LCOV - code coverage report
Current view: top level - atmosphere/ATM - ATMSkyStatus.cc (source / functions) Hit Total Coverage
Test: ctest_coverage.info Lines: 91 1419 6.4 %
Date: 2023-11-06 10:06:49 Functions: 14 125 11.2 %

          Line data    Source code
       1             : /*******************************************************************************
       2             :  * ALMA - Atacama Large Millimiter Array
       3             :  * (c) Instituto de Estructura de la Materia, 2009
       4             :  *
       5             :  * This library is free software; you can redistribute it and/or
       6             :  * modify it under the terms of the GNU Lesser General Public
       7             :  * License as published by the Free Software Foundation; either
       8             :  * version 2.1 of the License, or (at your option) any later version.
       9             :  *
      10             :  * This library is distributed in the hope that it will be useful,
      11             :  * but WITHOUT ANY WARRANTY; without even the implied warranty of
      12             :  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
      13             :  * Lesser General Public License for more details.
      14             :  *
      15             :  * You should have received a copy of the GNU Lesser General Public
      16             :  * License along with this library; if not, write to the Free Software
      17             :  * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307  USA
      18             :  *
      19             :  * "@(#) $Id: ATMSkyStatus.cpp Exp $"
      20             :  *
      21             :  * who       when      what
      22             :  * --------  --------  ----------------------------------------------
      23             :  * pardo     24/03/09  created
      24             :  */
      25             : 
      26             : #include "ATMSkyStatus.h"
      27             : 
      28             : #include <iostream>
      29             : #include <math.h>
      30             : 
      31             : ATM_NAMESPACE_BEGIN
      32             : 
      33             : // Constructors
      34             : 
      35         864 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile) :
      36             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(1.0),
      37         864 :       skyBackgroundTemperature_(2.73, Temperature::UnitKelvin)
      38             : {
      39             : 
      40         864 :   iniSkyStatus();
      41             : 
      42         864 : }
      43             : 
      44           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
      45           0 :                      double airMass) :
      46             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
      47           0 :       skyBackgroundTemperature_(2.73, Temperature::UnitKelvin)
      48             : {
      49             : 
      50           0 :   iniSkyStatus();
      51             : 
      52           0 : }
      53             : 
      54           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
      55           0 :                      const Temperature &temperatureBackground) :
      56             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(1.0),
      57           0 :       skyBackgroundTemperature_(temperatureBackground)
      58             : {
      59             : 
      60           0 :   iniSkyStatus();
      61             : 
      62           0 : }
      63             : 
      64           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
      65           0 :                      const Length &wh2o) :
      66             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(1.0),
      67           0 :       skyBackgroundTemperature_(2.73, Temperature::UnitKelvin), wh2o_user_(wh2o)
      68             : {
      69             : 
      70           0 :   iniSkyStatus();
      71             : 
      72           0 : }
      73             : 
      74           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
      75             :                      const Temperature &temperatureBackground,
      76           0 :                      double airMass) :
      77             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
      78           0 :       skyBackgroundTemperature_(temperatureBackground)
      79             : {
      80             : 
      81           0 :   iniSkyStatus();
      82             : 
      83           0 : }
      84             : 
      85           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
      86             :                      double airMass,
      87           0 :                      const Temperature &temperatureBackground) :
      88             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
      89           0 :       skyBackgroundTemperature_(temperatureBackground)
      90             : {
      91             : 
      92           0 :   iniSkyStatus();
      93             : 
      94           0 : }
      95             : 
      96           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
      97             :                      const Length &wh2o,
      98           0 :                      double airMass) :
      99             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     100           0 :       skyBackgroundTemperature_(2.73, Temperature::UnitKelvin), wh2o_user_(wh2o)
     101             : {
     102             : 
     103           0 :   iniSkyStatus();
     104             : 
     105           0 : }
     106             : 
     107           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     108             :                      double airMass,
     109           0 :                      const Length &wh2o) :
     110             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     111           0 :       skyBackgroundTemperature_(2.73, Temperature::UnitKelvin), wh2o_user_(wh2o)
     112             : {
     113             : 
     114           0 :   iniSkyStatus();
     115             : 
     116           0 : }
     117             : 
     118           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     119             :                      const Length &wh2o,
     120           0 :                      const Temperature &temperatureBackground) :
     121             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(1.0),
     122           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     123             : {
     124             : 
     125           0 :   iniSkyStatus();
     126             : 
     127           0 : }
     128             : 
     129           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     130             :                      const Temperature &temperatureBackground,
     131           0 :                      const Length &wh2o) :
     132             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(1.0),
     133           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     134             : {
     135             : 
     136           0 :   iniSkyStatus();
     137             : 
     138           0 : }
     139             : 
     140           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     141             :                      const Temperature &temperatureBackground,
     142             :                      double airMass,
     143           0 :                      const Length &wh2o) :
     144             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     145           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     146             : {
     147             : 
     148           0 :   iniSkyStatus();
     149             : 
     150           0 : }
     151             : 
     152           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     153             :                      const Temperature &temperatureBackground,
     154             :                      const Length &wh2o,
     155           0 :                      double airMass) :
     156             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     157           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     158             : {
     159             : 
     160           0 :   iniSkyStatus();
     161             : 
     162           0 : }
     163             : 
     164           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     165             :                      double airMass,
     166             :                      const Temperature &temperatureBackground,
     167           0 :                      const Length &wh2o) :
     168             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     169           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     170             : {
     171             : 
     172           0 :   iniSkyStatus();
     173             : 
     174           0 : }
     175             : 
     176           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     177             :                      double airMass,
     178             :                      const Length &wh2o,
     179           0 :                      const Temperature &temperatureBackground) :
     180             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     181           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     182             : {
     183             : 
     184           0 :   iniSkyStatus();
     185             : 
     186           0 : }
     187             : 
     188           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     189             :                      const Length &wh2o,
     190             :                      const Temperature &temperatureBackground,
     191           0 :                      double airMass) :
     192             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     193           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     194             : {
     195             : 
     196           0 :   iniSkyStatus();
     197             : 
     198           0 : }
     199             : 
     200           0 : SkyStatus::SkyStatus(const RefractiveIndexProfile &refractiveIndexProfile,
     201             :                      const Length &wh2o,
     202             :                      double airMass,
     203           0 :                      const Temperature &temperatureBackground) :
     204             :   RefractiveIndexProfile(refractiveIndexProfile), airMass_(airMass),
     205           0 :       skyBackgroundTemperature_(temperatureBackground), wh2o_user_(wh2o)
     206             : {
     207             : 
     208           0 :   iniSkyStatus();
     209             : 
     210           0 : }
     211             : 
     212         248 : SkyStatus::SkyStatus(const SkyStatus & a) : RefractiveIndexProfile(a)
     213             : {
     214             : 
     215             :   // 2015-03-02 (DB) :
     216             :   // Use constructor of base class RefractiveIndexProfile()
     217             :   // and comment the following code because it is executed in RefractiveIndexProfile() constructor
     218             : 
     219             : //   groundTemperature_ = a.groundTemperature_;
     220             : //   tropoLapseRate_ = a.tropoLapseRate_;
     221             : //   groundPressure_ = a.groundPressure_;
     222             : //   relativeHumidity_ = a.relativeHumidity_;
     223             : //   wvScaleHeight_ = a.wvScaleHeight_;
     224             : //   pressureStep_ = a.pressureStep_;
     225             : //   pressureStepFactor_ = a.pressureStepFactor_;
     226             : //   altitude_ = a.altitude_;
     227             : //   topAtmProfile_ = a.topAtmProfile_;
     228             : //   numLayer_ = a.numLayer_;
     229             : //   newBasicParam_ = a.newBasicParam_;
     230             : //   v_layerThickness_.reserve(numLayer_);
     231             : //   v_layerTemperature_.reserve(numLayer_);
     232             : //   v_layerWaterVapor_.reserve(numLayer_);
     233             : //   v_layerCO_.reserve(numLayer_);
     234             : //   v_layerO3_.reserve(numLayer_);
     235             : //   v_layerN2O_.reserve(numLayer_);
     236             : //   v_layerNO2_.reserve(numLayer_);
     237             : //   v_layerSO2_.reserve(numLayer_);
     238             : //   for(unsigned int n = 0; n < numLayer_; n++) {
     239             : //     v_layerThickness_.push_back(a.v_layerThickness_[n]);
     240             : //     v_layerTemperature_.push_back(a.v_layerTemperature_[n]);
     241             : //     //v_layerDeltaT_.push_back(a.v_layerDeltaT_[n]);
     242             : //     //cout << "n=" << n << endl;
     243             : //     v_layerWaterVapor_.push_back(a.v_layerWaterVapor_[n]);
     244             : //     v_layerPressure_.push_back(a.v_layerPressure_[n]);
     245             : //     v_layerCO_.push_back(a.v_layerCO_[n]);
     246             : //     v_layerO3_.push_back(a.v_layerO3_[n]);
     247             : //     v_layerN2O_.push_back(a.v_layerN2O_[n]);
     248             : //     v_layerNO2_.push_back(a.v_layerNO2_[n]);
     249             : //     v_layerSO2_.push_back(a.v_layerSO2_[n]);
     250             : //   }
     251             : 
     252             : //   // level Spectral Grid
     253             : //   freqUnits_ = a.freqUnits_;
     254             : //   v_chanFreq_ = a.v_chanFreq_;
     255             : 
     256             : //   v_numChan_ = a.v_numChan_;
     257             : //   v_refChan_ = a.v_refChan_;
     258             : //   v_refFreq_ = a.v_refFreq_;
     259             : //   v_chanSep_ = a.v_chanSep_;
     260             : //   v_maxFreq_ = a.v_maxFreq_;
     261             : //   v_minFreq_ = a.v_minFreq_;
     262             : //   v_intermediateFrequency_ = a.v_intermediateFrequency_;
     263             : //   v_loFreq_ = a.v_loFreq_;
     264             : 
     265             : //   v_sidebandSide_ = a.v_sidebandSide_;
     266             : //   v_sidebandType_ = a.v_sidebandType_;
     267             : 
     268             : //   vv_assocSpwId_ = a.vv_assocSpwId_;
     269             : //   vv_assocNature_ = a.vv_assocNature_;
     270             : 
     271             : //   v_transfertId_ = a.v_transfertId_;
     272             : 
     273             : //   // level Absorption Profile
     274             : //   vv_N_H2OLinesPtr_.reserve(a.v_chanFreq_.size());
     275             : //   vv_N_H2OContPtr_.reserve(a.v_chanFreq_.size());
     276             : //   vv_N_O2LinesPtr_.reserve(a.v_chanFreq_.size());
     277             : //   vv_N_DryContPtr_.reserve(a.v_chanFreq_.size());
     278             : //   vv_N_O3LinesPtr_.reserve(a.v_chanFreq_.size());
     279             : //   vv_N_COLinesPtr_.reserve(a.v_chanFreq_.size());
     280             : //   vv_N_N2OLinesPtr_.reserve(a.v_chanFreq_.size());
     281             : //   vv_N_NO2LinesPtr_.reserve(a.v_chanFreq_.size());
     282             : //   vv_N_SO2LinesPtr_.reserve(a.v_chanFreq_.size());
     283             : 
     284             : //   vector<complex<double> >* v_N_H2OLinesPtr;
     285             : //   vector<complex<double> >* v_N_H2OContPtr;
     286             : //   vector<complex<double> >* v_N_O2LinesPtr;
     287             : //   vector<complex<double> >* v_N_DryContPtr;
     288             : //   vector<complex<double> >* v_N_O3LinesPtr;
     289             : //   vector<complex<double> >* v_N_COLinesPtr;
     290             : //   vector<complex<double> >* v_N_N2OLinesPtr;
     291             : //   vector<complex<double> >* v_N_NO2LinesPtr;
     292             : //   vector<complex<double> >* v_N_SO2LinesPtr;
     293             : 
     294             : //   for(unsigned int nc = 0; nc < v_chanFreq_.size(); nc++) {
     295             : 
     296             : //     v_N_H2OLinesPtr = new vector<complex<double> > ;
     297             : //     v_N_H2OLinesPtr->reserve(numLayer_);
     298             : //     v_N_H2OContPtr = new vector<complex<double> > ;
     299             : //     v_N_H2OContPtr->reserve(numLayer_);
     300             : //     v_N_O2LinesPtr = new vector<complex<double> > ;
     301             : //     v_N_O2LinesPtr->reserve(numLayer_);
     302             : //     v_N_DryContPtr = new vector<complex<double> > ;
     303             : //     v_N_DryContPtr->reserve(numLayer_);
     304             : //     v_N_O3LinesPtr = new vector<complex<double> > ;
     305             : //     v_N_O3LinesPtr->reserve(numLayer_);
     306             : //     v_N_COLinesPtr = new vector<complex<double> > ;
     307             : //     v_N_COLinesPtr->reserve(numLayer_);
     308             : //     v_N_N2OLinesPtr = new vector<complex<double> > ;
     309             : //     v_N_N2OLinesPtr->reserve(numLayer_);
     310             : //     v_N_NO2LinesPtr = new vector<complex<double> > ;
     311             : //     v_N_NO2LinesPtr->reserve(numLayer_);
     312             : //     v_N_SO2LinesPtr = new vector<complex<double> > ;
     313             : //     v_N_SO2LinesPtr->reserve(numLayer_);
     314             : 
     315             : //     for(unsigned int n = 0; n < numLayer_; n++) {
     316             : 
     317             : //       // cout << "numLayer_=" << nc << " " << n << endl; // COMMENTED OUT BY JUAN MAY/16/2005
     318             : 
     319             : //       v_N_H2OLinesPtr->push_back(a.vv_N_H2OLinesPtr_[nc]->at(n));
     320             : //       v_N_H2OContPtr->push_back(a.vv_N_H2OContPtr_[nc]->at(n));
     321             : //       v_N_O2LinesPtr->push_back(a.vv_N_O2LinesPtr_[nc]->at(n));
     322             : //       v_N_DryContPtr->push_back(a.vv_N_DryContPtr_[nc]->at(n));
     323             : //       v_N_O3LinesPtr->push_back(a.vv_N_O3LinesPtr_[nc]->at(n));
     324             : //       v_N_COLinesPtr->push_back(a.vv_N_COLinesPtr_[nc]->at(n));
     325             : //       v_N_N2OLinesPtr->push_back(a.vv_N_N2OLinesPtr_[nc]->at(n));
     326             : //       v_N_NO2LinesPtr->push_back(a.vv_N_NO2LinesPtr_[nc]->at(n));
     327             : //       v_N_SO2LinesPtr->push_back(a.vv_N_SO2LinesPtr_[nc]->at(n));
     328             : 
     329             : //     }
     330             : 
     331             : //     vv_N_H2OLinesPtr_.push_back(v_N_H2OLinesPtr);
     332             : //     vv_N_H2OContPtr_.push_back(v_N_H2OContPtr);
     333             : //     vv_N_O2LinesPtr_.push_back(v_N_O2LinesPtr);
     334             : //     vv_N_DryContPtr_.push_back(v_N_DryContPtr);
     335             : //     vv_N_O3LinesPtr_.push_back(v_N_O3LinesPtr);
     336             : //     vv_N_COLinesPtr_.push_back(v_N_COLinesPtr);
     337             : //     vv_N_N2OLinesPtr_.push_back(v_N_N2OLinesPtr);
     338             : //     vv_N_NO2LinesPtr_.push_back(v_N_NO2LinesPtr);
     339             : //     vv_N_SO2LinesPtr_.push_back(v_N_SO2LinesPtr);
     340             : 
     341             : //   }
     342             : 
     343             :   // level Atm Radiance
     344             : 
     345         248 :   airMass_ = a.airMass_;
     346         248 :   skyBackgroundTemperature_ = a.skyBackgroundTemperature_;
     347         248 :   wh2o_user_ = a.wh2o_user_;
     348             : 
     349         248 : }
     350             : 
     351        1976 : SkyStatus::~SkyStatus()
     352             : {
     353        1112 :   rmSkyStatus();
     354        1976 : }
     355             : 
     356          43 : bool SkyStatus::setBasicAtmosphericParameters(const Length &altitude,
     357             :                                               const Pressure &groundPressure,
     358             :                                               const Temperature &groundTemperature,
     359             :                                               double tropoLapseRate,
     360             :                                               const Humidity &relativeHumidity,
     361             :                                               const Length &wvScaleHeight)
     362             : {
     363          43 :   bool update = updateProfilesAndRadiance(altitude,
     364             :                                           groundPressure,
     365             :                                           groundTemperature,
     366             :                                           tropoLapseRate,
     367             :                                           relativeHumidity,
     368             :                                           wvScaleHeight);
     369          43 :   return update;
     370             : }
     371             : 
     372           0 : bool SkyStatus::setBasicAtmosphericParameters(const Length &altitude,
     373             :                                               const Length &wvScaleHeight)
     374             : {
     375           0 :   bool update = updateProfilesAndRadiance(altitude,
     376           0 :                                           groundPressure_,
     377           0 :                                           groundTemperature_,
     378             :                                           tropoLapseRate_,
     379           0 :                                           relativeHumidity_,
     380             :                                           wvScaleHeight);
     381           0 :   return update;
     382             : }
     383             : 
     384           0 : bool SkyStatus::setBasicAtmosphericParameters(const Length &altitude)
     385             : {
     386           0 :   bool update = updateProfilesAndRadiance(altitude,
     387           0 :                                           groundPressure_,
     388           0 :                                           groundTemperature_,
     389             :                                           tropoLapseRate_,
     390           0 :                                           relativeHumidity_,
     391           0 :                                           wvScaleHeight_);
     392           0 :   return update;
     393             : }
     394             : 
     395           0 : bool SkyStatus::setBasicAtmosphericParameters(const Temperature &groundTemperature)
     396             : {
     397           0 :   bool update = updateProfilesAndRadiance(altitude_,
     398           0 :                                           groundPressure_,
     399             :                                           groundTemperature,
     400             :                                           tropoLapseRate_,
     401           0 :                                           relativeHumidity_,
     402           0 :                                           wvScaleHeight_);
     403           0 :   return update;
     404             : }
     405             : 
     406           0 : bool SkyStatus::setBasicAtmosphericParameters(const Pressure &groundPressure)
     407             : {
     408             : 
     409           0 :   bool update = updateProfilesAndRadiance(altitude_,
     410             :                                           groundPressure,
     411           0 :                                           groundTemperature_,
     412             :                                           tropoLapseRate_,
     413           0 :                                           relativeHumidity_,
     414           0 :                                           wvScaleHeight_);
     415             : 
     416           0 :   return update;
     417             : }
     418             : 
     419           0 : bool SkyStatus::setBasicAtmosphericParameters(const Humidity &relativeHumidity)
     420             : {
     421           0 :   bool update = updateProfilesAndRadiance(altitude_,
     422           0 :                                           groundPressure_,
     423           0 :                                           groundTemperature_,
     424             :                                           tropoLapseRate_,
     425             :                                           relativeHumidity,
     426           0 :                                           wvScaleHeight_);
     427           0 :   return update;
     428             : }
     429             : 
     430           0 : bool SkyStatus::setBasicAtmosphericParameters(double tropoLapseRate)
     431             : {
     432           0 :   bool update = updateProfilesAndRadiance(altitude_,
     433           0 :                                           groundPressure_,
     434           0 :                                           groundTemperature_,
     435             :                                           tropoLapseRate,
     436           0 :                                           relativeHumidity_,
     437           0 :                                           wvScaleHeight_);
     438           0 :   return update;
     439             : }
     440             : 
     441           0 : bool SkyStatus::setBasicAtmosphericParameters(const Length &altitude,
     442             :                                               const Temperature &groundTemperature)
     443             : {
     444           0 :   bool update = updateProfilesAndRadiance(altitude,
     445           0 :                                           groundPressure_,
     446             :                                           groundTemperature,
     447             :                                           tropoLapseRate_,
     448           0 :                                           relativeHumidity_,
     449           0 :                                           wvScaleHeight_);
     450           0 :   return update;
     451             : }
     452             : 
     453           0 : bool SkyStatus::setBasicAtmosphericParameters(const Length &altitude,
     454             :                                               const Pressure &groundPressure)
     455             : {
     456           0 :   bool update = updateProfilesAndRadiance(altitude,
     457             :                                           groundPressure,
     458           0 :                                           groundTemperature_,
     459             :                                           tropoLapseRate_,
     460           0 :                                           relativeHumidity_,
     461           0 :                                           wvScaleHeight_);
     462           0 :   return update;
     463             : }
     464             : 
     465           0 : bool SkyStatus::setBasicAtmosphericParameters(const Length &altitude,
     466             :                                               const Humidity &relativeHumidity)
     467             : {
     468           0 :   bool update = updateProfilesAndRadiance(altitude,
     469           0 :                                           groundPressure_,
     470           0 :                                           groundTemperature_,
     471             :                                           tropoLapseRate_,
     472             :                                           relativeHumidity,
     473           0 :                                           wvScaleHeight_);
     474           0 :   return update;
     475             : }
     476             : 
     477           0 : bool SkyStatus::setBasicAtmosphericParameters(const Length &altitude,
     478             :                                               double tropoLapseRate)
     479             : {
     480           0 :   bool update = updateProfilesAndRadiance(altitude,
     481           0 :                                           groundPressure_,
     482           0 :                                           groundTemperature_,
     483             :                                           tropoLapseRate,
     484           0 :                                           relativeHumidity_,
     485           0 :                                           wvScaleHeight_);
     486           0 :   return update;
     487             : }
     488             : 
     489           0 : bool SkyStatus::setBasicAtmosphericParameters(const Temperature &groundTemperature,
     490             :                                               const Pressure &groundPressure)
     491             : {
     492           0 :   bool update = updateProfilesAndRadiance(altitude_,
     493             :                                           groundPressure,
     494             :                                           groundTemperature,
     495             :                                           tropoLapseRate_,
     496           0 :                                           relativeHumidity_,
     497           0 :                                           wvScaleHeight_);
     498           0 :   return update;
     499             : }
     500           0 : bool SkyStatus::setBasicAtmosphericParameters(const Pressure &groundPressure,
     501             :                                               const Temperature &groundTemperature)
     502             : {
     503           0 :   bool update = updateProfilesAndRadiance(altitude_,
     504             :                                           groundPressure,
     505             :                                           groundTemperature,
     506             :                                           tropoLapseRate_,
     507           0 :                                           relativeHumidity_,
     508           0 :                                           wvScaleHeight_);
     509           0 :   return update;
     510             : }
     511             : 
     512           0 : bool SkyStatus::setBasicAtmosphericParameters(const Temperature &groundTemperature,
     513             :                                               const Humidity &relativeHumidity)
     514             : {
     515           0 :   bool update = updateProfilesAndRadiance(altitude_,
     516           0 :                                           groundPressure_,
     517             :                                           groundTemperature,
     518             :                                           tropoLapseRate_,
     519             :                                           relativeHumidity,
     520           0 :                                           wvScaleHeight_);
     521           0 :   return update;
     522             : }
     523           0 : bool SkyStatus::setBasicAtmosphericParameters(const Humidity &relativeHumidity,
     524             :                                               const Temperature &groundTemperature)
     525             : {
     526           0 :   bool update = updateProfilesAndRadiance(altitude_,
     527           0 :                                           groundPressure_,
     528             :                                           groundTemperature,
     529             :                                           tropoLapseRate_,
     530             :                                           relativeHumidity,
     531           0 :                                           wvScaleHeight_);
     532           0 :   return update;
     533             : }
     534             : 
     535           0 : bool SkyStatus::setBasicAtmosphericParameters(const Temperature &groundTemperature,
     536             :                                               double tropoLapseRate)
     537             : {
     538           0 :   bool update = updateProfilesAndRadiance(altitude_,
     539           0 :                                           groundPressure_,
     540             :                                           groundTemperature,
     541             :                                           tropoLapseRate,
     542           0 :                                           relativeHumidity_,
     543           0 :                                           wvScaleHeight_);
     544           0 :   return update;
     545             : }
     546           0 : bool SkyStatus::setBasicAtmosphericParameters(double tropoLapseRate,
     547             :                                               const Temperature &groundTemperature)
     548             : {
     549           0 :   bool update = updateProfilesAndRadiance(altitude_,
     550           0 :                                           groundPressure_,
     551             :                                           groundTemperature,
     552             :                                           tropoLapseRate,
     553           0 :                                           relativeHumidity_,
     554           0 :                                           wvScaleHeight_);
     555           0 :   return update;
     556             : }
     557             : 
     558           0 : bool SkyStatus::setBasicAtmosphericParameters(const Temperature &groundTemperature,
     559             :                                               const Length &wvScaleHeight)
     560             : {
     561           0 :   bool update = updateProfilesAndRadiance(altitude_,
     562           0 :                                           groundPressure_,
     563             :                                           groundTemperature,
     564             :                                           tropoLapseRate_,
     565           0 :                                           relativeHumidity_,
     566             :                                           wvScaleHeight);
     567           0 :   return update;
     568             : }
     569             : 
     570           0 : bool SkyStatus::setBasicAtmosphericParameters(const Pressure &groundPressure,
     571             :                                               const Humidity &relativeHumidity)
     572             : {
     573           0 :   bool update = updateProfilesAndRadiance(altitude_,
     574             :                                           groundPressure,
     575           0 :                                           groundTemperature_,
     576             :                                           tropoLapseRate_,
     577             :                                           relativeHumidity,
     578           0 :                                           wvScaleHeight_);
     579           0 :   return update;
     580             : }
     581           0 : bool SkyStatus::setBasicAtmosphericParameters(const Humidity &relativeHumidity,
     582             :                                               const Pressure &groundPressure)
     583             : {
     584           0 :   bool update = updateProfilesAndRadiance(altitude_,
     585             :                                           groundPressure,
     586           0 :                                           groundTemperature_,
     587             :                                           tropoLapseRate_,
     588             :                                           relativeHumidity,
     589           0 :                                           wvScaleHeight_);
     590           0 :   return update;
     591             : }
     592             : 
     593           0 : bool SkyStatus::setBasicAtmosphericParameters(const Pressure &groundPressure,
     594             :                                               double tropoLapseRate)
     595             : {
     596           0 :   bool update = updateProfilesAndRadiance(altitude_,
     597             :                                           groundPressure,
     598           0 :                                           groundTemperature_,
     599             :                                           tropoLapseRate,
     600           0 :                                           relativeHumidity_,
     601           0 :                                           wvScaleHeight_);
     602           0 :   return update;
     603             : }
     604           0 : bool SkyStatus::setBasicAtmosphericParameters(double tropoLapseRate,
     605             :                                               const Pressure &groundPressure)
     606             : {
     607           0 :   bool update = updateProfilesAndRadiance(altitude_,
     608             :                                           groundPressure,
     609           0 :                                           groundTemperature_,
     610             :                                           tropoLapseRate,
     611           0 :                                           relativeHumidity_,
     612           0 :                                           wvScaleHeight_);
     613           0 :   return update;
     614             : }
     615             : 
     616           0 : bool SkyStatus::setBasicAtmosphericParameters(const Pressure &groundPressure,
     617             :                                               const Length &wvScaleHeight)
     618             : {
     619           0 :   bool update = updateProfilesAndRadiance(altitude_,
     620             :                                           groundPressure,
     621           0 :                                           groundTemperature_,
     622             :                                           tropoLapseRate_,
     623           0 :                                           relativeHumidity_,
     624             :                                           wvScaleHeight);
     625           0 :   return update;
     626             : }
     627             : 
     628           0 : bool SkyStatus::setBasicAtmosphericParameters(const Humidity &relativeHumidity,
     629             :                                               double tropoLapseRate)
     630             : {
     631           0 :   bool update = updateProfilesAndRadiance(altitude_,
     632           0 :                                           groundPressure_,
     633           0 :                                           groundTemperature_,
     634             :                                           tropoLapseRate,
     635             :                                           relativeHumidity,
     636           0 :                                           wvScaleHeight_);
     637           0 :   return update;
     638             : }
     639           0 : bool SkyStatus::setBasicAtmosphericParameters(double tropoLapseRate,
     640             :                                               const Humidity &relativeHumidity)
     641             : {
     642           0 :   bool update = updateProfilesAndRadiance(altitude_,
     643           0 :                                           groundPressure_,
     644           0 :                                           groundTemperature_,
     645             :                                           tropoLapseRate,
     646             :                                           relativeHumidity,
     647           0 :                                           wvScaleHeight_);
     648           0 :   return update;
     649             : }
     650             : 
     651           0 : bool SkyStatus::setBasicAtmosphericParameters(const Humidity &relativeHumidity,
     652             :                                               const Length &wvScaleHeight)
     653             : {
     654           0 :   bool update = updateProfilesAndRadiance(altitude_,
     655           0 :                                           groundPressure_,
     656           0 :                                           groundTemperature_,
     657             :                                           tropoLapseRate_,
     658             :                                           relativeHumidity,
     659             :                                           wvScaleHeight);
     660           0 :   return update;
     661             : }
     662             : 
     663           0 : bool SkyStatus::setBasicAtmosphericParameters(double tropoLapseRate,
     664             :                                               const Length &wvScaleHeight)
     665             : {
     666           0 :   bool update = updateProfilesAndRadiance(altitude_,
     667           0 :                                           groundPressure_,
     668           0 :                                           groundTemperature_,
     669             :                                           tropoLapseRate,
     670           0 :                                           relativeHumidity_,
     671             :                                           wvScaleHeight);
     672           0 :   return update;
     673             : }
     674             : 
     675          43 : bool SkyStatus::updateProfilesAndRadiance(const Length &altitude,
     676             :                                           const Pressure &groundPressure,
     677             :                                           const Temperature &groundTemperature,
     678             :                                           double tropoLapseRate,
     679             :                                           const Humidity &relativeHumidity,
     680             :                                           const Length &wvScaleHeight)
     681             : {
     682             : 
     683          43 :   bool updated = false;
     684             : 
     685          43 :   bool mkNewAbsPhaseProfile = updateRefractiveIndexProfile(altitude,
     686             :                                                            groundPressure,
     687             :                                                            groundTemperature,
     688             :                                                            tropoLapseRate,
     689             :                                                            relativeHumidity,
     690             :                                                            wvScaleHeight);
     691             : 
     692          43 :   if(mkNewAbsPhaseProfile) {
     693          43 :     updated = true;
     694             :   }
     695          43 :   return updated;
     696             : }
     697             : 
     698     7893903 : Opacity SkyStatus::getH2OLinesOpacity(unsigned int nc)
     699             : {
     700     7893903 :   if(!chanIndexIsValid(nc)) return (double) -999.0;
     701     7893903 :   double kv = 0;
     702   219698235 :   for(unsigned int j = 0; j < numLayer_; j++) {
     703   211804332 :     kv = kv + imag(vv_N_H2OLinesPtr_[nc]->at(j)) * v_layerThickness_[j];
     704             :   }
     705     7893903 :   return ((getUserWH2O().get()) / (getGroundWH2O().get())) * kv;
     706             : }
     707             : 
     708           0 : Opacity SkyStatus::getH2OLinesOpacityUpTo(unsigned int nc, Length refalti)
     709             : {
     710           0 :   unsigned int ires; unsigned int numlayerold; Length alti;
     711           0 :   Opacity opacityout0; Opacity opacityout1; Opacity zeroOp(0.0,Opacity::UnitNeper);
     712             :   double fractionLast; double g1; double g2;
     713             : 
     714           0 :   if(refalti.get(Length::UnitKiloMeter) <= altitude_.get(Length::UnitKiloMeter)) {
     715           0 :     return zeroOp;
     716             :   }else{
     717           0 :       fractionLast = 1.0; numlayerold = numLayer_;
     718           0 :       g1=getGroundWH2O().get();
     719           0 :       opacityout0=getH2OLinesOpacity(nc); ires=numlayerold-1; alti=altitude_;
     720           0 :       for(unsigned int i=0; i<numLayer_; i++){
     721           0 :         if(alti.get(Length::UnitKiloMeter) < refalti.get(Length::UnitKiloMeter) &&  (alti.get(Length::UnitKiloMeter)+v_layerThickness_[i]/1000.0) >= refalti.get(Length::UnitKiloMeter))
     722           0 :           { ires=i; fractionLast = (refalti.get(Length::UnitMeter)-alti.get(Length::UnitMeter))/v_layerThickness_[i]; }
     723           0 :         alti = alti + Length(v_layerThickness_[i],Length::UnitMeter);
     724             :       }
     725           0 :       numLayer_ = ires; g2=getGroundWH2O().get();
     726           0 :       opacityout0=getH2OLinesOpacity(nc)*(g2/g1);
     727           0 :       numLayer_ = ires+1; g2=getGroundWH2O().get();
     728           0 :       opacityout1=getH2OLinesOpacity(nc)*(g2/g1);
     729           0 :       numLayer_ = numlayerold;
     730           0 :       return opacityout0+(opacityout1-opacityout0)*fractionLast;
     731             :   }
     732             : }
     733             : 
     734             : /*
     735             : Opacity SkyStatus::getTotalOpacityUpTo(unsigned int nc, Length refalti)    //15NOV2017
     736             :   {
     737             :     unsigned int ires; unsigned int numlayerold; Length alti;
     738             :     Opacity opacityout; Opacity opacityout0;
     739             :     Opacity opacityout1; Opacity zeroOp(0.0,Opacity::UnitNeper);
     740             :     double fractionLast; double g1; double g2;
     741             : 
     742             :     if(refalti.get(Length::UnitKiloMeter) <= altitude_.get(Length::UnitKiloMeter)) {
     743             :       return zeroOp;
     744             :     }else{
     745             :       fractionLast = 1.0; numlayerold = numLayer_;
     746             :       g1=getGroundWH2O().get(); ires = numlayerold-1; alti=altitude_;
     747             :       for(unsigned int i=0; i<numLayer_; i++){
     748             :         if(alti.get(Length::UnitKiloMeter) < refalti.get(Length::UnitKiloMeter) &&  (alti.get(Length::UnitKiloMeter)+v_layerThickness_[i]/1000.0) >= refalti.get(Length::UnitKiloMeter))
     749             :           { ires=i; fractionLast = (refalti.get(Length::UnitMeter)-alti.get(Length::UnitMeter))/v_layerThickness_[i]; }
     750             :         alti = alti + Length(v_layerThickness_[i],Length::UnitMeter);
     751             :       }
     752             :       numLayer_ = ires+1; g2=getGroundWH2O().get();
     753             :       // std::cout << "En getTotalOpacityUpTo numlayerold numLayer_ fractionLast " << numlayerold << " " << numLayer_ << " " << fractionLast << std::endl;
     754             :       // std::cout << "calculando opacityout1" << std::endl;
     755             :       opacityout1 = getWetOpacity(nc)*(g2/g1) + getDryOpacity(nc);
     756             :       // std::cout << "opacityout1= " << opacityout1.get("np") << std::endl;
     757             :       // std::cout << "calculando opacityout0" << std::endl;
     758             :       // std::cout << "ires=" << ires << std::endl;
     759             :       if(ires == 0){
     760             :         opacityout0 = zeroOp;
     761             :       }else{
     762             :         numLayer_ = ires; g2=getGroundWH2O().get();
     763             :         opacityout0 = getWetOpacity(nc)*(g2/g1) + getDryOpacity(nc);
     764             :       }
     765             :       //    std::cout << "opacityout0= " << opacityout0.get("np") << std::endl;
     766             :       opacityout = opacityout0 + (opacityout1-opacityout0)*fractionLast;
     767             :       numLayer_ = numlayerold;
     768             :       return opacityout;
     769             :     }
     770             :   }
     771             : */
     772             : 
     773     7893903 : Opacity SkyStatus::getH2OContOpacity(unsigned int nc)
     774             : {
     775     7893903 :   if(!chanIndexIsValid(nc)) return (double) -999.0;
     776     7893903 :   double kv = 0;
     777   219698235 :   for(unsigned int j = 0; j < numLayer_; j++) {
     778   211804332 :     kv = kv + imag(vv_N_H2OContPtr_[nc]->at(j)) * v_layerThickness_[j];
     779             :   }
     780     7893903 :   return ((getUserWH2O().get()) / (getGroundWH2O().get())) * kv;
     781             : }
     782             : 
     783           0 : Opacity SkyStatus::getH2OContOpacityUpTo(unsigned int nc, Length refalti)
     784             : {
     785           0 :   unsigned int ires; unsigned int numlayerold; Length alti;
     786           0 :   Opacity opacityout0; Opacity opacityout1; Opacity zeroOp(0.0,Opacity::UnitNeper);
     787             :   double fractionLast; double g1; double g2;
     788             : 
     789             : 
     790           0 :   if(refalti.get(Length::UnitKiloMeter) <= altitude_.get(Length::UnitKiloMeter)) {
     791           0 :     return zeroOp;
     792             :   }else{
     793           0 :       fractionLast = 1.0; numlayerold = numLayer_;
     794           0 :       g1=getGroundWH2O().get();
     795           0 :       opacityout0=getH2OContOpacity(nc); ires=numlayerold-1; alti=altitude_;
     796           0 :       for(unsigned int i=0; i<numLayer_; i++){
     797           0 :         if(alti.get(Length::UnitKiloMeter) < refalti.get(Length::UnitKiloMeter) &&  (alti.get(Length::UnitKiloMeter)+v_layerThickness_[i]/1000.0) >= refalti.get(Length::UnitKiloMeter))
     798           0 :           { ires=i; fractionLast = (refalti.get(Length::UnitMeter)-alti.get(Length::UnitMeter))/v_layerThickness_[i]; }
     799           0 :         alti = alti + Length(v_layerThickness_[i],Length::UnitMeter);
     800             :       }
     801           0 :       numLayer_ = ires; g2=getGroundWH2O().get();
     802           0 :       opacityout0=getH2OContOpacity(nc)*(g2/g1);
     803           0 :       numLayer_ = ires+1; g2=getGroundWH2O().get();
     804           0 :       opacityout1=getH2OContOpacity(nc)*(g2/g1);
     805           0 :       numLayer_ = numlayerold;
     806           0 :       return opacityout0+(opacityout1-opacityout0)*fractionLast;
     807             :   }
     808             : }
     809             : 
     810           0 : Angle SkyStatus::getDispersiveH2OPhaseDelay(unsigned int nc)
     811             : {
     812           0 :   if(!chanIndexIsValid(nc)) {
     813           0 :     Angle aa(0.0, Angle::UnitDegree);
     814           0 :     return aa;
     815             :   }
     816           0 :   double kv = 0;
     817           0 :   for(unsigned int j = 0; j < numLayer_; j++) {
     818           0 :     kv = kv + real(vv_N_H2OLinesPtr_[nc]->at(j)) * v_layerThickness_[j];
     819             :   }
     820           0 :   Angle aa(((getUserWH2O().get()) / (getGroundWH2O().get())) * kv * 57.29578,
     821           0 :            Angle::UnitDegree);
     822           0 :   return aa;
     823             : }
     824             : 
     825           0 : Length SkyStatus::getDispersiveH2OPathLength(unsigned int nc)
     826             : {
     827           0 :   if(!chanIndexIsValid(nc)) {
     828           0 :     Length ll(0.0, Length::UnitMilliMeter);
     829           0 :     return ll;
     830             :   }
     831           0 :   double wavelength = 299792458.0 / v_chanFreq_[nc]; // in m
     832           0 :   Length ll((wavelength / 360.0) * getDispersiveH2OPhaseDelay(nc).get(Angle::UnitDegree),
     833           0 :             Length::UnitMeter);
     834           0 :   return ll;
     835             : }
     836             : 
     837           0 : Angle SkyStatus::getNonDispersiveH2OPhaseDelay(unsigned int nc)
     838             : {
     839           0 :   double kv = 0;
     840           0 :   if(!chanIndexIsValid(nc)) {
     841           0 :     Angle aa(0.0, Angle::UnitDegree);
     842           0 :     return aa;
     843             :   }
     844           0 :   for(unsigned int j = 0; j < numLayer_; j++) {
     845           0 :     kv = kv + real(vv_N_H2OContPtr_[nc]->at(j)) * v_layerThickness_[j];
     846             :   }
     847           0 :   Angle aa(((getUserWH2O().get()) / (getGroundWH2O().get())) * kv * 57.29578,
     848           0 :            Angle::UnitDegree);
     849           0 :   return aa;
     850             : }
     851             : 
     852           0 : Length SkyStatus::getNonDispersiveH2OPathLength(unsigned int nc)
     853             : {
     854           0 :   if(!chanIndexIsValid(nc)) {
     855           0 :     Length ll(0.0, Length::UnitMilliMeter);
     856           0 :     return ll;
     857             :   }
     858           0 :   double wavelength = 299792458.0 / v_chanFreq_[nc]; // in m
     859             :   Length
     860           0 :       ll((wavelength / 360.0) * getNonDispersiveH2OPhaseDelay(nc).get(Angle::UnitDegree),
     861           0 :          Length::UnitMeter);
     862           0 :   return ll;
     863             : }
     864             : 
     865           0 : Angle SkyStatus::getAverageDispersiveH2OPhaseDelay(unsigned int spwid)
     866             : {
     867           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
     868           0 :     Angle aa(-999.0, Angle::UnitDegree);
     869           0 :     return aa;
     870             :   }
     871           0 :   double av = 0.0;
     872           0 :   for(unsigned int i = 0; i < getNumChan(spwid); i++) {
     873           0 :     av = av + getDispersiveH2OPhaseDelay(v_transfertId_[spwid] + i).get(Angle::UnitDegree);
     874             :   }
     875           0 :   av = av / getNumChan(spwid);
     876           0 :   Angle average(av, Angle::UnitDegree);
     877           0 :   return average;
     878             : }
     879             : 
     880           0 : Length SkyStatus::getAverageDispersiveH2OPathLength(unsigned int spwid)
     881             : {
     882           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
     883           0 :     Length ll(0.0, Length::UnitMilliMeter);
     884           0 :     return ll;
     885             :   }
     886           0 :   double av = 0.0;
     887           0 :   for(unsigned int i = 0; i < getNumChan(spwid); i++) {
     888           0 :     av = av + getDispersiveH2OPathLength(v_transfertId_[spwid] + i).get(Length::UnitMilliMeter);
     889             :   }
     890           0 :   av = av / getNumChan(spwid);
     891           0 :   Length average(av, Length::UnitMilliMeter);
     892           0 :   return average;
     893             : }
     894             : 
     895           0 : Angle SkyStatus::getAverageNonDispersiveH2OPhaseDelay(unsigned int spwid)
     896             : {
     897           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
     898           0 :     Angle aa(0.0, Angle::UnitDegree);
     899           0 :     return aa;
     900             :   }
     901           0 :   double av = 0.0;
     902           0 :   for(unsigned int i = 0; i < getNumChan(spwid); i++) {
     903           0 :     av = av
     904           0 :         + getNonDispersiveH2OPhaseDelay(v_transfertId_[spwid] + i).get(Angle::UnitDegree);
     905             :   }
     906           0 :   av = av / getNumChan(spwid);
     907           0 :   Angle average(av, Angle::UnitDegree);
     908           0 :   return average;
     909             : }
     910             : 
     911           0 : Length SkyStatus::getAverageNonDispersiveH2OPathLength(unsigned int spwid)
     912             : {
     913           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
     914           0 :     Length ll(0.0, Length::UnitMilliMeter);
     915           0 :     return ll;
     916             :   }
     917           0 :   double av = 0.0;
     918           0 :   for(unsigned int i = 0; i < getNumChan(spwid); i++) {
     919           0 :     av = av
     920           0 :         + getNonDispersiveH2OPathLength(v_transfertId_[spwid] + i).get(Length::UnitMilliMeter);
     921             :   }
     922           0 :   av = av / getNumChan(spwid);
     923           0 :   Length average(av, Length::UnitMilliMeter);
     924           0 :   return average;
     925             : }
     926             : 
     927           0 : Temperature SkyStatus::getAverageTebbSky(unsigned int spwid,
     928             :                                          const Length &wh2o,
     929             :                                          double airmass,
     930             :                                          double skycoupling,
     931             :                                          const Temperature &Tspill)
     932             : {
     933           0 :   Temperature tt(-999, Temperature::UnitKelvin);
     934           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
     935           0 :     return tt;
     936             :   }
     937           0 :   if(wh2o.get() < 0.0) {
     938           0 :     return tt;
     939             :   }
     940             :   // if(skycoupling<0.0 || skycoupling>1.0){return tt;}
     941           0 :   if(airmass < 1.0) {
     942           0 :     return tt;
     943             :   }
     944           0 :   if(Tspill.get(Temperature::UnitKelvin) < 0.0 || Tspill.get(Temperature::UnitKelvin) > 350.0) {
     945           0 :     return tt;
     946             :   }
     947           0 :   return RT(((wh2o.get()) / (getGroundWH2O().get())),
     948             :             skycoupling,
     949             :             Tspill.get(Temperature::UnitKelvin),
     950             :             airmass,
     951           0 :             spwid);
     952             : }
     953             : 
     954           0 : Temperature SkyStatus::getAverageTebbSky(unsigned int spwid,
     955             :                                          const Length &wh2o,
     956             :                                          double airmass,
     957             :                                          double skycoupling,
     958             :                                          double signalgain,     // adition
     959             :                                          const Temperature &Tspill)
     960             : {
     961           0 :   Temperature tt(-999, Temperature::UnitKelvin);
     962           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
     963           0 :     return tt;
     964             :   }
     965           0 :   if(wh2o.get() < 0.0) {
     966           0 :     return tt;
     967             :   }
     968             :   // if(skycoupling<0.0 || skycoupling>1.0){return tt;}
     969           0 :   if(airmass < 1.0) {
     970           0 :     return tt;
     971             :   }
     972           0 :   if(Tspill.get(Temperature::UnitKelvin) < 0.0 || Tspill.get(Temperature::UnitKelvin) > 350.0) {
     973           0 :     return tt;
     974             :   }
     975           0 :   return signalgain*RT(((wh2o.get()) / (getGroundWH2O().get())),
     976             :             skycoupling,
     977             :             Tspill.get(Temperature::UnitKelvin),
     978             :             airmass,
     979             :             spwid)+
     980           0 :     +(1-signalgain)*RT(((wh2o.get()) / (getGroundWH2O().get())),
     981             :             skycoupling,
     982             :             Tspill.get(Temperature::UnitKelvin),
     983             :             airmass,
     984           0 :             getAssocSpwId(spwid)[0]);
     985             : }
     986             : 
     987      142876 : Temperature SkyStatus::getTebbSky(unsigned int spwid,
     988             :                                   unsigned int nc,
     989             :                                   const Length &wh2o,
     990             :                                   double airmass,
     991             :                                   double skycoupling,
     992             :                                   const Temperature &Tspill)
     993             : {
     994      285752 :   Temperature tt(-999, Temperature::UnitKelvin);
     995      142876 :   if(!spwidAndIndexAreValid(spwid, nc)) {
     996           0 :     return tt;
     997             :   }
     998      142876 :   if(wh2o.get() < 0.0) {
     999           0 :     return tt;
    1000             :   }
    1001      142876 :   if(skycoupling < 0.0 || skycoupling > 1.0) {
    1002           0 :     return tt;
    1003             :   }
    1004      142876 :   if(airmass < 1.0) {
    1005           0 :     return tt;
    1006             :   }
    1007      142876 :   if(Tspill.get(Temperature::UnitKelvin) < 0.0 || Tspill.get(Temperature::UnitKelvin) > 350.0) {
    1008           0 :     return tt;
    1009             :   }
    1010      285752 :   return RT(((wh2o.get()) / (getGroundWH2O().get())),
    1011             :             skycoupling,
    1012             :             Tspill.get(Temperature::UnitKelvin),
    1013             :             airmass,
    1014             :             spwid,
    1015      285752 :             nc);
    1016             : }
    1017             : 
    1018             : 
    1019           0 : Temperature SkyStatus::getAverageTrjSky(unsigned int spwid,
    1020             :                                          const Length &wh2o,
    1021             :                                          double airmass,
    1022             :                                          double skycoupling,
    1023             :                                          const Temperature &Tspill)
    1024             : {
    1025           0 :   Temperature tt(-999, Temperature::UnitKelvin);
    1026           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
    1027           0 :     return tt;
    1028             :   }
    1029           0 :   if(wh2o.get() < 0.0) {
    1030           0 :     return tt;
    1031             :   }
    1032             :   // if(skycoupling<0.0 || skycoupling>1.0){return tt;}
    1033           0 :   if(airmass < 1.0) {
    1034           0 :     return tt;
    1035             :   }
    1036           0 :   if(Tspill.get(Temperature::UnitKelvin) < 0.0 || Tspill.get(Temperature::UnitKelvin) > 350.0) {
    1037           0 :     return tt;
    1038             :   }
    1039           0 :   return RTRJ(((wh2o.get()) / (getGroundWH2O().get())),
    1040             :             skycoupling,
    1041             :             Tspill.get(Temperature::UnitKelvin),
    1042             :             airmass,
    1043           0 :             spwid);
    1044             : }
    1045             : 
    1046           0 : Temperature SkyStatus::getAverageTrjSky(unsigned int spwid,
    1047             :                                          const Length &wh2o,
    1048             :                                          double airmass,
    1049             :                                          double skycoupling,
    1050             :                                          double signalgain,     // adition
    1051             :                                          const Temperature &Tspill)
    1052             : {
    1053           0 :   Temperature tt(-999, Temperature::UnitKelvin);
    1054           0 :   if(!spwidAndIndexAreValid(spwid, 0)) {
    1055           0 :     return tt;
    1056             :   }
    1057           0 :   if(wh2o.get() < 0.0) {
    1058           0 :     return tt;
    1059             :   }
    1060             :   // if(skycoupling<0.0 || skycoupling>1.0){return tt;}
    1061           0 :   if(airmass < 1.0) {
    1062           0 :     return tt;
    1063             :   }
    1064           0 :   if(Tspill.get(Temperature::UnitKelvin) < 0.0 || Tspill.get(Temperature::UnitKelvin) > 350.0) {
    1065           0 :     return tt;
    1066             :   }
    1067           0 :   return signalgain*RTRJ(((wh2o.get()) / (getGroundWH2O().get())),
    1068             :             skycoupling,
    1069             :             Tspill.get(Temperature::UnitKelvin),
    1070             :             airmass,
    1071             :             spwid)+
    1072           0 :     +(1-signalgain)*RTRJ(((wh2o.get()) / (getGroundWH2O().get())),
    1073             :             skycoupling,
    1074             :             Tspill.get(Temperature::UnitKelvin),
    1075             :             airmass,
    1076           0 :             getAssocSpwId(spwid)[0]);
    1077             : }
    1078             : 
    1079    15124480 : Temperature SkyStatus::getTrjSky(unsigned int spwid,
    1080             :                                   unsigned int nc,
    1081             :                                   const Length &wh2o,
    1082             :                                   double airmass,
    1083             :                                   double skycoupling,
    1084             :                                   const Temperature &Tspill)
    1085             : {
    1086    30248960 :   Temperature tt(-999, Temperature::UnitKelvin);
    1087    15124480 :   if(!spwidAndIndexAreValid(spwid, nc)) {
    1088           0 :     return tt;
    1089             :   }
    1090    15124480 :   if(wh2o.get() < 0.0) {
    1091           0 :     return tt;
    1092             :   }
    1093    15124480 :   if(skycoupling < 0.0 || skycoupling > 1.0) {
    1094           0 :     return tt;
    1095             :   }
    1096    15124480 :   if(airmass < 1.0) {
    1097           0 :     return tt;
    1098             :   }
    1099    15124480 :   if(Tspill.get(Temperature::UnitKelvin) < 0.0 || Tspill.get(Temperature::UnitKelvin) > 350.0) {
    1100           0 :     return tt;
    1101             :   }
    1102    30248960 :   return RTRJ(((wh2o.get()) / (getGroundWH2O().get())),
    1103             :             skycoupling,
    1104             :             Tspill.get(Temperature::UnitKelvin),
    1105             :             airmass,
    1106             :             spwid,
    1107    30248960 :             nc);
    1108             : }
    1109             : 
    1110             : 
    1111             : 
    1112           0 : Angle SkyStatus::getDispersiveH2OPhaseDelay(unsigned int spwid, unsigned int nc)
    1113             : {
    1114           0 :   if(!spwidAndIndexAreValid(spwid, nc)) {
    1115           0 :     Angle aa(0.0, Angle::UnitDegree);
    1116           0 :     return aa;
    1117             :   }
    1118           0 :   return getDispersiveH2OPhaseDelay(v_transfertId_[spwid] + nc);
    1119             : }
    1120             : 
    1121           0 : Length SkyStatus::getDispersiveH2OPathLength(unsigned int spwid,
    1122             :                                              unsigned int nc)
    1123             : {
    1124           0 :   if(!spwidAndIndexAreValid(spwid, nc)) {
    1125           0 :     Length ll(0.0, Length::UnitMilliMeter);
    1126           0 :     return ll;
    1127             :   }
    1128           0 :   return getDispersiveH2OPathLength(v_transfertId_[spwid] + nc);
    1129             : }
    1130             : 
    1131           0 : Angle SkyStatus::getNonDispersiveH2OPhaseDelay(unsigned int spwid,
    1132             :                                                unsigned int nc)
    1133             : {
    1134           0 :   if(!spwidAndIndexAreValid(spwid, nc)) {
    1135           0 :     Angle aa(0.0, Angle::UnitDegree);
    1136           0 :     return aa;
    1137             :   }
    1138           0 :   return getNonDispersiveH2OPhaseDelay(v_transfertId_[spwid] + nc);
    1139             : }
    1140             : 
    1141           0 : Length SkyStatus::getNonDispersiveH2OPathLength(unsigned int spwid,
    1142             :                                                 unsigned int nc)
    1143             : {
    1144           0 :   if(!spwidAndIndexAreValid(spwid, nc)) return (double) 0.0;
    1145           0 :   return getNonDispersiveH2OPathLength(v_transfertId_[spwid] + nc);
    1146             : }
    1147             : 
    1148           0 : Length SkyStatus::WaterVaporRetrieval_fromFTS(unsigned int spwId,
    1149             :                                               const vector<double> &v_transmission,
    1150             :                                               const Frequency &f1,
    1151             :                                               const Frequency &f2)
    1152             : {
    1153           0 :   if(f1.get() > f2.get()) {
    1154           0 :     return Length(-999, Length::UnitMilliMeter);
    1155             :   }
    1156           0 :   if(v_transmission.size() == getSpectralWindow(spwId).size()) {
    1157             :     return mkWaterVaporRetrieval_fromFTS(spwId,
    1158             :                                          v_transmission,
    1159             :                                          // getAirMass(),    // unused parameter
    1160             :                                          f1,
    1161           0 :                                          f2);
    1162             :   } else {
    1163           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1164             :   }
    1165             : }
    1166             : 
    1167           0 :   Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1168             :                                                  const vector<Temperature> &v_tebb,
    1169             :                                                  const vector<double> &skycoupling,
    1170             :                                                  const vector<Temperature> &tspill)
    1171             :   {
    1172           0 :     vector<vector<double> > spwId_filters;
    1173           0 :     vector<double> spwId_filter;
    1174           0 :     for(unsigned int i = 0; i < spwId.size(); i++) {
    1175           0 :       for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1176           0 :         spwId_filter.push_back(1.0);
    1177             :       }
    1178           0 :       spwId_filters.push_back(spwId_filter);
    1179           0 :       spwId_filter.clear();
    1180             :     }
    1181             :     return WaterVaporRetrieval_fromTEBB(spwId,
    1182             :                                         v_tebb,
    1183             :                                         spwId_filters,
    1184             :                                         skycoupling,
    1185           0 :                                         tspill);
    1186             :   }
    1187             : 
    1188           0 :   Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1189             :                                                  const vector<Temperature> &v_tebb,
    1190             :                                                  double skycoupling,
    1191             :                                                  const Temperature &tspill)
    1192             :   {
    1193           0 :     vector<double> spwId_filter;
    1194           0 :     for(unsigned int n = 0; n < v_numChan_[spwId]; n++) {
    1195           0 :       spwId_filter.push_back(1.0);
    1196             :     }
    1197             :     return WaterVaporRetrieval_fromTEBB(spwId,
    1198             :                                         v_tebb,
    1199             :                                         spwId_filter,
    1200             :                                         skycoupling,
    1201           0 :                                         tspill);
    1202             :   }
    1203             : 
    1204             : 
    1205           0 :   Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1206             :                                                  const vector< vector<Temperature> > &vv_tebb,
    1207             :                                                  const vector<double> &skycoupling,
    1208             :                                                  const vector<Temperature> &tspill)
    1209             :   {
    1210           0 :     vector<vector<double> > spwId_filters;
    1211           0 :     vector<double> spwId_filter;
    1212           0 :     for(unsigned int i = 0; i < spwId.size(); i++) {
    1213           0 :       for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1214           0 :         spwId_filter.push_back(1.0);
    1215             :       }
    1216           0 :       spwId_filters.push_back(spwId_filter);
    1217           0 :       spwId_filter.clear();
    1218             :     }
    1219             :     return WaterVaporRetrieval_fromTEBB(spwId,
    1220             :                                         vv_tebb,
    1221             :                                         spwId_filters,
    1222             :                                         skycoupling,
    1223           0 :                                         tspill);
    1224             :   }
    1225             : 
    1226           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1227             :                                                const Percent &signalGain,
    1228             :                                                const vector<Temperature> &v_tebb,
    1229             :                                                double skycoupling,
    1230             :                                                const Temperature &tspill)
    1231             : {
    1232           0 :   vector<double> spwId_filter;
    1233           0 :   for(unsigned int n = 0; n < v_numChan_[spwId]; n++) {
    1234           0 :     spwId_filter.push_back(1.0);
    1235             :   }
    1236             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1237             :                                       signalGain,
    1238             :                                       v_tebb,
    1239             :                                       spwId_filter,
    1240             :                                       skycoupling,
    1241           0 :                                       tspill);
    1242             : }
    1243           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1244             :                                                const vector<Percent> &signalGain,
    1245             :                                                const vector<vector<Temperature> > &vv_tebb,
    1246             :                                                const vector<double> &skycoupling,
    1247             :                                                const vector<Temperature> &tspill)
    1248             : {
    1249           0 :   vector<vector<double> > spwId_filters;
    1250           0 :   vector<double> spwId_filter;
    1251           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1252           0 :     for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1253           0 :       spwId_filter.push_back(1.0);
    1254             :     }
    1255           0 :     spwId_filters.push_back(spwId_filter);
    1256           0 :     spwId_filter.clear();
    1257             :   }
    1258             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1259             :                                       signalGain,
    1260             :                                       vv_tebb,
    1261             :                                       spwId_filters,
    1262             :                                       skycoupling,
    1263           0 :                                       tspill);
    1264             : }
    1265           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1266             :                                                const vector<Percent> &signalGain,
    1267             :                                                const vector<Temperature> &v_tebb,
    1268             :                                                const vector<double> &skycoupling,
    1269             :                                                const vector<Temperature> &tspill)
    1270             : {
    1271           0 :   vector<vector<double> > spwId_filters;
    1272           0 :   vector<double> spwId_filter;
    1273           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1274           0 :     for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1275           0 :       spwId_filter.push_back(1.0);
    1276             :     }
    1277           0 :     spwId_filters.push_back(spwId_filter);
    1278           0 :     spwId_filter.clear();
    1279             :   }
    1280             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1281             :                                       signalGain,
    1282             :                                       v_tebb,
    1283             :                                       spwId_filters,
    1284             :                                       skycoupling,
    1285           0 :                                       tspill);
    1286             : }
    1287             : 
    1288           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1289             :                                                const vector<Temperature> &v_tebb,
    1290             :                                                const vector<double> &spwId_filter,
    1291             :                                                double skycoupling,
    1292             :                                                const Temperature &tspill)
    1293             : {
    1294           0 :   if(v_tebb.size() == getSpectralWindow(spwId).size()) {
    1295             :     return mkWaterVaporRetrieval_fromTEBB(spwId,
    1296           0 :                                           Percent(100.0, Percent::UnitPercent),
    1297             :                                           v_tebb,
    1298             :                                           getAirMass(),
    1299             :                                           spwId_filter,
    1300             :                                           skycoupling,
    1301           0 :                                           tspill);
    1302             :   } else {
    1303           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1304             :   }
    1305             : }
    1306           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1307             :                                                const vector<vector<Temperature> > &vv_tebb,
    1308             :                                                const vector<vector<double> > &spwId_filters,
    1309             :                                                const vector<double> &skycoupling,
    1310             :                                                const vector<Temperature> &tspill)
    1311             : {
    1312           0 :   vector<Percent> signalGain;
    1313           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1314           0 :     signalGain.push_back(Percent(100.0, Percent::UnitPercent));
    1315             :   }
    1316             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1317             :                                         signalGain,
    1318             :                                         vv_tebb,
    1319             :                                         getAirMass(),
    1320             :                                         spwId_filters,
    1321             :                                         skycoupling,
    1322           0 :                                         tspill);
    1323             : }
    1324           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1325             :                                                const vector<Temperature> &v_tebb,
    1326             :                                                const vector<vector<double> > &spwId_filters,
    1327             :                                                const vector<double> &skycoupling,
    1328             :                                                const vector<Temperature> &tspill)
    1329             : {
    1330           0 :   vector<Percent> signalGain;
    1331           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1332           0 :     signalGain.push_back(Percent(100.0, Percent::UnitPercent));
    1333             :   }
    1334             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1335             :                                         signalGain,
    1336             :                                         v_tebb,
    1337             :                                         getAirMass(),
    1338             :                                         spwId_filters,
    1339             :                                         skycoupling,
    1340           0 :                                         tspill);
    1341             : }
    1342             : 
    1343           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1344             :                                                const Percent &signalGain,
    1345             :                                                const vector<Temperature> &v_tebb,
    1346             :                                                const vector<double> &spwId_filter,
    1347             :                                                double skycoupling,
    1348             :                                                const Temperature &tspill)
    1349             : {
    1350           0 :   if(v_tebb.size() == getSpectralWindow(spwId).size()) {
    1351             :     return mkWaterVaporRetrieval_fromTEBB(spwId,
    1352             :                                           signalGain,
    1353             :                                           v_tebb,
    1354             :                                           getAirMass(),
    1355             :                                           spwId_filter,
    1356             :                                           skycoupling,
    1357           0 :                                           tspill);
    1358             :   } else {
    1359           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1360             :   }
    1361             : }
    1362           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1363             :                                                const vector<Percent> &signalGain,
    1364             :                                                const vector<vector<Temperature> > &vv_tebb,
    1365             :                                                const vector<vector<double> > &spwId_filters,
    1366             :                                                const vector<double> &skycoupling,
    1367             :                                                const vector<Temperature> &tspill)
    1368             : {
    1369             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1370             :                                         signalGain,
    1371             :                                         vv_tebb,
    1372             :                                         getAirMass(),
    1373             :                                         spwId_filters,
    1374             :                                         skycoupling,
    1375           0 :                                         tspill);
    1376             : }
    1377           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1378             :                                                const vector<Percent> &signalGain,
    1379             :                                                const vector<Temperature> &v_tebb,
    1380             :                                                const vector<vector<double> > &spwId_filters,
    1381             :                                                const vector<double> &skycoupling,
    1382             :                                                const vector<Temperature> &tspill)
    1383             : {
    1384             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1385             :                                         signalGain,
    1386             :                                         v_tebb,
    1387             :                                         getAirMass(),
    1388             :                                         spwId_filters,
    1389             :                                         skycoupling,
    1390           0 :                                         tspill);
    1391             : }
    1392             : 
    1393           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1394             :                                                const vector<Temperature> &v_tebb,
    1395             :                                                double airmass,
    1396             :                                                double skycoupling,
    1397             :                                                const Temperature &tspill)
    1398             : {
    1399           0 :   vector<double> spwId_filter;
    1400           0 :   for(unsigned int n = 0; n < v_numChan_[spwId]; n++) {
    1401           0 :     spwId_filter.push_back(1.0);
    1402             :   }
    1403             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1404             :                                       v_tebb,
    1405             :                                       spwId_filter,
    1406             :                                       airmass,
    1407             :                                       skycoupling,
    1408           0 :                                       tspill);
    1409             : }
    1410           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1411             :                                                const vector<vector<Temperature> > &vv_tebb,
    1412             :                                                double airmass,
    1413             :                                                const vector<double> &skycoupling,
    1414             :                                                const vector<Temperature> &tspill)
    1415             : {
    1416           0 :   vector<vector<double> > spwId_filters;
    1417           0 :   vector<double> spwId_filter;
    1418           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1419           0 :     for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1420           0 :       spwId_filter.push_back(1.0);
    1421             :     }
    1422           0 :     spwId_filters.push_back(spwId_filter);
    1423           0 :     spwId_filter.clear();
    1424             :   }
    1425             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1426             :                                       vv_tebb,
    1427             :                                       spwId_filters,
    1428             :                                       airmass,
    1429             :                                       skycoupling,
    1430           0 :                                       tspill);
    1431             : }
    1432           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1433             :                                                const vector<Temperature> &v_tebb,
    1434             :                                                double airmass,
    1435             :                                                const vector<double> &skycoupling,
    1436             :                                                const vector<Temperature> &tspill)
    1437             : {
    1438           0 :   vector<vector<double> > spwId_filters;
    1439           0 :   vector<double> spwId_filter;
    1440           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1441           0 :     for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1442           0 :       spwId_filter.push_back(1.0);
    1443             :     }
    1444           0 :     spwId_filters.push_back(spwId_filter);
    1445           0 :     spwId_filter.clear();
    1446             :   }
    1447             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1448             :                                       v_tebb,
    1449             :                                       spwId_filters,
    1450             :                                       airmass,
    1451             :                                       skycoupling,
    1452           0 :                                       tspill);
    1453             : }
    1454             : 
    1455           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1456             :                                                const Percent &signalGain,
    1457             :                                                const vector<Temperature> &v_tebb,
    1458             :                                                double airmass,
    1459             :                                                double skycoupling,
    1460             :                                                const Temperature &tspill)
    1461             : {
    1462           0 :   vector<double> spwId_filter;
    1463           0 :   for(unsigned int n = 0; n < v_numChan_[spwId]; n++) {
    1464           0 :     spwId_filter.push_back(1.0);
    1465             :   }
    1466             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1467             :                                       signalGain,
    1468             :                                       v_tebb,
    1469             :                                       spwId_filter,
    1470             :                                       airmass,
    1471             :                                       skycoupling,
    1472           0 :                                       tspill);
    1473             : }
    1474           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1475             :                                                const vector<Percent> &signalGain,
    1476             :                                                const vector<vector<Temperature> > &vv_tebb,
    1477             :                                                double airmass,
    1478             :                                                const vector<double> &skycoupling,
    1479             :                                                const vector<Temperature> &tspill)
    1480             : {
    1481           0 :   vector<vector<double> > spwId_filters;
    1482           0 :   vector<double> spwId_filter;
    1483           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1484           0 :     for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1485           0 :       spwId_filter.push_back(1.0);
    1486             :     }
    1487           0 :     spwId_filters.push_back(spwId_filter);
    1488           0 :     spwId_filter.clear();
    1489             :   }
    1490             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1491             :                                       signalGain,
    1492             :                                       vv_tebb,
    1493             :                                       spwId_filters,
    1494             :                                       airmass,
    1495             :                                       skycoupling,
    1496           0 :                                       tspill);
    1497             : }
    1498             : 
    1499           0 :   Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1500             :                                                  const Percent &signalGain,
    1501             :                                                  const Temperature &tebb,
    1502             :                                                  double airmass,
    1503             :                                                  double skycoupling,
    1504             :                                                  const Temperature &tspill)
    1505             :   {
    1506           0 :     vector<unsigned int> spwIdv;
    1507           0 :     vector<Percent> signalGainv;
    1508           0 :     vector<Temperature> tebbv;
    1509           0 :     vector<double> skycouplingv;
    1510           0 :     vector<Temperature> tspillv;
    1511           0 :     spwIdv.push_back(spwId);
    1512           0 :     signalGainv.push_back(signalGain);
    1513           0 :     tebbv.push_back(tebb);
    1514           0 :     skycouplingv.push_back(skycoupling);
    1515           0 :     tspillv.push_back(tspill);
    1516           0 :     return WaterVaporRetrieval_fromTEBB(spwIdv,signalGainv,tebbv,airmass,skycouplingv,tspillv);
    1517             :   }
    1518             : 
    1519             : 
    1520             : 
    1521           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1522             :                                                const vector<Percent> &signalGain,
    1523             :                                                const vector<Temperature> &v_tebb,
    1524             :                                                double airmass,
    1525             :                                                const vector<double> &skycoupling,
    1526             :                                                const vector<Temperature> &tspill)
    1527             : {
    1528           0 :   vector<vector<double> > spwId_filters;
    1529           0 :   vector<double> spwId_filter;
    1530           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1531           0 :     for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1532           0 :       spwId_filter.push_back(1.0);
    1533             :     }
    1534           0 :     spwId_filters.push_back(spwId_filter);
    1535           0 :     spwId_filter.clear();
    1536             :   }
    1537             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1538             :                                       signalGain,
    1539             :                                       v_tebb,
    1540             :                                       spwId_filters,
    1541             :                                       airmass,
    1542             :                                       skycoupling,
    1543           0 :                                       tspill);
    1544             : }
    1545             : 
    1546           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1547             :                                                const vector<Temperature> &v_tebb,
    1548             :                                                const vector<double> &spwId_filter,
    1549             :                                                double airmass,
    1550             :                                                double skycoupling,
    1551             :                                                const Temperature &tspill)
    1552             : {
    1553           0 :   if(v_tebb.size() == getSpectralWindow(spwId).size()) {
    1554             :     return mkWaterVaporRetrieval_fromTEBB(spwId,
    1555           0 :                                           Percent(100.0, Percent::UnitPercent),
    1556             :                                           v_tebb,
    1557             :                                           airmass,
    1558             :                                           spwId_filter,
    1559             :                                           skycoupling,
    1560           0 :                                           tspill);
    1561             :   } else {
    1562           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1563             :   }
    1564             : }
    1565           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1566             :                                                const vector<vector<Temperature> > &vv_tebb,
    1567             :                                                const vector<vector<double> > &spwId_filters,
    1568             :                                                double airmass,
    1569             :                                                const vector<double> &skycoupling,
    1570             :                                                const vector<Temperature> &tspill)
    1571             : {
    1572           0 :   for(unsigned int j = 0; j < spwId.size(); j++) {
    1573           0 :     if(vv_tebb[j].size() != getSpectralWindow(spwId[j]).size()) {
    1574           0 :       return Length(-999.0, Length::UnitMilliMeter);
    1575             :     }
    1576             :   }
    1577           0 :   vector<Percent> signalGain;
    1578           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1579           0 :     signalGain.push_back(Percent(100.0, Percent::UnitPercent));
    1580             :   }
    1581             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1582             :                                         signalGain,
    1583             :                                         vv_tebb,
    1584             :                                         airmass,
    1585             :                                         spwId_filters,
    1586             :                                         skycoupling,
    1587           0 :                                         tspill);
    1588             : }
    1589           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1590             :                                                const vector<Temperature> &v_tebb,
    1591             :                                                const vector<vector<double> > &spwId_filters,
    1592             :                                                double airmass,
    1593             :                                                const vector<double> &skycoupling,
    1594             :                                                const vector<Temperature> &tspill)
    1595             : {
    1596           0 :   vector<Percent> signalGain;
    1597           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1598           0 :     signalGain.push_back(Percent(100.0, Percent::UnitPercent));
    1599             :   }
    1600             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1601             :                                         signalGain,
    1602             :                                         v_tebb,
    1603             :                                         airmass,
    1604             :                                         spwId_filters,
    1605             :                                         skycoupling,
    1606           0 :                                         tspill);
    1607             : }
    1608             : 
    1609           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(unsigned int spwId,
    1610             :                                                const Percent &signalGain,
    1611             :                                                const vector<Temperature> &v_tebb,
    1612             :                                                const vector<double> &spwId_filter,
    1613             :                                                double airmass,
    1614             :                                                double skycoupling,
    1615             :                                                const Temperature &tspill)
    1616             : {
    1617           0 :   if(v_tebb.size() == getSpectralWindow(spwId).size()) {
    1618             :     return mkWaterVaporRetrieval_fromTEBB(spwId,
    1619             :                                           signalGain,
    1620             :                                           v_tebb,
    1621             :                                           airmass,
    1622             :                                           spwId_filter,
    1623             :                                           skycoupling,
    1624           0 :                                           tspill);
    1625             :   } else {
    1626           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1627             :   }
    1628             : }
    1629             : 
    1630           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1631             :                                                const vector<Percent> &signalGain,
    1632             :                                                const vector<vector<Temperature> > &vv_tebb,
    1633             :                                                const vector<vector<double> > &spwId_filter,
    1634             :                                                double airmass,
    1635             :                                                const vector<double> &skycoupling,
    1636             :                                                const vector<Temperature> &tspill)
    1637             : {
    1638             : 
    1639           0 :   if(spwId.size() != signalGain.size()) {
    1640           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1641             :   }
    1642           0 :   for(unsigned int j = 0; j < spwId.size(); j++) {
    1643           0 :     if(vv_tebb[j].size() != getSpectralWindow(spwId[j]).size()) {
    1644           0 :       return Length(-999.0, Length::UnitMilliMeter);
    1645             :     }
    1646             :   }
    1647           0 :   if(spwId.size() != spwId_filter.size()) {
    1648           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1649             :   }
    1650           0 :   if(spwId.size() != skycoupling.size()) {
    1651           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1652             :   }
    1653           0 :   if(spwId.size() != tspill.size()) {
    1654           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1655             :   }
    1656             : 
    1657             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1658             :                                         signalGain,
    1659             :                                         vv_tebb,
    1660             :                                         airmass,
    1661             :                                         spwId_filter,
    1662             :                                         skycoupling,
    1663           0 :                                         tspill);
    1664             : }
    1665             : 
    1666           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1667             :                                                const vector<Percent> &signalGain,
    1668             :                                                const vector<Temperature> &v_tebb,
    1669             :                                                const vector<vector<double> > &spwId_filter,
    1670             :                                                double airmass,
    1671             :                                                const vector<double> &skycoupling,
    1672             :                                                const vector<Temperature> &tspill)
    1673             : {
    1674           0 :   if(spwId.size() != signalGain.size()) {
    1675           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1676             :   }
    1677           0 :   if(spwId.size() != v_tebb.size()) {
    1678           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1679             :   }
    1680           0 :   if(spwId.size() != spwId_filter.size()) {
    1681           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1682             :   }
    1683           0 :   if(spwId.size() != skycoupling.size()) {
    1684           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1685             :   }
    1686           0 :   if(spwId.size() != tspill.size()) {
    1687           0 :     return Length(-999.0, Length::UnitMilliMeter);
    1688             :   }
    1689             : 
    1690             :   return mkWaterVaporRetrieval_fromTEBB(spwId,
    1691             :                                         signalGain,
    1692             :                                         v_tebb,
    1693             :                                         airmass,
    1694             :                                         spwId_filter,
    1695             :                                         skycoupling,
    1696           0 :                                         tspill);
    1697             : }
    1698             : 
    1699           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1700             :                                                const Percent &signalGain,
    1701             :                                                const vector<Temperature> &v_tebb,
    1702             :                                                const vector<vector<double> > &spwId_filters,
    1703             :                                                double airmass,
    1704             :                                                double skycoupling,
    1705             :                                                const Temperature &tspill)
    1706             : {
    1707           0 :   vector<Percent> v_signalGain;
    1708           0 :   vector<double> v_skycoupling;
    1709           0 :   vector<Temperature> v_tspill;
    1710           0 :   v_signalGain.reserve(spwId.size());
    1711           0 :   v_skycoupling.reserve(spwId.size());
    1712           0 :   v_tspill.reserve(spwId.size());
    1713             : 
    1714           0 :   for(unsigned int j = 0; j < spwId.size(); j++) {
    1715           0 :     v_signalGain.push_back(signalGain);
    1716           0 :     v_skycoupling.push_back(skycoupling);
    1717           0 :     v_tspill.push_back(tspill);
    1718             :   }
    1719             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1720             :                                       v_signalGain,
    1721             :                                       v_tebb,
    1722             :                                       spwId_filters,
    1723             :                                       airmass,
    1724             :                                       v_skycoupling,
    1725           0 :                                       v_tspill);
    1726             : }
    1727           0 : Length SkyStatus::WaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    1728             :                                                const Percent &signalGain,
    1729             :                                                const vector<Temperature> &v_tebb,
    1730             :                                                double airmass,
    1731             :                                                double skycoupling,
    1732             :                                                const Temperature &tspill)
    1733             : {
    1734           0 :   vector<vector<double> > spwId_filters;
    1735           0 :   vector<double> spwId_filter;
    1736           0 :   for(unsigned int i = 0; i < spwId.size(); i++) {
    1737           0 :     for(unsigned int n = 0; n < v_numChan_[spwId[i]]; n++) {
    1738           0 :       spwId_filter.push_back(1.0);
    1739             :     }
    1740           0 :     spwId_filters.push_back(spwId_filter);
    1741           0 :     spwId_filter.clear();
    1742             :   }
    1743             :   return WaterVaporRetrieval_fromTEBB(spwId,
    1744             :                                       signalGain,
    1745             :                                       v_tebb,
    1746             :                                       spwId_filters,
    1747             :                                       airmass,
    1748             :                                       skycoupling,
    1749           0 :                                       tspill);
    1750             : }
    1751             : 
    1752           0 : double SkyStatus::SkyCouplingRetrieval_fromTEBB(unsigned int spwId,
    1753             :                                                 const vector<Temperature> &v_tebb,
    1754             :                                                 double skycoupling,
    1755             :                                                 const Temperature &tspill)
    1756             : {
    1757           0 :   vector<double> spwId_filter;
    1758           0 :   for(unsigned int n = 0; n < v_numChan_[spwId]; n++) {
    1759           0 :     spwId_filter.push_back(1.0);
    1760             :   }
    1761           0 :   return SkyCouplingRetrieval_fromTEBB(spwId,
    1762             :                                        v_tebb,
    1763             :                                        spwId_filter,
    1764             :                                        skycoupling,
    1765           0 :                                        tspill);
    1766             : }
    1767             : 
    1768           0 : double SkyStatus::SkyCouplingRetrieval_fromTEBB(unsigned int spwId,
    1769             :                                                 const vector<Temperature> &v_tebb,
    1770             :                                                 const vector<double> &spwId_filter,
    1771             :                                                 double skycoupling,
    1772             :                                                 const Temperature &tspill)
    1773             : {
    1774           0 :   if(v_tebb.size() == getSpectralWindow(spwId).size()) {
    1775           0 :     return mkSkyCouplingRetrieval_fromTEBB(spwId,
    1776           0 :                                            Percent(100, Percent::UnitPercent),
    1777             :                                            v_tebb,
    1778             :                                            getAirMass(),
    1779             :                                            spwId_filter,
    1780             :                                            skycoupling,
    1781           0 :                                            tspill);
    1782             :   } else {
    1783           0 :     return -999.0;
    1784             :   }
    1785             : }
    1786             : 
    1787           0 : double SkyStatus::SkyCouplingRetrieval_fromTEBB(unsigned int spwId,
    1788             :                                                 const vector<Temperature> &v_tebb,
    1789             :                                                 double airmass,
    1790             :                                                 double skycoupling,
    1791             :                                                 const Temperature &tspill)
    1792             : {
    1793           0 :   vector<double> spwId_filter;
    1794           0 :   for(unsigned int n = 0; n < v_numChan_[spwId]; n++) {
    1795           0 :     spwId_filter.push_back(1.0);
    1796             :   }
    1797           0 :   return SkyCouplingRetrieval_fromTEBB(spwId,
    1798             :                                        v_tebb,
    1799             :                                        spwId_filter,
    1800             :                                        airmass,
    1801             :                                        skycoupling,
    1802           0 :                                        tspill);
    1803             : }
    1804             : 
    1805           0 : double SkyStatus::SkyCouplingRetrieval_fromTEBB(unsigned int spwId,
    1806             :                                                 const vector<Temperature> &v_tebb,
    1807             :                                                 const vector<double> &spwId_filter,
    1808             :                                                 double airmass,
    1809             :                                                 double skycoupling,
    1810             :                                                 const Temperature &tspill)
    1811             : {
    1812           0 :   if(v_tebb.size() == getSpectralWindow(spwId).size()) {
    1813           0 :     return mkSkyCouplingRetrieval_fromTEBB(spwId,
    1814           0 :                                            Percent(100, Percent::UnitPercent),
    1815             :                                            v_tebb,
    1816             :                                            airmass,
    1817             :                                            spwId_filter,
    1818             :                                            skycoupling,
    1819           0 :                                            tspill);
    1820             :   } else {
    1821           0 :     return -999.0;
    1822             :   }
    1823             : }
    1824             : 
    1825           0 : double SkyStatus::getSigmaTransmissionFit(unsigned int spwId,
    1826             :                                           const vector<double> &v_transmission,
    1827             :                                           double airm,
    1828             :                                           const Frequency &f1,
    1829             :                                           const Frequency &f2)
    1830             : {
    1831           0 :   if(f1.get() > f2.get()) {
    1832           0 :     return -999.0;
    1833             :   }
    1834           0 :   if(v_transmission.size() == getSpectralWindow(spwId).size()) {
    1835           0 :     double rms = 0.0;
    1836           0 :     unsigned int num = 0;
    1837             : 
    1838           0 :     for(unsigned int i = 0; i < v_transmission.size(); i++) {
    1839           0 :       if((getSpectralWindow(spwId)[i] * 1E-09 >= f1.get(Frequency::UnitGigaHertz)
    1840           0 :           && getSpectralWindow(spwId)[i] * 1E-09 <= f2.get(Frequency::UnitGigaHertz))) {
    1841           0 :         num++;
    1842           0 :         rms = rms + pow((v_transmission[i] - exp(-airm
    1843           0 :                                                  * ( (getDryContOpacity(spwId, i).get()+getO2LinesOpacity(spwId, i).get()+0.65*getO3LinesOpacity(spwId, i).get()  )  // getDryOpacity(spwId, i).get()
    1844           0 :                                 + getWetOpacity(spwId, i).get()))),
    1845             :                         2);
    1846             :       }
    1847             :     }
    1848           0 :     rms = sqrt(rms / num);
    1849           0 :     return rms;
    1850             :   } else {
    1851           0 :     return -999.0;
    1852             :   }
    1853             : }
    1854             : 
    1855           0 : Temperature SkyStatus::getSigmaFit(unsigned int spwId,
    1856             :                                    const vector<Temperature> &v_tebbspec,
    1857             :                                    const Length &wh2o,
    1858             :                                    double airmass,
    1859             :                                    double skyCoupling,
    1860             :                                    const Temperature &Tspill)
    1861             : {
    1862           0 :   Temperature ttt(-999, Temperature::UnitKelvin);
    1863           0 :   if(!spwidAndIndexAreValid(spwId, 0)) {
    1864           0 :     return ttt;
    1865             :   }
    1866           0 :   if(v_tebbspec.size() != getSpectralWindow(spwId).size()) {
    1867           0 :     return ttt;
    1868             :   }
    1869           0 :   if(wh2o.get(Length::UnitMilliMeter) < 0.0) {
    1870           0 :     return ttt;
    1871             :   }
    1872           0 :   if(skyCoupling < 0.0 || skyCoupling > 1.0) {
    1873           0 :     return ttt;
    1874             :   }
    1875           0 :   if(airmass < 1.0) {
    1876           0 :     return ttt;
    1877             :   }
    1878           0 :   if(Tspill.get(Temperature::UnitKelvin) < 0.0 || Tspill.get(Temperature::UnitKelvin) > 350.0) {
    1879           0 :     return ttt;
    1880             :   }
    1881           0 :   double rms = 0.0;
    1882           0 :   unsigned int num = 0;
    1883           0 :   for(unsigned int i = 0; i < v_tebbspec.size(); i++) {
    1884           0 :     if(v_tebbspec[i].get() > 0.0) {
    1885           0 :       num++;
    1886           0 :       rms = rms + pow((v_tebbspec[i].get(Temperature::UnitKelvin) - getTebbSky(spwId,
    1887             :                                                            i,
    1888             :                                                            wh2o,
    1889             :                                                            airmass,
    1890             :                                                            skyCoupling,
    1891           0 :                                                            Tspill).get(Temperature::UnitKelvin)),
    1892             :                       2);
    1893             :     }
    1894             :   }
    1895           0 :   rms = sqrt(rms / num);
    1896           0 :   return Temperature(rms, Temperature::UnitKelvin);
    1897             : }
    1898             : 
    1899           0 : Length SkyStatus::mkWaterVaporRetrieval_fromFTS(unsigned int spwId,
    1900             :                                                 const vector<double> &measuredSkyTransmission,
    1901             :                                                 //double airm,   // unused parameter
    1902             :                                                 const Frequency &fre1,
    1903             :                                                 const Frequency &fre2)
    1904             : {
    1905             :   double pfit_wh2o;
    1906           0 :   double deltaa = 0.02;
    1907           0 :   double sig_fit = -999.0;
    1908           0 :   double eps = 0.01;
    1909           0 :   vector<double> transmission_fit;
    1910           0 :   transmission_fit.reserve(measuredSkyTransmission.size()); // allows resizing
    1911             : 
    1912             :   unsigned int num;
    1913             :   double flamda;
    1914           0 :   unsigned int niter = 20;
    1915             :   double alpha;
    1916             :   double beta;
    1917             :   double array;
    1918             :   double f1;
    1919             :   double psave;
    1920             :   double f2;
    1921             :   double deriv;
    1922             :   double chisq1;
    1923             :   double chisqr;
    1924             :   double pfit_wh2o_b;
    1925             :   double res;
    1926           0 :   Length wh2o_retrieved(-999.0, Length::UnitMilliMeter);
    1927           0 :   Length werr(-888, Length::UnitMilliMeter);
    1928             :   double sigma_fit_transm0;
    1929           0 :   Length sigma_wh2o;
    1930             : 
    1931           0 :   num = 0;
    1932             : 
    1933           0 :   flamda = 0.001;
    1934           0 :   pfit_wh2o = 1.0; // (getUserWH2O().get(Length::UnitMilliMeter))/(getGroundWH2O().get(Length::UnitMilliMeter));
    1935             : 
    1936           0 :   unsigned int nl = 0;
    1937             : 
    1938           0 :   if(fre1.get(Frequency::UnitGigaHertz) < 0) {
    1939           0 :     nl = getSpectralWindow(spwId).size();
    1940             :   } else {
    1941           0 :     for(unsigned int i = 0; i < getSpectralWindow(spwId).size(); i++) {
    1942           0 :       if(getSpectralWindow(spwId)[i] * 1E-09 >= fre1.get(Frequency::UnitGigaHertz)
    1943           0 :           && getSpectralWindow(spwId)[i] * 1E-09 <= fre2.get(Frequency::UnitGigaHertz)) {
    1944           0 :         nl = nl + 1;
    1945             :       }
    1946             :     }
    1947             :   }
    1948             : 
    1949           0 :   for(unsigned int kite = 0; kite < niter; kite++) {
    1950             : 
    1951           0 :     num = num + 1;
    1952             : 
    1953           0 :     beta = 0.0;
    1954           0 :     alpha = 0.0;
    1955             : 
    1956             :     //    for(unsigned int i=0; i<getSpectralWindow(spwId).size(); i++){
    1957             : 
    1958           0 :     for(unsigned int i = 0; i < getSpectralWindow(spwId).size(); i++) {
    1959             : 
    1960           0 :       if(nl == getSpectralWindow(spwId).size() || (getSpectralWindow(spwId)[i]
    1961           0 :           * 1E-09 >= fre1.get(Frequency::UnitGigaHertz) && getSpectralWindow(spwId)[i] * 1E-09
    1962           0 :           <= fre2.get(Frequency::UnitGigaHertz))) {
    1963             :         //
    1964           0 :         transmission_fit[i] = exp(-( (getDryContOpacity(spwId, i).get()+getO2LinesOpacity(spwId, i).get()+0.65*getO3LinesOpacity(spwId, i).get() )                                              //getDryOpacity(spwId, i).get()
    1965           0 :                                      + pfit_wh2o * getWetOpacity(spwId, i).get() ) );
    1966             :         //
    1967           0 :         f1 = transmission_fit[i];
    1968           0 :         psave = pfit_wh2o;
    1969           0 :         pfit_wh2o = pfit_wh2o + deltaa;
    1970           0 :         f2 = exp(-( (getDryContOpacity(spwId, i).get()+getO2LinesOpacity(spwId, i).get()+0.65*getO3LinesOpacity(spwId, i).get() )     //getDryOpacity(spwId, i).get()
    1971           0 :                    + pfit_wh2o* getWetOpacity(spwId, i).get()));
    1972           0 :         deriv = (f2 - f1) / deltaa;
    1973           0 :         pfit_wh2o = psave;
    1974           0 :         beta = beta + (measuredSkyTransmission[i] - transmission_fit[i])
    1975           0 :             * deriv;
    1976           0 :         alpha = alpha + deriv * deriv;
    1977             :       }
    1978             :     }
    1979             : 
    1980           0 :     chisq1 = 0;
    1981           0 :     for(unsigned int i = 0; i < getSpectralWindow(spwId).size(); i++) {
    1982           0 :       if(nl == getSpectralWindow(spwId).size() || (getSpectralWindow(spwId)[i]
    1983           0 :           * 1E-09 >= fre1.get(Frequency::UnitGigaHertz) && getSpectralWindow(spwId)[i] * 1E-09
    1984           0 :           <= fre2.get(Frequency::UnitGigaHertz))) {
    1985           0 :         res = -transmission_fit[i] + measuredSkyTransmission[i];
    1986           0 :         chisq1 = chisq1 + res * res;
    1987             :       }
    1988             :     }
    1989           0 :     if(nl > 1) {
    1990           0 :       chisq1 = chisq1 / (nl - 1);
    1991             :     }
    1992             : 
    1993           0 :     adjust: array = 1.0 / (1.0 + flamda);
    1994           0 :     pfit_wh2o_b = pfit_wh2o;
    1995           0 :     pfit_wh2o_b = pfit_wh2o_b + beta * array / alpha;
    1996           0 :     if(pfit_wh2o_b < 0.0) pfit_wh2o_b = 0.9 * pfit_wh2o;
    1997             : 
    1998           0 :     chisqr = 0;
    1999           0 :     for(unsigned int i = 0; i < getSpectralWindow(spwId).size(); i++) {
    2000           0 :       if(nl == getSpectralWindow(spwId).size() || (getSpectralWindow(spwId)[i]
    2001           0 :           * 1E-09 >= fre1.get(Frequency::UnitGigaHertz) && getSpectralWindow(spwId)[i] * 1E-09
    2002           0 :           <= fre2.get(Frequency::UnitGigaHertz))) {
    2003           0 :         transmission_fit[i] = exp(-( ( getDryContOpacity(spwId, i).get()+getO2LinesOpacity(spwId, i).get()+0.65*getO3LinesOpacity(spwId, i).get() )             //      (getDryOpacity(spwId, i).get())
    2004           0 :                                      + pfit_wh2o_b * getWetOpacity(spwId, i).get()));
    2005           0 :         res = -transmission_fit[i] + measuredSkyTransmission[i];
    2006           0 :         chisqr = chisqr + res * res;
    2007             :       }
    2008             :     }
    2009             : 
    2010           0 :     if(nl > 1) {
    2011           0 :       chisqr = chisqr / (nl - 1);
    2012             :     }
    2013             : 
    2014           0 :     if(fabs(chisq1 - chisqr) > 0.001) {
    2015           0 :       if(chisq1 < chisqr) {
    2016           0 :         flamda = flamda * 10.0;
    2017           0 :         goto adjust;
    2018             :       }
    2019             :     }
    2020             : 
    2021           0 :     flamda = flamda / 10.0;
    2022           0 :     sig_fit = sqrt(chisqr);
    2023           0 :     pfit_wh2o = pfit_wh2o_b;
    2024           0 :     sigma_wh2o = Length(sqrt(array / alpha) * sig_fit * pfit_wh2o
    2025           0 :         * (getUserWH2O().get()), Length::UnitMilliMeter);
    2026             : 
    2027           0 :     if(fabs(sqrt(chisq1) - sqrt(chisqr)) < eps) {
    2028             : 
    2029             :       /*        for(unsigned int i=0; i<getSpectralWindow(spwId).size(); i++){
    2030             :        cout << getSpectralWindow(spwId)[i]*1E-09 << "  "  << measuredSkyTransmission[i] << "  "  << transmission_fit[i] << endl;
    2031             :        } */
    2032             : 
    2033           0 :       sigma_fit_transm0 = sig_fit;
    2034             : 
    2035           0 :       wh2o_retrieved = Length(pfit_wh2o * getUserWH2O().get(Length::UnitMilliMeter), Length::UnitMilliMeter);
    2036             : 
    2037           0 :       goto salir;
    2038             : 
    2039             :     }
    2040             : 
    2041             :   }
    2042             : 
    2043           0 :   wh2o_retrieved = werr; // Extra error code, fit not reached after 20 iterations
    2044           0 :   sigma_fit_transm0 = -888.0; // Extra error code, fit not reached after 20 iterations
    2045           0 :   sigma_wh2o = werr; // Extra error code, fit not reached after 20 iterations
    2046             : 
    2047           0 :   salir:
    2048             : 
    2049           0 :   sigma_transmission_FTSfit_ = sigma_fit_transm0;
    2050             : 
    2051           0 :   if(wh2o_retrieved.get() > 0.0) {
    2052           0 :     wh2o_user_ = wh2o_retrieved;
    2053             :   }
    2054           0 :   return wh2o_retrieved;
    2055             : 
    2056             : }
    2057             : 
    2058           0 : Length SkyStatus::mkWaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    2059             :                                                  const vector<Percent> &signalGain,
    2060             :                                                  const vector<Temperature> &measuredAverageSkyTEBB,
    2061             :                                                  double airm,
    2062             :                                                  const vector<vector<double> > &spwId_filter,
    2063             :                                                  const vector<double> &skycoupling,
    2064             :                                                  const vector<Temperature> &tspill)
    2065             : {
    2066             : 
    2067             :   double pfit_wh2o;
    2068           0 :   double deltaa = 0.02;
    2069           0 :   double sig_fit = -999.0;
    2070           0 :   double eps = 0.001;
    2071           0 :   vector<Temperature> v_tebb_fit;
    2072             : 
    2073             :   unsigned int num;
    2074             :   double flamda;
    2075           0 :   unsigned int niter = 20;
    2076             :   double alpha;
    2077             :   double beta;
    2078             :   double array;
    2079             :   double f1;
    2080             :   double psave;
    2081             :   double f2;
    2082             :   double deriv;
    2083             :   double chisq1;
    2084             :   double chisqr;
    2085             :   double pfit_wh2o_b;
    2086             :   double res;
    2087           0 :   Length wh2o_retrieved(-999.0, Length::UnitMilliMeter);
    2088           0 :   Length werr(-888, Length::UnitMilliMeter);
    2089             :   double sigma_fit_transm0;
    2090           0 :   Length sigma_wh2o;
    2091           0 :   v_tebb_fit.reserve(measuredAverageSkyTEBB.size());
    2092             : 
    2093           0 :   num = 0;
    2094           0 :   flamda = 0.001;
    2095             : 
    2096           0 :   pfit_wh2o = (getUserWH2O().get(Length::UnitMilliMeter)) / (getGroundWH2O().get(Length::UnitMilliMeter));
    2097             : 
    2098           0 :   for(unsigned int kite = 0; kite < niter; kite++) {
    2099             : 
    2100           0 :     num = num + 1;
    2101             : 
    2102           0 :     beta = 0.0;
    2103           0 :     alpha = 0.0;
    2104             : 
    2105           0 :     for(unsigned int j = 0; j < spwId.size(); j++) {
    2106             : 
    2107             : 
    2108           0 :       f1 = RT(pfit_wh2o,
    2109           0 :               skycoupling[j],
    2110           0 :               tspill[j].get(Temperature::UnitKelvin),
    2111             :               airm,
    2112           0 :               spwId[j],
    2113           0 :               spwId_filter[j],
    2114           0 :               signalGain[j]);    // if signalGain[j] < 1.0 then there is an image side
    2115             :                                  // band and it is correctly taken into account in RT
    2116             : 
    2117           0 :       v_tebb_fit[j] = Temperature(f1, Temperature::UnitKelvin);
    2118             : 
    2119           0 :       psave = pfit_wh2o;
    2120           0 :       pfit_wh2o = pfit_wh2o + deltaa;
    2121             : 
    2122           0 :       f2 = RT(pfit_wh2o,
    2123           0 :               skycoupling[j],
    2124           0 :               tspill[j].get(Temperature::UnitKelvin),
    2125             :               airm,
    2126           0 :               spwId[j],
    2127           0 :               spwId_filter[j],
    2128           0 :               signalGain[j]);
    2129             : 
    2130           0 :       deriv = (f2 - f1) / deltaa;
    2131             : 
    2132           0 :       pfit_wh2o = psave;
    2133           0 :       beta = beta + ((measuredAverageSkyTEBB[j]).get(Temperature::UnitKelvin) - f1) * deriv;
    2134           0 :       alpha = alpha + deriv * deriv;
    2135             : 
    2136             :     }
    2137             : 
    2138           0 :     chisq1 = 0;
    2139             : 
    2140           0 :     for(unsigned int j = 0; j < measuredAverageSkyTEBB.size(); j++) {
    2141             : 
    2142           0 :       res = -v_tebb_fit[j].get(Temperature::UnitKelvin) + (measuredAverageSkyTEBB[j]).get(Temperature::UnitKelvin);
    2143           0 :       chisq1 = chisq1 + res * res;
    2144             : 
    2145             :     }
    2146             : 
    2147           0 :     if(measuredAverageSkyTEBB.size() > 1) {
    2148           0 :       chisq1 = chisq1 / (measuredAverageSkyTEBB.size() - 1);
    2149             :     }
    2150             : 
    2151           0 :     adjust: array = 1.0 / (1.0 + flamda);
    2152           0 :     pfit_wh2o_b = pfit_wh2o;
    2153           0 :     pfit_wh2o_b = pfit_wh2o_b + beta * array / alpha;
    2154           0 :     if(pfit_wh2o_b < 0.0) pfit_wh2o_b = 0.9 * pfit_wh2o;
    2155             : 
    2156           0 :     chisqr = 0;
    2157             : 
    2158           0 :     for(unsigned int j = 0; j < spwId.size(); j++) {
    2159             : 
    2160           0 :       v_tebb_fit[j] = Temperature(RT(pfit_wh2o_b,
    2161           0 :                                      skycoupling[j],
    2162           0 :                                      tspill[j].get(Temperature::UnitKelvin),
    2163             :                                      airm,
    2164           0 :                                      spwId[j],
    2165           0 :                                      spwId_filter[j],
    2166           0 :                                      signalGain[j]), Temperature::UnitKelvin);
    2167             : 
    2168           0 :       res = -v_tebb_fit[j].get(Temperature::UnitKelvin) + (measuredAverageSkyTEBB[j]).get(Temperature::UnitKelvin);
    2169           0 :       chisqr = chisqr + res * res;
    2170             : 
    2171             :     }
    2172             : 
    2173           0 :     if(spwId.size() > 1) {
    2174           0 :       chisqr = chisqr / (spwId.size() - 1);
    2175             :     }
    2176             : 
    2177           0 :     if(fabs(chisq1 - chisqr) > 0.001) {
    2178           0 :       if(chisq1 < chisqr) {
    2179           0 :         flamda = flamda * 10.0;
    2180           0 :         goto adjust;
    2181             :       }
    2182             :     }
    2183             : 
    2184           0 :     flamda = flamda / 10.0;
    2185           0 :     sig_fit = sqrt(chisqr);
    2186           0 :     pfit_wh2o = pfit_wh2o_b;
    2187           0 :     sigma_wh2o = Length(sqrt(array / alpha) * sig_fit * pfit_wh2o
    2188           0 :         * (getGroundWH2O().get(Length::UnitMilliMeter)), Length::UnitMilliMeter);
    2189             : 
    2190           0 :     if(fabs(sqrt(chisq1) - sqrt(chisqr)) < eps) {
    2191             : 
    2192           0 :       sigma_fit_transm0 = sig_fit;
    2193             : 
    2194           0 :       wh2o_retrieved = Length(pfit_wh2o * getGroundWH2O().get(Length::UnitMilliMeter), Length::UnitMilliMeter);
    2195             : 
    2196           0 :       goto salir;
    2197             : 
    2198             :     }
    2199             : 
    2200             :   }
    2201             : 
    2202           0 :   wh2o_retrieved = werr; // Extra error code, fit not reached after 20 iterations
    2203           0 :   sigma_fit_transm0 = -888.0; // Extra error code, fit not reached after 20 iterations
    2204           0 :   sigma_wh2o = werr; // Extra error code, fit not reached after 20 iterations
    2205             : 
    2206           0 :   salir:
    2207             : 
    2208           0 :   sigma_TEBBfit_ = Temperature(sigma_fit_transm0, Temperature::UnitKelvin);
    2209           0 :   if(wh2o_retrieved.get() > 0.0) {
    2210           0 :     wh2o_user_ = wh2o_retrieved;
    2211             :   }
    2212           0 :   return wh2o_retrieved;
    2213             : 
    2214             : }
    2215             : 
    2216           0 : Length SkyStatus::mkWaterVaporRetrieval_fromTEBB(const vector<unsigned int> &spwId,
    2217             :                                                  const vector<Percent> &signalGain,
    2218             :                                                  const vector<vector<Temperature> > &measuredSkyTEBB,
    2219             :                                                  double airm,
    2220             :                                                  const vector<vector<double> > &spwId_filter,
    2221             :                                                  const vector<double> &skycoupling,
    2222             :                                                  const vector<Temperature> &tspill)
    2223             : {
    2224             : 
    2225             :   double pfit_wh2o;
    2226           0 :   double deltaa = 0.02;
    2227           0 :   double sig_fit = -999.0;
    2228           0 :   double eps = 0.01;
    2229           0 :   vector<vector<Temperature> > vv_tebb_fit;
    2230           0 :   vector<Temperature> v_tebb_fit;
    2231             : 
    2232             :   unsigned int num;
    2233             :   double flamda;
    2234           0 :   unsigned int niter = 20;
    2235             :   double alpha;
    2236             :   double beta;
    2237             :   double array;
    2238             :   double f1;
    2239             :   double psave;
    2240             :   double f2;
    2241             :   double deriv;
    2242             :   double chisq1;
    2243             :   double chisqr;
    2244             :   double pfit_wh2o_b;
    2245             :   double res;
    2246           0 :   Length wh2o_retrieved(-999.0, Length::UnitMilliMeter);
    2247           0 :   Length werr(-888, Length::UnitMilliMeter);
    2248             :   double sigma_fit_transm0;
    2249           0 :   Length sigma_wh2o;
    2250           0 :   vector<double> spwIdNorm;
    2251           0 :   vector<double> validchannels;
    2252           0 :   spwIdNorm.reserve(spwId.size());
    2253           0 :   validchannels.reserve(spwId.size());
    2254           0 :   vv_tebb_fit.reserve(spwId.size());
    2255             : 
    2256           0 :   for(unsigned int j = 0; j < spwId.size(); j++) {
    2257           0 :     spwIdNorm[j] = 0.0;
    2258           0 :     validchannels[j] = 0.0;
    2259           0 :     for(unsigned int i = 0; i < getSpectralWindow(spwId[j]).size(); i++) {
    2260           0 :       if(spwId_filter[j][i] > 0) {
    2261           0 :         spwIdNorm[j] = spwIdNorm[j] + spwId_filter[j][i];
    2262           0 :         validchannels[j] = validchannels[j] + 1.0;
    2263             :       }
    2264             :     }
    2265             :   }
    2266             : 
    2267           0 :   num = 0;
    2268           0 :   flamda = 0.001;
    2269           0 :   pfit_wh2o = (getUserWH2O().get(Length::UnitMilliMeter)) / (getGroundWH2O().get(Length::UnitMilliMeter));
    2270             : 
    2271           0 :   for(unsigned int kite = 0; kite < niter; kite++) {
    2272             : 
    2273           0 :     num = num + 1;
    2274             : 
    2275           0 :     beta = 0.0;
    2276           0 :     alpha = 0.0;
    2277             : 
    2278           0 :     for(unsigned int j = 0; j < spwId.size(); j++) {
    2279             : 
    2280           0 :       v_tebb_fit.clear();
    2281             : 
    2282           0 :       for(unsigned int i = 0; i < getSpectralWindow(spwId[j]).size(); i++) {
    2283             : 
    2284           0 :         if(spwId_filter[j][i] > 0) {
    2285             : 
    2286           0 :           if(signalGain[j].get() < 1.0) {
    2287           0 :             f1 = RT(pfit_wh2o,
    2288           0 :                     skycoupling[j],
    2289           0 :                     tspill[j].get(Temperature::UnitKelvin),
    2290             :                     airm,
    2291           0 :                     spwId[j],
    2292           0 :                     i) * signalGain[j].get() + RT(pfit_wh2o,
    2293           0 :                                                   skycoupling[j],
    2294           0 :                                                   tspill[j].get(Temperature::UnitKelvin),
    2295             :                                                   airm,
    2296           0 :                                                   getAssocSpwId(spwId[j])[0],
    2297             :                                                   i)
    2298           0 :                 * (1 - signalGain[j].get());
    2299             :           } else {
    2300           0 :             f1 = RT(pfit_wh2o,
    2301           0 :                     skycoupling[j],
    2302           0 :                     tspill[j].get(Temperature::UnitKelvin),
    2303             :                     airm,
    2304           0 :                     spwId[j],
    2305             :                     i);
    2306             :           }
    2307             : 
    2308           0 :           psave = pfit_wh2o;
    2309           0 :           pfit_wh2o = pfit_wh2o + deltaa;
    2310             : 
    2311           0 :           v_tebb_fit.push_back(Temperature(f1, Temperature::UnitKelvin));
    2312             : 
    2313           0 :           if(signalGain[j].get() < 1.0) {
    2314           0 :             f2 = (RT(pfit_wh2o,
    2315           0 :                      skycoupling[j],
    2316           0 :                      tspill[j].get(Temperature::UnitKelvin),
    2317             :                      airm,
    2318           0 :                      spwId[j],
    2319           0 :                      i) * signalGain[j].get() + RT(pfit_wh2o,
    2320           0 :                                                    skycoupling[j],
    2321           0 :                                                    tspill[j].get(Temperature::UnitKelvin),
    2322             :                                                    airm,
    2323           0 :                                                    getAssocSpwId(spwId[j])[0],
    2324           0 :                                                    i) * (1
    2325           0 :                 - signalGain[j].get()));
    2326             :           } else {
    2327           0 :             f2 = (RT(pfit_wh2o,
    2328           0 :                      skycoupling[j],
    2329           0 :                      tspill[j].get(Temperature::UnitKelvin),
    2330             :                      airm,
    2331           0 :                      spwId[j],
    2332           0 :                      i) * signalGain[j].get());
    2333             :           }
    2334             : 
    2335           0 :           f2 = f2 * spwId_filter[j][i] * validchannels[j] / spwIdNorm[j];
    2336           0 :           f1 = f1 * spwId_filter[j][i] * validchannels[j] / spwIdNorm[j];
    2337           0 :           deriv = (f2 - f1) / deltaa;
    2338             : 
    2339           0 :           pfit_wh2o = psave;
    2340           0 :           beta = beta + ((measuredSkyTEBB[j][i]).get(Temperature::UnitKelvin) - f1) * deriv; //*spwId_filter[j][i]/spwIdNorm[j];
    2341           0 :           alpha = alpha + deriv * deriv;
    2342             : 
    2343             :         } else {
    2344             : 
    2345           0 :           v_tebb_fit.push_back(Temperature(-999, Temperature::UnitKelvin));
    2346             : 
    2347             :         }
    2348             : 
    2349             :       }
    2350             : 
    2351           0 :       vv_tebb_fit.push_back(v_tebb_fit);
    2352             : 
    2353             :     }
    2354             : 
    2355           0 :     chisq1 = 0;
    2356             : 
    2357           0 :     for(unsigned int j = 0; j < spwId.size(); j++) {
    2358             : 
    2359           0 :       for(unsigned int i = 0; i < getSpectralWindow(spwId[j]).size(); i++) {
    2360           0 :         if(spwId_filter[j][i] > 0) {
    2361             :           res
    2362           0 :               = (-vv_tebb_fit[j][i].get(Temperature::UnitKelvin) + (measuredSkyTEBB[j][i]).get(Temperature::UnitKelvin))
    2363           0 :                   * spwId_filter[j][i] * validchannels[j] / spwIdNorm[j];
    2364           0 :           chisq1 = chisq1 + res * res;
    2365             :         }
    2366             :       }
    2367             : 
    2368             :     }
    2369             : 
    2370           0 :     if(spwId.size() > 1) {
    2371           0 :       chisq1 = chisq1 / (spwId.size() - 1);
    2372             :     }
    2373             : 
    2374           0 :     adjust: array = 1.0 / (1.0 + flamda);
    2375           0 :     pfit_wh2o_b = pfit_wh2o;
    2376           0 :     pfit_wh2o_b = pfit_wh2o_b + beta * array / alpha;
    2377           0 :     if(pfit_wh2o_b < 0.0) pfit_wh2o_b = 0.9 * pfit_wh2o;
    2378             : 
    2379           0 :     chisqr = 0;
    2380             : 
    2381           0 :     for(unsigned int j = 0; j < spwId.size(); j++) {
    2382             : 
    2383           0 :       for(unsigned int i = 0; i < getSpectralWindow(spwId[j]).size(); i++) {
    2384             : 
    2385           0 :         if(spwId_filter[j][i] > 0) {
    2386             : 
    2387           0 :           if(signalGain[j].get() < 1.0) {
    2388           0 :             vv_tebb_fit[j][i] = Temperature(RT(pfit_wh2o_b,
    2389           0 :                                                skycoupling[j],
    2390           0 :                                                tspill[j].get(Temperature::UnitKelvin),
    2391             :                                                airm,
    2392           0 :                                                spwId[j],
    2393           0 :                                                i) * signalGain[j].get()
    2394           0 :                 + RT(pfit_wh2o_b,
    2395           0 :                      skycoupling[j],
    2396           0 :                      tspill[j].get(Temperature::UnitKelvin),
    2397             :                      airm,
    2398           0 :                      getAssocSpwId(spwId[j])[0],
    2399           0 :                      i) * (1 - signalGain[j].get()), Temperature::UnitKelvin);
    2400             :           } else {
    2401           0 :             vv_tebb_fit[j][i] = Temperature(RT(pfit_wh2o_b,
    2402           0 :                                                skycoupling[j],
    2403           0 :                                                tspill[j].get(Temperature::UnitKelvin),
    2404             :                                                airm,
    2405           0 :                                                spwId[j],
    2406           0 :                                                i) * signalGain[j].get(), Temperature::UnitKelvin);
    2407             :           }
    2408             : 
    2409             :           res
    2410           0 :               = (-vv_tebb_fit[j][i].get(Temperature::UnitKelvin) + (measuredSkyTEBB[j][i]).get(Temperature::UnitKelvin))
    2411           0 :                   * spwId_filter[j][i] * validchannels[j] / spwIdNorm[j];
    2412             : 
    2413           0 :           chisqr = chisqr + res * res;
    2414             :         }
    2415             :       }
    2416             : 
    2417             :     }
    2418             : 
    2419           0 :     if(spwId.size() > 1) {
    2420           0 :       chisqr = chisqr / (spwId.size() - 1);
    2421             :     }
    2422             : 
    2423           0 :     if(fabs(chisq1 - chisqr) > 0.001) {
    2424           0 :       if(chisq1 < chisqr) {
    2425           0 :         flamda = flamda * 10.0;
    2426           0 :         goto adjust;
    2427             :       }
    2428             :     }
    2429             : 
    2430           0 :     flamda = flamda / 10.0;
    2431           0 :     sig_fit = sqrt(chisqr);
    2432           0 :     pfit_wh2o = pfit_wh2o_b;
    2433           0 :     sigma_wh2o = Length(sqrt(array / alpha) * sig_fit * pfit_wh2o
    2434           0 :         * (getGroundWH2O().get(Length::UnitMilliMeter)), Length::UnitMilliMeter);
    2435             : 
    2436           0 :     if(fabs(sqrt(chisq1) - sqrt(chisqr)) < eps) {
    2437             : 
    2438           0 :       sigma_fit_transm0 = sig_fit;
    2439             : 
    2440           0 :       wh2o_retrieved = Length(pfit_wh2o * getGroundWH2O().get(Length::UnitMilliMeter), Length::UnitMilliMeter);
    2441             : 
    2442           0 :       goto salir;
    2443             : 
    2444             :     }
    2445             : 
    2446             :   }
    2447             : 
    2448           0 :   wh2o_retrieved = werr; // Extra error code, fit not reached after 20 iterations
    2449           0 :   sigma_fit_transm0 = -888.0; // Extra error code, fit not reached after 20 iterations
    2450           0 :   sigma_wh2o = werr; // Extra error code, fit not reached after 20 iterations
    2451             : 
    2452           0 :   salir:
    2453             : 
    2454           0 :   sigma_TEBBfit_ = Temperature(sigma_fit_transm0, Temperature::UnitKelvin);
    2455           0 :   if(wh2o_retrieved.get() > 0.0) {
    2456           0 :     wh2o_user_ = wh2o_retrieved;
    2457             :   }
    2458           0 :   return wh2o_retrieved;
    2459             : 
    2460             : }
    2461             : 
    2462           0 : double SkyStatus::mkSkyCouplingRetrieval_fromTEBB(unsigned int spwId,
    2463             :                                                   const Percent &signalGain,
    2464             :                                                   const vector<Temperature> &measuredSkyTEBB,
    2465             :                                                   double airm,
    2466             :                                                   const vector<double> &spwId_filter,
    2467             :                                                   double skycoupling,
    2468             :                                                   const Temperature &tspill)
    2469             : {
    2470             : 
    2471             :   // double pfit_wh2o;  // [-Wunused_but_set_variable]
    2472             :   double pfit_skycoupling;
    2473             :   double pfit_skycoupling_b;
    2474           0 :   double deltaa = 0.02;
    2475             :   // double sig_fit = -999.0;  // [-Wunused_but_set_variable]
    2476           0 :   double eps = 0.01;
    2477           0 :   vector<Temperature> tebb_fit;
    2478           0 :   tebb_fit.reserve(measuredSkyTEBB.size()); // allows resizing
    2479             : 
    2480             :   unsigned int num;
    2481             :   double flamda;
    2482           0 :   unsigned int niter = 20;
    2483             :   double alpha;
    2484             :   double beta;
    2485             :   double array;
    2486             :   double f1;
    2487             :   double psave;
    2488             :   double f2;
    2489             :   double deriv;
    2490             :   double chisq1;
    2491             :   double chisqr;
    2492             :   double res;
    2493           0 :   Length wh2o_retrieved(-999.0, Length::UnitMilliMeter);
    2494           0 :   Length werr(-888, Length::UnitMilliMeter);
    2495             :   // double sigma_fit_transm0; // [-Wunused_but_set_variable]
    2496           0 :   Length sigma_wh2o;
    2497             : 
    2498           0 :   num = 0;
    2499             : 
    2500           0 :   flamda = 0.001;
    2501             :   // pfit_wh2o = (getUserWH2O().get(Length::UnitMilliMeter)) / (getGroundWH2O().get(Length::UnitMilliMeter)); // [-Wunused_but_set_variable]
    2502           0 :   pfit_skycoupling = 1.0;
    2503             : 
    2504           0 :   for(unsigned int kite = 0; kite < niter; kite++) {
    2505             : 
    2506           0 :     num = num + 1;
    2507             : 
    2508           0 :     beta = 0.0;
    2509           0 :     alpha = 0.0;
    2510             : 
    2511             :     //    for(unsigned int i=0; i<getSpectralWindow(spwId).size(); i++){
    2512             : 
    2513           0 :     mkWaterVaporRetrieval_fromTEBB(spwId,
    2514             :                                    signalGain,
    2515             :                                    measuredSkyTEBB,
    2516             :                                    airm,
    2517             :                                    spwId_filter,
    2518             :                                    pfit_skycoupling * skycoupling,
    2519             :                                    tspill);
    2520           0 :     f1 = sigma_TEBBfit_.get(Temperature::UnitKelvin);
    2521             :     // cout << "pfit_skycoupling =" << pfit_skycoupling << "  f1=" << f1 << "  wh2o_user_=" << wh2o_user_.get(Length::UnitMilliMeter) << " mm" << endl;
    2522           0 :     psave = pfit_skycoupling;
    2523           0 :     pfit_skycoupling = pfit_skycoupling + deltaa;
    2524           0 :     mkWaterVaporRetrieval_fromTEBB(spwId,
    2525             :                                    signalGain,
    2526             :                                    measuredSkyTEBB,
    2527             :                                    airm,
    2528             :                                    spwId_filter,
    2529             :                                    pfit_skycoupling * skycoupling,
    2530             :                                    tspill);
    2531           0 :     f2 = sigma_TEBBfit_.get(Temperature::UnitKelvin);
    2532             :     // cout << "pfit_skycoupling =" << pfit_skycoupling << "  f2=" << f2 << "  wh2o_user_=" << wh2o_user_.get(Length::UnitMilliMeter) << " mm" << endl;
    2533           0 :     deriv = (f2 - f1) / deltaa;
    2534           0 :     pfit_skycoupling = psave;
    2535           0 :     beta = beta - f1 * deriv;
    2536           0 :     alpha = alpha + deriv * deriv;
    2537             : 
    2538           0 :     chisq1 = 0;
    2539           0 :     res = f1;
    2540           0 :     chisq1 = chisq1 + res * res;
    2541             : 
    2542           0 :     adjust: array = 1.0 / (1.0 + flamda);
    2543           0 :     pfit_skycoupling_b = pfit_skycoupling;
    2544           0 :     pfit_skycoupling_b = pfit_skycoupling_b + beta * array / alpha;
    2545           0 :     if(pfit_skycoupling_b < 0.0) pfit_skycoupling_b = 0.9 * pfit_skycoupling;
    2546           0 :     chisqr = 0;
    2547           0 :     mkWaterVaporRetrieval_fromTEBB(spwId,
    2548             :                                    signalGain,
    2549             :                                    measuredSkyTEBB,
    2550             :                                    airm,
    2551             :                                    spwId_filter,
    2552             :                                    pfit_skycoupling_b * skycoupling,
    2553             :                                    tspill);
    2554           0 :     res = sigma_TEBBfit_.get(Temperature::UnitKelvin);
    2555             :     // cout << "pfit_skycoupling =" << pfit_skycoupling_b << "  res=" << res << "  wh2o_user_=" << wh2o_user_.get(Length::UnitMilliMeter) << " mm" << endl;
    2556           0 :     chisqr = chisqr + res * res;
    2557             : 
    2558           0 :     if(fabs(chisq1 - chisqr) > 0.001) {
    2559           0 :       if(chisq1 < chisqr) {
    2560           0 :         flamda = flamda * 10.0;
    2561           0 :         goto adjust;
    2562             :       }
    2563             :     }
    2564             : 
    2565           0 :     flamda = flamda / 10.0;
    2566             :     // sig_fit = sqrt(chisqr); // [-Wunused_but_set_variable]
    2567           0 :     pfit_skycoupling = pfit_skycoupling_b;
    2568             : 
    2569           0 :     if(fabs(sqrt(chisq1) - sqrt(chisqr)) < eps) {
    2570           0 :       goto salir;
    2571             :     }
    2572             : 
    2573             :   }
    2574             : 
    2575           0 :   wh2o_retrieved = werr; // Extra error code, fit not reached after 20 iterations
    2576             :   //sigma_fit_transm0 = -888.0; // Extra error code, fit not reached after 20 iterations [-Wunused_but_set_variable]
    2577           0 :   sigma_wh2o = werr; // Extra error code, fit not reached after 20 iterations
    2578             : 
    2579           0 :   salir: return pfit_skycoupling * skycoupling;
    2580             : 
    2581             : }
    2582             : 
    2583             : 
    2584           0 :   double SkyStatus::RT(double pfit_wh2o,
    2585             :                        double skycoupling,
    2586             :                        double tspill,
    2587             :                        double airmass,
    2588             :                        unsigned int spwid,
    2589             :                        const vector<double> &spwId_filter,
    2590             :                        const Percent &signalgain)
    2591             :   {
    2592             : 
    2593           0 :     double tebb_channel = 0.0;
    2594             :     double rtr;
    2595           0 :     double norm = 0.0;
    2596             : 
    2597           0 :     for(unsigned int n = 0; n < v_numChan_[spwid]; n++) {
    2598           0 :       if(spwId_filter[n] > 0) {
    2599           0 :         norm = norm + spwId_filter[n];
    2600             :       }
    2601             :     }
    2602             : 
    2603           0 :     if(norm == 0.0) {
    2604           0 :       return norm;
    2605             :     }
    2606             : 
    2607           0 :     for(unsigned int n = 0; n < v_numChan_[spwid]; n++) {
    2608             : 
    2609           0 :       if(spwId_filter[n] > 0) {
    2610             : 
    2611           0 :         if(signalgain.get() < 1.0) {
    2612           0 :           rtr = RT(pfit_wh2o, skycoupling, tspill, airmass, spwid, n)
    2613           0 :               * signalgain.get() + RT(pfit_wh2o,
    2614             :                                       skycoupling,
    2615             :                                       tspill,
    2616             :                                       airmass,
    2617           0 :                                       getAssocSpwId(spwid)[0],
    2618           0 :                                       n) * (1.0 - signalgain.get());
    2619             :         } else {
    2620           0 :           rtr = RT(pfit_wh2o, skycoupling, tspill, airmass, spwid, n);
    2621             :         }
    2622           0 :         tebb_channel = tebb_channel + rtr * spwId_filter[n] / norm;
    2623             :       }
    2624             :     }
    2625             : 
    2626           0 :     return tebb_channel;
    2627             :   }
    2628             : 
    2629             : 
    2630             : 
    2631      142876 : double SkyStatus::RT(double pfit_wh2o,
    2632             :                      double skycoupling,
    2633             :                      double tspill,
    2634             :                      double airm,
    2635             :                      unsigned int spwid,
    2636             :                      unsigned int nc)
    2637             : {
    2638             : 
    2639             :   double radiance;
    2640             :   double singlefreq;
    2641             :   // double chanwidth;  // [-Wunused_but_set_variable]
    2642             :   double tebb;
    2643      142876 :   double h_div_k = 0.04799274551; /* plank=6.6262e-34,boltz=1.3806E-23 */
    2644             :   double kv;
    2645             :   double tau_layer;
    2646      142876 :   double tbgr = skyBackgroundTemperature_.get(Temperature::UnitKelvin);
    2647      142876 :   double ratioWater = pfit_wh2o;
    2648             : 
    2649      142876 :   singlefreq = getChanFreq(spwid, nc).get(Frequency::UnitGigaHertz);
    2650             :   // chanwidth = getChanWidth(spwid, nc).get(Frequency::UnitGigaHertz); // [-Wunused_but_set_variable]
    2651             :   // cout << "Chan freq. =" << singlefreq << " GHz" << endl;
    2652             :   // cout << "Chan width =" << chanwidth << " GHz" << endl;
    2653             : 
    2654      142876 :   tebb=0.0;
    2655      142876 :   kv = 0.0;
    2656      142876 :   radiance = 0.0;
    2657             : 
    2658     2745868 :   for(unsigned int i = 0; i < getNumLayer(); i++) {
    2659             : 
    2660     2602992 :     tau_layer = ((getAbsTotalWet(spwid, nc, i).get()) * ratioWater+ getAbsTotalDry(spwid, nc, i).get()) * getLayerThickness(i).get();
    2661             : 
    2662             :     // cout << i << "  " <<  getAbsTotalWet(spwid, nc, i).get() << "  " << getAbsTotalDry(spwid, nc, i).get() << endl;
    2663             : 
    2664     2602992 :     radiance = radiance + (1.0 / (exp(h_div_k * singlefreq/ getLayerTemperature(i).get()) - 1.0)) * exp(-kv * airm) * (1.0- exp(-airm * tau_layer));
    2665             : 
    2666     2602992 :     kv = kv + tau_layer;
    2667             : 
    2668             :   }
    2669             : 
    2670      142876 :   radiance = skycoupling * (radiance + (1.0 / (exp(h_div_k * singlefreq / tbgr)- 1.0)) * exp(-kv * airm)) + (1.0 / (exp(h_div_k * singlefreq / tspill)- 1.0)) * (1 - skycoupling);
    2671             : 
    2672      142876 :   tebb = h_div_k * singlefreq / log(1 + (1 / radiance));
    2673             :   // tebb = tebb+  h_div_k * singlefreq * radiance;
    2674             :   // cout << "singlefreq = " << singlefreq <<  " total opacity = " << kv << " tebb = " << tebb << endl;
    2675             : 
    2676      142876 :   return tebb;
    2677             : 
    2678             : }
    2679             : 
    2680             : 
    2681    15124480 : double SkyStatus::RTRJ(double pfit_wh2o,
    2682             :                      double skycoupling,
    2683             :                      double tspill,
    2684             :                      double airm,
    2685             :                      unsigned int spwid,
    2686             :                      unsigned int nc)
    2687             : {
    2688             : 
    2689             :   double radiance;
    2690             :   double singlefreq;
    2691             :   // double chanwidth;  // [-Wunused_but_set_variable]
    2692             :   double trj;
    2693    15124480 :   double h_div_k = 0.04799274551; /* plank=6.6262e-34,boltz=1.3806E-23 */
    2694             :   double kv;
    2695             :   double tau_layer;
    2696    15124480 :   double tbgr = skyBackgroundTemperature_.get(Temperature::UnitKelvin);
    2697    15124480 :   double ratioWater = pfit_wh2o;
    2698             : 
    2699    15124480 :   singlefreq = getChanFreq(spwid, nc).get(Frequency::UnitGigaHertz);
    2700             :   // chanwidth = getChanWidth(spwid, nc).get(Frequency::UnitGigaHertz); // [-Wunused_but_set_variable]
    2701    15124480 :   trj=0.0;
    2702    15124480 :   kv = 0.0;
    2703    15124480 :   radiance = 0.0;
    2704             : 
    2705   424775680 :   for(unsigned int i = 0; i < getNumLayer(); i++) {
    2706             : 
    2707   409651200 :     tau_layer = ((getAbsTotalWet(spwid, nc, i).get()) * ratioWater+ getAbsTotalDry(spwid, nc, i).get()) * getLayerThickness(i).get();
    2708             : 
    2709   409651200 :     radiance = radiance + (1.0 / (exp(h_div_k * singlefreq/ getLayerTemperature(i).get()) - 1.0)) * exp(-kv * airm) * (1.0- exp(-airm * tau_layer));
    2710             : 
    2711   409651200 :     kv = kv + tau_layer;
    2712             : 
    2713             :   }
    2714             : 
    2715    15124480 :   radiance = skycoupling * (radiance + (1.0 / (exp(h_div_k * singlefreq / tbgr)- 1.0)) * exp(-kv * airm)) + (1.0 / (exp(h_div_k * singlefreq / tspill)- 1.0)) * (1 - skycoupling);
    2716             : 
    2717    15124480 :   trj = h_div_k * singlefreq * radiance;
    2718             : 
    2719    15124480 :   return trj;
    2720             : 
    2721             : }
    2722             : 
    2723             : 
    2724             : 
    2725         864 : void SkyStatus::iniSkyStatus()
    2726             : {
    2727             : 
    2728        1728 :   Length wh2o_default(1, Length::UnitMilliMeter);
    2729        1728 :   Length wh2o_default_neg(-999, Length::UnitMilliMeter);
    2730        1728 :   Temperature temp_default_neg(-999, Temperature::UnitKelvin);
    2731             : 
    2732        1728 :   if(wh2o_user_.get() <= 0.0 || wh2o_user_.get() > (getGroundWH2O().get())
    2733         864 :       * (200 / (getRelativeHumidity().get(Percent::UnitPercent)))) {
    2734         864 :     wh2o_user_ = wh2o_default;
    2735             :   }
    2736             : 
    2737         864 : }
    2738             : 
    2739           0 : double SkyStatus::getAverageNonDispersiveDryPathLength_GroundPressureDerivative(unsigned int spwid)
    2740             : {
    2741           0 :   Pressure ref = getGroundPressure();
    2742             :   Length a =
    2743           0 :       RefractiveIndexProfile::getAverageNonDispersiveDryPathLength(spwid);
    2744           0 :   setBasicAtmosphericParameters(ref + Pressure(1.0, Pressure::UnitMilliBar));
    2745             :   Length b =
    2746           0 :       RefractiveIndexProfile::getAverageNonDispersiveDryPathLength(spwid);
    2747           0 :   setBasicAtmosphericParameters(ref);
    2748           0 :   return b.get(Length::UnitMicrons) - a.get(Length::UnitMicrons);
    2749             : }
    2750             : 
    2751           0 : double SkyStatus::getAverageNonDispersiveDryPathLength_GroundTemperatureDerivative(unsigned int spwid)
    2752             : {
    2753           0 :   Temperature ref = getGroundTemperature();
    2754           0 :   double oldLapseRate = getTropoLapseRate();
    2755             :   Length a =
    2756           0 :       RefractiveIndexProfile::getAverageNonDispersiveDryPathLength(spwid);
    2757             :   double newLapseRate =
    2758           0 :       ((getTropopauseTemperature() - ref - Temperature(1.0, Temperature::UnitKelvin)).get(Temperature::UnitKelvin))
    2759           0 :           / ((getTropopauseAltitude() - getAltitude()).get(Length::UnitKiloMeter));
    2760           0 :   setBasicAtmosphericParameters(ref + Temperature(1.0, Temperature::UnitKelvin), newLapseRate);
    2761             :   Length b =
    2762           0 :       RefractiveIndexProfile::getAverageNonDispersiveDryPathLength(spwid);
    2763           0 :   setBasicAtmosphericParameters(ref, oldLapseRate);
    2764           0 :   return b.get(Length::UnitMicrons) - a.get(Length::UnitMicrons);
    2765             : }
    2766             : 
    2767           0 : double SkyStatus::getAverageDispersiveDryPathLength_GroundPressureDerivative(unsigned int spwid)
    2768             : {
    2769           0 :   Pressure ref = getGroundPressure();
    2770           0 :   Length a = RefractiveIndexProfile::getAverageDispersiveDryPathLength(spwid);
    2771             :   // scanf("%d",&e);
    2772           0 :   setBasicAtmosphericParameters(ref + Pressure(1.0, Pressure::UnitMilliBar));
    2773           0 :   Length b = RefractiveIndexProfile::getAverageDispersiveDryPathLength(spwid);
    2774           0 :   setBasicAtmosphericParameters(ref);
    2775           0 :   return b.get(Length::UnitMicrons) - a.get(Length::UnitMicrons);
    2776             : }
    2777             : 
    2778           0 : double SkyStatus::getAverageDispersiveDryPathLength_GroundTemperatureDerivative(unsigned int spwid)
    2779             : {
    2780           0 :   Temperature ref = getGroundTemperature();
    2781           0 :   double oldLapseRate = getTropoLapseRate();
    2782           0 :   Length a = RefractiveIndexProfile::getAverageDispersiveDryPathLength(spwid);
    2783             :   double newLapseRate =
    2784           0 :       ((getTropopauseTemperature() - ref - Temperature(1.0, Temperature::UnitKelvin)).get(Temperature::UnitKelvin))
    2785           0 :           / ((getTropopauseAltitude() - getAltitude()).get(Length::UnitKiloMeter));
    2786           0 :   setBasicAtmosphericParameters(ref + Temperature(1.0, Temperature::UnitKelvin), newLapseRate);
    2787           0 :   Length b = RefractiveIndexProfile::getAverageDispersiveDryPathLength(spwid);
    2788           0 :   setBasicAtmosphericParameters(ref, oldLapseRate);
    2789           0 :   return b.get(Length::UnitMicrons) - a.get(Length::UnitMicrons);
    2790             : }
    2791             : 
    2792           0 : Temperature SkyStatus::getWVRAverageSigmaTskyFit(const vector<WVRMeasurement> &RadiometerData,
    2793             :                                                  unsigned int n,
    2794             :                                                  unsigned int m)
    2795             : {
    2796           0 :   double sigma = 0.0;
    2797             :   double tr;
    2798           0 :   Temperature sigmaT;
    2799           0 :   if(m < n) {
    2800           0 :     return Temperature(-999, Temperature::UnitKelvin);
    2801             :   }
    2802           0 :   for(unsigned int i = n; i < m; i++) {
    2803           0 :     tr = RadiometerData[i].getSigmaFit().get(Temperature::UnitKelvin);
    2804           0 :     if(tr < 0) {
    2805           0 :       return Temperature(-999, Temperature::UnitKelvin);
    2806             :     }
    2807           0 :     sigma = sigma + tr * tr;
    2808             :   }
    2809           0 :   if(m == n) {
    2810           0 :     sigmaT = RadiometerData[n].getSigmaFit();
    2811             :   } else {
    2812           0 :     sigma = sqrt(sigma / (m - n));
    2813           0 :     sigmaT = Temperature(sigma, Temperature::UnitKelvin);
    2814             :   }
    2815           0 :   return sigmaT;
    2816             : }
    2817           0 : Temperature SkyStatus::getWVRSigmaChannelTskyFit(const vector<WVRMeasurement> &RadiometerData,
    2818             :                                                  unsigned int ichan,
    2819             :                                                  unsigned int n,
    2820             :                                                  unsigned int m)
    2821             : {
    2822           0 :   double sigma = 0.0;
    2823             :   double dtr;
    2824           0 :   Temperature sigmaT;
    2825           0 :   if(m <= n) {
    2826           0 :     return Temperature(-999, Temperature::UnitKelvin);
    2827             :   }
    2828           0 :   for(unsigned int i = n; i < m; i++) {
    2829           0 :     dtr = RadiometerData[i].getmeasuredSkyBrightness()[ichan].get(Temperature::UnitKelvin)
    2830           0 :       -RadiometerData[i].getfittedSkyBrightness()[ichan].get(Temperature::UnitKelvin);
    2831           0 :     sigma = sigma + dtr * dtr;
    2832             :   }
    2833           0 :   sigma = sqrt(sigma / (m - n));
    2834           0 :   sigmaT = Temperature(sigma, Temperature::UnitKelvin);
    2835           0 :   return sigmaT;
    2836             : }
    2837             : 
    2838           0 : WVRMeasurement SkyStatus::mkWaterVaporRetrieval_fromWVR(const vector<Temperature> &measuredSkyBrightnessVector,
    2839             :                                                         const vector<unsigned int> &IdChannels,
    2840             :                                                         const vector<double> &skyCoupling,
    2841             :                                                         const vector<Percent> &signalGain,
    2842             :                                                         const Temperature &spilloverTemperature,
    2843             :                                                         const Angle &elevation)
    2844             : {
    2845           0 :   double tspill = spilloverTemperature.get(Temperature::UnitKelvin);
    2846             :   double pfit_wh2o;
    2847           0 :   double deltaa = 0.02;
    2848           0 :   double sig_fit = -999.0;
    2849           0 :   double eps = 0.01;
    2850           0 :   vector<double> tebb_fit;
    2851           0 :   tebb_fit.reserve(measuredSkyBrightnessVector.size());
    2852           0 :   double airm = 1.0 / sin((3.1415926 * elevation.get(Angle::UnitDegree)) / 180.0);
    2853             :   unsigned int num;
    2854             :   double flamda;
    2855           0 :   unsigned int niter = 20;
    2856             :   double alpha;
    2857             :   double beta;
    2858             :   double array;
    2859             :   double f1;
    2860             :   double psave;
    2861             :   double f2;
    2862             :   double deriv;
    2863             :   double chisq1;
    2864             :   double chisqr;
    2865             :   double pfit_wh2o_b;
    2866             :   double res;
    2867           0 :   Length wh2o_retrieved(-999.0, Length::UnitMilliMeter);
    2868           0 :   Length werr(-888, Length::UnitMilliMeter);
    2869           0 :   Temperature sigma_fit_temp0;
    2870           0 :   Temperature t_astro;
    2871           0 :   Length sigma_wh2o;
    2872             : 
    2873           0 :   num = 0;
    2874             : 
    2875           0 :   flamda = 0.001;
    2876             : 
    2877           0 :   pfit_wh2o = (getUserWH2O().get(Length::UnitMilliMeter)) / (getGroundWH2O().get(Length::UnitMilliMeter));
    2878             : 
    2879             :   //    cout << "pfit_wh2o=" << pfit_wh2o << endl;
    2880             : 
    2881           0 :   for(unsigned int kite = 0; kite < niter; kite++) {
    2882             : 
    2883           0 :     num = num + 1;
    2884             : 
    2885           0 :     beta = 0.0;
    2886           0 :     alpha = 0.0;
    2887             : 
    2888           0 :     for(unsigned int i = 0; i < IdChannels.size(); i++) {
    2889             : 
    2890           0 :       tebb_fit[i] = RT(pfit_wh2o,
    2891           0 :                        skyCoupling[i],
    2892             :                        tspill,
    2893             :                        airm,
    2894           0 :                        IdChannels[i],
    2895           0 :                        signalGain[i]);
    2896             :       // cout << i << " " << tebb_fit[i] << endl;
    2897             : 
    2898             : 
    2899           0 :       f1 = tebb_fit[i];
    2900           0 :       psave = pfit_wh2o;
    2901           0 :       pfit_wh2o = pfit_wh2o + deltaa;
    2902           0 :       f2 = RT(pfit_wh2o,
    2903           0 :               skyCoupling[i],
    2904             :               tspill,
    2905             :               airm,
    2906           0 :               IdChannels[i],
    2907           0 :               signalGain[i]);
    2908           0 :       deriv = (f2 - f1) / deltaa;
    2909           0 :       pfit_wh2o = psave;
    2910           0 :       beta = beta + (measuredSkyBrightnessVector[i].get(Temperature::UnitKelvin) - tebb_fit[i])
    2911           0 :           * deriv;
    2912             : 
    2913           0 :       alpha = alpha + deriv * deriv;
    2914             : 
    2915             :     }
    2916             : 
    2917           0 :     chisq1 = 0;
    2918           0 :     for(unsigned int i = 0; i < measuredSkyBrightnessVector.size(); i++) {
    2919           0 :       res = -tebb_fit[i] + measuredSkyBrightnessVector[i].get(Temperature::UnitKelvin);
    2920           0 :       chisq1 = chisq1 + res * res;
    2921             :     }
    2922           0 :     if(measuredSkyBrightnessVector.size() > 1) {
    2923           0 :       chisq1 = chisq1 / (measuredSkyBrightnessVector.size() - 1);
    2924             :     }
    2925             : 
    2926           0 :     adjust: array = 1.0 / (1.0 + flamda);
    2927           0 :     pfit_wh2o_b = pfit_wh2o;
    2928           0 :     pfit_wh2o_b = pfit_wh2o_b + beta * array / alpha;
    2929           0 :     if(pfit_wh2o_b < 0.0) pfit_wh2o_b = 0.9 * pfit_wh2o;
    2930             : 
    2931           0 :     for(unsigned int i = 0; i < IdChannels.size(); i++) {
    2932             : 
    2933           0 :       tebb_fit[i] = RT(pfit_wh2o_b,
    2934           0 :                        skyCoupling[i],
    2935             :                        tspill,
    2936             :                        airm,
    2937           0 :                        IdChannels[i],
    2938           0 :                        signalGain[i]);
    2939             : 
    2940             :     }
    2941             : 
    2942           0 :     chisqr = 0;
    2943           0 :     for(unsigned int i = 0; i < IdChannels.size(); i++) {
    2944           0 :       res = -tebb_fit[i] + measuredSkyBrightnessVector[i].get(Temperature::UnitKelvin);
    2945           0 :       chisqr = chisqr + res * res;
    2946             :     }
    2947           0 :     if(IdChannels.size() > 1) {
    2948           0 :       chisqr = chisqr / (IdChannels.size() - 1);
    2949             :     }
    2950             : 
    2951           0 :     if(fabs(chisq1 - chisqr) > 0.001) {
    2952           0 :       if(chisq1 < chisqr) {
    2953           0 :         flamda = flamda * 10.0;
    2954           0 :         goto adjust;
    2955             :       }
    2956             :     }
    2957             : 
    2958           0 :     flamda = flamda / 10.0;
    2959           0 :     sig_fit = sqrt(chisqr);
    2960           0 :     pfit_wh2o = pfit_wh2o_b;
    2961           0 :     sigma_wh2o = Length(sqrt(array / alpha) * sig_fit * pfit_wh2o
    2962           0 :         * (getGroundWH2O().get(Length::UnitMilliMeter)), Length::UnitMilliMeter);
    2963             : 
    2964           0 :     if(fabs(sqrt(chisq1) - sqrt(chisqr)) < eps) {
    2965             : 
    2966           0 :       sigma_fit_temp0 = Temperature(sig_fit, Temperature::UnitKelvin);
    2967             : 
    2968           0 :       wh2o_retrieved = Length(pfit_wh2o * getGroundWH2O().get(Length::UnitMilliMeter), Length::UnitMilliMeter);
    2969             : 
    2970           0 :       goto salir;
    2971             : 
    2972             :     }
    2973             : 
    2974             :   }
    2975             : 
    2976           0 :   wh2o_retrieved = werr; // Extra error code, fit not reached after 20 iterations
    2977           0 :   sigma_fit_temp0 = Temperature(sig_fit, Temperature::UnitKelvin); // Extra error code, fit not reached after 20 iterations
    2978           0 :   sigma_wh2o = werr; // Extra error code, fit not reached after 20 iterations
    2979             : 
    2980           0 :   salir:
    2981             : 
    2982           0 :   vector<Temperature> ttt;
    2983             : 
    2984           0 :   for(unsigned int i = 0; i < IdChannels.size(); i++) {
    2985           0 :     ttt.push_back(Temperature(tebb_fit[i], Temperature::UnitKelvin));
    2986             :   }
    2987             : 
    2988           0 :   if(wh2o_retrieved.get() > 0.0) {
    2989           0 :     wh2o_user_ = wh2o_retrieved;
    2990             :   }
    2991             :   return WVRMeasurement(elevation,
    2992             :                         measuredSkyBrightnessVector,
    2993             :                         ttt,
    2994             :                         wh2o_retrieved,
    2995           0 :                         sigma_fit_temp0);
    2996             : 
    2997             : }
    2998             : 
    2999           0 : void SkyStatus::WaterVaporRetrieval_fromWVR(vector<WVRMeasurement> &RadiometerData,
    3000             :                                             unsigned int n,
    3001             :                                             unsigned int m)
    3002             : {
    3003             : 
    3004           0 :   for(unsigned int i = n; i < m; i++) {
    3005             : 
    3006           0 :     WaterVaporRetrieval_fromWVR(RadiometerData[i]);
    3007             : 
    3008             :   }
    3009             : 
    3010           0 : }
    3011             : 
    3012           0 : void SkyStatus::WaterVaporRetrieval_fromWVR(WVRMeasurement &RadiometerData)
    3013             : {
    3014             : 
    3015           0 :   WVRMeasurement RadiometerData_withRetrieval;
    3016             : 
    3017             :   //    cout << waterVaporRadiometer_.getIdChannels().size() << endl;
    3018             :   //    cout << RadiometerData.getmeasuredSkyBrightness()[0].get(Temperature::UnitKelvin) << " K" << endl;
    3019             :   //    cout << waterVaporRadiometer_.getIdChannels()[1] << endl;
    3020             :   //    cout << getAssocSpwIds(waterVaporRadiometer_.getIdChannels())[1] << endl;
    3021             : 
    3022             : 
    3023             :   //    cout << "zz=" << waterVaporRadiometer_.getIdChannels().size() << endl;
    3024             : 
    3025             :   RadiometerData_withRetrieval
    3026           0 :       = mkWaterVaporRetrieval_fromWVR(RadiometerData.getmeasuredSkyBrightness(),
    3027           0 :                                       waterVaporRadiometer_.getIdChannels(),
    3028           0 :                                       waterVaporRadiometer_.getSkyCoupling(),
    3029           0 :                                       waterVaporRadiometer_.getsignalGain(),
    3030           0 :                                       waterVaporRadiometer_.getSpilloverTemperature(),
    3031           0 :                                       RadiometerData.getElevation());
    3032             : 
    3033             :   // cout << "_fromWVR Sky Coupling = " <<  waterVaporRadiometer_.getSkyCoupling()[0] << endl;
    3034             :   // cout << "Signal Gain = " << waterVaporRadiometer_.getsignalGain()[0].get(Percent::UnitPercent) << " %" <<  endl;
    3035             :   // cout << "Spillover Temp. = " << waterVaporRadiometer_.getSpilloverTemperature().get(Temperature::UnitKelvin) << " K" << endl;
    3036             :   // cout << "Elevation = " << RadiometerData.getElevation().get(Angle::UnitDegree) << endl;
    3037             :   // cout << "PWV=" << RadiometerData_withRetrieval.getretrievedWaterVaporColumn().get(Length::UnitMilliMeter) << " mm" << endl;
    3038             : 
    3039           0 :   RadiometerData.setretrievedWaterVaporColumn(RadiometerData_withRetrieval.getretrievedWaterVaporColumn());
    3040           0 :   RadiometerData.setfittedSkyBrightness(RadiometerData_withRetrieval.getfittedSkyBrightness());
    3041           0 :   RadiometerData.setSigmaFit(RadiometerData_withRetrieval.getSigmaFit());
    3042             : 
    3043           0 : }
    3044             : 
    3045           0 : void SkyStatus::updateSkyCoupling_fromWVR(vector<WVRMeasurement> &RadiometerData,
    3046             :                                           unsigned int n,
    3047             :                                           unsigned int m)
    3048             : {
    3049             :   double pfit;
    3050           0 :   double deltaa = 0.02;
    3051             :   // double sig_fit = -999.0; // [-Wunused_but_set_variable]
    3052           0 :   double eps = 0.01;
    3053             : 
    3054             :   unsigned int num;
    3055             :   double flamda;
    3056           0 :   unsigned int niter = 20;
    3057             :   double alpha;
    3058             :   double beta;
    3059             :   double array;
    3060             :   double f1;
    3061             :   double psave;
    3062             :   double f2;
    3063             :   double deriv;
    3064             :   double chisq1;
    3065             :   double chisqr;
    3066             :   double pfit_b;
    3067             :   double res;
    3068             : 
    3069           0 :   num = 0;
    3070             : 
    3071           0 :   flamda = 0.001;
    3072           0 :   pfit = 0.5;
    3073             : 
    3074             :   // Find the maximum of skycoupling on the WVR channels
    3075             :   // This value is used to assure that the found skycoupling does not exceed 1
    3076           0 :   double maxCoupling =0.;
    3077           0 :   for (unsigned int i=0; i<waterVaporRadiometer_.getSkyCoupling().size(); i++)
    3078           0 :     if (waterVaporRadiometer_.getSkyCoupling()[i]>maxCoupling)
    3079           0 :       maxCoupling = waterVaporRadiometer_.getSkyCoupling()[i];
    3080             : 
    3081             : 
    3082           0 :   for(unsigned int kite = 0; kite < niter; kite++) {
    3083             : 
    3084           0 :     num = num + 1;
    3085           0 :     beta = 0.0;
    3086           0 :     alpha = 0.0;
    3087             : 
    3088           0 :     if (pfit*maxCoupling>1.5)
    3089           0 :       pfit = 1.-deltaa;
    3090           0 :     f1 = sigmaSkyCouplingRetrieval_fromWVR(pfit,
    3091           0 :                                            waterVaporRadiometer_,
    3092             :                                            RadiometerData,
    3093             :                                            n,
    3094             :                                            m);
    3095           0 :     psave = pfit;
    3096           0 :     pfit = pfit + deltaa;
    3097           0 :     f2 = sigmaSkyCouplingRetrieval_fromWVR(pfit,
    3098           0 :                                            waterVaporRadiometer_,
    3099             :                                            RadiometerData,
    3100             :                                            n,
    3101             :                                            m);
    3102           0 :     deriv = (f2 - f1) / deltaa;
    3103           0 :     pfit = psave;
    3104           0 :     beta = beta - f1 * deriv;
    3105           0 :     alpha = alpha + deriv * deriv;
    3106           0 :     chisq1 = f1 * f1;
    3107             : 
    3108           0 :     adjust: array = 1.0 / (1.0 + flamda);
    3109           0 :     pfit_b = pfit;
    3110           0 :     pfit_b = pfit_b + beta * array / alpha;
    3111             : 
    3112           0 :     chisqr = 0.;
    3113             : 
    3114           0 :     if(pfit_b < 0.0) {
    3115           0 :       pfit_b = 0.9 * pfit;
    3116             :     }
    3117           0 :     if (pfit_b*maxCoupling>1.5)
    3118           0 :       pfit_b = 1;
    3119             : 
    3120           0 :     res = sigmaSkyCouplingRetrieval_fromWVR(pfit_b,
    3121           0 :                                             waterVaporRadiometer_,
    3122             :                                             RadiometerData,
    3123             :                                             n,
    3124             :                                             m);
    3125           0 :     chisqr = chisqr + res * res;
    3126             : 
    3127           0 :     if(fabs(chisq1 - chisqr) > 0.001) {
    3128           0 :       if(chisq1 < chisqr) {
    3129           0 :         flamda = flamda * 10.0;
    3130           0 :         goto adjust;
    3131             :       }
    3132             :     }
    3133             : 
    3134           0 :     flamda = flamda / 10.0;
    3135             :     // sig_fit = sqrt(chisqr); // [-Wunused_but_set_variable]
    3136           0 :     pfit = pfit_b;
    3137             : 
    3138           0 :     if(fabs(sqrt(chisq1) - sqrt(chisqr)) < eps) {
    3139           0 :       goto salir;
    3140             :     }
    3141             : 
    3142             :   }
    3143             : 
    3144           0 :   salir: waterVaporRadiometer_.multiplySkyCoupling(pfit);
    3145             : 
    3146             :   //    cout << "pfit=" << pfit << "  sky_coupling: " << waterVaporRadiometer_.getSkyCoupling()[0]   << endl;
    3147             : 
    3148             : 
    3149           0 : }
    3150           0 : void SkyStatus::updateSkyCouplingChannel_fromWVR(vector<WVRMeasurement> &RadiometerData,
    3151             :                                                  unsigned int ichan,
    3152             :                                                  unsigned int n,
    3153             :                                                  unsigned int m)
    3154             : {
    3155             :   double pfit;
    3156           0 :   double deltaa = 0.02;
    3157             :   // double sig_fit = -999.0;    // [-Wunused_but_set_variable]
    3158           0 :   double eps = 0.01;
    3159             : 
    3160             :   unsigned int num;
    3161             :   double flamda;
    3162           0 :   unsigned int niter = 20;
    3163             :   double alpha;
    3164             :   double beta;
    3165             :   double array;
    3166             :   double f1;
    3167             :   double psave;
    3168             :   double f2;
    3169             :   double deriv;
    3170             :   double chisq1;
    3171             :   double chisqr;
    3172             :   double pfit_b;
    3173             :   double res;
    3174             : 
    3175           0 :   num = 0;
    3176             : 
    3177           0 :   flamda = 0.001;
    3178           0 :   pfit = 1.00;
    3179             : 
    3180             :   // This value is used to assure that the found skycoupling does not exceed 1
    3181           0 :   double maxCoupling = waterVaporRadiometer_.getSkyCoupling()[ichan];
    3182             : 
    3183             : 
    3184           0 :   for(unsigned int kite = 0; kite < niter; kite++) {
    3185             : 
    3186           0 :     num = num + 1;
    3187           0 :     beta = 0.0;
    3188           0 :     alpha = 0.0;
    3189             : 
    3190           0 :     if (pfit*maxCoupling>1)
    3191           0 :       pfit = 1.-deltaa;
    3192           0 :     f1 = sigmaSkyCouplingChannelRetrieval_fromWVR(pfit,
    3193           0 :                                                   waterVaporRadiometer_,
    3194             :                                                   RadiometerData,
    3195             :                                                   ichan,
    3196             :                                                   n,
    3197             :                                                   m);
    3198           0 :     psave = pfit;
    3199           0 :     pfit = pfit + deltaa;
    3200           0 :     f2 = sigmaSkyCouplingChannelRetrieval_fromWVR(pfit,
    3201           0 :                                                   waterVaporRadiometer_,
    3202             :                                                   RadiometerData,
    3203             :                                                   ichan,
    3204             :                                                   n,
    3205             :                                                   m);
    3206           0 :     deriv = (f2 - f1) / deltaa;
    3207           0 :     pfit = psave;
    3208           0 :     beta = beta - f1 * deriv;
    3209           0 :     alpha = alpha + deriv * deriv;
    3210           0 :     chisq1 = f1 * f1;
    3211             : 
    3212           0 :     adjust: array = 1.0 / (1.0 + flamda);
    3213           0 :     pfit_b = pfit;
    3214           0 :     pfit_b = pfit_b + beta * array / alpha;
    3215             : 
    3216           0 :     chisqr = 0.;
    3217             : 
    3218           0 :     if(pfit_b < 0.0) {
    3219           0 :       pfit_b = 0.9 * pfit;
    3220             :     }
    3221           0 :     if (pfit_b*maxCoupling>1)
    3222           0 :       pfit_b = 1/maxCoupling;
    3223             : 
    3224           0 :     res = sigmaSkyCouplingChannelRetrieval_fromWVR(pfit_b,
    3225           0 :                                                    waterVaporRadiometer_,
    3226             :                                                    RadiometerData,
    3227             :                                                    ichan,
    3228             :                                                    n,
    3229             :                                                    m);
    3230           0 :     chisqr = chisqr + res * res;
    3231             : 
    3232           0 :     if(fabs(chisq1 - chisqr) > 0.001) {
    3233           0 :       if(chisq1 < chisqr) {
    3234           0 :         flamda = flamda * 10.0;
    3235           0 :         goto adjust;
    3236             :       }
    3237             :     }
    3238             : 
    3239           0 :     flamda = flamda / 10.0;
    3240             :     // sig_fit = sqrt(chisqr);   // [-Wunused_but_set_variable]
    3241           0 :     pfit = pfit_b;
    3242             : 
    3243           0 :     if(fabs(sqrt(chisq1) - sqrt(chisqr)) < eps) {
    3244           0 :       goto salir;
    3245             :     }
    3246             : 
    3247             :   }
    3248             : 
    3249           0 :  salir: waterVaporRadiometer_.multiplySkyCouplingChannel(ichan, pfit);
    3250             : 
    3251             :   //    cout << "pfit=" << pfit << "  sky_coupling: " << waterVaporRadiometer_.getSkyCoupling()[0]   << endl;
    3252             : 
    3253             : 
    3254           0 : }
    3255             : 
    3256           0 : double SkyStatus::sigmaSkyCouplingRetrieval_fromWVR(double par_fit,
    3257             :                                                     const WaterVaporRadiometer &wvr,
    3258             :                                                     vector<WVRMeasurement> &RadiometerData,
    3259             :                                                     unsigned int n,
    3260             :                                                     unsigned int m)
    3261             : {
    3262             : 
    3263           0 :   vector<double> skyCoupling = wvr.getSkyCoupling();
    3264             : 
    3265           0 :   for(unsigned int i = 0; i < skyCoupling.size(); i++) {
    3266           0 :     skyCoupling[i] = skyCoupling[i] * par_fit;
    3267             :   }
    3268             : 
    3269           0 :   WVRMeasurement RadiometerData_withRetrieval;
    3270             : 
    3271           0 :   for(unsigned int i = n; i < m; i++) {
    3272             : 
    3273             :     RadiometerData_withRetrieval
    3274           0 :         = mkWaterVaporRetrieval_fromWVR(RadiometerData[i].getmeasuredSkyBrightness(),
    3275           0 :                                         wvr.getIdChannels(),
    3276             :                                         skyCoupling,
    3277           0 :                                         wvr.getsignalGain(),
    3278           0 :                                         wvr.getSpilloverTemperature(),
    3279           0 :                                         RadiometerData[i].getElevation());
    3280             : 
    3281           0 :     RadiometerData[i].setretrievedWaterVaporColumn(RadiometerData_withRetrieval.getretrievedWaterVaporColumn());
    3282           0 :     RadiometerData[i].setfittedSkyBrightness(RadiometerData_withRetrieval.getfittedSkyBrightness());
    3283           0 :     RadiometerData[i].setSigmaFit(RadiometerData_withRetrieval.getSigmaFit());
    3284             : 
    3285             :   }
    3286             : 
    3287           0 :   return getWVRAverageSigmaTskyFit(RadiometerData, n, m).get(Temperature::UnitKelvin);
    3288             : 
    3289             : }
    3290             : 
    3291           0 : double SkyStatus::sigmaSkyCouplingChannelRetrieval_fromWVR(double par_fit,
    3292             :                                                            const WaterVaporRadiometer &wvr,
    3293             :                                                            vector<WVRMeasurement> &RadiometerData,
    3294             :                                                            unsigned int ichan,
    3295             :                                                            unsigned int n,
    3296             :                                                            unsigned int m)
    3297             : {
    3298             : 
    3299           0 :   vector<double> skyCoupling = wvr.getSkyCoupling();
    3300             : 
    3301             :   //for(unsigned int i = 0; i < skyCoupling.size(); i++) {
    3302           0 :   skyCoupling[ichan] = skyCoupling[ichan] * par_fit;
    3303             :     //}
    3304             : 
    3305           0 :   WVRMeasurement RadiometerData_withRetrieval;
    3306             : 
    3307           0 :   for(unsigned int i = n; i < m; i++) {
    3308             : 
    3309             :     RadiometerData_withRetrieval
    3310           0 :         = mkWaterVaporRetrieval_fromWVR(RadiometerData[i].getmeasuredSkyBrightness(),
    3311           0 :                                         wvr.getIdChannels(),
    3312             :                                         skyCoupling,
    3313           0 :                                         wvr.getsignalGain(),
    3314           0 :                                         wvr.getSpilloverTemperature(),
    3315           0 :                                         RadiometerData[i].getElevation());
    3316             : 
    3317           0 :     RadiometerData[i].setretrievedWaterVaporColumn(RadiometerData_withRetrieval.getretrievedWaterVaporColumn());
    3318           0 :     RadiometerData[i].setfittedSkyBrightness(RadiometerData_withRetrieval.getfittedSkyBrightness());
    3319           0 :     RadiometerData[i].setSigmaFit(RadiometerData_withRetrieval.getSigmaFit());
    3320             : 
    3321             :   }
    3322             : 
    3323           0 :   return getWVRAverageSigmaTskyFit(RadiometerData, n, m).get(Temperature::UnitKelvin);
    3324             :   // return getWVRSigmaChannelTskyFit(RadiometerData, ichan, n, m).get(Temperature::UnitKelvin);
    3325             : 
    3326             : }
    3327             : 
    3328        1112 : void SkyStatus::rmSkyStatus()
    3329             : {
    3330             : 
    3331             :   /* CODE À ÉCRIRE */
    3332             : 
    3333        1112 : }
    3334             : ATM_NAMESPACE_END
    3335             : 

Generated by: LCOV version 1.16