/***************************************************************************** * Project: RooFit * * Package: RooFitCore * * @(#)root/roofitcore:$Id$ * Authors: * * WV, Wouter Verkerke, UC Santa Barbara, verkerke@slac.stanford.edu * * DK, David Kirkby, UC Irvine, dkirkby@uci.edu * * * * Copyright (c) 2000-2005, Regents of the University of California * * and Stanford University. All rights reserved. * * * * Redistribution and use in source and binary forms, * * with or without modification, are permitted according to the terms * * listed in LICENSE (http://roofit.sourceforge.net/license.txt) * *****************************************************************************/ ////////////////////////////////////////////////////////////////////////////// // // BEGIN_HTML // A RooEllipse is a two-dimensional ellipse that can be used to represent // an error contour. // END_HTML // #include "RooFit.h" #include "RooEllipse.h" #include "RooEllipse.h" #include "TMath.h" #include "RooMsgService.h" #include "Riostream.h" #include "TClass.h" #include #include using namespace std; ClassImp(RooEllipse) //_____________________________________________________________________________ RooEllipse::RooEllipse() { // Default constructor } //_____________________________________________________________________________ RooEllipse::~RooEllipse() { // Destructor } //_____________________________________________________________________________ RooEllipse::RooEllipse(const char *name, Double_t x1, Double_t x2, Double_t s1, Double_t s2, Double_t rho, Int_t points) { // Create a 2-dimensional ellipse centered at (x1,x2) that represents the confidence // level contour for a measurement with errors (s1,s2) and correlation coefficient rho. // The resulting curve is defined as the unique ellipse that passes through these points: // // (x1+rho*s1,x2+s2) , (x1-rho*s1,x2-s2) , (x1+s1,x2+rho*s2) , (x1-s1,x2-rho*s2) // // and is described by the implicit equation: // // x*x 2*rho*x*y y*y // ----- - --------- + ----- = 1 - rho*rho // s1*s1 s1*s2 s2*s2 // // The input parameters s1,s2 must be > 0 and also |rho| <= 1. // The degenerate case |rho|=1 corresponds to a straight line and // is handled as a special case. SetName(name); SetTitle(name); if(s1 <= 0 || s2 <= 0) { coutE(InputArguments) << "RooEllipse::RooEllipse: bad parameter s1 or s2 < 0" << endl; return; } Double_t tmp= 1-rho*rho; if(tmp < 0) { coutE(InputArguments) << "RooEllipse::RooEllipse: bad parameter |rho| > 1" << endl; return; } if(tmp == 0) { // handle the degenerate case of |rho|=1 SetPoint(0,x1-s1,x2-s2); SetPoint(1,x1+s1,x2+s2); setYAxisLimits(x2-s2,x2+s2); } else { Double_t r,psi,phi,u1,u2,xx1,xx2,dphi(2*TMath::Pi()/points); for(Int_t index= 0; index < points; index++) { phi= index*dphi; // adjust the angular spacing of the points for the aspect ratio psi= atan2(s2*sin(phi),s1*cos(phi)); u1= cos(psi)/s1; u2= sin(psi)/s2; r= sqrt(tmp/(u1*u1 - 2*rho*u1*u2 + u2*u2)); xx1= x1 + r*u1*s1; xx2= x2 + r*u2*s2; SetPoint(index, xx1, xx2); if(index == 0) { setYAxisLimits(xx2,xx2); // add an extra segment to close the curve SetPoint(points, xx1, xx2); } else { updateYAxisLimits(xx2); } } } } //_____________________________________________________________________________ void RooEllipse::printName(ostream& os) const { // Print name of ellipse on ostream os << GetName() ; } //_____________________________________________________________________________ void RooEllipse::printTitle(ostream& os) const { // Print title of ellipse on ostream os << GetName() ; } //_____________________________________________________________________________ void RooEllipse::printClassName(ostream& os) const { // Print class name of ellipse on ostream os << IsA()->GetName() ; } //_____________________________________________________________________________ void RooEllipse::printMultiline(ostream& os, Int_t contents, Bool_t verbose, TString indent) const { // Print detailed multi line information on ellipse on ostreamx RooPlotable::printMultiline(os,contents,verbose,indent); for(Int_t index=0; index < fNpoints; index++) { os << indent << "Point [" << index << "] is at (" << fX[index] << "," << fY[index] << ")" << endl; } }