);
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| 353 | // use fitter.residual(model=True) to get the model
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| 354 | thefit_.resize(x_.nelements());
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| 355 | fitter.residual(thefit_,x_,True);
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| 356 | return true;
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| 357 | }
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[483] | 358 |
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[1391] | 359 | bool Fitter::lfit() {
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| 360 | LinearFit<Float> fitter;
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| 361 | CompoundFunction<Float> func;
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[483] | 362 |
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[1391] | 363 | uInt n = funcs_.nelements();
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| 364 | for (uInt i=0; i<n; ++i) {
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| 365 | func.addFunction(*funcs_[i]);
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| 366 | }
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| 367 |
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| 368 | fitter.setFunction(func);
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| 369 | //fitter.setMaxIter(50+n*10);
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| 370 | // Convergence criterium
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| 371 | //fitter.setCriteria(0.001);
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| 372 |
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| 373 | // Fit
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| 374 | Vector<Float> sigma(x_.nelements());
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| 375 | sigma = 1.0;
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| 376 |
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| 377 | parameters_.resize();
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| 378 | parameters_ = fitter.fit(x_, y_, sigma, &m_);
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| 379 | std::vector<float> ps;
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| 380 | parameters_.tovector(ps);
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| 381 | setParameters(ps);
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| 382 |
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| 383 | error_.resize();
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| 384 | error_ = fitter.errors();
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| 385 |
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| 386 | chisquared_ = fitter.getChi2();
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| 387 |
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| 388 | residual_.resize();
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| 389 | residual_ = y_;
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| 390 | fitter.residual(residual_,x_);
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| 391 | // use fitter.residual(model=True) to get the model
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| 392 | thefit_.resize(x_.nelements());
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| 393 | fitter.residual(thefit_,x_,True);
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| 394 | return true;
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| 395 | }
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| 396 |
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[890] | 397 | std::vector<float> Fitter::evaluate(int whichComp) const
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| 398 | {
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[517] | 399 | std::vector<float> stlout;
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[890] | 400 | uInt idx = uInt(whichComp);
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[517] | 401 | Float y;
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| 402 | if ( idx < funcs_.nelements() ) {
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| 403 | for (uInt i=0; i<x_.nelements(); ++i) {
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| 404 | y = (*funcs_[idx])(x_[i]);
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| 405 | stlout.push_back(float(y));
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| 406 | }
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| 407 | }
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| 408 | return stlout;
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| 409 | }
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[483] | 410 |
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