/* ======================================================================== *\ ! ! * ! * This file is part of MARS, the MAGIC Analysis and Reconstruction ! * Software. It is distributed to you in the hope that it can be a useful ! * and timesaving tool in analysing Data of imaging Cerenkov telescopes. ! * It is distributed WITHOUT ANY WARRANTY. ! * ! * Permission to use, copy, modify and distribute this software and its ! * documentation for any purpose is hereby granted without fee, ! * provided that the above copyright notice appear in all copies and ! * that both that copyright notice and this permission notice appear ! * in supporting documentation. It is provided "as is" without express ! * or implied warranty. ! * ! ! macro comprob.C ! ! Author(s): Abelardo Moralejo ! Author(s): Thomas Bretz, 2002 ! ! Copyright: MAGIC Software Development, 2000-2002 ! ! \* ======================================================================== */ // ------------------------------------------------------------------------- // // This macro demonstrates one way of gamma hadron separation using the // composite probability method. To use it you need a star-file (which is // a file ouput by the star.C macro containing image parameters) // void comprob() { // // Create a empty Parameter List and an empty Task List // The tasklist is identified in the eventloop by its name // MParList plist; // Create task list and add it to the parameter list: MTaskList tlist; plist.AddToList(&tlist); // First task in list: read the star file (reference data) MReadMarsFile read("Events", "star.root"); read.DisableAutoScheme(); tlist.AddToList(&read); // // Task to do the composite analysis of Hillas parameters: // Add(rule, number of bins, lower limit, upper limit) // For the meaning of the rule see MDataChain // MHCompProb compprob(500); compprob.Add("MHillas.fWidth", 500, 0, 160); compprob.Add("MHillas.fLength", 500, 0, 300); compprob.Add("abs(MHillas.fAsym)", 500, 0, 400); compprob.Add("MHillasSrc.fDist", 500, 0, 400); compprob.Add("abs(MHillasSrc.fHeadTail)", 500, 0, 400); compprob.Add("abs(MHillas.fM3Long)", 500, 0, 300); compprob.Add("abs(MHillas.fM3Trans)", 500, 0, 150); compprob.Add("MHillas.fConc1", 500, 0, 0.6); compprob.Add("MHillas.fConc", 500, 0, 0.9); compprob.Add("log10(MHillas.fSize)", 500, 0, 5); plist.AddToList(&compprob); MFillH fill(&compprob, "MMcEvt"); // Use this if you want to do it for a fixed energy range: /* MF filter("MMcEvt.fEnergy < 100"); fill->SetFilter(&filter); tlist.AddToList(&filter); */ tlist.AddToList(&fill); // // Create and setup the eventloop // MEvtLoop evtloop; evtloop.SetParList(&plist); // Loop over all data to fill the "normal" histograms: if (!evtloop.Eventloop()) return; tlist.PrintStatistics(); gLog.SetDebugLevel(2); // Loop to fill the variable bin histograms: read.SetEventNum(0); if (!evtloop.Eventloop()) return; // ------------------------------------------------------------------ // Create task list and replace the old task list with the new one MTaskList tlist2; plist.Replace(&tlist2); // First task in list: read star file (test data) MReadMarsFile read2("Events", "star2.root"); read2.DisableAutoScheme(); tlist2.AddToList(&read2); // create task to calculate composite probabilities MCompProbCalc calc; tlist2.AddToList(&calc); // fill probabilities (hadroness) into histogram MFillH fill2("MHHadronness"); tlist2.AddToList(&fill2); // Loop to fill the hadronness histograms: if (!evtloop.Eventloop()) return; // // Display the hadroness histograms and print some informations on // the console window // plist.FindObject("MHHadronness")->DrawClone(); plist.FindObject("MHHadronness")->Print(); }