[1325] | 1 | //#---------------------------------------------------------------------------
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| 2 | //# pks_maths.cc: Mathematical functions for Parkes single-dish data reduction
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| 3 | //#---------------------------------------------------------------------------
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| 4 | //# Copyright (C) 1994-2006
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| 5 | //# Associated Universities, Inc. Washington DC, USA.
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| 6 | //#
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| 7 | //# This library is free software; you can redistribute it and/or modify it
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| 8 | //# under the terms of the GNU Library General Public License as published by
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| 9 | //# the Free Software Foundation; either version 2 of the License, or (at your
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| 10 | //# option) any later version.
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| 11 | //#
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| 12 | //# This library is distributed in the hope that it will be useful, but WITHOUT
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| 13 | //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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| 14 | //# FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library General Public
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| 15 | //# License for more details.
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| 16 | //#
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| 17 | //# You should have received a copy of the GNU Library General Public License
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| 18 | //# along with this library; if not, write to the Free Software Foundation,
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| 19 | //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
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| 20 | //#
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| 21 | //# Correspondence concerning AIPS++ should be addressed as follows:
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| 22 | //# Internet email: aips2-request@nrao.edu.
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| 23 | //# Postal address: AIPS++ Project Office
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| 24 | //# National Radio Astronomy Observatory
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| 25 | //# 520 Edgemont Road
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| 26 | //# Charlottesville, VA 22903-2475 USA
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| 27 | //#
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| 28 | //# Original: Mark Calabretta
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| 29 | //# $Id: pks_maths.cc,v 1.5 2006/05/19 00:12:35 mcalabre Exp $
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| 30 | //----------------------------------------------------------------------------
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| 31 |
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| 32 | // AIPS++ includes.
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| 33 | #include <casa/aips.h>
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| 34 | #include <casa/math.h>
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| 35 | #include <casa/Arrays/ArrayMath.h>
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| 36 | #include <casa/Arrays/Vector.h>
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| 37 | #include <casa/BasicSL/Constants.h>
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| 38 | #include <casa/Utilities/GenSort.h>
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| 39 |
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| 40 | // Parkes includes.
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| 41 | #include <atnf/pks/pks_maths.h>
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| 42 |
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| 43 |
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| 44 | //----------------------------------------------------------------------- nint
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| 45 |
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| 46 | // Nearest integral value; halfway cases are rounded to the integral value
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| 47 | // larger in value. No check is made for integer overflow.
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| 48 |
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| 49 | Int nint(Double v)
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| 50 | {
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| 51 | return Int(floor(v + 0.5));
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| 52 | }
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| 53 |
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| 54 | //---------------------------------------------------------------------- anint
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| 55 |
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| 56 | // Nearest integral value; halfway cases are rounded to the integral value
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| 57 | // larger in value.
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| 58 |
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| 59 | Double anint(Double v)
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| 60 | {
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| 61 | return floor(v + 0.5);
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| 62 | }
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| 63 |
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| 64 | //---------------------------------------------------------------------- round
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| 65 |
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| 66 | // Round value v to the nearest integral multiple of precision p.
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| 67 |
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| 68 | Double round(Double v, Double p)
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| 69 | {
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| 70 | return p * floor(v/p + 0.5);
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| 71 | }
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| 72 |
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| 73 | //--------------------------------------------------------------------- median
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| 74 |
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| 75 | // Compute the weighted median value of an array.
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| 76 |
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| 77 | Float median(const Vector<Float> &v, const Vector<Float> &wgt)
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| 78 | {
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| 79 | uInt nElem = v.nelements();
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| 80 | if (nElem == 0) return 0.0f;
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| 81 |
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| 82 | // Generate the sort index.
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| 83 | Vector<uInt> sortindex(nElem);
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| 84 | GenSortIndirect<Float>::sort(sortindex, v);
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| 85 |
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| 86 | // Find the middle weight.
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| 87 | Float wgt_2 = sum(wgt)/2.0f;
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| 88 |
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| 89 | // Find the corresponding vector element.
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| 90 | Float weight = 0.0f;
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| 91 | Float accwgt = 0.0f;
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| 92 | uInt j1 = 0;
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| 93 | uInt j2;
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| 94 | for (j2 = 0; j2 < nElem; j2++) {
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| 95 | weight = wgt(sortindex(j2));
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| 96 | if (weight == 0.0f) {
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| 97 | // Ignore zero-weight data;
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| 98 | continue;
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| 99 | }
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| 100 |
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| 101 | // The accumulated weight.
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| 102 | accwgt += weight;
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| 103 |
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| 104 | if (accwgt <= wgt_2) {
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| 105 | // Keep looping.
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| 106 | j1 = j2;
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| 107 | } else {
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| 108 | break;
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| 109 | }
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| 110 | }
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| 111 |
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| 112 | // Compute weighted median.
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| 113 | Float v1 = v(sortindex(j1));
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| 114 | Float v2 = v(sortindex(j2));
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| 115 |
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| 116 | // Compute pro-rata value from below.
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| 117 | Float dw = wgt_2 - (accwgt - weight);
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| 118 | v1 += (v2 - v1) * dw / weight;
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| 119 |
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| 120 | // Find next non-zero-weight value.
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| 121 | for (j2++ ; j2 < nElem; j2++) {
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| 122 | weight = wgt(sortindex(j2));
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| 123 | if (weight != 0.0f) {
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| 124 | break;
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| 125 | }
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| 126 | }
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| 127 |
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| 128 | if (j2 < nElem) {
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| 129 | // Compute pro-rata value from above.
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| 130 | Float v3 = v(sortindex(j2));
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| 131 |
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| 132 | v2 += (v3 - v2) * dw / weight;
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| 133 | }
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| 134 |
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| 135 | return (v1 + v2)/2.0f;
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| 136 | }
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| 137 |
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| 138 | //---------------------------------------------------------------- angularDist
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| 139 |
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| 140 | // Determine the angular distance between two directions (angles in radians).
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| 141 |
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| 142 | Double angularDist(Double lng0, Double lat0, Double lng, Double lat)
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| 143 | {
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| 144 | Double costheta = sin(lat0)*sin(lat) + cos(lat0)*cos(lat)*cos(lng0-lng);
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| 145 | return acos(costheta);
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| 146 | }
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| 147 |
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| 148 | //--------------------------------------------------------------------- distPA
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| 149 |
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| 150 | void distPA(Double lng0, Double lat0, Double lng, Double lat, Double &dist,
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| 151 | Double &pa)
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| 152 |
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| 153 | // Determine the generalized position angle of the field point (lng,lat) from
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| 154 | // the reference point (lng0,lat0) and the angular distance between them
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| 155 | // (angles in radians).
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| 156 |
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| 157 | {
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| 158 | // Euler angles which rotate the coordinate frame so that (lng0,lat0) is
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| 159 | // at the pole of the new system, with the pole of the old system at zero
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| 160 | // longitude in the new.
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| 161 | Double phi0 = C::pi_2 + lng0;
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| 162 | Double theta = C::pi_2 - lat0;
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| 163 | Double phi = -C::pi_2;
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| 164 |
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| 165 | // Rotate the field point to the new system.
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| 166 | Double alpha, beta;
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| 167 | eulerx(lng, lat, phi0, theta, phi, alpha, beta);
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| 168 |
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| 169 | dist = C::pi_2 - beta;
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| 170 | pa = -alpha;
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| 171 | if (pa < -C::pi) pa = pa + C::_2pi;
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| 172 | }
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| 173 |
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| 174 | //--------------------------------------------------------------------- eulerx
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| 175 |
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| 176 | void eulerx(Double lng0, Double lat0, Double phi0, Double theta, Double phi,
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| 177 | Double &lng1, Double &lat1)
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| 178 |
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| 179 | // Applies the Euler angle based transformation of spherical coordinates.
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| 180 | //
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| 181 | // phi0 Longitude of the ascending node in the old system, radians. The
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| 182 | // ascending node is the point of intersection of the equators of
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| 183 | // the two systems such that the equator of the new system crosses
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| 184 | // from south to north as viewed in the old system.
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| 185 | //
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| 186 | // theta Angle between the poles of the two systems, radians. THETA is
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| 187 | // positive for a positive rotation about the ascending node.
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| 188 | //
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| 189 | // phi Longitude of the ascending node in the new system, radians.
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| 190 |
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| 191 | {
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| 192 | // Compute intermediaries.
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| 193 | Double lng0p = lng0 - phi0;
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| 194 | Double slng0p = sin(lng0p);
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| 195 | Double clng0p = cos(lng0p);
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| 196 | Double slat0 = sin(lat0);
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| 197 | Double clat0 = cos(lat0);
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| 198 | Double ctheta = cos(theta);
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| 199 | Double stheta = sin(theta);
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| 200 |
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| 201 | Double x = clat0*clng0p;
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| 202 | Double y = clat0*slng0p*ctheta + slat0*stheta;
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| 203 |
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| 204 | // Longitude in the new system.
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| 205 | if (x != 0.0 || y != 0.0) {
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| 206 | lng1 = phi + atan2(y, x);
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| 207 | } else {
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| 208 | // Longitude at the poles in the new system is consistent with that
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| 209 | // specified in the old system.
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| 210 | lng1 = phi + lng0p;
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| 211 | }
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| 212 | lng1 = fmod(lng1, C::_2pi);
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| 213 | if (lng1 < 0.0) lng1 += C::_2pi;
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| 214 |
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| 215 | lat1 = asin(slat0*ctheta - clat0*stheta*slng0p);
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| 216 | }
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| 217 |
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| 218 | //------------------------------------------------------------------------ sol
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| 219 |
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| 220 | // Low precision coordinates of the Sun (accurate to 1 arcmin between 1800 and
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| 221 | // 2200) from http://aa.usno.navy.mil/faq/docs/SunApprox.html matches closely
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| 222 | // that in the Astronomical Almanac.
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| 223 |
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| 224 | void sol(Double mjd, Double &elng, Double &ra, Double &dec)
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| 225 | {
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| 226 | Double d2r = C::pi/180.0;
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| 227 |
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| 228 | // Number of days since J2000.0.
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| 229 | Double d = mjd - 51544.5;
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| 230 |
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| 231 | // Mean longitude and mean anomaly of the Sun (deg).
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| 232 | Double L = 280.459 + 0.98564736*d;
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| 233 | Double g = 357.529 + 0.98560028*d;
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| 234 |
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| 235 | // Apparent ecliptic longitude corrected for aberration (deg).
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| 236 | g *= d2r;
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| 237 | elng = L + 1.915*sin(g) + 0.020*sin(g+g);
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| 238 | elng = fmod(elng, 360.0);
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| 239 | if (elng < 0.0) elng += 360.0;
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| 240 |
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| 241 | // Obliquity of the ecliptic (deg).
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| 242 | Double epsilon = 23.439 - 0.00000036*d;
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| 243 |
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| 244 | // Transform ecliptic to equatorial coordinates.
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| 245 | elng *= d2r;
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| 246 | epsilon *= d2r;
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| 247 | ra = atan2(cos(epsilon)*sin(elng), cos(elng));
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| 248 | dec = asin(sin(epsilon)*sin(elng));
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| 249 | if (ra < 0.0) ra += C::_2pi;
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| 250 | }
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| 251 |
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| 252 | //------------------------------------------------------------------------ gst
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| 253 |
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| 254 | // Greenwich mean sidereal time, and low precision Greenwich apparent sidereal
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| 255 | // time, both in radian, from http://aa.usno.navy.mil/faq/docs/GAST.html. UT1
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| 256 | // is given in MJD form.
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| 257 |
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| 258 | void gst(Double ut1, Double &gmst, Double &gast)
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| 259 | {
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| 260 | Double d2r = C::pi/180.0;
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| 261 |
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| 262 | Double d = ut1 - 51544.5;
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| 263 | Double d0 = int(ut1) - 51544.5;
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| 264 | Double h = 24.0*(d - d0);
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| 265 | Double t = d / 35625.0;
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| 266 |
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| 267 | // GMST (hr).
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| 268 | gmst = 6.697374558 + 0.06570982441908*d0 + 1.00273790935*h + 0.000026*t*t;
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| 269 | gmst = fmod(gmst, 24.0);
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| 270 |
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| 271 | // Longitude of the ascending node of the Moon (deg).
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| 272 | Double Omega = 125.04 - 0.052954*d;
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| 273 |
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| 274 | // Mean Longitude of the Sun (deg).
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| 275 | Double L = 280.47 + 0.98565*d;
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| 276 |
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| 277 | // Obliquity of the ecliptic (deg).
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| 278 | Double epsilon = 23.4393 - 0.0000004*d;
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| 279 |
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| 280 | // Approximate nutation in longitude (hr).
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| 281 | Double dpsi = -0.000319*sin(Omega*d2r) - 0.000024*sin((L+L)*d2r);
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| 282 |
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| 283 | // Equation of the equinoxes (hr).
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| 284 | Double eqeq = dpsi*cos(epsilon*d2r);
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| 285 |
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| 286 | // GAST (hr).
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| 287 | gast = gmst + eqeq;
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| 288 | gast = fmod(gast, 24.0);
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| 289 |
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| 290 | // Convert to radian.
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| 291 | gmst *= C::pi/12.0;
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| 292 | gast *= C::pi/12.0;
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| 293 | }
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| 294 |
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| 295 | //----------------------------------------------------------------------- azel
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| 296 |
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| 297 | // Convert (ra,dec) to (az,el), from
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| 298 | // http://aa.usno.navy.mil/faq/docs/Alt_Az.html. Position as a Cartesian
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| 299 | // triplet in m, UT1 in MJD form, and all angles in radian.
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| 300 |
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| 301 | void azel(const Vector<Double> position, Double ut1, Double ra, Double dec,
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| 302 | Double &az, Double &el)
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| 303 | {
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| 304 | // Get gocentric longitude and latitude (rad).
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| 305 | Double x = position(0);
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| 306 | Double y = position(1);
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| 307 | Double z = position(2);
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| 308 | Double r = sqrt(x*x + y*y + z*z);
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| 309 | Double lng = atan2(y, x);
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| 310 | Double lat = asin(z/r);
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| 311 |
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| 312 | // Get GAST (rad).
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| 313 | Double gast, gmst;
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| 314 | gst(ut1, gmst, gast);
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| 315 |
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| 316 | // Local hour angle (rad).
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| 317 | Double ha = (gast + lng) - ra;
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| 318 |
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| 319 | // Azimuth and elevation (rad).
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| 320 | az = atan2(cos(dec)*sin(ha), cos(dec)*sin(lat)*cos(ha) - sin(dec)*cos(lat));
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| 321 | if (az < 0.0) az += C::_2pi;
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| 322 | el = asin(cos(dec)*cos(lat)*cos(ha) + sin(dec)*sin(lat));
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| 323 | }
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| 324 |
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| 325 | //---------------------------------------------------------------------- solel
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| 326 |
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| 327 | // Compute the Solar elevation using the above functions.
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| 328 |
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| 329 | Double solel(const Vector<Double> position, Double ut1)
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| 330 | {
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| 331 | Double az, dec, el, elng, gast, gmst, ra;
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| 332 | sol(ut1, elng, ra, dec);
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| 333 | gst(ut1, gmst, gast);
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| 334 | azel(position, ut1, ra, dec, az, el);
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| 335 | return el;
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| 336 | }
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