/[PAMELA software]/DarthVader/OrbitalInfo/src/OrbitalInfoCore.cpp

Diff of /DarthVader/OrbitalInfo/src/OrbitalInfoCore.cpp

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-revision 1.1 by mocchiut,
Fri May 19 13:15:57 2006 UTC
+revision 1.40 by mocchiut,
Tue Aug  4 14:01:26 2009 UTC
 Line 13
  #include <TClassEdit.h>
  #include <TObject.h>
  #include <TList.h>
- #include <TArrayL.h>
+ #include <TArrayI.h>
  #include <TSystem.h>
  #include <TSystemDirectory.h>
  #include <TString.h>
 Line 23
  #include <TSQLRow.h>
  #include <TSQLResult.h>
  //
+ // RunInfo header
+ //
+ #include <RunInfo.h>
+ #include <GLTables.h>
+ //
  // YODA headers
  //
  #include <PamelaRun.h>
- #include <RegistryEvent.h>
  #include <PscuHeader.h>
  #include <PscuEvent.h>
  #include <EventHeader.h>
- #include <RegistryEvent.h>
+ #include <mcmd/McmdEvent.h>
- //
+ #include <mcmd/McmdRecord.h>
- // RunInfo header
- //
- #include <RunInfo.h>
- #include <GLTables.h>
  //
  // This program headers
  //
  #include <OrbitalInfo.h>
- #include <OrbitalInfoCore.h>
  #include <OrbitalInfoVerl2.h>
+ #include <OrbitalInfoCore.h>
+ #include <InclinationInfo.h>
  using namespace std;
-Line 49 
 using namespace std;
+Line 51 
 using namespace std;
  // CORE ROUTINE
  //
  //
+ int OrbitalInfoCore(UInt_t run, TFile *file, GL_TABLES *glt, Int_t OrbitalInfoargc, char *OrbitalInfoargv[]){
- int OrbitalInfoCore(ULong64_t run, TFile *file, TSQLServer *dbc, Int_t OrbitalInfoargc, char *OrbitalInfoargv[]){
+   //
    Int_t i = 0;
+   TString host = glt->CGetHost();
+   TString user = glt->CGetUser();
+   TString psw = glt->CGetPsw();
+   TSQLServer *dbc = TSQLServer::Connect(host.Data(),user.Data(),psw.Data());
+   //
+   stringstream myquery;
+   myquery.str("");
+   myquery << "SET time_zone='+0:00'";
+   dbc->Query(myquery.str().c_str());
    //
-   TString processFolder = "OrbitalInfoFolder";
+   TString processFolder = Form("OrbitalInfoFolder_%u",run);
    //
    // Set these to true to have a very verbose output.
    //
    Bool_t debug = false;
    //
    Bool_t verbose = false;
+   //
+   Bool_t standalone = false;
+   //
    if ( OrbitalInfoargc > 0 ){
      i = 0;
      while ( i < OrbitalInfoargc ){
-Line 73 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 86 
 int OrbitalInfoCore(ULong64_t run, TFile
        };
        if ( (!strcmp(OrbitalInfoargv[i],"--debug")) || (!strcmp(OrbitalInfoargv[i],"-g")) ) {
          verbose = true;
+         debug = true;
        };
        if ( (!strcmp(OrbitalInfoargv[i],"--verbose")) || (!strcmp(OrbitalInfoargv[i],"-v")) ) {
          verbose = true;
        };
+       if ( (!strcmp(OrbitalInfoargv[i],"--standalone")) ) {
+         standalone = true;
+       };
+       if ( (!strcmp(OrbitalInfoargv[i],"--calculate-pitch")) ) {
+         standalone = false;
+       };
        i++;
      };
    };
-Line 84 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 104 
 int OrbitalInfoCore(ULong64_t run, TFile
    const char* outDir = gSystem->DirName(gSystem->DirName(file->GetPath()));
    //
    TTree *OrbitalInfotr = 0;
-   Long64_t nevents = 0LL;
+   UInt_t nevents = 0;
+   UInt_t neventsm = 0;
    //
    // variables needed to reprocess data
    //
+   Long64_t maxsize = 10000000000LL;
+   TTree::SetMaxTreeSize(maxsize);
+   //
    TString OrbitalInfoversion;
    ItoRunInfo *runinfo = 0;
-   TArrayL *runlist = 0;
+   TArrayI *runlist = 0;
    TTree *OrbitalInfotrclone = 0;
    Bool_t reproc = false;
    Bool_t reprocall = false;
-Line 99 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 123 
 int OrbitalInfoCore(ULong64_t run, TFile
    UInt_t numbofrun = 0;
    stringstream ftmpname;
    TString fname;
-   Long64_t totfileentries = 0ULL;
+   UInt_t totfileentries = 0;
-   Long64_t idRun = 0LL;
+   UInt_t idRun = 0;
+   //
+   // My variables. Vitaly.
+   //
+   //  UInt_t iev = 0;
+   //  UInt_t j3 = 0;
+   UInt_t oi = 0;
+   Int_t tmpSize = 0;
    //
    // variables needed to handle error signals
    //
-Line 116 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 147 
 int OrbitalInfoCore(ULong64_t run, TFile
    //
    TFile *l0File = 0;
    TTree *l0tr = 0;
-   TBranch *l0registry = 0;
+   //  TTree *l0trm = 0;
-   pamela::RegistryEvent *l0reg=0;
+   TChain *ch = 0;
+   // EM: open also header branch
+   TBranch *l0head = 0;
+   pamela::EventHeader *eh = 0;
+   pamela::PscuHeader *ph = 0;
+   pamela::McmdEvent *mcmdev = 0;
+   pamela::McmdRecord *mcmdrc = 0;
+   // end EM
+   //  pamela::RunHeaderEvent *reh = new pamela::RunHeaderEvent;
+   //  pamela::EventHeader    *eH  = new pamela::EventHeader;
    //
    // Define other basic variables
    //
-Line 126 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 168 
 int OrbitalInfoCore(ULong64_t run, TFile
    stringstream file3;
    stringstream qy;
    Int_t totevent = 0;
-   ULong64_t atime = 0ULL;
+   UInt_t atime = 0;
-   Int_t ei = 0;
+   UInt_t re = 0;
-   Int_t re = 0;
+   UInt_t ik = 0;
+   // Position
+   Float_t lon, lat, alt;
+   //
+   // IGRF stuff
+   //
+   Float_t dimo = 0.0; // dipole moment (computed from dat files)
+   Float_t bnorth, beast, bdown, babs;
+   Float_t xl; // L value
+   Float_t icode; // code value for L accuracy (see fortran code)
+   Float_t bab1; // What's  the difference with babs?
+   Float_t stps = 0.005; // step size for field line tracing
+   Float_t bdel = 0.01; // required accuracy
+   Float_t bequ;  // equatorial b value (also called b_0)
+   Bool_t value = 0; // false if bequ is not the minimum b value
+   Float_t rr0; // equatorial radius normalized to earth radius
    //
    // Working filename
    //
-Line 143 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 203 
 int OrbitalInfoCore(ULong64_t run, TFile
    TTree *tempOrbitalInfo = 0;
    stringstream tempname;
    stringstream OrbitalInfofolder;
+   Bool_t myfold = false;
    tempname.str("");
    tempname << outDir;
    tempname << "/" << processFolder.Data();
    OrbitalInfofolder.str("");
    OrbitalInfofolder << tempname.str().c_str();
-   gSystem->MakeDirectory(OrbitalInfofolder.str().c_str());
    tempname << "/OrbitalInfotree_run";
    tempname << run << ".root";
+   UInt_t totnorun = 0;
    //
    // DB classes
    //
    GL_ROOT *glroot = new GL_ROOT();
+   GL_TIMESYNC *dbtime = 0;
+   GL_TLE *gltle = new GL_TLE();
+   //
+   //Quaternions classes
+   //
+   Quaternions *L_QQ_Q_l_lower = new Quaternions();
+   InclinationInfo *RYPang_lower = new InclinationInfo();
+   Quaternions *L_QQ_Q_l_upper = new Quaternions();
+   InclinationInfo *RYPang_upper = new InclinationInfo();
+   cEci eCi;
+   // Initialize fortran routines!!!
+   Int_t ltp2 = 0;
+   Int_t ltp3 = 0;
+   Int_t uno = 1;
+   char *niente = " ";
+   GL_PARAM *glparam = new GL_PARAM();
+   GL_PARAM *glparam2 = new GL_PARAM();
+   Int_t parerror=glparam->Query_GL_PARAM(1,301,dbc); // parameters stored in DB in GL_PRAM table
+   //
+   // Orientation variables
+   //
+   UInt_t evfrom = 0;
+   UInt_t jumped = 0;
+   Int_t itr = -1;
+   Double_t A1;
+   Double_t A2;
+   Double_t A3;
+   Double_t Px = 0;
+   Double_t Py = 0;
+   Double_t Pz = 0;
+   TTree *ttof = 0;
+   ToFLevel2 *tof = new ToFLevel2();
+   OrientationInfo *PO = new OrientationInfo();
+   Int_t nz = 6;
+   Float_t zin[6];
+   Int_t nevtofl2 = 0;
+   //
+   if ( parerror<0 ) {
+     code = parerror;
+     goto closeandexit;
+   };
+   ltp2 = (Int_t)(glparam->PATH+glparam->NAME).Length();
+   if ( verbose ) printf(" Reading Earth's Magnetic Field parameter file: %s \n",(glparam->PATH+glparam->NAME).Data());
+   //
+   parerror=glparam2->Query_GL_PARAM(1,302,dbc); // parameters stored in DB in GL_PRAM table
+   if ( parerror<0 ) {
+     code = parerror;
+     goto closeandexit;
+   };
+   ltp3 = (Int_t)(glparam2->PATH+glparam2->NAME).Length();
+   if ( verbose ) printf(" Reading Earth's Magnetic Field parameter file: %s \n",(glparam2->PATH+glparam2->NAME).Data());
+   //
+   initize_((char *)niente,&uno,(char *)(glparam->PATH+glparam->NAME).Data(),&ltp2,(char *)(glparam2->PATH+glparam2->NAME).Data(),&ltp3);
+   //
+   // End IGRF stuff//
+   //
+   for (Int_t ip=0;ip<nz;ip++){
+     zin[ip] = tof->GetZTOF(tof->GetToFPlaneID(ip));
+   };
+   //
+   if ( !standalone ){
+     //
+     // Does it contain the Tracker tree?
+     //
+     ttof = (TTree*)file->Get("ToF");
+     if ( !ttof ) {
+       if ( verbose ) printf(" OrbitalInfo - ERROR: no tof tree\n");
+       code = -900;
+       goto closeandexit;
+     };
+     ttof->SetBranchAddress("ToFLevel2",&tof);
+     nevtofl2 = ttof->GetEntries();
+   };
    //
    // Let's start!
    //
-Line 162 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 298 
 int OrbitalInfoCore(ULong64_t run, TFile
    // if run != 0 we must process only that run but first we have to check if the tree MyDetector2 already exist in the file
    // if it exists we are reprocessing data and we must delete that entries, if not we must create it.
    //
-   if ( run == 0ULL )  reproc = true;
+   if ( run == 0 )  reproc = true;
    //
    //
    // Output file is "outputfile"
-Line 209 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 345 
 int OrbitalInfoCore(ULong64_t run, TFile
    // number of run to be processed
    //
    numbofrun = runinfo->GetNoRun();
+   totnorun = runinfo->GetRunEntries();
    //
    // Try to access the OrbitalInfo tree in the file, if it exists we are reprocessing data if not we are processing a new run
    //
-Line 219 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 356 
 int OrbitalInfoCore(ULong64_t run, TFile
      // tree does not exist, we are not reprocessing
      //
      reproc = false;
-     if ( run == 0ULL ){
+     if ( run == 0 ){
        if (verbose) printf(" OrbitalInfo - WARNING: you are reprocessing data but OrbitalInfo tree does not exist!\n");
      }
-     if ( runinfo->IsReprocessing() && run != 0ULL ) {
+     if ( runinfo->IsReprocessing() && run != 0 ) {
        if (verbose) printf(" OrbitalInfo - WARNING: it seems you are not reprocessing data but OrbitalInfo\n versioning information already exists in RunInfo.\n");
      }
    } else {
      //
      // tree exists, we are reprocessing data. Are we reprocessing a single run or all the file?
      //
+     OrbitalInfotrclone->SetAutoSave(900000000000000LL);
      reproc = true;
      //
      //
      if (verbose) printf("\n Preparing the pre-processing...\n");
      //
-     if ( run == 0ULL ){
+     if ( run == 0 || totnorun == 1 ){
        //
        // we are reprocessing all the file
        // if we are reprocessing everything we don't need to copy any old event and we can just work with the new tree and delete the old one immediately
-Line 249 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 387 
 int OrbitalInfoCore(ULong64_t run, TFile
        //
        reprocall = false;
        //
-       if (verbose) printf("\n OrbitalInfo - WARNING: Reprocessing run number %llu \n",run);
+       if (verbose) printf("\n OrbitalInfo - WARNING: Reprocessing run number %u \n",run);
        //
        // copying old tree to a new file
        //
+       gSystem->MakeDirectory(OrbitalInfofolder.str().c_str());
+       myfold = true;
        tempfile = new TFile(tempname.str().c_str(),"RECREATE");
        tempOrbitalInfo = OrbitalInfotrclone->CloneTree(-1,"fast");
        tempOrbitalInfo->SetName("OrbitalInfo-old");
-Line 272 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 412 
 int OrbitalInfoCore(ULong64_t run, TFile
    //
    file->cd();
    OrbitalInfotr = new TTree("OrbitalInfo-new","PAMELA OrbitalInfo data");
+   OrbitalInfotr->SetAutoSave(900000000000000LL);
+   orbitalinfo->Set();//ELENA **TEMPORANEO?**
    OrbitalInfotr->Branch("OrbitalInfo","OrbitalInfo",&orbitalinfo);
    //
    if ( reproc && !reprocall ){
-Line 280 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 422 
 int OrbitalInfoCore(ULong64_t run, TFile
      //
      tempfile = new TFile(tempname.str().c_str(),"READ");
      OrbitalInfotrclone = (TTree*)tempfile->Get("OrbitalInfo-old");
+     OrbitalInfotrclone->SetAutoSave(900000000000000LL);
      OrbitalInfotrclone->SetBranchAddress("OrbitalInfo",&orbitalinfoclone);
      //
      if ( nobefrun > 0 ){
        if (verbose){
-       printf("\n Pre-processing: copying events from the old tree before the processed run\n");
+         printf("\n Pre-processing: copying events from the old tree before the processed run\n");
-       printf(" Copying %u events in the file which are before the beginning of the run %llu \n",nobefrun,run);
+         printf(" Copying %u events in the file which are before the beginning of the run %u \n",nobefrun,run);
-       printf(" Start copying at event number 0, end copying at event number %u \n",nobefrun);
+         printf(" Start copying at event number 0, end copying at event number %u \n",nobefrun);
        }
        for (UInt_t j = 0; j < nobefrun; j++){
          //
-Line 294 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 437 
 int OrbitalInfoCore(ULong64_t run, TFile
          //
          // copy orbitalinfoclone to mydec
          //
-         orbitalinfo = new OrbitalInfo();
+         orbitalinfo->Clear();
+         //
          memcpy(&orbitalinfo,&orbitalinfoclone,sizeof(orbitalinfoclone));
          //
          // Fill entry in the new tree
-Line 316 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 460 
 int OrbitalInfoCore(ULong64_t run, TFile
      //
      // retrieve the first run ID to be processed using the RunInfo list
      //
      idRun = runlist->At(irun);
      if (verbose){
        printf("\n\n\n ####################################################################### \n");
-Line 323 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 468 
 int OrbitalInfoCore(ULong64_t run, TFile
        printf(" ####################################################################### \n\n\n");
      }
      //
-     runinfo->ID_REG_RUN = 0ULL;
+     runinfo->ID_ROOT_L0 = 0;
      //
      // store in the runinfo class the GL_RUN variables for our run
      //
      sgnl = 0;
      sgnl = runinfo->GetRunInfo(idRun);
      if ( sgnl ){
-       //printf("\n OrbitalInfo - ERROR: RunInfo exited with non-zero status\n");
+       if ( debug ) printf("\n OrbitalInfo - ERROR: RunInfo exited with non-zero status\n");
        code = sgnl;
        goto closeandexit;
      } else {
-Line 339 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 484 
 int OrbitalInfoCore(ULong64_t run, TFile
      //
      // now you can access that variables using the RunInfo class this way runinfo->ID_REG_RUN
      //
-     if ( runinfo->ID_REG_RUN == 0 ){
+     if ( runinfo->ID_ROOT_L0 == 0 ){
-       //printf("\n OrbitalInfo - ERROR: no run with ID_RUN = %i \n\n Exiting... \n\n",(int)idRun);
+       if ( debug ) printf("\n OrbitalInfo - ERROR: no run with ID_RUN = %u \n\n Exiting... \n\n",idRun);
        code = -5;
        goto closeandexit;
      };
      //
+     // prepare the timesync for the db
+     //
+     dbtime = new GL_TIMESYNC(runinfo->ID_ROOT_L0,"ID",dbc);
+     //
      // Search in the DB the path and name of the LEVEL0 file to be processed.
      //
-     glroot->Query_GL_ROOT(runinfo->ID_REG_RUN,dbc);
+     glroot->Query_GL_ROOT(runinfo->ID_ROOT_L0,dbc);
      //
      ftmpname.str("");
      ftmpname << glroot->PATH.Data() << "/";
      ftmpname << glroot->NAME.Data();
      fname = ftmpname.str().c_str();
+     ftmpname.str("");
      //
-     // print out informations
+     // print nout informations
      //
-     totevent = runinfo->EV_REG_PHYS_TO - runinfo->EV_REG_PHYS_FROM + 1;
+     totevent = runinfo->NEVENTS;
+     evfrom = runinfo->EV_FROM;
+     //cout<<"totevents = "<<totevent<<"\n";
      if (verbose){
        printf("\n LEVEL0 data file: %s \n",fname.Data());
-       printf(" RUN HEADER absolute time is:  %llu \n",runinfo->RUNHEADER_TIME);
+       printf(" RUN HEADER absolute time is:  %u \n",runinfo->RUNHEADER_TIME);
-       printf(" RUN TRAILER absolute time is: %llu \n",runinfo->RUNTRAILER_TIME);
+       printf(" RUN TRAILER absolute time is: %u \n",runinfo->RUNTRAILER_TIME);
-       printf(" %i events to be processed for run %llu: from %i to %i (reg entries)\n\n",totevent,idRun,runinfo->EV_REG_PHYS_FROM,runinfo->EV_REG_PHYS_TO);
+       printf(" %i events to be processed for run %u: from %i to %i \n\n",totevent,idRun,runinfo->EV_FROM+1,runinfo->EV_FROM+totevent);
      }//
+     //
+     //    if ( !totevent ) goto closeandexit;
      // Open Level0 file
      l0File = new TFile(fname.Data());
      if ( !l0File ) {
-       //printf(" OrbitalInfo - ERROR: problems opening Level0 file\n");
+       if ( debug ) printf(" OrbitalInfo - ERROR: problems opening Level0 file\n");
        code = -6;
        goto closeandexit;
      };
      l0tr = (TTree*)l0File->Get("Physics");
      if ( !l0tr ) {
-       //printf(" OrbitalInfo - ERROR: no Physics tree in Level0 file\n");
+       if ( debug ) printf(" OrbitalInfo - ERROR: no Physics tree in Level0 file\n");
        l0File->Close();
        code = -7;
        goto closeandexit;
      };
-     l0registry = l0tr->GetBranch("Registry");
+     // EM: open header branch as well
-     if ( !l0registry ) {
+     l0head = l0tr->GetBranch("Header");
-       //printf(" OrbitalInfo - ERROR: no Registry branch in Level0 tree\n");
+     if ( !l0head ) {
+       if ( debug ) printf(" OrbitalInfo - ERROR: no Header branch in Level0 tree\n");
        l0File->Close();
-       code = -9;
+       code = -8;
        goto closeandexit;
      };
+     l0tr->SetBranchAddress("Header", &eh);
+     // end EM
+     nevents = l0head->GetEntries();
      //
-     l0tr->SetBranchAddress("Registry", &l0reg);
+     if ( nevents < 1 && totevent ) {
-     //
+       if ( debug ) printf(" OrbitalInfo - ERROR: Level0 file is empty\n\n");
-     nevents = l0registry->GetEntries();
-     //
-     if ( nevents < 1 ) {
-       //printf(" OrbitalInfo - ERROR: Level0 file is empty\n\n");
        l0File->Close();
        code = -11;
        goto closeandexit;
      };
      //
-     if ( runinfo->EV_REG_PHYS_TO > nevents-1 ) {
+     if ( runinfo->EV_TO > nevents-1 && totevent ) {
-       //printf(" OrbitalInfo - ERROR: too few entries in the registry tree\n");
+       if ( debug ) printf(" OrbitalInfo - ERROR: too few entries in the registry tree\n");
        l0File->Close();
        code = -12;
        goto closeandexit;
      };
      //
+ //     TTree *tp = (TTree*)l0File->Get("RunHeader");
+ //     tp->SetBranchAddress("Header", &eH);
+ //     tp->SetBranchAddress("RunHeader", &reh);
+ //     tp->GetEntry(0);
+ //     ph = eH->GetPscuHeader();
+ //     ULong_t TimeSync = reh->LAST_TIME_SYNC_INFO;
+ //     ULong_t ObtSync = reh->OBT_TIME_SYNC;
+ //     if ( debug ) printf(" 1 TimeSync %lu ObtSync %lu DeltaOBT %lu\n",TimeSync,ObtSync,TimeSync-ObtSync);
+ //
+     ULong_t TimeSync = (ULong_t)dbtime->GetTimesync();
+     ULong_t ObtSync = (ULong_t)(dbtime->GetObt0()/1000);
+     ULong_t DeltaOBT = TimeSync - ObtSync;
+     if ( debug ) printf(" 2 TimeSync %lu ObtSync %lu DeltaOBT %lu\n",(ULong_t)(dbtime->GetTimesync()/1000),(ULong_t)dbtime->GetObt0(),TimeSync-ObtSync);
+     //
+     // Read MCMDs from up to 11 files, 5 before and 5 after the present one in order to have some kind of inclination information
+     //
+     ch = new TChain("Mcmd","Mcmd");
+     //
+     // look in the DB to find the closest files to this run
+     //
+     TSQLResult *pResult = 0;
+     TSQLRow *Row = 0;
+     stringstream myquery;
+     UInt_t l0fid[10];
+     Int_t i = 0;
+     memset(l0fid,0,10*sizeof(Int_t));
+     //
+     myquery.str("");
+     myquery << "select ID_ROOT_L0 from GL_RUN where RUNHEADER_TIME<=" << runinfo->RUNHEADER_TIME << " group by ID_ROOT_L0 order by RUNHEADER_TIME desc limit 5;";
+     //
+     pResult = dbc->Query(myquery.str().c_str());
+     //
+     i = 9;
+     if( pResult ){
+       //
+       Row = pResult->Next();
+       //
+       while ( Row ){
+         //
+         // store infos and exit
+         //
+         l0fid[i] = (UInt_t)atoll(Row->GetField(0));
+         i--;
+         Row = pResult->Next();
+         //
+       };
+       pResult->Delete();
+     };
+     //
+     myquery.str("");
+     myquery << "select ID_ROOT_L0 from GL_RUN where RUNHEADER_TIME>" << runinfo->RUNHEADER_TIME << " group by ID_ROOT_L0 order by RUNHEADER_TIME asc limit 5;";
+     //
+     pResult = dbc->Query(myquery.str().c_str());
+     //
+     i = 0;
+     if( pResult ){
+       //
+       Row = pResult->Next();
+       //
+       while ( Row ){
+         //
+         // store infos and exit
+         //
+         l0fid[i] = (UInt_t)atoll(Row->GetField(0));
+         i++;
+         Row = pResult->Next();
+         //
+       };
+       pResult->Delete();
+     };
+     //
+     i = 0;
+     UInt_t previd = 0;
+     while ( i < 10 ){
+       if ( l0fid[i] && previd != l0fid[i] ){
+         previd = l0fid[i];
+         myquery.str("");
+         myquery << "select PATH,NAME from GL_ROOT where ID=" << l0fid[i] << " ;";
+         //
+         pResult = dbc->Query(myquery.str().c_str());
+         //
+         if( pResult ){
+           //
+           Row = pResult->Next();
+           //
+           if ( debug ) printf(" Using inclination informations from file: %s \n",(((TString)gSystem->ExpandPathName(Row->GetField(0)))+"/"+(TString)Row->GetField(1)).Data());
+           ch->Add(((TString)gSystem->ExpandPathName(Row->GetField(0)))+"/"+(TString)Row->GetField(1));
+           //
+           pResult->Delete();
+         };
+       };
+       i++;
+     };
+     //
+     //    l0trm = (TTree*)l0File->Get("Mcmd");
+     //    ch->ls();
+     ch->SetBranchAddress("Mcmd",&mcmdev);
+     //    printf(" entries %llu \n", ch->GetEntries());
+     //    l0trm = ch->GetTree();
+     //    neventsm = l0trm->GetEntries();
+     neventsm = ch->GetEntries();
+     if ( debug ) printf(" entries %u \n", neventsm);
+     //    neventsm = 0;
+     //
+     if (neventsm == 0){
+       if ( debug ) printf("InclinationInfo - WARNING: No quaternions in this File");
+       //      l0File->Close();
+       code = 900;
+       //      goto closeandexit;
+     }
+     //
+     //    l0trm->SetBranchAddress("Mcmd", &mcmdev);
+     //    l0trm->SetBranchAddress("Header", &eh);
+     //
+     //
+     //
+     UInt_t mctren = 0;
+     UInt_t mcreen = 0;
+     UInt_t numrec = 0;
+     //
+     Double_t upperqtime = 0;
+     Double_t lowerqtime = 0;
+     Double_t incli = 0;
+     oi = 0;
+     UInt_t ooi = 0;
+     //
+     // init quaternions sync
+     //
+     Bool_t isf = true;
+     Int_t fgh = 0;
+     //
      // run over all the events of the run
      //
      if (verbose) printf("\n Ready to start! \n\n Processed events: \n\n");
      //
-     for ( re = runinfo->EV_REG_PHYS_FROM; re <= runinfo->EV_REG_PHYS_TO; re++){
+      //
+     for ( re = runinfo->EV_FROM; re < (runinfo->EV_FROM+runinfo->NEVENTS); re++){
        //
-       if ( procev%1000 == 0 && procev > 0 && verbose) printf(" %iK \n",procev/1000);
+       if ( procev%1000 == 0 && procev > 0 && verbose ) printf(" %iK \n",procev/1000);
+       if ( debug ) printf(" %i \n",procev);
        //
-       l0registry->GetEntry(re);
+       l0head->GetEntry(re);
        //
        // absolute time of this event
        //
-       atime = l0reg->absTime;
+       ph = eh->GetPscuHeader();
-       //
+       atime = dbtime->DBabsTime(ph->GetOrbitalTime());
-       // physics events is at entry number ei where
+       if ( debug ) printf(" %i absolute time \n",procev);
-       //
-       ei = l0reg->event;
        //
        // paranoid check
        //
-       if ( (atime > runinfo->RUNTRAILER_TIME) || (atime < runinfo->RUNHEADER_TIME)  ) {
+       if ( (atime > (runinfo->RUNTRAILER_TIME+1)) || (atime < (runinfo->RUNHEADER_TIME-1))  ) {
          if (verbose) printf(" OrbitalInfo - WARNING: event at time outside the run time window, skipping it\n");
-         goto jumpev;
+         jumped++;
+ //      debug = true;
+         continue;
+       }
+       //
+       // retrieve tof informations
+       //
+       if ( !reprocall ){
+         itr = nobefrun + (re - evfrom - jumped);
+         //itr = re-(46438+200241);
+       } else {
+         itr = runinfo->GetFirstEntry() + (re - evfrom - jumped);
+       };
+       //
+       if ( !standalone ){
+         if ( itr > nevtofl2 ){
+           if ( verbose ) printf(" OrbitalInfo - ERROR: no tof events with entry = %i in Level2 file\n",itr);
+           if ( debug ) printf(" nobefrun %u re %u evfrom %u jumped %u reprocall %i \n",nobefrun,re,evfrom,jumped,reprocall);
+           l0File->Close();
+           code = -901;
+           goto closeandexit;
+         };
+         //
+         tof->Clear();
+         //
+         ttof->GetEntry(itr);
+         //
        };
        //
        procev++;
        //
        // start processing
        //
-       orbitalinfo = new OrbitalInfo();
+       if ( debug ) printf(" %i start processing \n",procev);
-       orbitalinfo->absTime = l0reg->absTime;
+       orbitalinfo->Clear();
+       //
+       OrbitalInfoTrkVar *t_orb = new OrbitalInfoTrkVar();
+       if( !(orbitalinfo->OrbitalInfoTrk) ) orbitalinfo->OrbitalInfoTrk = new TClonesArray("OrbitalInfoTrkVar",2);
+       TClonesArray &tor = *orbitalinfo->OrbitalInfoTrk;
+       //
+       // Fill OBT, pkt_num and absTime
+       //
+       orbitalinfo->pkt_num = ph->GetCounter();
+       orbitalinfo->OBT = ph->GetOrbitalTime();
+       orbitalinfo->absTime = atime;
+       if ( debug ) printf(" %i pktnum obt abstime \n",procev);
+       //
+       // Propagate the orbit from the tle time to atime, using SGP(D)4.
+       //
+       if ( debug ) printf(" %i sgp4 \n",procev);
+       cCoordGeo coo;
+       Float_t jyear=0.;
+       //
+       if(atime >= gltle->GetToTime()) {
+         if ( !gltle->Query(atime, dbc) ){
+           //
+           // Compute the magnetic dipole moment.
+           //
+           if ( debug ) printf(" %i compute magnetic dipole moment \n",procev);
+           UInt_t year, month, day, hour, min, sec;
+           //
+           TTimeStamp t = TTimeStamp(atime, kTRUE);
+           t.GetDate(kTRUE, 0, &year, &month, &day);
+           t.GetTime(kTRUE, 0, &hour, &min, &sec);
+           jyear = (float) year
+             + (month*31.+ (float) day)/365.
+             + (hour*3600.+min*60.+(float)sec)/(24*3600*365.);
+           //
+           if ( debug ) printf(" %i compute magnetic dipole moment get dipole moment for year\n",procev);
+           feldcof_(&jyear, &dimo); // get dipole moment for year
+           if ( debug ) printf(" %i compute magnetic dipole moment end\n",procev);
+         } else {
+           code = -56;
+           goto closeandexit;
+         };
+       }
+       coo = getCoo(atime, gltle->GetFromTime(), gltle->GetTle());
+       //
+       cOrbit orbits(*gltle->GetTle());
+       //
+       if ( debug ) printf(" I am Here \n");
+       //
+       // synchronize with quaternions data
+       //
+       if ( isf && neventsm>0 ){
+         if ( debug ) printf(" I am here \n");
+         //
+         // First event
+         //
+         isf = false;
+         upperqtime = atime;
+         lowerqtime = runinfo->RUNHEADER_TIME;
+         for ( ik = 0; ik < neventsm; ik++){
+           //      l0trm->GetEntry(ik);
+           ch->GetEntry(ik);
+           tmpSize = mcmdev->Records->GetEntries();
+           numrec = tmpSize;
+           for (Int_t j3 = 0;j3<tmpSize;j3++){
+             if ( debug ) printf(" ik %i j3 %i eh eh eh \n",ik,j3);
+             mcmdrc = (pamela::McmdRecord*)mcmdev->Records->At(j3);
+             if ( mcmdrc ){ // missing inclination bug [8RED 090116]
+               if ((int)mcmdrc->ID1 == 226){
+                 L_QQ_Q_l_upper->fill(mcmdrc->McmdData);
+                 for (UInt_t ui = 0; ui < 6; ui++){
+                   if (ui>0){
+                     if (L_QQ_Q_l_upper->time[ui]>L_QQ_Q_l_upper->time[0]){
+                       if (dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[ui]*1000-DeltaOBT*1000))<atime){
+                         upperqtime = dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[ui]*1000-DeltaOBT*1000));
+                         orbits.getPosition((double) (upperqtime - gltle->GetFromTime())/60., &eCi);
+                         RYPang_upper->TransAngle(eCi.getPos().m_x,eCi.getPos().m_y,eCi.getPos().m_z,eCi.getVel().m_x,eCi.getVel().m_y,eCi.getVel().m_z,L_QQ_Q_l_upper->quat[ui][0],L_QQ_Q_l_upper->quat[ui][1],L_QQ_Q_l_upper->quat[ui][2],L_QQ_Q_l_upper->quat[ui][3]);
+                       }else {
+                         lowerqtime = upperqtime;
+                         upperqtime = dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[ui]*1000-DeltaOBT*1000));
+                         orbits.getPosition((double) (upperqtime - gltle->GetFromTime())/60., &eCi);
+                         RYPang_upper->TransAngle(eCi.getPos().m_x,eCi.getPos().m_y,eCi.getPos().m_z,eCi.getVel().m_x,eCi.getVel().m_y,eCi.getVel().m_z,L_QQ_Q_l_upper->quat[ui][0],L_QQ_Q_l_upper->quat[ui][1],L_QQ_Q_l_upper->quat[ui][2],L_QQ_Q_l_upper->quat[ui][3]);
+                         mcreen = j3;
+                         mctren = ik;
+                         if(fgh==0){
+                           CopyQ(L_QQ_Q_l_lower,L_QQ_Q_l_upper);
+                           CopyAng(RYPang_lower,RYPang_upper);
+                         }
+                         oi=ui;
+                         goto closethisloop;
+                       }
+                       fgh++;
+                       CopyQ(L_QQ_Q_l_lower,L_QQ_Q_l_upper);
+                       CopyAng(RYPang_lower,RYPang_upper);
+                     }
+                   }else{
+                     if (dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))<atime){
+                       upperqtime = dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+                       orbits.getPosition((double) (upperqtime - gltle->GetFromTime())/60., &eCi);
+                       RYPang_upper->TransAngle(eCi.getPos().m_x,eCi.getPos().m_y,eCi.getPos().m_z,eCi.getVel().m_x,eCi.getVel().m_y,eCi.getVel().m_z,L_QQ_Q_l_upper->quat[0][0],L_QQ_Q_l_upper->quat[0][1],L_QQ_Q_l_upper->quat[0][2],L_QQ_Q_l_upper->quat[0][3]);
+                     }
+                     else {
+                       lowerqtime = upperqtime;
+                       upperqtime = dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+                       orbits.getPosition((double) (upperqtime - gltle->GetFromTime())/60., &eCi);
+                       RYPang_upper->TransAngle(eCi.getPos().m_x,eCi.getPos().m_y,eCi.getPos().m_z,eCi.getVel().m_x,eCi.getVel().m_y,eCi.getVel().m_z,L_QQ_Q_l_upper->quat[0][0],L_QQ_Q_l_upper->quat[0][1],L_QQ_Q_l_upper->quat[0][2],L_QQ_Q_l_upper->quat[0][3]);
+                       mcreen = j3;
+                       mctren = ik;
+                       if(fgh==0){
+                         CopyQ(L_QQ_Q_l_lower,L_QQ_Q_l_upper);
+                         CopyAng(RYPang_lower,RYPang_upper);
+                         lowerqtime = atime-1;
+                       }
+                       oi=ui;
+                       goto closethisloop;
+                       //_0 = true;
+                     }
+                     fgh++;
+                     CopyQ(L_QQ_Q_l_lower,L_QQ_Q_l_upper);
+                     CopyAng(RYPang_lower,RYPang_upper);
+                     //_0 = true;
+                   };
+                   //cin>>grib;
+                 };
+               };
+             };
+           };
+         };
+       };
+     closethisloop:
+       //
+       if ( debug ) printf(" I am There \n");
+       //
+       if (((atime>(UInt_t)upperqtime)||(atime<(UInt_t)lowerqtime)) && neventsm>0 ){
+         if ( debug ) printf(" I am there \n");
+         //
+         lowerqtime = upperqtime;
+         Long64_t maxloop = 100000000LL;
+         Long64_t mn = 0;
+         Bool_t gh=false;
+         ooi=oi;
+         if ( verbose ) printf(" OrbitalInfoCore: sync with quaternions data upperqtime %u lowerqtime %u atime %u \n",(UInt_t)upperqtime,(UInt_t)lowerqtime,atime);
+         while (!gh){
+           if ( mn > maxloop ){
+             if ( verbose ) printf(" OrbitalInfoCore: quaternions sync out of range! exiting\n");
+             gh = true;
+             neventsm = 0;
+           };
+           mn++;
+           if (oi<5) oi++;
+           else oi=0;
+           if (oi==0 && numrec > 0){
+             if ( debug ) printf(" mumble \n");
+             mcreen++;
+             if (mcreen == numrec){
+               mctren++;
+               mcreen = 0;
+               //              l0trm->GetEntry(mctren);
+               ch->GetEntry(mctren);
+               numrec = mcmdev->Records->GetEntries();
+             }
+             CopyQ(L_QQ_Q_l_lower,L_QQ_Q_l_upper);
+             CopyAng(RYPang_lower,RYPang_upper);
+             mcmdrc = (pamela::McmdRecord*)mcmdev->Records->At(mcreen);
+             if ( mcmdrc ){ // missing inclination bug [8RED 090116]
+               if ((int)mcmdrc->ID1 == 226){
+                 L_QQ_Q_l_upper->fill(mcmdrc->McmdData);
+                 upperqtime = dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+                 if (upperqtime<lowerqtime){
+                   upperqtime=runinfo->RUNTRAILER_TIME;
+                   CopyQ(L_QQ_Q_l_upper,L_QQ_Q_l_lower);
+                   CopyAng(RYPang_upper,RYPang_lower);
+                 }else{
+                   orbits.getPosition((double) (upperqtime - gltle->GetFromTime())/60., &eCi);
+                   RYPang_upper->TransAngle(eCi.getPos().m_x,eCi.getPos().m_y,eCi.getPos().m_z,eCi.getVel().m_x,eCi.getVel().m_y,eCi.getVel().m_z,L_QQ_Q_l_upper->quat[0][0],L_QQ_Q_l_upper->quat[0][1],L_QQ_Q_l_upper->quat[0][2],L_QQ_Q_l_upper->quat[0][3]);
+                 }
+                 //            re--;
+                 gh=true;
+               }
+             };
+           }else{
+             if ((Int_t)L_QQ_Q_l_upper->time[oi]>(Int_t)L_QQ_Q_l_upper->time[0]){
+               upperqtime = dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+               orbits.getPosition((double) (upperqtime - gltle->GetFromTime())/60., &eCi);
+               RYPang_upper->TransAngle(eCi.getPos().m_x,eCi.getPos().m_y,eCi.getPos().m_z,eCi.getVel().m_x,eCi.getVel().m_y,eCi.getVel().m_z,L_QQ_Q_l_upper->quat[oi][0],L_QQ_Q_l_upper->quat[oi][1],L_QQ_Q_l_upper->quat[oi][2],L_QQ_Q_l_upper->quat[oi][3]);
+               orbits.getPosition((double) (lowerqtime - gltle->GetFromTime())/60., &eCi);
+               RYPang_lower->TransAngle(eCi.getPos().m_x,eCi.getPos().m_y,eCi.getPos().m_z,eCi.getVel().m_x,eCi.getVel().m_y,eCi.getVel().m_z,L_QQ_Q_l_upper->quat[oi-1][0],L_QQ_Q_l_upper->quat[oi-1][1],L_QQ_Q_l_upper->quat[oi-1][2],L_QQ_Q_l_upper->quat[oi-1][3]);
+               //              re--;
+               gh=true;
+             };
+           };
+         };
+         if ( verbose ) printf(" OrbitalInfoCore: sync with quaternions data now we have upperqtime %u lowerqtime %u atime %u \n",(UInt_t)upperqtime,(UInt_t)lowerqtime,atime);
+       };
+       //
+       if ( debug ) printf(" I am THIS \n");
+       //
+       // Fill in quaternions and angles
+       //
+       if ((atime<=(UInt_t)upperqtime)&&(atime>=(UInt_t)lowerqtime)&& neventsm>0){
+         if ( debug ) printf(" I am this \n");
+         UInt_t tut = holeq(lowerqtime, upperqtime, L_QQ_Q_l_lower, L_QQ_Q_l_upper, oi);
+         if (oi == 0){
+           if ((tut!=5)||(tut!=6)){
+             incli = (L_QQ_Q_l_upper->quat[0][0]-L_QQ_Q_l_lower->quat[ooi][0])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+             orbitalinfo->q0 =  incli*atime+L_QQ_Q_l_upper->quat[0][0]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+             incli =     (L_QQ_Q_l_upper->quat[0][1]-L_QQ_Q_l_lower->quat[ooi][1])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+             orbitalinfo->q1 =  incli*atime+L_QQ_Q_l_upper->quat[0][1]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+             incli = (L_QQ_Q_l_upper->quat[0][2]-L_QQ_Q_l_lower->quat[ooi][2])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+             orbitalinfo->q2 =  incli*atime+L_QQ_Q_l_upper->quat[0][2]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+             incli = (L_QQ_Q_l_upper->quat[0][3]-L_QQ_Q_l_lower->quat[ooi][3])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+             orbitalinfo->q3 =  incli*atime+L_QQ_Q_l_upper->quat[0][3]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+             incli = (RYPang_upper->Tangazh-RYPang_lower->Tangazh)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+             orbitalinfo->theta =  incli*atime+RYPang_upper->Tangazh-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+             incli = (RYPang_upper->Ryskanie-RYPang_lower->Ryskanie)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+             orbitalinfo->phi =  incli*atime+RYPang_upper->Ryskanie-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+             incli = (RYPang_upper->Kren-RYPang_lower->Kren)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000)));
+             orbitalinfo->etha =  incli*atime+RYPang_upper->Kren-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+           }
+           if (tut==6){
+             if (fabs(RYPang_lower->Kren-RYPang_upper->Kren)<0.1){
+               incli = (L_QQ_Q_l_upper->quat[0][0]-L_QQ_Q_l_lower->quat[ooi][0])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+               orbitalinfo->q0 =  incli*atime+L_QQ_Q_l_upper->quat[0][0]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+               incli =           (L_QQ_Q_l_upper->quat[0][1]-L_QQ_Q_l_lower->quat[ooi][1])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+               orbitalinfo->q1 =  incli*atime+L_QQ_Q_l_upper->quat[0][1]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+               incli = (L_QQ_Q_l_upper->quat[0][2]-L_QQ_Q_l_lower->quat[ooi][2])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+               orbitalinfo->q2 =  incli*atime+L_QQ_Q_l_upper->quat[0][2]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+               incli = (L_QQ_Q_l_upper->quat[0][3]-L_QQ_Q_l_lower->quat[ooi][3])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+               orbitalinfo->q3 =  incli*atime+L_QQ_Q_l_upper->quat[0][3]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+               incli = (RYPang_upper->Tangazh-RYPang_lower->Tangazh)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+               orbitalinfo->theta =  incli*atime+RYPang_upper->Tangazh-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+               incli = (RYPang_upper->Ryskanie-RYPang_lower->Ryskanie)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+               orbitalinfo->phi =  incli*atime+RYPang_upper->Ryskanie-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+               //cout<<"upper = "<<RYPang_upper->Ryskanie<<" lower = "<<RYPang_lower->Ryskanie<<" timeupper[0] = "<<L_QQ_Q_l_upper->time[0]-5500000<<" timelower["<<ooi<<"] = "<<L_QQ_Q_l_lower->time[ooi]-5500000<<" Ryscanie = "<<orbitalinfo->phi<<" incli = "<<incli<<" upper-lower = "<<RYPang_upper->Ryskanie-RYPang_lower->Ryskanie<<" Dtime = "<<dbtime->DBabsTime((UInt_t)L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000)<<"-"<<dbtime->DBabsTime((UInt_t)L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)<<" atime = "<<atime<<"\n";
+               //cin>>grib;
+               incli = (RYPang_upper->Kren-RYPang_lower->Kren)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_lower->time[ooi]*1000-DeltaOBT*1000)));
+               orbitalinfo->etha =  incli*atime+RYPang_upper->Kren-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[0]*1000-DeltaOBT*1000));
+             }
+           }
+         } else {
+           if((tut!=6)||(tut!=7)||(tut!=9)){
+             incli = (L_QQ_Q_l_upper->quat[oi][0]-L_QQ_Q_l_upper->quat[oi-1][0])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+             orbitalinfo->q0 =  incli*atime+L_QQ_Q_l_upper->quat[oi][0]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+             incli = (L_QQ_Q_l_upper->quat[oi][1]-L_QQ_Q_l_upper->quat[oi-1][1])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+             orbitalinfo->q1 =  incli*atime+L_QQ_Q_l_upper->quat[oi][1]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+             incli = (L_QQ_Q_l_upper->quat[oi][2]-L_QQ_Q_l_upper->quat[oi-1][2])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+             orbitalinfo->q2 =  incli*atime+L_QQ_Q_l_upper->quat[oi][2]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+             incli = (L_QQ_Q_l_upper->quat[oi][3]-L_QQ_Q_l_upper->quat[oi-1][3])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+             orbitalinfo->q3 =  incli*atime+L_QQ_Q_l_upper->quat[oi][3]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+             incli = (RYPang_upper->Tangazh-RYPang_lower->Tangazh)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+             orbitalinfo->theta =  incli*atime+RYPang_upper->Tangazh-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+             incli = (RYPang_upper->Ryskanie-RYPang_lower->Ryskanie)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+             orbitalinfo->phi =  incli*atime+RYPang_upper->Ryskanie-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+             //cout<<"upper = "<<RYPang_upper->Ryskanie<<" lower = "<<RYPang_lower->Ryskanie<<" timeupper["<<oi<<"] = "<<L_QQ_Q_l_upper->time[oi]-5500000<<" timelower["<<oi-1<<"] = "<<L_QQ_Q_l_lower->time[oi-1]-5500000<<" Ryscanie = "<<orbitalinfo->phi<<" incli = "<<incli<<" upper-lower = "<<RYPang_upper->Ryskanie-RYPang_lower->Ryskanie<<" Dtime = "<<dbtime->DBabsTime((UInt_t)L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000)<<"-"<<dbtime->DBabsTime((UInt_t)L_QQ_Q_l_lower->time[oi-1]*1000-DeltaOBT*1000)<<" atime = "<<atime<<"\n";
+             //cin>>grib;
+             incli = (RYPang_upper->Kren-RYPang_lower->Kren)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+             orbitalinfo->etha =  incli*atime+RYPang_upper->Kren-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+           }
+           if (tut==6){
+             if (fabs(RYPang_lower->Kren-RYPang_upper->Kren)<0.1){
+               incli = (L_QQ_Q_l_upper->quat[oi][0]-L_QQ_Q_l_upper->quat[oi-1][0])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+               orbitalinfo->q0 =  incli*atime+L_QQ_Q_l_upper->quat[oi][0]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+               incli = (L_QQ_Q_l_upper->quat[oi][1]-L_QQ_Q_l_upper->quat[oi-1][1])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+               orbitalinfo->q1 =  incli*atime+L_QQ_Q_l_upper->quat[oi][1]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+               incli = (L_QQ_Q_l_upper->quat[oi][2]-L_QQ_Q_l_upper->quat[oi-1][2])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+               orbitalinfo->q2 =  incli*atime+L_QQ_Q_l_upper->quat[oi][2]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+               incli = (L_QQ_Q_l_upper->quat[oi][3]-L_QQ_Q_l_upper->quat[oi-1][3])/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+               orbitalinfo->q3 =  incli*atime+L_QQ_Q_l_upper->quat[oi][3]-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+               incli = (RYPang_upper->Tangazh-RYPang_lower->Tangazh)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+               orbitalinfo->theta =  incli*atime+RYPang_upper->Tangazh-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+               incli = (RYPang_upper->Ryskanie-RYPang_lower->Ryskanie)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+               orbitalinfo->phi =  incli*atime+RYPang_upper->Ryskanie-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+               //cout<<"upper = "<<RYPang_upper->Ryskanie<<" lower = "<<RYPang_lower->Ryskanie<<" timeupper["<<oi<<"] = "<<L_QQ_Q_l_upper->time[oi]-5500000<<" timelower["<<oi-1<<"] = "<<L_QQ_Q_l_lower->time[oi-1]-5500000<<" Ryscanie = "<<orbitalinfo->phi<<" incli = "<<incli<<" upper-lower = "<<RYPang_upper->Ryskanie-RYPang_lower->Ryskanie<<" Dtime = "<<dbtime->DBabsTime((UInt_t)L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000)<<"-"<<dbtime->DBabsTime((UInt_t)L_QQ_Q_l_lower->time[oi-1]*1000-DeltaOBT*1000)<<" atime = "<<atime<<"\n";
+               //cin>>grib;
+               incli = (RYPang_upper->Kren-RYPang_lower->Kren)/(dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000))-dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi-1]*1000-DeltaOBT*1000)));
+               orbitalinfo->etha =  incli*atime+RYPang_upper->Kren-incli*dbtime->DBabsTime((UInt_t)(L_QQ_Q_l_upper->time[oi]*1000-DeltaOBT*1000));
+             }
+           }
+         }
+         //
+         orbitalinfo->mode = holeq(lowerqtime, upperqtime, L_QQ_Q_l_lower, L_QQ_Q_l_upper, oi);
+         //
+       } else {
+         if ( debug ) printf(" ops no incl! \n");
+         orbitalinfo->mode = 10;
+       };
+       //
+       // ops no inclination information
+       //
+       if ( orbitalinfo->q0< -999 || orbitalinfo->q1 < -999 || orbitalinfo->q2 < -999 || orbitalinfo->q3 < -999 || orbitalinfo->q0 != orbitalinfo->q0 || orbitalinfo->q1 != orbitalinfo->q1 || orbitalinfo->q2 != orbitalinfo->q2 || orbitalinfo->q3 != orbitalinfo->q3 ){
+         orbitalinfo->mode = 10;
+         orbitalinfo->q0 = -1000.;
+         orbitalinfo->q1 = -1000.;
+         orbitalinfo->q2 = -1000.;
+         orbitalinfo->q3 = -1000.;
+         orbitalinfo->etha = -1000.;
+         orbitalinfo->phi = -1000.;
+         orbitalinfo->theta = -1000.;
+       };
+       //
+       // #########################################################################################################################
+       //
+       // fill orbital positions
+       //
+       // Build coordinates in the right range.  We want to convert,
+       // longitude from (0, 2*pi) to (-180deg, 180deg).  Altitude is
+       // in meters.
+       lon = (coo.m_Lon > M_PI) ? rad2deg(coo.m_Lon - 2*M_PI) : rad2deg(coo.m_Lon);
+       lat = rad2deg(coo.m_Lat);
+       alt = coo.m_Alt;
+       //
+       if( lon<180 && lon>-180 && lat<90 && lat>-90 && alt>0 ){
+         //
+         orbitalinfo->lon = lon;
+         orbitalinfo->lat = lat;
+         orbitalinfo->alt = alt ;
+         //
+         // compute mag field components and L shell.
+         //
+         feldg_(&lat, &lon, &alt, &bnorth, &beast, &bdown, &babs);
+         shellg_(&lat, &lon, &alt, &dimo, &xl, &icode, &bab1);
+         findb0_(&stps, &bdel, &value, &bequ, &rr0);
+         //
+         orbitalinfo->Bnorth = bnorth;
+         orbitalinfo->Beast = beast;
+         orbitalinfo->Bdown = bdown;
+         orbitalinfo->Babs = babs;
+         orbitalinfo->BB0 = babs/bequ;
+         orbitalinfo->L = xl;
+         // Set Stormer vertical cutoff using L shell.
+         orbitalinfo->cutoffsvl = 14.9/(xl*xl);
+         //
+       };
+       //
+       if ( debug ) printf(" pitch angle \n");
+       //
+       // pitch angles
+       //
+       if ( orbitalinfo->mode != 10 && orbitalinfo->mode != 5 && orbitalinfo->mode !=7 && orbitalinfo->mode != 9 ){
+         //
+         Float_t Bx = -orbitalinfo->Bdown;                       //don't need for PamExp ExpOnly for all geography areas
+         Float_t By = orbitalinfo->Beast;                        //don't need for PamExp ExpOnly for all geography areas
+         Float_t Bz = orbitalinfo->Bnorth;                       //don't need for PamExp ExpOnly for all geography areas
+         //
+         TMatrixD Fij = PO->ECItoGreenwich(PO->QuatoECI(orbitalinfo->q0,orbitalinfo->q1,orbitalinfo->q2,orbitalinfo->q3),orbitalinfo->absTime);
+         TMatrixD Dij = PO->GreenwichtoGEO(orbitalinfo->lat,orbitalinfo->lon,Fij);
+         TMatrixD Iij = PO->ColPermutation(Dij);
+         //
+         orbitalinfo->Iij.ResizeTo(Iij);
+         orbitalinfo->Iij = Iij;
+         //
+         A1 = Iij(0,2);
+         A2 = Iij(1,2);
+         A3 = Iij(2,2);
+         //
+         //      orbitalinfo->pamzenitangle = (Float_t)PO->GetPitchAngle(1,0,0,A1,A2,A3);                        // Angle between zenit and Pamela's main axiz
+         //      orbitalinfo->pamBangle = (Float_t)PO->GetPitchAngle(A1,A2,A3,Bx,By,Bz);                 // Angle between Pamela's main axiz and B
+         //
+         if ( !standalone && tof->ntrk() > 0 ){
+           //
+           Int_t nn = 0;
+           for(Int_t nt=0; nt < tof->ntrk(); nt++){
+             //
+             ToFTrkVar *ptt = tof->GetToFTrkVar(nt);
+             Double_t E11x = ptt->xtr_tof[0]; // tr->x[0];
+             Double_t E11y = ptt->ytr_tof[0]; //tr->y[0];
+             Double_t E11z = zin[0];
+             Double_t E22x = ptt->xtr_tof[3];//tr->x[3];
+             Double_t E22y = ptt->ytr_tof[3];//tr->y[3];
+             Double_t E22z = zin[3];
+             if ( (E11x < 100. && E11y < 100. && E22x < 100. && E22y < 100.) || ptt->trkseqno != -1  ){
+               Double_t norm = sqrt(pow(E22x-E11x,2)+pow(E22y-E11y,2)+pow(E22z-E11z,2));
+ //            Double_t MyAzim = TMath::RadToDeg()*atan(TMath::Abs(E22y-E11y)/TMath::Abs(E22x-E11x));
+ //            if(E22x-E11x>=0 && E22y-E11y <0) MyAzim =  360. - MyAzim;
+ //            if(E22x-E11x>=0 && E22y-E11y >=0) MyAzim = MyAzim;
+ //            if(E22x-E11x<0 && E22y-E11y >0) MyAzim = 180. - MyAzim;
+ //            if(E22x-E11x<0 && E22y-E11y <0) MyAzim = 180. + MyAzim;
+               Px = (E22x-E11x)/norm;
+               Py = (E22y-E11y)/norm;
+               Pz = (E22z-E11z)/norm;
+               //
+               t_orb->trkseqno = ptt->trkseqno;
+               //
+               TMatrixD Eij = PO->PamelatoGEO(Iij,Px,Py,Pz);
+               t_orb->Eij.ResizeTo(Eij);
+               t_orb->Eij = Eij;
+               //
+               TMatrixD Sij = PO->PamelatoGEO(Fij,Px,Py,Pz);
+               t_orb->Sij.ResizeTo(Sij);
+               t_orb->Sij = Sij;
+               //
+               t_orb->pitch = (Float_t)PO->GetPitchAngle(Eij(0,0),Eij(1,0),Eij(2,0),Bx,By,Bz);
+               //
+               //
+               Double_t omega = PO->GetPitchAngle(Eij(0,0),Eij(1,0),Eij(2,0),cos(orbitalinfo->lon+TMath::Pi()/2)-sin(orbitalinfo->lon+TMath::Pi()/2),cos(orbitalinfo->lon+TMath::Pi()/2)+sin(orbitalinfo->lon+TMath::Pi()/2),1);
+               //
+               t_orb->cutoff = 59.3/(pow(orbitalinfo->L,2)*pow((1+sqrt(1-pow(orbitalinfo->L,-3/2)*cos(omega))),2));
+               //
+               if ( t_orb->pitch != t_orb->pitch ) t_orb->pitch = -1000.;
+               if ( t_orb->cutoff != t_orb->cutoff ) t_orb->cutoff = -1000.;
+               //
+               if ( debug ) printf(" orbitalinfo->cutoffsvl %f vitaly %f \n",orbitalinfo->cutoffsvl,t_orb->cutoff);
+               //
+               new(tor[nn]) OrbitalInfoTrkVar(*t_orb);
+               nn++;
+               //
+               t_orb->Clear();
+               //
+             };
+             //
+           };
+         } else {
+           if ( debug ) printf(" mmm... mode %u standalone %i ntrk %i \n",orbitalinfo->mode,standalone,tof->ntrk());
+         };
+         //
+       } else {
+         if ( !standalone && tof->ntrk() > 0 ){
+           //
+           Int_t nn = 0;
+           for(Int_t nt=0; nt < tof->ntrk(); nt++){
+             //
+             ToFTrkVar *ptt = tof->GetToFTrkVar(nt);
+             if ( ptt->trkseqno != -1  ){
+               //
+               t_orb->trkseqno = ptt->trkseqno;
+               //
+               t_orb->Eij = 0;
+               //
+               t_orb->Sij = 0;
+               //
+               t_orb->pitch = -1000.;
+               //
+               t_orb->cutoff = -1000.;
+               //
+               new(tor[nn]) OrbitalInfoTrkVar(*t_orb);
+               nn++;
+               //
+               t_orb->Clear();
+               //
+             };
+             //
+           };
+         };
+       };
+       //
+       // Fill the class
+       //
        OrbitalInfotr->Fill();
-       //
        //
-     jumpev:
+       delete t_orb;
-       debug = false;
        //
-     };
+     }; // loop over the events in the run
      //
      // Here you may want to clear some variables before processing another run
      //
-     ei = 0;
+     delete dbtime;
+     if ( L_QQ_Q_l_upper ) delete L_QQ_Q_l_upper;
+     if ( L_QQ_Q_l_lower ) delete L_QQ_Q_l_lower;
+     if ( RYPang_upper ) delete RYPang_upper;
+     if ( RYPang_lower ) delete RYPang_lower;
    }; // process all the runs
-   //
    if (verbose) printf("\n Finished processing data \n");
    //
   closeandexit:
-Line 468 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 1235 
 int OrbitalInfoCore(ULong64_t run, TFile
          //
          // copy orbitalinfoclone to OrbitalInfo
          //
-         orbitalinfo = new OrbitalInfo();
+         orbitalinfo->Clear();
+         //
          memcpy(&orbitalinfo,&orbitalinfoclone,sizeof(orbitalinfoclone));
          //
          // Fill entry in the new tree
-Line 483 
 int OrbitalInfoCore(ULong64_t run, TFile
+Line 1251 
 int OrbitalInfoCore(ULong64_t run, TFile
    //
    if ( l0File ) l0File->Close();
    if ( tempfile ) tempfile->Close();
-   gSystem->Unlink(tempname.str().c_str());
+   if ( myfold ) gSystem->Unlink(tempname.str().c_str());
+   //
-   //if ( code < 0 ) printf("\n OrbitalInfo - ERROR: an error occurred, try to save anyway...\n");
-   //printf("\n Writing and closing rootple\n");
    if ( runinfo ) runinfo->Close();
    if ( OrbitalInfotr ) OrbitalInfotr->SetName("OrbitalInfo");
+   if ( tof ) tof->Delete();
+   if ( ttof ) ttof->Delete();
+   //
    if ( file ){
      file->cd();
      file->Write();
    };
    //
-   gSystem->Unlink(OrbitalInfofolder.str().c_str());
+   if ( myfold ) gSystem->Unlink(OrbitalInfofolder.str().c_str());
    //
    // the end
    //
+   if ( dbc ){
+     dbc->Close();
+     delete dbc;
+   };
    if (verbose) printf("\n Exiting...\n");
    if(OrbitalInfotr)OrbitalInfotr->Delete();
+   //
+   if ( PO ) delete PO;
+   if ( orbitalinfo ) delete orbitalinfo;
+   if ( orbitalinfoclone ) delete orbitalinfoclone;
+   if ( glroot ) delete glroot;
+   if ( runinfo ) delete runinfo;
+   //
    if(code < 0)  throw code;
    return(code);
  }
+ //
+ // Returns the cCoordGeo structure holding the geographical
+ // coordinates for the event (see sgp4.h).
+ //
+ // atime is the abstime of the event in UTC unix time.
+ // tletime is the time of the tle in UTC unix time.
+ // tle is the previous and nearest tle (compared to atime).
+ cCoordGeo getCoo(UInt_t atime, UInt_t tletime, cTle *tle)
+ {
+   cEci eci;
+   cOrbit orbit(*tle);
+   orbit.getPosition((double) (atime - tletime)/60., &eci);
+   return eci.toGeo();
+ }
+ // function of copyng of quatrnions classes
+ void CopyQ(Quaternions *Q1, Quaternions *Q2){
+   for(UInt_t i = 0; i < 6; i++){
+     Q1->time[i]=Q2->time[i];
+     for (UInt_t j = 0; j < 4; j++)Q1->quat[i][j]=Q2->quat[i][j];
+   }
+   return;
+ }
+ // functions of copyng InclinationInfo classes
+ void CopyAng(InclinationInfo *A1, InclinationInfo *A2){
+   A1->Tangazh = A2->Tangazh;
+   A1->Ryskanie = A2->Ryskanie;
+   A1->Kren = A2->Kren;
+   return;
+ }
+ UInt_t holeq(Double_t lower,Double_t upper,Quaternions *Qlower, Quaternions *Qupper, UInt_t f){
+   UInt_t hole = 10;
+   Bool_t R10l = false;     // Sign of R10 mode in lower quaternions array
+   Bool_t R10u = false;     // Sign of R10 mode in upper quaternions array
+   Bool_t insm = false;     // Sign that we inside quaternions array
+   Bool_t mxtml = false;    // Sign of mixt mode in lower quaternions array
+   Bool_t mxtmu = false;    // Sign of mixt mode in upper quaternions array
+   Bool_t npasm = false;     // Sign of normall pass between R10 and non R10 or between non R10 and R10
+   UInt_t NCQl = 6;       // Number of correct quaternions in lower array
+   UInt_t NCQu = 6;       // Number of correct quaternions in upper array
+   if (f>0){
+     insm = true;
+     if(Qupper->time[f]-Qupper->time[f-1]==30) R10u = false;
+     if(Qupper->time[f]-Qupper->time[f-1]<1) R10u = true;
+   }else{
+     insm = false;
+     if((Qlower->time[5]-Qlower->time[0]<2)&&(Qlower->time[1]-Qlower->time[0]<2)) R10l = true;
+     if((Qupper->time[5]-Qupper->time[0]<2)&&(Qupper->time[1]-Qupper->time[0]<2)) R10u = true;
+     if((Qlower->time[5]-Qlower->time[0]==150)&&(Qlower->time[1]-Qlower->time[0]==30)) R10l = false;
+     if((Qupper->time[5]-Qupper->time[0]==150)&&(Qupper->time[1]-Qupper->time[0]==30)) R10u = false;
+     if((Qlower->time[5]-Qlower->time[0]<2)&&(Qlower->time[1]-Qlower->time[0]==30)){
+       mxtml = true;
+       for(UInt_t i = 1; i < 6; i++){
+         if(Qlower->time[i]-Qlower->time[0]==30*i) NCQl=i;
+       }
+     }
+     if((Qupper->time[5]-Qupper->time[0]<2)&&(Qupper->time[1]-Qupper->time[0]==30)){
+       mxtmu = true;
+       for(UInt_t i = 1; i < 6; i++){
+         if(Qupper->time[i]-Qupper->time[0]==30*i) NCQu=i;
+       }
+     }
+   }
+   if(((upper-lower==1.5)||(upper-lower==3.)||(upper-lower==30.)||(upper-lower==31.5)||(upper-lower==33.)||(upper-lower==181.5)||(upper-lower==210.)||(upper-lower==211.5))&&!insm) npasm = true;
+   if (R10u&&insm) hole=0; // best event R10
+   if ((upper-lower<=5)&&(!insm)&&R10l&&R10u) hole = 1; // when first of 6 quaternions in array is correct
+   if (((!R10u)&&insm)||((!insm)&&(!R10u)&&(!R10l)&&((upper-lower==210+(6-NCQl)*30)||(upper-lower==30)))) hole = 2; //non R10
+   if (npasm&&(!insm)&&((R10l&&!R10u)||(R10u&&!R10l))) hole = 3; //normall pass from R10 to non R10 or from non R10 to R10
+   if ((!npasm)&&(upper-lower<=300)&&(!insm)&&((R10l&&!R10u)||(R10u&&!R10l))) hole = 4; // eliminable hole between R10 and non R10 or between non R10 and R10
+   if ((upper-lower>=300)&&(!insm)&&((R10l&&!R10u)||(R10u&&!R10l))) hole = 5; //uneliminable hole between R10 and non R10 or between non R10 and R10
+   if ((upper-lower>5)&&(upper-lower<=300)&&R10u&&R10l) hole = 6; // eliminable hole inside R10
+   if ((upper-lower>300)&&R10u&&R10l) hole = 7; //uneliminable hole inside R10
+   if ((upper-lower>210)&&(upper-lower<=1200)&&(!R10u)&&(!R10l)) hole = 8; //eliminable hole inside non R10
+   if ((upper-lower>1200)&&!R10u&&!R10l) hole = 9; // uneliminable hole inside non R10
+   return hole;
+ }

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