LCOV - code coverage report
Current view: top level - synthesis/MeasurementComponents - EVLASwPow.cc (source / functions) Hit Total Coverage
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Date: 2024-10-10 15:00:01 Functions: 0 18 0.0 %

          Line data    Source code
       1             : //# EVLASwPow.cc: Implementation of EVLA Switched Power Calibration
       2             : //# Copyright (C) 1996,1997,1998,1999,2000,2001,2002,2003
       3             : //# Associated Universities, Inc. Washington DC, USA.
       4             : //#
       5             : //# This library is free software; you can redistribute it and/or modify it
       6             : //# under the terms of the GNU Library General Public License as published by
       7             : //# the Free Software Foundation; either version 2 of the License, or (at your
       8             : //# option) any later version.
       9             : //#
      10             : //# This library is distributed in the hope that it will be useful, but WITHOUT
      11             : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
      12             : //# FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Library General Public
      13             : //# License for more details.
      14             : //#
      15             : //# You should have received a copy of the GNU Library General Public License
      16             : //# along with this library; if not, write to the Free Software Foundation,
      17             : //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
      18             : //#
      19             : //# Correspondence concerning AIPS++ should be addressed as follows:
      20             : //#        Internet email: casa-feedback@nrao.edu.
      21             : //#        Postal address: AIPS++ Project Office
      22             : //#                        National Radio Astronomy Observatory
      23             : //#                        520 Edgemont Road
      24             : //#                        Charlottesville, VA 22903-2475 USA
      25             : //#
      26             : 
      27             : #include <synthesis/MeasurementComponents/EVLASwPow.h>
      28             : 
      29             : #include <synthesis/MeasurementComponents/MSMetaInfoForCal.h>
      30             : 
      31             : #include <casacore/ms/MeasurementSets/MSColumns.h>
      32             : #include <casacore/casa/BasicMath/Math.h>
      33             : #include <casacore/tables/Tables/Table.h>
      34             : #include <casacore/tables/Tables/TableIter.h>
      35             : #include <synthesis/CalTables/CTGlobals.h>
      36             : 
      37             : #include <casacore/casa/BasicSL/String.h>
      38             : #include <casacore/casa/Utilities/Assert.h>
      39             : #include <casacore/casa/Utilities/GenSort.h>
      40             : #include <casacore/casa/Exceptions/Error.h>
      41             : #include <casacore/casa/System/Aipsrc.h>
      42             : #include <casacore/casa/System/ProgressMeter.h>
      43             : 
      44             : #include <sstream>
      45             : 
      46             : #include <casacore/casa/Logging/LogMessage.h>
      47             : #include <casacore/casa/Logging/LogSink.h>
      48             : 
      49             : 
      50             : 
      51             : using namespace casacore;
      52             : namespace casa { //# NAMESPACE CASA - BEGIN
      53             : 
      54             : 
      55             : // **********************************************************
      56             : //  EVLASwPow Implementations
      57             : //
      58             : 
      59           0 : EVLASwPow::SPType EVLASwPow::sptype(const String name) {
      60           0 :   String utype=upcase(name);
      61           0 :   if (utype.contains("SWP/RQ"))
      62           0 :     return EVLASwPow::SWPOVERRQ;
      63           0 :   if (utype.contains("SWPOW"))
      64           0 :     return EVLASwPow::SWPOW;
      65           0 :   if (utype.contains("EVLAGAIN"))
      66           0 :     return EVLASwPow::SWPOW;
      67           0 :   if (utype.contains("RQ"))
      68           0 :     return EVLASwPow::RQ;
      69           0 :   if (utype.contains("SWPWTS"))
      70           0 :     return EVLASwPow::SWPWTS;
      71             : 
      72             :   // Only get here if name unrecognized
      73           0 :   throw(AipsError(name+" is not among recognized EVLA Switched Power types ('swpow','evlagain','rq','swp/rq', 'swpwts')"));
      74             : 
      75             :   // Should never reach here, but this is accurate (and avoids compiler warning)
      76             :   return EVLASwPow::NONE;
      77             :   
      78           0 : }
      79             : 
      80           0 : String EVLASwPow::sptype(EVLASwPow::SPType sptype) {
      81           0 :   switch (sptype) {
      82           0 :   case EVLASwPow::SWPOW: {
      83           0 :     return String("swpow");
      84             :     break;
      85             :   }
      86           0 :   case EVLASwPow::RQ: {
      87           0 :     return String("rq");
      88             :     break;
      89             :   }
      90           0 :   case EVLASwPow::SWPOVERRQ: {
      91           0 :     return String("swpow/rq");
      92             :     break;
      93             :   }
      94           0 :   case EVLASwPow::SWPWTS: {
      95           0 :     return String("swpwts");
      96             :     break;
      97             :   }
      98           0 :   case EVLASwPow::NONE:
      99             :   default: {
     100           0 :     throw(AipsError("Unrecognized EVLA Switched Power type"));
     101             :   }
     102             :   }
     103             :   // Should never reach here, but this is accurate (and avoids compiler warning)
     104             :   return String("None");
     105             : }
     106             : 
     107           0 : EVLASwPow::EVLASwPow(VisSet& vs) :
     108             :   VisCal(vs),             // virtual base
     109             :   VisMueller(vs),         // virtual base
     110             :   GJones(vs),              // immediate parent
     111           0 :   sysPowTabName_(vs.syspowerTableName()),
     112           0 :   calDevTabName_(vs.caldeviceTableName()),
     113           0 :   correff_(Float(0.932)),     // EVLA-specific net corr efficiency (4bit)
     114           0 :   frgrotscale_(Float(1.176)), // EVLA-specific fringe rotation mean _scale_
     115             :   //nyquist_(1.0),
     116           0 :   effChBW_()
     117             : 
     118             : {
     119           0 :   if (prtlev()>2) cout << "EVLASwPow::EVLASwPow(vs)" << endl;
     120             : 
     121           0 :   nChanParList().set(1);
     122           0 :   startChanList().set(0);
     123             : 
     124             :   // Get spw total bandwidths
     125           0 :   const MSSpWindowColumns& spwcols = vs.iter().msColumns().spectralWindow();
     126           0 :   effChBW_.resize(nSpw());
     127           0 :   for (Int ispw=0;ispw<nSpw();++ispw) 
     128           0 :     effChBW_(ispw)=Vector<Double>(spwcols.effectiveBW()(0))(0);
     129             :   
     130           0 : }
     131             : 
     132           0 : EVLASwPow::EVLASwPow(String msname,Int MSnAnt,Int MSnSpw) :
     133             :   VisCal(msname,MSnAnt,MSnSpw),             // virtual base
     134             :   VisMueller(msname,MSnAnt,MSnSpw),         // virtual base
     135             :   GJones(msname,MSnAnt,MSnSpw),             // immediate parent
     136           0 :   sysPowTabName_(""),
     137           0 :   calDevTabName_(""),
     138           0 :   correff_(Float(0.932)),     // EVLA-specific net corr efficiency (4bit)
     139           0 :   frgrotscale_(Float(1.176)), // EVLA-specific fringe rotation mean _scale_
     140             :   //nyquist_(1.0),
     141           0 :   effChBW_()
     142             : 
     143             : {
     144           0 :   if (prtlev()>2) cout << "EVLASwPow::EVLASwPow(msname,MSnAnt,MSnSpw)" << endl;
     145             : 
     146           0 :   nChanParList().set(1);
     147           0 :   startChanList().set(0);
     148             : 
     149             :   // Temporary MS to get some info
     150           0 :   MeasurementSet ms(msname);
     151             : 
     152             :   // The relevant subtable names (there must be a better way...)
     153           0 :   sysPowTabName_ = ms.rwKeywordSet().asTable("SYSPOWER").tableName();
     154           0 :   calDevTabName_ = ms.rwKeywordSet().asTable("CALDEVICE").tableName();
     155             : 
     156             :   // Get spw total bandwidths
     157           0 :   MSColumns mscol(ms);
     158           0 :   const MSSpWindowColumns& spwcols = mscol.spectralWindow();
     159           0 :   effChBW_.resize(nSpw());
     160           0 :   for (Int ispw=0;ispw<nSpw();++ispw) 
     161           0 :     effChBW_(ispw)=Vector<Double>(spwcols.effectiveBW()(0))(0);
     162             :   
     163           0 : }
     164             : 
     165           0 : EVLASwPow::EVLASwPow(const MSMetaInfoForCal& msmc) :
     166             :   VisCal(msmc),             // virtual base
     167             :   VisMueller(msmc),         // virtual base
     168             :   GJones(msmc),             // immediate parent
     169           0 :   sysPowTabName_(""),
     170           0 :   calDevTabName_(""),
     171           0 :   correff_(Float(0.932)),     // EVLA-specific net corr efficiency (4bit)
     172           0 :   frgrotscale_(Float(1.176)), // EVLA-specific fringe rotation mean _scale_
     173             :   //nyquist_(1.0),
     174           0 :   effChBW_()
     175             : 
     176             : {
     177           0 :   if (prtlev()>2) cout << "EVLASwPow::EVLASwPow(msmc)" << endl;
     178             : 
     179           0 :   nChanParList().set(1);
     180           0 :   startChanList().set(0);
     181             : 
     182             :   // Temporary MS to get some info
     183           0 :   MeasurementSet ms(this->msmc().msname());
     184             : 
     185             :   // The relevant subtable names (there must be a better way...)
     186           0 :   sysPowTabName_ = ms.rwKeywordSet().asTable("SYSPOWER").tableName();
     187           0 :   calDevTabName_ = ms.rwKeywordSet().asTable("CALDEVICE").tableName();
     188             : 
     189             :   // Get spw total bandwidths
     190           0 :   MSColumns mscol(ms);
     191           0 :   const MSSpWindowColumns& spwcols = mscol.spectralWindow();
     192           0 :   effChBW_.resize(nSpw());
     193           0 :   for (Int ispw=0;ispw<nSpw();++ispw) 
     194           0 :     effChBW_(ispw)=Vector<Double>(spwcols.effectiveBW()(0))(0);
     195             :   
     196           0 : }
     197             : 
     198           0 : EVLASwPow::EVLASwPow(const Int& nAnt) :
     199             :   VisCal(nAnt), 
     200             :   VisMueller(nAnt),
     201           0 :   GJones(nAnt)
     202             : {
     203           0 :   if (prtlev()>2) cout << "EVLASwPow::EVLASwPow(nAnt)" << endl;
     204             : 
     205           0 :   throw(AipsError("Cannot use EVLASwPow with generic ctor."));
     206             : 
     207           0 : }
     208             : 
     209           0 : EVLASwPow::~EVLASwPow() {
     210           0 :   if (prtlev()>2) cout << "EVLASwPow::~EVLASwPow()" << endl;
     211           0 : }
     212             : 
     213           0 : void EVLASwPow::setSpecify(const Record& specify) {
     214             : 
     215           0 :   LogMessage message(LogOrigin("EVLASwPow","setSpecify"));
     216             : 
     217             :   // Escape if SYSPOWER or CALDEVICE tables absent
     218           0 :   if (!Table::isReadable(sysPowTabName_))
     219           0 :     throw(AipsError("The SYSPOWER subtable is not present in the specified MS."));
     220           0 :   if (!Table::isReadable(calDevTabName_))
     221           0 :     throw(AipsError("The CALDEVICE subtable is not present in the specified MS."));
     222             : 
     223             :   // Not actually applying or solving
     224           0 :   setSolved(false);
     225           0 :   setApplied(false);
     226             : 
     227             :   // Collect Cal table parameters
     228           0 :   if (specify.isDefined("caltable")) {
     229           0 :     calTableName()=specify.asString("caltable");
     230             : 
     231           0 :     if (Table::isReadable(calTableName()))
     232             :       logSink() << "FYI: We are going to overwrite an existing CalTable: "
     233           0 :                 << calTableName()
     234           0 :                 << LogIO::POST;
     235             :   }
     236             : 
     237             :   // we are creating a table from scratch
     238           0 :   logSink() << "Creating " << typeName()
     239             :     //      << " table from CANNED VALUES."
     240             :             << " table from MS SYSPOWER/CALDEVICE subtables."
     241           0 :             << LogIO::POST;
     242             : 
     243             :   // Create a caltable to fill up
     244           0 :   createMemCalTable();
     245             : 
     246             :   // Init the shapes of solveAllRPar, etc.
     247           0 :   initSolvePar();
     248             : 
     249           0 : }
     250             : 
     251           0 : void EVLASwPow::specify(const Record& specify) {
     252             : 
     253             :   // Escape if SYSPOWER or CALDEVICE tables absent
     254           0 :   if (!Table::isReadable(sysPowTabName_))
     255           0 :     throw(AipsError("The SYSPOWER subtable is not present in the specified MS."));
     256           0 :   if (!Table::isReadable(calDevTabName_))
     257           0 :     throw(AipsError("The CALDEVICE subtable is not present in the specified MS."));
     258             :  
     259             :   // Fill the Tcals first
     260           0 :   fillTcals();
     261             : 
     262             :   // Discern which kind of calibration to calculate
     263           0 :   SPType swptype(EVLASwPow::SWPOW);
     264           0 :   if (specify.isDefined("caltype")) {
     265           0 :     String ctype=specify.asString("caltype");
     266           0 :     swptype=sptype(ctype);
     267             :     //cout << "caltype=" << ctype << " " << swptype << " " << sptype(swptype) << endl;
     268           0 :   }
     269             : 
     270           0 :   logSink() << "Filling switched-power (" << sptype(swptype) << ") data from the SYSPOWER table." << LogIO::POST;
     271             : 
     272             :   // The net digital factor for antenna-based (voltage) gain
     273           0 :   Float dig=sqrt(correff_*frgrotscale_);
     274             : 
     275             :   // Keep a count of the number of Tsys found per spw/ant
     276           0 :   Matrix<Int> goodcount(nSpw(),nElem(),0), badcount(nSpw(),nElem(),0);
     277             : 
     278           0 :   Block<String> columns(2);
     279           0 :   columns[0] = "TIME";
     280           0 :   columns[1] = "SPECTRAL_WINDOW_ID";
     281           0 :   Table sysPowTab(sysPowTabName_,Table::Old);
     282           0 :   TableIterator sysPowIter(sysPowTab,columns);
     283             : 
     284             :   // Count iterations
     285           0 :   Int niter(0);
     286           0 :   while (!sysPowIter.pastEnd()) {
     287           0 :     ++niter;
     288           0 :     sysPowIter.next();
     289             :   }
     290           0 :   sysPowIter.reset();
     291             : 
     292           0 :   logSink() << "Found " << niter << " TIME/SPW switched-power samples in SYSPOWER table" << LogIO::POST;
     293             : 
     294             :   // Iterate
     295             :   // Vectors for referencing slices of working info
     296           0 :   Vector<Float> currpsum,currpdif,currrq,currtcal,gain,tsys;  
     297             : 
     298             :   // Emit progress meter reports (at least until we improve performance)
     299           0 :   cerr << "Switched-Power ("+sptype(swptype)+") calculation: 0";
     300           0 :   ProgressMeter pm(0.,niter , "", "", "", "", true, niter/100);
     301             : 
     302           0 :   Int iter(0);
     303           0 :   while (!sysPowIter.pastEnd()) {
     304             : 
     305             :     // Update the progress meter
     306           0 :     pm.update(iter);
     307             : 
     308           0 :     Table itab(sysPowIter.table());
     309             : 
     310           0 :     ScalarColumn<Int> spwCol(itab,"SPECTRAL_WINDOW_ID");
     311           0 :     ScalarColumn<Double> timeCol(itab,"TIME");
     312           0 :     ScalarColumn<Double> intervalCol(itab,"INTERVAL");
     313           0 :     ScalarColumn<Int> antCol(itab,"ANTENNA_ID");
     314           0 :     ArrayColumn<Float> swsumCol(itab,"SWITCHED_SUM");
     315           0 :     ArrayColumn<Float> swdiffCol(itab,"SWITCHED_DIFF");
     316           0 :     ArrayColumn<Float> rqCol(itab,"REQUANTIZER_GAIN");
     317             : 
     318           0 :     Int ispw=spwCol(0);
     319             : 
     320           0 :     Double timestamp=timeCol(0);
     321             :     //    Double interval=intervalCol(0);
     322             : 
     323           0 :     Vector<Int> ants;
     324           0 :     antCol.getColumn(ants);
     325             : 
     326           0 :     Matrix<Float> psum,pdif,rq;
     327           0 :     swsumCol.getColumn(psum);
     328           0 :     swdiffCol.getColumn(pdif);
     329           0 :     rqCol.getColumn(rq);
     330           0 :     IPosition psumshape(psum.shape());
     331           0 :     IPosition pdifshape(pdif.shape());
     332             : 
     333           0 :     AlwaysAssert(psumshape.isEqual(pdifshape),AipsError);
     334             : 
     335             :     // the number of receptors
     336           0 :     Int nrec=psumshape(0);
     337             : 
     338             :     // Now prepare to record pars in the caltable
     339           0 :     currSpw()=ispw;
     340           0 :     refTime()=timestamp;
     341           0 :     currField()=msmc().fieldIdAtTime(timestamp);
     342           0 :     currScan()=msmc().scanNumberAtTime(timestamp);
     343             : 
     344             :     // Initialize solveAllRPar, etc.
     345           0 :     solveAllRPar()=1.0;
     346           0 :     solveAllParOK()=false;  
     347           0 :     solveAllParErr()=0.0;  // what should we use here?  ~1/bandwidth?
     348           0 :     solveAllParSNR()=1.0;
     349             : 
     350           0 :     IPosition blc(3,0,0,0),trc(3,2*nrec-1,0,0),stp(3,nrec,1,1);
     351           0 :     for (uInt iant=0;iant<ants.nelements();++iant) {
     352           0 :       Int thisant=ants(iant);
     353             : 
     354             :       // Reference this ant's info
     355           0 :       currpsum.reference(psum.column(iant));
     356           0 :       currpdif.reference(pdif.column(iant));
     357           0 :       currrq.reference(rq.column(iant));
     358           0 :       currtcal.reference(tcals_.xyPlane(ispw).column(thisant));
     359             : 
     360             :       // If any of the required values are goofy, we'll skip this antenna
     361             :       Bool good;
     362           0 :       switch (swptype) {
     363           0 :       case EVLASwPow::SWPOW: {
     364           0 :         good=(allGT(currtcal,FLT_EPSILON) &&
     365           0 :               allGT(currpdif,FLT_EPSILON) &&
     366           0 :               allGT(currpsum,FLT_EPSILON));
     367             :       }
     368           0 :       case EVLASwPow::SWPOVERRQ:{
     369           0 :         good=(allGT(currtcal,FLT_EPSILON) &&
     370           0 :               allGT(currpdif,FLT_EPSILON) &&
     371           0 :               allGT(currpsum,FLT_EPSILON) &&
     372           0 :               allGT(currrq,FLT_EPSILON));
     373           0 :         break;
     374             :       }
     375           0 :       case EVLASwPow::RQ: {
     376           0 :         good=allGT(currrq,FLT_EPSILON);
     377           0 :         break;
     378             :       }
     379           0 :       case EVLASwPow::SWPWTS: {
     380           0 :         good=(allGT(currpsum,FLT_EPSILON) &&
     381           0 :               allGT(currrq,FLT_EPSILON));
     382           0 :     break;
     383             :       }
     384           0 :       default: {
     385           0 :         throw(AipsError("Unrecognized EVLA Switched Power type"));
     386             :         break;
     387             :       }
     388             :       }
     389           0 :       blc(2)=trc(2)=thisant; // the MS ant index (not loop index)
     390             : 
     391           0 :       blc(0)=0;
     392           0 :       gain.reference(solveAllRPar()(blc,trc,stp).nonDegenerate(1)); // 'gain'
     393           0 :       blc(0)=1;
     394           0 :       tsys.reference(solveAllRPar()(blc,trc,stp).nonDegenerate(1)); // 'tsys'
     395             : 
     396           0 :       if (!good) {
     397             : 
     398             :         // ensure transparent values
     399           0 :         gain=1.0;  
     400           0 :         tsys=1.0;
     401           0 :         solveAllParOK().xyPlane(thisant)=false;
     402             :         
     403             :         // Increment bad counter
     404           0 :         ++badcount(ispw,thisant);
     405             :       }
     406             :       else {
     407             : 
     408             :         // Calculate "gain" and "tsys" for different modes
     409             :         //  NB: gain includes correction for digital effects (loss and scale)
     410             :         //  NB: No digital stuff in Tsys!  net dig losses included OTF
     411             :         //      in syncWtScale
     412             :         
     413           0 :         switch (swptype) {
     414           0 :         case EVLASwPow::SWPOW: {
     415           0 :           gain=sqrt(currpdif/currtcal);
     416           0 :           gain*=dig; // scale by net digital factor
     417           0 :           tsys=(currtcal*currpsum/currpdif/2.0);  // 'tsys'
     418           0 :           break;
     419             :         }
     420           0 :         case EVLASwPow::RQ: {
     421           0 :           gain=currrq;              // RQ gain only!
     422           0 :           gain*=dig;                // scale by net digital factor
     423           0 :           tsys=1.0;
     424           0 :           tsys/=square(currrq); // vis scale by rq req wt scale by 1/rq**2
     425           0 :           break;
     426             :         }
     427           0 :         case EVLASwPow::SWPOVERRQ: {
     428           0 :           gain=sqrt(currpdif/currtcal);     // ordinary sw power gain
     429           0 :           gain/=currrq;                     // remove rq effect
     430           0 :           gain*=dig;                        // scale by net digital factor
     431           0 :           tsys=(currtcal*currpsum/currpdif/2.0);  // 'tsys'
     432           0 :           break;
     433             :         }
     434           0 :         case EVLASwPow::SWPWTS:{
     435           0 :           gain=(currrq*dig);          // include digital stuff, as for RQ
     436           0 :           tsys = currpsum/2.0;
     437           0 :           tsys/=square(currrq);   // includ 1/rq**2, as for RQ
     438           0 :           break;
     439             :         }
     440           0 :         default: {
     441           0 :           throw(AipsError("Unrecognized EVLA Switched Power type"));
     442             :           break;
     443             :         }
     444             :         }
     445           0 :         solveAllParOK().xyPlane(thisant)=true;
     446             :       
     447             :         // Increment good counter
     448           0 :         ++goodcount(ispw,thisant);
     449             : 
     450             :       }
     451             : 
     452             :     }
     453             :     
     454             :     // Record in the memory caltable
     455           0 :     keepNCT();
     456             : 
     457           0 :     sysPowIter.next();
     458           0 :     ++iter;
     459             : 
     460           0 :   }
     461             : 
     462             :   // Set scan and fieldid info
     463             :   //  assignCTScanField(*ct_,msName());
     464             : 
     465           0 :   logSink() << "GOOD gain counts per spw for antenna Ids 0-"<<nElem()-1<<":" << LogIO::POST;
     466           0 :   for (Int ispw=0;ispw<nSpw();++ispw) {
     467           0 :     Vector<Int> goodcountspw(goodcount.row(ispw));
     468           0 :     if (sum(goodcountspw)>0)
     469             :       logSink() << "  Spw " << ispw << ": " << goodcountspw 
     470             :                 << " (" << sum(goodcountspw) << ")" 
     471           0 :                 << LogIO::POST;
     472             :     else
     473           0 :       logSink() << "Spw " << ispw << ": NONE." << LogIO::POST;
     474           0 :   }
     475             : 
     476           0 :   logSink() << "BAD gain counts per spw for antenna Ids 0-"<<nElem()-1<<":" << LogIO::POST;
     477           0 :   for (Int ispw=0;ispw<nSpw();++ispw) {
     478           0 :     Vector<Int> badcountspw(badcount.row(ispw));
     479           0 :     if (sum(badcountspw)>0)
     480             :       logSink() << "  Spw " << ispw << ": " << badcountspw 
     481             :                 << " (" << sum(badcountspw) << ")" 
     482           0 :                 << LogIO::POST;
     483           0 :   }
     484             : 
     485           0 :   logSink() << "BAD gain count FRACTION per spw for antenna Ids 0-"<<nElem()-1<<":" << LogIO::POST;
     486           0 :   for (Int ispw=0;ispw<nSpw();++ispw) {
     487           0 :     Vector<Float> badcountspw(badcount.row(ispw).shape());
     488           0 :     Vector<Float> goodcountspw(goodcount.row(ispw).shape());
     489           0 :     convertArray(badcountspw,badcount.row(ispw));
     490           0 :     convertArray(goodcountspw,goodcount.row(ispw));
     491           0 :     if (sum(badcountspw)>0.0f) {
     492           0 :       Vector<Float> fracbad=badcountspw/(badcountspw+goodcountspw);
     493           0 :       fracbad=floor(1000.0f*fracbad)/1000.0f;
     494           0 :       Float fracbadsum=sum(badcountspw)/(sum(badcountspw)+sum(goodcountspw));
     495           0 :       fracbadsum=floor(1000.0f*fracbadsum)/1000.0f;
     496             :       logSink() << "  Spw " << ispw << ": " << fracbad
     497             :                 << " (" << fracbadsum << ")" 
     498           0 :                 << LogIO::POST;
     499           0 :     }
     500           0 :   }
     501             : 
     502             : 
     503           0 : }
     504             : 
     505           0 : void EVLASwPow::fillTcals() {
     506             : 
     507           0 :   logSink() << "Filling Tcals from the CALDEVICE table." << LogIO::POST;
     508             : 
     509           0 :   Block<String> columns(2);
     510           0 :   columns[0] = "SPECTRAL_WINDOW_ID";
     511           0 :   columns[1] = "ANTENNA_ID";
     512           0 :   Table calDevTab(calDevTabName_,Table::Old);
     513           0 :   TableIterator calDevIter(calDevTab,columns);
     514             : 
     515           0 :   tcals_.resize(2,nElem(),nSpw());
     516           0 :   tcals_.set(-1.0f);
     517             : 
     518             :   // Iterate over CALDEVICE table
     519           0 :   Int iter(0);
     520           0 :   Vector<Int> islot(nSpw(),0);
     521             : 
     522           0 :   Bool ignoreSolar(false);
     523           0 :   while (!calDevIter.pastEnd()) {
     524             : 
     525           0 :     Table itab(calDevIter.table());
     526             : 
     527           0 :     ScalarColumn<Int> spwCol(itab,"SPECTRAL_WINDOW_ID");
     528           0 :     ScalarColumn<Double> timeCol(itab,"TIME");
     529           0 :     ScalarColumn<Double> intervalCol(itab,"INTERVAL");
     530           0 :     ScalarColumn<Int> antCol(itab,"ANTENNA_ID");
     531           0 :     ScalarColumn<Int> numLoadCol(itab,"NUM_CAL_LOAD");
     532             : 
     533           0 :     ArrayColumn<Float> noiseCalCol(itab,"NOISE_CAL");
     534             : 
     535           0 :     Int ispw=spwCol(0);
     536           0 :     Int iant=antCol(0);
     537           0 :     Int nTcal=noiseCalCol(0).nelements();
     538             : 
     539           0 :     if (nTcal==1) {
     540             :       // One value (not clear this was ever the case)
     541           0 :       Vector<Float> thisTcal=noiseCalCol(0);
     542           0 :       AlwaysAssert(thisTcal.nelements()==1,AipsError);
     543           0 :       tcals_.xyPlane(ispw).column(iant)=thisTcal(0);
     544           0 :     }
     545           0 :     else if (nTcal==2) {
     546             :       // Pre-solar Tcal support: two values
     547           0 :       Vector<Float> thisTcal=noiseCalCol(0);
     548           0 :       AlwaysAssert(thisTcal.nelements()==2,AipsError);
     549           0 :       tcals_.xyPlane(ispw).column(iant)=thisTcal;
     550           0 :     }
     551           0 :     else if (nTcal==4) {
     552           0 :       ignoreSolar=true;  // we will ignore solar Tcals
     553           0 :       Matrix<Float> thisTcalMat=noiseCalCol(0);
     554           0 :       AlwaysAssert(thisTcalMat.shape()==IPosition(2,2,2),AipsError);
     555           0 :       Int tcalset(0);  // first pair, for now, which is ordinary non-solar Tcals
     556           0 :       tcals_.xyPlane(ispw).column(iant)=thisTcalMat(Slice(tcalset,1,1),Slice());
     557           0 :     }
     558             : 
     559             :     // Increment the iterator
     560           0 :     ++iter;
     561           0 :     calDevIter.next();
     562           0 :   }
     563             : 
     564             :   // Report if we ignored solar Tcals
     565           0 :   if (ignoreSolar)
     566           0 :     logSink() << "Ignoring the SOLAR Tcals, which seem to be present in CALDEVICE." << LogIO::POST;
     567             : 
     568             : 
     569           0 : }
     570             : 
     571           0 : void EVLASwPow::calcAllJones() {
     572             : 
     573             :   // 0th and 2nd pars are the gains
     574             :   //  currJElem()=currRPar()(Slice(0,2,2),Slice(),Slice()); // NEWCALTABLE
     575           0 :   convertArray(currJElem(),currRPar()(Slice(0,2,2),Slice(),Slice()));
     576           0 :   currJElemOK()=currParOK()(Slice(0,2,2),Slice(),Slice());
     577             : 
     578           0 : }
     579             : 
     580           0 : void EVLASwPow::syncWtScale() {
     581             : 
     582           0 :   Int nPolWt=currRPar().shape()(0)/2;
     583           0 :   currWtScale().resize(nPolWt,1,nAnt());
     584             : 
     585           0 :   Cube<Float> Tsys(currRPar()(Slice(1,2,2),Slice(),Slice()));
     586           0 :   Tsys(Tsys<FLT_MIN)=1.0;  // OK?
     587             : 
     588           0 :   currWtScale() = 1.0f/Tsys;
     589           0 :   currWtScale()*=correff_; // reduce by correlator efficiency (per ant)
     590             : 
     591             :   //  cout << "Tsys = " << Tsys << endl;
     592             :   //  cout << "currWtScale() = " << currWtScale() << endl;
     593             : 
     594           0 : }
     595             : 
     596             : /*
     597             : void EVLASwPow::updateWt(Vector<Float>& wt,const Int& a1,const Int& a2) {
     598             : 
     599             :   Vector<Float> ws1(currWtScale().column(a1));
     600             :   Vector<Float> ws2(currWtScale().column(a2));
     601             : 
     602             :   if (a1==0 && a2==1) {
     603             :     cout << "wt = " << wt << endl;
     604             :     cout << "ws1 = " << ws1 << endl;
     605             :     cout << "ws2 = " << ws2 << endl;
     606             :   }
     607             : 
     608             :   VisJones::updateWt(wt,a1,a2);
     609             : 
     610             :   if (a1==0 && a2==1) {
     611             :     cout << "wt = " << wt << endl;
     612             :   }
     613             : }
     614             : */
     615             : 
     616             : } //# NAMESPACE CASA - END

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