[3] | 1 | #include <iostream> |
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| 2 | #include <sstream> |
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| 3 | #include <iomanip> |
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| 4 | #include <string> |
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| 5 | #include <math.h> |
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[120] | 6 | #include <duchamp.hh> |
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| 7 | #include <param.hh> |
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[3] | 8 | #include <Utils/utils.hh> |
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| 9 | |
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| 10 | using std::setw; |
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| 11 | using std::setfill; |
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| 12 | using std::setprecision; |
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| 13 | |
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[103] | 14 | string getIAUName(double ra, double dec, FitsHeader head) |
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| 15 | { |
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| 16 | /** |
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| 17 | * string getIAUName(double, double, FitsHeader) |
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| 18 | * front end to the two getIAUName tasks. It parses the FitsHeader |
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| 19 | * object and works out the coord type and, if necessary, the |
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| 20 | * equinox. |
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| 21 | */ |
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[112] | 22 | string longitudeType = head.getWCS()->lngtyp; |
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| 23 | if(longitudeType=="RA") |
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[103] | 24 | return getIAUNameEQ(ra, dec, head.getWCS()->equinox); |
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| 25 | else |
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| 26 | return getIAUNameGAL(ra, dec); |
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| 27 | } |
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| 28 | |
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[3] | 29 | string getIAUNameEQ(double ra, double dec, float equinox) |
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| 30 | { |
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| 31 | /** |
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| 32 | * string getIAUNameEQ(double, double, float) |
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| 33 | * both ra and dec are assumed to be in degrees. |
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| 34 | * returns name of the form J1234-4321 for equinox = 2000, |
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| 35 | * and B1234-4321 otherwise |
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| 36 | */ |
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| 37 | |
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| 38 | double raHrs = ra / 15.; |
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| 39 | int h = int(raHrs); |
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| 40 | int m = (int)(fmod(raHrs,1.)*60.); |
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[112] | 41 | int s = (int)(fmod(raHrs,1./60.)*3600.); |
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[3] | 42 | std::stringstream ss(std::stringstream::out); |
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| 43 | ss.setf(std::ios::showpoint); |
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| 44 | ss.setf(std::ios::fixed); |
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| 45 | if(equinox==2000.) ss << "J"; |
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| 46 | else ss << "B"; |
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| 47 | ss<<setw(2)<<setfill('0')<<h; |
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| 48 | ss<<setw(2)<<setfill('0')<<m; |
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[112] | 49 | ss<<setw(2)<<setfill('0')<<s; |
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[3] | 50 | int sign = int( dec / fabs(dec) ); |
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| 51 | double d = dec / sign; |
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| 52 | h = int(d); |
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| 53 | m = (int)(fmod(d,1.)*60.); |
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[112] | 54 | s = (int)(fmod(d,1./60.)*3600.); |
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[3] | 55 | if(sign==1) ss<<"+"; else ss<<"-"; |
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| 56 | ss<<setw(2)<<setfill('0')<<h; |
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| 57 | ss.unsetf(std::ios::showpos); |
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| 58 | ss<<setw(2)<<setfill('0')<<m; |
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[112] | 59 | ss<<setw(2)<<setfill('0')<<s; |
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[3] | 60 | return ss.str(); |
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| 61 | } |
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| 62 | |
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| 63 | string getIAUNameGAL(double lon, double lat) |
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| 64 | { |
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| 65 | /** |
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| 66 | * string getIAUNameGAL(double, double) |
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| 67 | * both ra and dec are assumed to be in degrees. |
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[112] | 68 | * returns name of the form G321.123+01.234 |
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[3] | 69 | */ |
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| 70 | |
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| 71 | std::stringstream ss(std::stringstream::out); |
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| 72 | ss.setf(std::ios::showpoint); |
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| 73 | ss.setf(std::ios::fixed); |
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| 74 | ss<<"G"; |
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[112] | 75 | ss<<setw(7)<<setfill('0')<<setprecision(3)<<lon; |
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[3] | 76 | ss.setf(std::ios::showpos); |
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| 77 | ss.setf(std::ios::internal); |
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[112] | 78 | ss<<setw(7)<<setfill('0')<<setprecision(3)<<lat; |
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[3] | 79 | ss.unsetf(std::ios::internal); |
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| 80 | ss.unsetf(std::ios::showpos); |
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| 81 | ss.unsetf(std::ios::showpoint); |
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| 82 | ss.unsetf(std::ios::fixed); |
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| 83 | return ss.str(); |
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| 84 | } |
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| 85 | |
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[38] | 86 | string decToDMS(const double dec, const string type) |
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[3] | 87 | { |
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| 88 | /** |
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[38] | 89 | * string decToDMS(double, string) |
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| 90 | * converts a decimal angle (in degrees) to a format reflecting the axis type: |
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| 91 | * RA (right ascension) --> hh:mm:ss.ss, with dec made modulo 360. (or 24hrs) |
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| 92 | * DEC (declination) --> sdd:mm:ss.ss (with sign, either + or -) |
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| 93 | * GLON (galactic longitude) --> ddd:mm:ss.ss, with dec made modulo 360. |
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| 94 | * GLAT (galactic latitude) --> sdd:mm:ss.ss (with sign, either + or -) |
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| 95 | * Any other type defaults to RA, and prints warning. |
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[3] | 96 | */ |
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| 97 | |
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| 98 | double dec_abs,sec; |
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| 99 | int deg,min; |
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| 100 | const double onemin=1./60.; |
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[38] | 101 | double thisDec = dec; |
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| 102 | string sign=""; |
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| 103 | int degSize = 2; // number of figures in the degrees part of the output. |
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[3] | 104 | |
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[38] | 105 | if((type=="RA")||(type=="GLON")){ |
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| 106 | if(type=="GLON") degSize = 3; // three figures in degrees when doing longitude. |
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| 107 | // Make these modulo 360.; |
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| 108 | while (thisDec < 0.) { thisDec += 360.; } |
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| 109 | while (thisDec >= 360.) { thisDec -= 360.; } |
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| 110 | if(type=="RA") thisDec /= 15.; // Convert to hours. |
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| 111 | } |
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| 112 | else if((type=="DEC")||(type=="GLAT")){ |
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| 113 | if(thisDec<0.) sign = "-"; |
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| 114 | else sign = "+"; |
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| 115 | } |
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| 116 | else { // UNKNOWN TYPE -- DEFAULT TO RA. |
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[120] | 117 | duchampWarning("decToDMS", |
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| 118 | "Unknown axis type (" + type + "). Defaulting to using RA.\n"); |
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[38] | 119 | while (thisDec < 0.) { thisDec += 360.; } |
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| 120 | while (thisDec >= 360.) { thisDec -= 360.; } |
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| 121 | thisDec /= 15.; |
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| 122 | } |
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| 123 | |
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| 124 | dec_abs = fabs(thisDec); |
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[3] | 125 | deg = int(dec_abs);//floor(d) |
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| 126 | min = (int)(fmod(dec_abs,1.)*60.); |
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| 127 | sec = fmod(dec_abs,onemin)*3600.; |
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| 128 | if(fabs(sec-60.)<1.e-10){ /* to prevent rounding errors stuffing things up*/ |
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| 129 | sec=0.; |
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| 130 | min++; |
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| 131 | } |
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| 132 | std::stringstream ss(std::stringstream::out); |
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| 133 | ss.setf(std::ios::showpoint); |
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| 134 | ss.setf(std::ios::fixed); |
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[38] | 135 | ss << sign; |
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| 136 | ss << setw(degSize)<<setfill('0')<<deg<<":"; |
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[3] | 137 | ss<<setw(2)<<setfill('0')<<min<<":"; |
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| 138 | ss<<setw(5)<<setprecision(2)<<sec; |
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| 139 | return ss.str(); |
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| 140 | } |
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| 141 | |
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[38] | 142 | |
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[3] | 143 | double dmsToDec(string dms) |
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| 144 | { |
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| 145 | /** |
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| 146 | * double dmsToDec(string) |
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| 147 | * Converts a string in the format +12:23:34.45 to a decimal angle in degrees. |
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| 148 | * Assumes the angle given is in degrees, so if passing RA as the argument, |
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| 149 | * need to multiply by 15 to get the result in degrees rather than hours. |
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| 150 | * The sign of the angle is preserved, if present. |
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| 151 | */ |
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| 152 | |
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| 153 | |
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| 154 | bool isNeg = false; |
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| 155 | if(dms[0]=='-') isNeg = true; |
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| 156 | |
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| 157 | std::stringstream ss; |
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| 158 | ss.str(dms); |
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| 159 | string deg,min,sec; |
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| 160 | getline(ss,deg,':'); |
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| 161 | getline(ss,min,':'); |
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| 162 | getline(ss,sec); |
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| 163 | char *end; |
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| 164 | double d = strtod(deg.c_str(),&end); |
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| 165 | double m = strtod(min.c_str(),&end); |
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| 166 | double s = strtod(sec.c_str(),&end); |
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| 167 | |
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| 168 | double dec = fabs(d) + m/60. + s/3600.; |
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| 169 | if(isNeg) dec = dec * -1.; |
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| 170 | |
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| 171 | return dec; |
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| 172 | |
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| 173 | } |
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| 174 | |
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| 175 | double angularSeparation(double &ra1, double &dec1, double &ra2, double &dec2) |
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| 176 | { |
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| 177 | /** |
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| 178 | * double angularSeparation(double &,double &,double &,double &); |
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| 179 | * Enter ra & dec for two positions. |
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| 180 | * (all positions in degrees) |
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| 181 | * Returns the angular separation in degrees. |
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| 182 | */ |
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| 183 | |
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| 184 | double angsep = cos((ra1-ra2)*M_PI/180.)*cos(dec1*M_PI/180.)*cos(dec2*M_PI/180.) |
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| 185 | + sin(dec1*M_PI/180.)*sin(dec2*M_PI/180.); |
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| 186 | angsep = acos(angsep)*180./M_PI; |
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| 187 | |
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| 188 | return angsep; |
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| 189 | |
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| 190 | } |
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