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STApplyCal.cpp@ 2730

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Last change on this file since 2730 was 2727, checked in by Takeshi Nakazato, 12 years ago

New Development: No

JIRA Issue: Yes CAS-4770, CAS-4774

Ready for Test: Yes

Interface Changes: No

What Interface Changed: Please list interface changes

Test Programs: List test programs

Put in Release Notes: Yes/No

Module(s): Module Names change impacts.

Description: Describe your changes here...

Updated STApplyCal to be able to specify interpolation method.
The method can be specified in time and frequency axes independently.
Possible options are nearest, linear (default), (natural) cubic spline,
and polynomial with arbitrary order.

File size: 15.7 KB

Rev	Line
[2720]	1	//
	2	// C++ Implementation: STApplyCal
	3	//
	4	// Description:
	5	//
	6	//
	7	// Author: Takeshi Nakazato <takeshi.nakazato@nao.ac.jp> (C) 2012
	8	//
	9	// Copyright: See COPYING file that comes with this distribution
	10	//
	11	//
[2722]	12	#include <assert.h>
[2720]	13
	14	#include <casa/Arrays/Array.h>
	15	#include <casa/Arrays/Vector.h>
	16	#include <casa/Arrays/Matrix.h>
	17	#include <casa/Arrays/ArrayIO.h>
	18	#include <casa/Arrays/ArrayMath.h>
	19	#include <casa/BasicSL/String.h>
	20	#include <casa/Logging/LogIO.h>
	21	#include <casa/Exceptions/Error.h>
	22	#include <casa/Utilities/CountedPtr.h>
	23	#include <casa/Utilities/Sort.h>
	24	#include <tables/Tables/Table.h>
	25
	26	#include "Scantable.h"
	27	#include "STApplyCal.h"
	28	#include "STApplyTable.h"
	29	#include "STCalTsysTable.h"
	30	#include "STCalSkyTable.h"
	31	#include "STCalEnum.h"
	32	#include "STIdxIter.h"
	33	#include "Calibrator.h"
	34	#include "PSAlmaCalibrator.h"
	35	#include "NearestInterpolator1D.h"
[2727]	36	#include "BufferedLinearInterpolator1D.h"
	37	#include "PolynomialInterpolator1D.h"
	38	#include "CubicSplineInterpolator1D.h"
[2720]	39	#include <atnf/PKSIO/SrcType.h>
	40
	41
	42	using namespace casa;
	43	using namespace std;
	44
	45	namespace asap {
	46
	47	STApplyCal::STApplyCal()
	48	{
	49	init();
	50	}
	51
	52	STApplyCal::STApplyCal(CountedPtr<Scantable> target)
	53	: target_(target)
	54	{
	55	init();
	56	}
	57
	58	STApplyCal::~STApplyCal()
	59	{
	60	}
	61
	62	void STApplyCal::init()
	63	{
	64	caltype_ = STCalEnum::NoType;
	65	doTsys_ = False;
	66	interp_.resize((int)STCalEnum::NumAxis);
[2727]	67	// default is linear interpolation
	68	for (unsigned int i = 0; i < interp_.size(); i++) {
	69	interp_[i] = STCalEnum::LinearInterpolation;
	70	}
[2720]	71	}
	72
	73	void STApplyCal::setTarget(CountedPtr<Scantable> target)
	74	{
	75	target_ = target;
	76	}
	77
	78	void STApplyCal::setTarget(const String &name)
	79	{
	80	// always create PlainTable
	81	target_ = new Scantable(name, Table::Plain);
	82	}
	83
	84	void STApplyCal::push(STCalSkyTable *table)
	85	{
	86	skytable_.push_back(table);
	87	STCalEnum::CalType caltype = STApplyTable::getCalType(table);
	88	os_ << "caltype=" << caltype << LogIO::POST;
	89	if (caltype_ == STCalEnum::NoType \|\|
	90	caltype_ == STCalEnum::DefaultType \|\|
	91	caltype_ == STCalEnum::CalTsys) {
	92	caltype_ = caltype;
	93	}
	94	os_ << "caltype_=" << caltype_ << LogIO::POST;
	95	}
	96
	97	void STApplyCal::push(STCalTsysTable *table)
	98	{
	99	tsystable_.push_back(table);
	100	doTsys_ = True;
	101	}
	102
	103	void STApplyCal::setInterpolation(STCalEnum::InterpolationAxis axis, STCalEnum::InterpolationType itype, Int order)
	104	{
	105	interp_[(int)axis] = itype;
	106	order_ = order;
	107	}
	108
	109	void STApplyCal::setTsysTransfer(uInt from, Vector<uInt> to)
	110	{
	111	os_ << "from=" << from << ", to=" << to << LogIO::POST;
	112	map<uInt, Vector<uInt> >::iterator i = spwmap_.find(from);
	113	if (i == spwmap_.end()) {
	114	spwmap_.insert(pair<uInt, Vector<uInt> >(from, to));
	115	}
	116	else {
	117	Vector<uInt> toNew = i->second;
	118	spwmap_.erase(i);
	119	uInt k = toNew.nelements();
	120	toNew.resize(k+to.nelements(), True);
	121	for (uInt i = 0; i < to.nelements(); i++)
	122	toNew[i+k] = to[i];
	123	spwmap_.insert(pair<uInt, Vector<uInt> >(from, toNew));
	124	}
	125	}
	126
	127	void STApplyCal::apply(Bool insitu)
	128	{
	129	// calibrator
	130	if (caltype_ == STCalEnum::CalPSAlma)
	131	calibrator_ = new PSAlmaCalibrator();
	132
	133	// interpolator
[2727]	134	initInterpolator();
[2720]	135
	136	// select data
	137	sel_.reset();
	138	if (caltype_ == STCalEnum::CalPSAlma \|\|
	139	caltype_ == STCalEnum::CalPS) {
	140	sel_.setTypes(vector<int>(1,(int)SrcType::PSON));
	141	}
	142	target_->setSelection(sel_);
	143
	144	os_ << "sel_.print()=" << sel_.print() << LogIO::POST;
	145
	146	// working data
	147	if (insitu)
	148	work_ = target_;
	149	else
	150	work_ = new Scantable(*target_, false);
	151
	152	os_ << "work_->nrow()=" << work_->nrow() << LogIO::POST;
	153
	154	// list of apply tables for sky calibration
	155	Vector<uInt> skycalList;
	156	uInt numSkyCal = 0;
	157	uInt nrowSky = 0;
	158	// list of apply tables for Tsys calibration
	159	// Vector<uInt> tsyscalList;
	160
	161	for (uInt i = 0 ; i < skytable_.size(); i++) {
	162	STCalEnum::CalType caltype = STApplyTable::getCalType(skytable_[i]);
	163	if (caltype == caltype_) {
	164	skycalList.resize(numSkyCal+1, True);
	165	skycalList[numSkyCal] = i;
	166	numSkyCal++;
	167	nrowSky += skytable_[i]->nrow();
	168	}
	169	}
	170
	171
	172	vector<string> cols( 3 ) ;
	173	cols[0] = "BEAMNO" ;
	174	cols[1] = "POLNO" ;
	175	cols[2] = "IFNO" ;
	176	CountedPtr<STIdxIter> iter = new STIdxIterAcc(work_, cols) ;
	177	while (!iter->pastEnd()) {
	178	Vector<uInt> ids = iter->current();
	179	Vector<uInt> rows = iter->getRows(SHARE);
	180	os_ << "ids=" << ids << LogIO::POST;
	181	if (rows.nelements() > 0)
	182	doapply(ids[0], ids[2], ids[1], rows, skycalList);
	183	iter->next();
	184	}
	185
	186	target_->unsetSelection();
	187	}
	188
	189	void STApplyCal::doapply(uInt beamno, uInt ifno, uInt polno,
	190	Vector<uInt> &rows,
	191	Vector<uInt> &skylist)
	192	{
	193	os_ << "skylist=" << skylist << LogIO::POST;
	194	os_ << "rows=" << rows << LogIO::POST;
	195	Bool doTsys = doTsys_;
	196
	197	//STSelector sel = sel_;
	198	STSelector sel;
	199	vector<int> id(1);
	200	id[0] = beamno;
	201	sel.setBeams(id);
	202	id[0] = ifno;
	203	sel.setIFs(id);
	204	id[0] = polno;
	205	sel.setPolarizations(id);
	206	os_ << "sel=" << sel.print() << LogIO::POST;
	207
	208	// apply selection to apply tables
	209	uInt nrowSky = 0;
	210	uInt nrowTsys = 0;
	211	for (uInt i = 0; i < skylist.nelements(); i++) {
	212	skytable_[skylist[i]]->setSelection(sel);
	213	nrowSky += skytable_[skylist[i]]->nrow();
	214	os_ << "nrowSky=" << nrowSky << LogIO::POST;
	215	}
	216	uInt nchanTsys = 0;
	217	Vector<Double> ftsys;
	218	uInt tsysifno = getIFForTsys(ifno);
	219	os_ << "tsysifno=" << tsysifno << LogIO::POST;
	220	if (tsystable_.size() == 0) {
	221	os_.origin(LogOrigin("STApplyTable", "doapply", WHERE));
	222	os_ << "No Tsys tables are given. Skip Tsys calibratoin." << LogIO::POST;
	223	doTsys = False;
	224	}
	225	else if (tsysifno == (uInt)-1) {
	226	os_.origin(LogOrigin("STApplyTable", "doapply", WHERE));
	227	os_ << "No corresponding Tsys for IFNO " << ifno << ". Skip Tsys calibration" << LogIO::POST;
	228	doTsys = False;
	229	}
	230	else {
	231	nchanTsys = tsystable_[0]->nchan(tsysifno);
	232	ftsys = tsystable_[0]->getBaseFrequency(0);
	233	interpolatorF_->setX(ftsys.data(), nchanTsys);
	234	os_ << "nchanTsys=" << nchanTsys << LogIO::POST;
	235	id[0] = (int)tsysifno;
	236	sel.setIFs(id);
	237	for (uInt i = 0; i < tsystable_.size() ; i++) {
	238	tsystable_[i]->setSelection(sel);
	239	nrowTsys += tsystable_[i]->nrow();
	240	os_ << "nrowTsys=" << nrowTsys << LogIO::POST;
	241	}
	242	}
	243
	244	uInt nchanSp = skytable_[skylist[0]]->nchan(ifno);
	245	os_ << "nchanSp = " << nchanSp << LogIO::POST;
	246	Vector<Double> timeSky(nrowSky);
	247	Matrix<Float> spoff(nchanSp, nrowSky);
	248	Vector<Float> iOff(nchanSp);
	249	nrowSky = 0;
	250	os_ << "spoff.shape()=" << spoff.shape() << LogIO::POST;
	251	for (uInt i = 0 ; i < skylist.nelements(); i++) {
	252	STCalSkyTable *p = skytable_[skylist[i]];
	253	os_ << "table " << i << ": nrow=" << p->nrow() << LogIO::POST;
	254	Vector<Double> t = p->getTime();
	255	Matrix<Float> sp = p->getSpectra();
	256	os_ << "sp.shape()=" << sp.shape() << LogIO::POST;
	257	os_ << "t.nelements()=" << t.nelements() << LogIO::POST;
	258	for (uInt j = 0; j < t.nelements(); j++) {
	259	timeSky[nrowSky] = t[j];
	260	os_ << "timeSky[" << nrowSky << "]-timeSky[0]=" << timeSky[nrowSky] - timeSky[0] << LogIO::POST;
	261	spoff.column(nrowSky) = sp.column(j);
	262	nrowSky++;
	263	}
	264	}
	265	os_ << "timeSky-timeSky[0]=" << timeSky-timeSky[0] << LogIO::POST;
	266
	267	Vector<uInt> skyIdx = timeSort(timeSky);
	268	os_ << "skyIdx = " << skyIdx << LogIO::POST;
	269
	270	double *xa = new double[skyIdx.nelements()];
	271	float *ya = new float[skyIdx.nelements()];
	272	IPosition ipos(1, skyIdx.nelements());
	273	Vector<double> timeSkySorted(ipos, xa, TAKE_OVER);
	274	Vector<Float> tmpOff(ipos, ya, TAKE_OVER);
	275	for (uInt i = 0 ; i < skyIdx.nelements(); i++) {
	276	timeSkySorted[i] = (double)timeSky[skyIdx[i]];
	277	os_ << "timeSkySorted[" << i << "]-timeSkySorted[0]=" << timeSkySorted[i] - timeSkySorted[0] << LogIO::POST;
	278	}
	279	os_ << "timeSkySorted-timeSkySorted[0]=" << timeSkySorted-timeSkySorted[0] << LogIO::POST;
	280
	281	interpolatorS_->setX(xa, skyIdx.nelements());
	282
	283	os_ << "doTsys = " << doTsys << LogIO::POST;
	284	Vector<uInt> tsysIdx;
	285	Vector<Double> timeTsys(nrowTsys);
	286	Matrix<Float> tsys;
	287	Vector<double> timeTsysSorted;
	288	Vector<Float> tmpTsys;
	289	if (doTsys) {
	290	os_ << "doTsys" << LogIO::POST;
	291	timeTsys.resize(nrowTsys);
	292	tsys.resize(nchanTsys, nrowTsys);
	293	nrowTsys = 0;
	294	for (uInt i = 0 ; i < tsystable_.size(); i++) {
	295	STCalTsysTable *p = tsystable_[i];
	296	os_ << "p->nrow()=" << p->nrow() << LogIO::POST;
	297	Vector<Double> t = p->getTime();
	298	os_ << "t=" << t << LogIO::POST;
	299	Matrix<Float> ts = p->getTsys();
	300	for (uInt j = 0; j < t.nelements(); j++) {
	301	timeTsys[nrowTsys] = t[j];
	302	tsys.column(nrowTsys) = ts.column(j);
	303	nrowTsys++;
	304	}
	305	}
	306	tsysIdx = timeSort(timeTsys);
	307	os_ << "tsysIdx = " << tsysIdx << LogIO::POST;
	308
	309	double *xb = new double[tsysIdx.nelements()];
	310	float *yb = new float[tsysIdx.nelements()];
	311	IPosition ipos(1, tsysIdx.nelements());
	312	timeTsysSorted.takeStorage(ipos, xb, TAKE_OVER);
	313	tmpTsys.takeStorage(ipos, yb, TAKE_OVER);
	314	for (uInt i = 0 ; i < tsysIdx.nelements(); i++) {
	315	timeTsysSorted[i] = (double)timeTsys[tsysIdx[i]];
	316	os_ << "timeTsysSorted[" << i << "]-timeTsysSorted[0]=" << timeTsysSorted[i] - timeTsysSorted[0] << LogIO::POST;
	317	}
	318	os_ << "timeTsysSorted=" << timeTsysSorted << LogIO::POST;
	319	interpolatorT_->setX(xb, tsysIdx.nelements());
	320	}
	321
	322	Table tab = work_->table();
	323	ArrayColumn<Float> spCol(tab, "SPECTRA");
	324	ScalarColumn<Double> timeCol(tab, "TIME");
	325	Vector<Float> on;
	326	for (uInt i = 0; i < rows.nelements(); i++) {
	327	os_ << "start row " << i << LogIO::POST;
	328	uInt irow = rows[i];
	329
	330	// target spectral data
	331	on = spCol(irow);
	332	calibrator_->setSource(on);
	333
	334	// interpolation
	335	double t0 = (double)timeCol(irow);
	336	for (uInt ichan = 0; ichan < nchanSp; ichan++) {
	337	Vector<Float> spOffSlice = spoff.row(ichan);
	338	//os_ << "spOffSlice = " << spOffSlice << LogIO::POST;
	339	for (uInt j = 0; j < skyIdx.nelements(); j++) {
	340	tmpOff[j] = (float)spOffSlice[skyIdx[j]];
	341	}
	342	interpolatorS_->setY(ya, skyIdx.nelements());
	343	iOff[ichan] = interpolatorS_->interpolate(t0);
	344	}
	345	//os_ << "iOff=" << iOff << LogIO::POST;
	346	calibrator_->setReference(iOff);
	347
	348	Float *Y = new Float[nchanSp];
	349	Vector<Float> iTsys(IPosition(1,nchanSp), Y, TAKE_OVER);
	350	if (doTsys) {
	351	// Tsys correction
	352	float *yt = new float[nchanTsys];
	353	Vector<Float> iTsysT(IPosition(1,nchanTsys), yt, TAKE_OVER);
	354	float *yb = tmpTsys.data();
	355	for (uInt ichan = 0; ichan < nchanTsys; ichan++) {
	356	Vector<Float> tsysSlice = tsys.row(ichan);
	357	for (uInt j = 0; j < tsysIdx.nelements(); j++) {
	358	tmpTsys[j] = (float)tsysSlice[tsysIdx[j]];
	359	}
	360	interpolatorT_->setY(yb, tsysIdx.nelements());
	361	iTsysT[ichan] = interpolatorT_->interpolate(t0);
	362	}
	363	os_ << "iTsysT=" << iTsysT << LogIO::POST;
	364	if (nchanSp == 1) {
	365	// take average
	366	iTsys[0] = mean(iTsysT);
	367	}
	368	else {
	369	// interpolation on frequency axis
	370	os_ << "getBaseFrequency for target" << LogIO::POST;
	371	Vector<Double> fsp = getBaseFrequency(rows[i]);
	372	os_ << "fsp = " << fsp << LogIO::POST;
	373	interpolatorF_->setY(yt, nchanTsys);
	374	for (uInt ichan = 0; ichan < nchanSp; ichan++) {
	375	iTsys[ichan] = (Float)interpolatorF_->interpolate(fsp[ichan]);
	376	}
	377	}
	378	}
	379	else {
	380	iTsys = 1.0;
	381	}
	382	os_ << "iTsys=" << iTsys << LogIO::POST;
	383	calibrator_->setScaler(iTsys);
	384
	385	// do calibration
	386	calibrator_->calibrate();
	387
	388	// update table
	389	os_ << "calibrated=" << calibrator_->getCalibrated() << LogIO::POST;
	390	spCol.put(irow, calibrator_->getCalibrated());
	391
	392	}
	393
	394
	395	// reset selection on apply tables
	396	for (uInt i = 0; i < skylist.nelements(); i++)
	397	skytable_[i]->unsetSelection();
	398	for (uInt i = 0; i < tsystable_.size(); i++)
	399	tsystable_[i]->unsetSelection();
	400
	401
	402	// reset interpolator
	403	interpolatorS_->reset();
	404	interpolatorF_->reset();
	405	interpolatorT_->reset();
	406	}
	407
	408	Vector<uInt> STApplyCal::timeSort(Vector<Double> &t)
	409	{
	410	Sort sort;
	411	sort.sortKey(&t[0], TpDouble, 0, Sort::Ascending);
	412	Vector<uInt> idx;
	413	sort.sort(idx, t.nelements(), Sort::QuickSort\|Sort::NoDuplicates);
	414	return idx;
	415	}
	416
	417	uInt STApplyCal::getIFForTsys(uInt to)
	418	{
	419	for (map<casa::uInt, Vector<uInt> >::iterator i = spwmap_.begin();
	420	i != spwmap_.end(); i++) {
	421	Vector<uInt> tolist = i->second;
	422	os_ << i->first << ": tolist=" << tolist << LogIO::POST;
	423	for (uInt j = 0; j < tolist.nelements(); j++) {
	424	if (tolist[j] == to)
	425	return i->first;
	426	}
	427	}
	428	return (uInt)-1;
	429	}
	430
	431	void STApplyCal::save(const String &name)
	432	{
	433	if (work_.null())
	434	return;
	435
	436	work_->setSelection(sel_);
	437	work_->makePersistent(name);
	438	work_->unsetSelection();
	439	}
	440
	441	Vector<Double> STApplyCal::getBaseFrequency(uInt whichrow)
	442	{
	443	assert(whichrow <= (uInt)work_->nrow());
	444	ROTableColumn col(work_->table(), "IFNO");
	445	uInt ifno = col.asuInt(whichrow);
	446	col.attach(work_->table(), "FREQ_ID");
	447	uInt freqid = col.asuInt(whichrow);
	448	uInt nc = work_->nchan(ifno);
	449	STFrequencies ftab = work_->frequencies();
	450	Double rp, rf, inc;
	451	ftab.getEntry(rp, rf, inc, freqid);
	452	Vector<Double> r(nc);
	453	indgen(r, rf-rp*inc, inc);
	454	return r;
	455	}
	456
[2727]	457	void STApplyCal::initInterpolator()
	458	{
	459	int ta = (int)STCalEnum::TimeAxis;
	460	int fa = (int)STCalEnum::FrequencyAxis;
	461	int order = (order_ > 0) ? order_ : 1;
	462	switch (interp_[ta]) {
	463	case STCalEnum::NearestInterpolation:
	464	{
	465	os_ << "use NearestInterpolator in time axis" << LogIO::POST;
	466	interpolatorS_ = new NearestInterpolator1D();
	467	interpolatorT_ = new NearestInterpolator1D();
	468	break;
	469	}
	470	case STCalEnum::LinearInterpolation:
	471	{
	472	os_ << "use BufferedLinearInterpolator in time axis" << LogIO::POST;
	473	interpolatorS_ = new BufferedLinearInterpolator1D();
	474	interpolatorT_ = new BufferedLinearInterpolator1D();
	475	break;
	476	}
	477	case STCalEnum::CubicSplineInterpolation:
	478	{
	479	os_ << "use CubicSplineInterpolator in time axis" << LogIO::POST;
	480	interpolatorS_ = new CubicSplineInterpolator1D();
	481	interpolatorT_ = new CubicSplineInterpolator1D();
	482	break;
	483	}
	484	case STCalEnum::PolynomialInterpolation:
	485	{
	486	os_ << "use PolynomialInterpolator in time axis" << LogIO::POST;
	487	if (order == 0) {
	488	interpolatorS_ = new NearestInterpolator1D();
	489	interpolatorT_ = new NearestInterpolator1D();
	490	}
	491	else {
	492	interpolatorS_ = new PolynomialInterpolator1D();
	493	interpolatorT_ = new PolynomialInterpolator1D();
	494	interpolatorS_->setOrder(order);
	495	interpolatorT_->setOrder(order);
	496	}
	497	break;
	498	}
	499	default:
	500	{
	501	os_ << "use BufferedLinearInterpolator in time axis" << LogIO::POST;
	502	interpolatorS_ = new BufferedLinearInterpolator1D();
	503	interpolatorT_ = new BufferedLinearInterpolator1D();
	504	break;
	505	}
	506	}
	507
	508	switch (interp_[fa]) {
	509	case STCalEnum::NearestInterpolation:
	510	{
	511	os_ << "use NearestInterpolator in frequency axis" << LogIO::POST;
	512	interpolatorF_ = new NearestInterpolator1D();
	513	break;
	514	}
	515	case STCalEnum::LinearInterpolation:
	516	{
	517	os_ << "use BufferedLinearInterpolator in frequency axis" << LogIO::POST;
	518	interpolatorF_ = new BufferedLinearInterpolator1D();
	519	break;
	520	}
	521	case STCalEnum::CubicSplineInterpolation:
	522	{
	523	os_ << "use CubicSplineInterpolator in frequency axis" << LogIO::POST;
	524	interpolatorF_ = new CubicSplineInterpolator1D();
	525	break;
	526	}
	527	case STCalEnum::PolynomialInterpolation:
	528	{
	529	os_ << "use PolynomialInterpolator in frequency axis" << LogIO::POST;
	530	if (order == 0) {
	531	interpolatorF_ = new NearestInterpolator1D();
	532	}
	533	else {
	534	interpolatorF_ = new PolynomialInterpolator1D();
	535	interpolatorF_->setOrder(order);
	536	}
	537	break;
	538	}
	539	default:
	540	{
	541	os_ << "use LinearInterpolator in frequency axis" << LogIO::POST;
	542	interpolatorF_ = new BufferedLinearInterpolator1D();
	543	break;
	544	}
	545	}
[2720]	546	}
[2727]	547	}

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