| 1 | // Classes to compute Multi-Dish or CRT-like radio interferometer response
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| 2 | // R. Ansari - Avril-Mai 2010
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| 3 |
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| 4 | #ifndef MDISH_SEEN
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| 5 | #define MDISH_SEEN
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| 6 |
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| 7 | #include "machdefs.h" // SOPHYA .h
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| 8 | #include "sopnamsp.h" // SOPHYA .h
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| 9 | #include <math.h>
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| 10 | #include <iostream>
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| 11 | #include <vector>
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| 12 | #include <string>
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| 13 |
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| 14 | #include "genericfunc.h" // SOPHYA .h
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| 15 | #include "array.h" // SOPHYA .h
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| 16 | #include "qhist.h"
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| 17 |
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| 18 | #ifndef DeuxPI
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| 19 | #define DeuxPI 2.*M_PI
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| 20 | #endif
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| 21 |
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| 22 | // -- Four2DResponse : Reponse instrumentale ds le plan k_x,k_y (angles theta,phi)
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| 23 | // typ=1 : Reponse gaussienne parabole diametre D exp[ - 0.5 (lambda k_g / D )^2 ]
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| 24 | // typ=2 : Reponse parabole diametre D Triangle <= kmax= 2 pi D / lambda
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| 25 | // typ=3 : Reponse rectangle Dx x Dy Triangle (|kx|,|k_y|) <= (2 pi Dx / lambda, 2 pi Dx / lambda)
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| 26 | class Four2DResponse {
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| 27 | public:
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| 28 | // On donne dx=D/lambda=Dx/lambda , dy=Dy/lambda
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| 29 | Four2DResponse(int typ, double dx, double dy);
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| 30 |
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| 31 | Four2DResponse(Four2DResponse const& a)
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| 32 | { typ_ = a.typ_; dx_=a.dx_; dy_=a.dy_; }
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| 33 | Four2DResponse& operator=(Four2DResponse const& a)
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| 34 | { typ_ = a.typ_; dx_=a.dx_; dy_=a.dy_; return (*this); }
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| 35 |
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| 36 | inline void setLambdaRef(double lambda=1.)
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| 37 | { lambdaref_ = lambda; }
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| 38 | inline void setLambda(double lambda=1.)
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| 39 | { lambda_ = lambda; lambda_ratio_ = lambdaref_/lambda_; }
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| 40 |
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| 41 | // Return the 2D response for wave vector (kx,ky)
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| 42 | virtual double Value(double kx, double ky);
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| 43 | inline double operator()(double kx, double ky)
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| 44 | { return Value(kx, ky); }
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| 45 | virtual Histo2D GetResponse(int nx=256, int ny=256);
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| 46 | inline double D() { return dx_; } ;
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| 47 | inline double Dx() { return dx_; } ;
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| 48 | inline double Dy() { return dy_; } ;
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| 49 |
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| 50 | int typ_;
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| 51 | double dx_, dy_;
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| 52 | double lambdaref_, lambda_;
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| 53 | double lambda_ratio_; // lambdaref_/lambda_;
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| 54 |
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| 55 | };
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| 56 |
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| 57 | // -- Four2DRespTable : Reponse tabulee instrumentale ds le plan k_x,k_y (angles theta,phi)
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| 58 | class Four2DRespTable : public Four2DResponse {
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| 59 | public:
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| 60 | // On donne dx=D/lambda=Dx/lambda , dy=Dy/lambda
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| 61 | Four2DRespTable(Histo2D const & hrep, double d);
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| 62 | // Return the 2D response for wave vector (kx,ky)
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| 63 | virtual double Value(double kx, double ky);
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| 64 | Histo2D hrep_;
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| 65 | };
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| 66 |
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| 67 | // Classe toute simple pour representer un element de reception de type dish
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| 68 | class Dish {
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| 69 | public:
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| 70 | // Circular dish
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| 71 | Dish(int id, double x, double y, double diam)
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| 72 | : id_(id), X(x), Y(y), D(diam), Dx(D), Dy(D), fgcirc_(true) { }
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| 73 | // Receiver with rectangular type answer in kx,ky plane
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| 74 | Dish(int id, double x, double y, double dx, double dy)
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| 75 | : id_(id), X(x), Y(y), D(sqrt(dx*dy)), Dx(dx), Dy(dy), fgcirc_(false) { }
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| 76 | Dish(Dish const& a)
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| 77 | : id_(a.id_), X(a.X), Y(a.Y), D(a.D), Dx(a.Dx), Dy(a.Dy), fgcirc_(a.fgcirc_) { }
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| 78 | inline bool isCircular() { return fgcirc_; }
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| 79 | inline int ReflectorId() { return id_; }
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| 80 | inline double Diameter() { return D; }
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| 81 | inline double DiameterX() { return Dx; }
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| 82 | inline double DiameterY() { return Dx; }
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| 83 |
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| 84 | int id_; // numero de reflecteur
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| 85 | double D,X,Y;
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| 86 | double Dx, Dy;
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| 87 | bool fgcirc_; // false -> rectangular dish
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| 88 | };
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| 89 |
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| 90 |
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| 91 | // -------------------------------------------------------------------
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| 92 | // -- Pour calculer la reponse ds le plan kx,ky d'un system MultiDish
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| 93 | class MultiDish {
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| 94 | public:
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| 95 | MultiDish(double lambda, double dmax, vector<Dish>& dishes, bool fgnoauto=false);
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| 96 |
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| 97 | inline void SetThetaPhiRange(double thetamax=0., int ntet=1, double phimax=0., int nphi=1)
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| 98 | { thetamax_=thetamax; ntet_=ntet; phimax_=phimax; nphi_=nphi; }
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| 99 |
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| 100 | inline void SetRespHisNBins(int nx=128, int ny=128)
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| 101 | { nx_=nx; ny_=ny; }
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| 102 | Histo2D GetResponse();
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| 103 |
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| 104 | double CumulResp(Four2DResponse& rd, double theta=0., double phi=0.);
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| 105 | inline size_t NbDishes() { return dishes_.size(); }
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| 106 | inline Dish& operator[](size_t k) { return dishes_[k]; }
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| 107 |
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| 108 | virtual Histo2D PosDist(int nx=30, int ny=30, double dmax=0.);
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| 109 |
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| 110 | protected:
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| 111 | double AddToHisto(double kx0, double ky0, double x, double y, double w, bool fgfh);
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| 112 |
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| 113 | double lambda_, dmax_;
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| 114 | vector<Dish> dishes_;
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| 115 | bool fgnoauto_;
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| 116 | double thetamax_, phimax_;
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| 117 | int ntet_,nphi_;
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| 118 | int nx_, ny_;
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| 119 | // Histo2D h2w_, h2cnt_;
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| 120 | QHis2D h2w_;
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| 121 | int mcnt_;
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| 122 | };
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| 123 |
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| 124 |
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| 125 | #endif
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