diff --git a/kstars/ekos/capture/capture.cpp b/kstars/ekos/capture/capture.cpp
index d38b41fe4..fb39b02f2 100644
--- a/kstars/ekos/capture/capture.cpp
+++ b/kstars/ekos/capture/capture.cpp
@@ -1,5715 +1,5794 @@
 /*  Ekos
     Copyright (C) 2012 Jasem Mutlaq <mutlaqja@ikarustech.com>
 
     This application is free software; you can redistribute it and/or
     modify it under the terms of the GNU General Public
     License as published by the Free Software Foundation; either
     version 2 of the License, or (at your option) any later version.
  */
 
 #include "capture.h"
 
 #include "captureadaptor.h"
 #include "dslrinfodialog.h"
 #include "kstars.h"
 #include "kstarsdata.h"
 #include "Options.h"
 #include "rotatorsettings.h"
 #include "sequencejob.h"
 #include "skymap.h"
 #include "ui_calibrationoptions.h"
 #include "auxiliary/QProgressIndicator.h"
 #include "ekos/manager.h"
 #include "ekos/auxiliary/darklibrary.h"
 #include "fitsviewer/fitsdata.h"
 #include "fitsviewer/fitsview.h"
 #include "indi/driverinfo.h"
 #include "indi/indifilter.h"
 #include "indi/clientmanager.h"
 #include "oal/observeradd.h"
 
 #include <basedevice.h>
 
 #include <ekos_capture_debug.h>
 
 #define MF_TIMER_TIMEOUT    90000
 #define GD_TIMER_TIMEOUT    60000
 #define MF_RA_DIFF_LIMIT    4
 
 // Wait 3-minutes as maximum beyond exposure
 // value.
 #define CAPTURE_TIMEOUT_THRESHOLD  180000
 
 // Current Sequence File Format:
 #define SQ_FORMAT_VERSION 2.0
 // We accept file formats with version back to:
 #define SQ_COMPAT_VERSION 2.0
 
 namespace Ekos
 {
 Capture::Capture()
 {
     setupUi(this);
 
     qRegisterMetaType<Ekos::CaptureState>("Ekos::CaptureState");
     qDBusRegisterMetaType<Ekos::CaptureState>();
 
     new CaptureAdaptor(this);
     QDBusConnection::sessionBus().registerObject("/KStars/Ekos/Capture", this);
 
     KStarsData::Instance()->userdb()->GetAllDSLRInfos(DSLRInfos);
 
     dirPath = QUrl::fromLocalFile(QDir::homePath());
 
     //isAutoGuiding   = false;
 
     rotatorSettings.reset(new RotatorSettings(this));
 
     pi = new QProgressIndicator(this);
 
     progressLayout->addWidget(pi, 0, 4, 1, 1);
 
     seqFileCount = 0;
     //seqWatcher		= new KDirWatch();
     seqTimer = new QTimer(this);
     connect(seqTimer, &QTimer::timeout, this, &Ekos::Capture::captureImage);
 
     connect(startB, &QPushButton::clicked, this, &Ekos::Capture::toggleSequence);
     connect(pauseB, &QPushButton::clicked, this, &Ekos::Capture::pause);
 
     startB->setIcon(QIcon::fromTheme("media-playback-start"));
     startB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     pauseB->setIcon(QIcon::fromTheme("media-playback-pause"));
     pauseB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
 
     filterManagerB->setIcon(QIcon::fromTheme("view-filter"));
     filterManagerB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
 
     FilterDevicesCombo->addItem("--");
 
     connect(binXIN, static_cast<void (QSpinBox::*)(int)>(&QSpinBox::valueChanged), binYIN, &QSpinBox::setValue);
 
     connect(CCDCaptureCombo, static_cast<void (QComboBox::*)(const QString&)>(&QComboBox::activated), this, &Ekos::Capture::setDefaultCCD);
     connect(CCDCaptureCombo, static_cast<void (QComboBox::*)(int)>(&QComboBox::activated), this, &Ekos::Capture::checkCCD);
 
     connect(liveVideoB, &QPushButton::clicked, this, &Ekos::Capture::toggleVideo);
 
     guideDeviationTimer.setInterval(GD_TIMER_TIMEOUT);
     connect(&guideDeviationTimer, &QTimer::timeout, this, &Ekos::Capture::checkGuideDeviationTimeout);
 
     connect(clearConfigurationB, &QPushButton::clicked, this, &Ekos::Capture::clearCameraConfiguration);
 
     connect(FilterDevicesCombo, static_cast<void (QComboBox::*)(int)>(&QComboBox::activated), this, &Ekos::Capture::checkFilter);
 
     connect(temperatureCheck, &QCheckBox::toggled, [this](bool toggled)
     {
         if (currentCCD)
         {
             QVariantMap auxInfo = currentCCD->getDriverInfo()->getAuxInfo();
             auxInfo[QString("%1_TC").arg(currentCCD->getDeviceName())] = toggled;
             currentCCD->getDriverInfo()->setAuxInfo(auxInfo);
         }
     });
 
     connect(FilterPosCombo, static_cast<void(QComboBox::*)(const QString &)>(&QComboBox::currentIndexChanged),
             [=]()
     {
         updateHFRThreshold();
     });
     connect(previewB, &QPushButton::clicked, this, &Ekos::Capture::captureOne);
 
     //connect( seqWatcher, SIGNAL(dirty(QString)), this, &Ekos::Capture::checkSeqFile(QString)));
 
     connect(addToQueueB, &QPushButton::clicked, this, &Ekos::Capture::addJob);
     connect(removeFromQueueB, &QPushButton::clicked, this, &Ekos::Capture::removeJob);
     connect(queueUpB, &QPushButton::clicked, this, &Ekos::Capture::moveJobUp);
     connect(queueDownB, &QPushButton::clicked, this, &Ekos::Capture::moveJobDown);
     connect(selectFITSDirB, &QPushButton::clicked, this, &Ekos::Capture::saveFITSDirectory);
     connect(queueSaveB, &QPushButton::clicked, this, static_cast<void(Ekos::Capture::*)()>(&Ekos::Capture::saveSequenceQueue));
     connect(queueSaveAsB, &QPushButton::clicked, this, &Ekos::Capture::saveSequenceQueueAs);
     connect(queueLoadB, &QPushButton::clicked, this, static_cast<void(Ekos::Capture::*)()>(&Ekos::Capture::loadSequenceQueue));
     connect(resetB, &QPushButton::clicked, this, &Ekos::Capture::resetJobs);
     connect(queueTable, &QAbstractItemView::doubleClicked, this, &Ekos::Capture::editJob);
     connect(queueTable, &QTableWidget::itemSelectionChanged, this, &Ekos::Capture::resetJobEdit);
     connect(setTemperatureB, &QPushButton::clicked, [&]() {
         if (currentCCD)
             currentCCD->setTemperature(temperatureIN->value());
     });
     connect(coolerOnB, &QPushButton::clicked, [&]() {
         if (currentCCD)
             currentCCD->setCoolerControl(true);
     });
     connect(coolerOffB, &QPushButton::clicked, [&]() {
         if (currentCCD)
             currentCCD->setCoolerControl(false);
     });
     connect(temperatureIN, &QDoubleSpinBox::editingFinished, setTemperatureB, static_cast<void (QPushButton::*)()>(&QPushButton::setFocus));
     connect(frameTypeCombo, static_cast<void (QComboBox::*)(int)>(&QComboBox::activated), this, &Ekos::Capture::checkFrameType);
     connect(resetFrameB, &QPushButton::clicked, this, &Ekos::Capture::resetFrame);
     connect(calibrationB, &QPushButton::clicked, this, &Ekos::Capture::openCalibrationDialog);
     connect(rotatorB, &QPushButton::clicked, rotatorSettings.get(), &Ekos::Capture::show);
 
     addToQueueB->setIcon(QIcon::fromTheme("list-add"));
     addToQueueB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     removeFromQueueB->setIcon(QIcon::fromTheme("list-remove"));
     removeFromQueueB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     queueUpB->setIcon(QIcon::fromTheme("go-up"));
     queueUpB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     queueDownB->setIcon(QIcon::fromTheme("go-down"));
     queueDownB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     selectFITSDirB->setIcon(
                 QIcon::fromTheme("document-open-folder"));
     selectFITSDirB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     queueLoadB->setIcon(QIcon::fromTheme("document-open"));
     queueLoadB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     queueSaveB->setIcon(QIcon::fromTheme("document-save"));
     queueSaveB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     queueSaveAsB->setIcon(QIcon::fromTheme("document-save-as"));
     queueSaveAsB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     resetB->setIcon(QIcon::fromTheme("system-reboot"));
     resetB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     resetFrameB->setIcon(QIcon::fromTheme("view-refresh"));
     resetFrameB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     calibrationB->setIcon(QIcon::fromTheme("run-build"));
     calibrationB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     rotatorB->setIcon(QIcon::fromTheme("kstars_solarsystem"));
     rotatorB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
 
     addToQueueB->setToolTip(i18n("Add job to sequence queue"));
     removeFromQueueB->setToolTip(i18n("Remove job from sequence queue"));
 
     fitsDir->setText(Options::fitsDir());
 
     for (auto &filter : FITSViewer::filterTypes)
         filterCombo->addItem(filter);
 
     guideDeviationCheck->setChecked(Options::enforceGuideDeviation());
     guideDeviation->setValue(Options::guideDeviation());
     autofocusCheck->setChecked(Options::enforceAutofocus());
     refocusEveryNCheck->setChecked(Options::enforceRefocusEveryN());
-    meridianCheck->setChecked(Options::autoMeridianFlip());    
+    meridianCheck->setChecked(Options::autoMeridianFlip());
     meridianHours->setValue(Options::autoMeridianHours());
 
     QCheckBox * const checkBoxes[] = {
         guideDeviationCheck,
         refocusEveryNCheck,
         guideDeviationCheck,
         meridianCheck
     };
     for (const QCheckBox* control : checkBoxes)
         connect(control, &QCheckBox::toggled, this, &Ekos::Capture::setDirty);
 
     QDoubleSpinBox *const dspinBoxes[] {
         HFRPixels,
         guideDeviation,
         meridianHours
     };
     for (const QDoubleSpinBox *control : dspinBoxes)
        connect(control, static_cast<void (QDoubleSpinBox::*)(double)>(&QDoubleSpinBox::valueChanged), this, &Ekos::Capture::setDirty);
 
     connect(uploadModeCombo, static_cast<void (QComboBox::*)(int)>(&QComboBox::activated), this, &Ekos::Capture::setDirty);
     connect(remoteDirIN, &QLineEdit::editingFinished, this, &Ekos::Capture::setDirty);
 
     m_ObserverName = Options::defaultObserver();
     observerB->setIcon(QIcon::fromTheme("im-user"));
     observerB->setAttribute(Qt::WA_LayoutUsesWidgetRect);
     connect(observerB, &QPushButton::clicked, this, &Ekos::Capture::showObserverDialog);
 
     // Exposure Timeout
     captureTimeout.setSingleShot(true);
     connect(&captureTimeout, &QTimer::timeout, this, &Ekos::Capture::processCaptureTimeout);
 
     // Post capture script
     connect(&postCaptureScript, static_cast<void (QProcess::*)(int exitCode)>(&QProcess::finished), this, &Ekos::Capture::postScriptFinished);
 
     // Remote directory
     connect(uploadModeCombo, static_cast<void (QComboBox::*)(int)>(&QComboBox::activated), this,
             [&](int index) { remoteDirIN->setEnabled(index != 0); });
 
     customPropertiesDialog.reset(new CustomProperties());
     connect(customValuesB, &QPushButton::clicked, customPropertiesDialog.get(), &Ekos::Capture::show);
 
     flatFieldSource = static_cast<FlatFieldSource>(Options::calibrationFlatSourceIndex());
     flatFieldDuration = static_cast<FlatFieldDuration>(Options::calibrationFlatDurationIndex());
     wallCoord.setAz(Options::calibrationWallAz());
     wallCoord.setAlt(Options::calibrationWallAlt());
     targetADU = Options::calibrationADUValue();
     targetADUTolerance = Options::calibrationADUValueTolerance();
 
     fitsDir->setText(Options::captureDirectory());
     connect(fitsDir, &QLineEdit::textChanged, [&]() { Options::setCaptureDirectory(fitsDir->text());});
 
     // Keep track of TARGET transfer format when changing CCDs (FITS or NATIVE). Actual format is not changed until capture
     connect(
                 transferFormatCombo, static_cast<void (QComboBox::*)(int)>(&QComboBox::activated), this,
                 [&](int index)
     {
         if (currentCCD)
             currentCCD->setTargetTransferFormat(static_cast<ISD::CCD::TransferFormat>(index));
         Options::setCaptureFormatIndex(index);
     });
 
     // Load FIlter Offets
     //loadFilterOffsets();
 
     //Note:  This is to prevent a button from being called the default button
     //and then executing when the user hits the enter key such as when on a Text Box
     QList<QPushButton *> qButtons = findChildren<QPushButton *>();
     for (auto &button : qButtons)
         button->setAutoDefault(false);
 }
 
 Capture::~Capture()
 {
     qDeleteAll(jobs);
 }
 
 void Capture::setDefaultCCD(QString ccd)
 {
     Options::setDefaultCaptureCCD(ccd);
 }
 
 void Capture::addCCD(ISD::GDInterface *newCCD)
 {
     ISD::CCD *ccd = static_cast<ISD::CCD *>(newCCD);
 
     if (CCDs.contains(ccd))
         return;
 
     CCDs.append(ccd);
 
     CCDCaptureCombo->addItem(ccd->getDeviceName());
 
     if (Filters.count() > 0)
         syncFilterInfo();
 
     checkCCD();
 }
 
 void Capture::addGuideHead(ISD::GDInterface *newCCD)
 {
     QString guiderName = newCCD->getDeviceName() + QString(" Guider");
 
     if (CCDCaptureCombo->findText(guiderName) == -1)
     {
         CCDCaptureCombo->addItem(guiderName);
         CCDs.append(static_cast<ISD::CCD *>(newCCD));
     }
 }
 
 void Capture::addFilter(ISD::GDInterface *newFilter)
 {
     foreach (ISD::GDInterface *filter, Filters)
     {
         if (!strcmp(filter->getDeviceName(), newFilter->getDeviceName()))
             return;
     }
 
     FilterDevicesCombo->addItem(newFilter->getDeviceName());
 
     Filters.append(static_cast<ISD::Filter *>(newFilter));
 
     filterManagerB->setEnabled(true);
 
     checkFilter(1);
 
     FilterDevicesCombo->setCurrentIndex(1);
 }
 
 void Capture::pause()
 {
     pauseFunction = nullptr;
     m_State         = CAPTURE_PAUSED;
     emit newStatus(Ekos::CAPTURE_PAUSED);
     appendLogText(i18n("Sequence shall be paused after current exposure is complete."));
     pauseB->setEnabled(false);
 
     startB->setIcon(QIcon::fromTheme("media-playback-start"));
     startB->setToolTip(i18n("Resume Sequence"));
 }
 
 void Capture::toggleSequence()
 {
     if (m_State == CAPTURE_PAUSED)
     {
         startB->setIcon(
                     QIcon::fromTheme("media-playback-stop"));
         startB->setToolTip(i18n("Stop Sequence"));
         pauseB->setEnabled(true);
 
         m_State = CAPTURE_CAPTURING;
         emit newStatus(Ekos::CAPTURE_CAPTURING);
 
         appendLogText(i18n("Sequence resumed."));
 
         // Call from where ever we have left of when we paused
         if (pauseFunction)
             (this->*pauseFunction)();
     }
     else if (m_State == CAPTURE_IDLE || m_State == CAPTURE_ABORTED || m_State == CAPTURE_COMPLETE)
     {
         start();
     }
     else
     {
         abort();
     }
 }
 
 void Capture::start()
 {
     if (darkSubCheck->isChecked())
     {
         KMessageBox::error(this, i18n("Auto dark subtract is not supported in batch mode."));
         return;
     }
 
     Options::setGuideDeviation(guideDeviation->value());
     Options::setEnforceGuideDeviation(guideDeviationCheck->isChecked());
     Options::setEnforceAutofocus(autofocusCheck->isChecked());
     Options::setEnforceRefocusEveryN(refocusEveryNCheck->isChecked());
 
     Options::setAutoMeridianFlip(meridianCheck->isChecked());
     Options::setAutoMeridianHours(meridianHours->value());
 
     // Reset progress option if there is no captured frame map set at the time of start - fixes the end-user setting the option just before starting
     ignoreJobProgress = !capturedFramesMap.count() && Options::alwaysResetSequenceWhenStarting();
 
     if (queueTable->rowCount() == 0)
     {
         if (addJob() == false)
             return;
     }
 
     SequenceJob *first_job = nullptr;
 
     foreach (SequenceJob *job, jobs)
     {
         if (job->getStatus() == SequenceJob::JOB_IDLE || job->getStatus() == SequenceJob::JOB_ABORTED)
         {
             first_job = job;
             break;
         }
     }
 
     // If there are no idle nor aborted jobs, question is whether to reset and restart
     // Scheduler will start a non-empty new job each time and doesn't use this execution path
     if (first_job == nullptr)
     {
         // If we have at least one job that are in error, bail out, even if ignoring job progress
         foreach (SequenceJob *job, jobs)
         {
             if (job->getStatus() != SequenceJob::JOB_DONE)
             {
                 appendLogText(i18n("No pending jobs found. Please add a job to the sequence queue."));
                 return;
             }
         }
 
         // If we only have completed jobs and we don't ignore job progress, ask the end-user what to do
         if (!ignoreJobProgress)
             if(KMessageBox::warningContinueCancel(
                         nullptr,
                         i18n("All jobs are complete. Do you want to reset the status of all jobs and restart capturing?"),
                         i18n("Reset job status"), KStandardGuiItem::cont(), KStandardGuiItem::cancel(),
                         "reset_job_complete_status_warning") != KMessageBox::Continue)
                 return;
 
         // If the end-user accepted to reset, reset all jobs and restart
         foreach (SequenceJob *job, jobs)
             job->resetStatus();
 
         first_job = jobs.first();
     }
     // If we need to ignore job progress, systematically reset all jobs and restart
     // Scheduler will never ignore job progress and doesn't use this path
     else if (ignoreJobProgress)
     {
         appendLogText(i18n("Warning: option \"Always Reset Sequence When Starting\" is enabled and resets the sequence counts."));
         foreach (SequenceJob *job, jobs)
             job->resetStatus();
     }
 
     // Record initialHA and initialMount position when we are starting fresh
     // If recovering from deviation error, these values should not be recorded.
     // Refocus timer should not be reset on deviation error
     if (m_DeviationDetected == false && m_State != CAPTURE_SUSPENDED)
     {
         initialHA         = getCurrentHA();
         qCDebug(KSTARS_EKOS_CAPTURE) << "Initial hour angle:" << initialHA;
         meridianFlipStage = MF_NONE;
         // Record initial mount coordinates that we may use later to perform a meridian flip
         if (currentTelescope)
         {
             double initialRA, initialDE;
             currentTelescope->getEqCoords(&initialRA, &initialDE);
             if (currentTelescope->isJ2000())
             {
                 initialMountCoords.setRA0(initialRA);
                 initialMountCoords.setDec0(initialDE);
                 initialMountCoords.apparentCoord(static_cast<long double>(J2000), KStars::Instance()->data()->ut().djd());
             }
             else
             {
                 initialMountCoords.setRA(initialRA);
                 initialMountCoords.setDec(initialDE);
             }
 
             qCDebug(KSTARS_EKOS_CAPTURE) << "Initial mount coordinates RA:" << initialMountCoords.ra().toHMSString()
                                          << "DE:" << initialMountCoords.dec().toDMSString();
         }
 
         // start timer to measure time until next forced refocus
         startRefocusEveryNTimer();
     }
 
+    // Only reset these counters if we are NOT restarting from deviation errors
+    // So when starting a new job or fresh then we reset them.
+    if (m_DeviationDetected == false)
+    {
+        ditherCounter     = Options::ditherFrames();
+        inSequenceFocusCounter = Options::inSequenceCheckFrames();
+    }
+
     m_DeviationDetected = false;
     m_SpikeDetected     = false;
 
-    ditherCounter     = Options::ditherFrames();
-    inSequenceFocusCounter = Options::inSequenceCheckFrames();
-
     m_State = CAPTURE_PROGRESS;
     emit newStatus(Ekos::CAPTURE_PROGRESS);
 
     startB->setIcon(QIcon::fromTheme("media-playback-stop"));
     startB->setToolTip(i18n("Stop Sequence"));
     pauseB->setEnabled(true);
 
     setBusy(true);
 
     if (guideDeviationCheck->isChecked() && autoGuideReady == false)
         appendLogText(i18n("Warning: Guide deviation is selected but autoguide process was not started."));
     if (autofocusCheck->isChecked() && autoFocusReady == false)
         appendLogText(i18n("Warning: in-sequence focusing is selected but autofocus process was not started."));
 
     prepareJob(first_job);
 }
 
 void Capture::stop(CaptureState targetState)
 {
     retries         = 0;
     //seqTotalCount   = 0;
     //seqCurrentCount = 0;
 
     captureTimeout.stop();
 
     ADURaw.clear();
     ExpRaw.clear();
 
     if (activeJob)
     {
         if (activeJob->getStatus() == SequenceJob::JOB_BUSY)
         {
             QString stopText;
             switch (targetState)
             {
                 case CAPTURE_IDLE:
                     stopText = i18n("CCD capture stopped");
                 break;
 
                 case CAPTURE_SUSPENDED:
                    stopText = i18n("CCD capture suspended");
                 break;
 
                default:
                 stopText = i18n("CCD capture aborted");
             break;
             }
             KSNotification::event(QLatin1String("CaptureFailed"), stopText);
             appendLogText(stopText);
             activeJob->abort();
             if (activeJob->isPreview() == false)
             {
                 int index = jobs.indexOf(activeJob);
                 QJsonObject oneSequence = m_SequenceArray[index].toObject();
                 oneSequence["Status"] = "Aborted";
                 m_SequenceArray.replace(index, oneSequence);
                 emit sequenceChanged(m_SequenceArray);
             }
             emit newStatus(targetState);
         }
 
         // In case of batch job
         if (activeJob->isPreview() == false)
         {
             activeJob->disconnect(this);
             activeJob->reset();
         }
         // or preview job in calibration stage
         else if (calibrationStage == CAL_CALIBRATION)
         {
             activeJob->disconnect(this);
             activeJob->reset();
             activeJob->setPreview(false);
             currentCCD->setUploadMode(rememberUploadMode);
         }
         // or regular preview job
         else
         {
             currentCCD->setUploadMode(rememberUploadMode);
             jobs.removeOne(activeJob);
             // Delete preview job
             delete (activeJob);
             activeJob = nullptr;
         }
     }
 
     calibrationStage = CAL_NONE;
     m_State            = targetState;
 
     // Turn off any calibration light, IF they were turned on by Capture module
     if (dustCap && dustCapLightEnabled)
     {
         dustCapLightEnabled = false;
         dustCap->SetLightEnabled(false);
     }
     if (lightBox && lightBoxLightEnabled)
     {
         lightBoxLightEnabled = false;
         lightBox->SetLightEnabled(false);
     }
 
     secondsLabel->clear();
     disconnect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Capture::newFITS);
     disconnect(currentCCD, &ISD::CCD::newExposureValue, this,  &Ekos::Capture::setExposureProgress);
     disconnect(currentCCD, &ISD::CCD::ready, this, &Ekos::Capture::ready);
 
     currentCCD->setFITSDir("");
 
     // In case of exposure looping, let's abort
     if (currentCCD->isLooping())
         targetChip->abortExposure();
 
     imgProgress->reset();
     imgProgress->setEnabled(false);
 
     fullImgCountOUT->setText(QString());
     currentImgCountOUT->setText(QString());
     exposeOUT->setText(QString());
 
     setBusy(false);
 
     if (m_State == CAPTURE_ABORTED || m_State == CAPTURE_SUSPENDED)
     {
         startB->setIcon(
                     QIcon::fromTheme("media-playback-start"));
         startB->setToolTip(i18n("Start Sequence"));
         pauseB->setEnabled(false);
     }
 
     //foreach (QAbstractButton *button, queueEditButtonGroup->buttons())
     //button->setEnabled(true);
 
     seqTimer->stop();
 
     activeJob = nullptr;
 }
 
 void Capture::sendNewImage(const QString &filename, ISD::CCDChip *myChip)
 {
     if (activeJob && (myChip == nullptr || myChip == targetChip))
     {
         emit newImage(activeJob);
         // We only emit this for client/both images since remote images already send this automatically
         if (currentCCD->getUploadMode() != ISD::CCD::UPLOAD_LOCAL && activeJob->isPreview() == false)
             emit newSequenceImage(filename);
     }
 }
 
 bool Capture::setCamera(const QString &device)
 {
     for (int i = 0; i < CCDCaptureCombo->count(); i++)
         if (device == CCDCaptureCombo->itemText(i))
         {
             CCDCaptureCombo->setCurrentIndex(i);
             checkCCD(i);
             return true;
         }
 
     return false;
 }
 
 QString Capture::camera()
 {
      if (currentCCD)
          return currentCCD->getDeviceName();
 
      return QString();
 }
 
 void Capture::checkCCD(int ccdNum)
 {
     if (ccdNum == -1)
     {
         ccdNum = CCDCaptureCombo->currentIndex();
 
         if (ccdNum == -1)
             return;
     }
 
     foreach (ISD::CCD *ccd, CCDs)
     {
         disconnect(ccd, &ISD::CCD::numberUpdated, this, &Ekos::Capture::processCCDNumber);
         disconnect(ccd, &ISD::CCD::newTemperatureValue, this, &Ekos::Capture::updateCCDTemperature);
         disconnect(ccd, &ISD::CCD::coolerToggled, this, &Ekos::Capture::setCoolerToggled);
         disconnect(ccd, &ISD::CCD::newRemoteFile, this, &Ekos::Capture::setNewRemoteFile);
         disconnect(ccd, &ISD::CCD::videoStreamToggled, this, &Ekos::Capture::setVideoStreamEnabled);
         disconnect(ccd, &ISD::CCD::ready, this, &Ekos::Capture::ready);
     }
 
     if (ccdNum <= CCDs.count())
     {
         // Check whether main camera or guide head only
         currentCCD = CCDs.at(ccdNum);
 
         if (CCDCaptureCombo->itemText(ccdNum).right(6) == QString("Guider"))
         {
             useGuideHead = true;
             targetChip   = currentCCD->getChip(ISD::CCDChip::GUIDE_CCD);
         }
         else
         {
             currentCCD   = CCDs.at(ccdNum);
             targetChip   = currentCCD->getChip(ISD::CCDChip::PRIMARY_CCD);
             useGuideHead = false;
         }
 
         if (currentCCD->hasCoolerControl())
         {
             coolerOnB->setEnabled(true);
             coolerOffB->setEnabled(true);
             coolerOnB->setChecked(currentCCD->isCoolerOn());
             coolerOffB->setChecked(!currentCCD->isCoolerOn());
         }
         else
         {
             coolerOnB->setEnabled(false);
             coolerOnB->setChecked(false);
             coolerOffB->setEnabled(false);
             coolerOffB->setChecked(false);
         }
 
 
         if (currentCCD->hasCooler())
         {
             temperatureCheck->setEnabled(true);
             temperatureIN->setEnabled(true);
 
             if (currentCCD->getBaseDevice()->getPropertyPermission("CCD_TEMPERATURE") != IP_RO)
             {
                 double min, max, step;
                 setTemperatureB->setEnabled(true);
                 temperatureIN->setReadOnly(false);
                 temperatureCheck->setEnabled(true);
                 currentCCD->getMinMaxStep("CCD_TEMPERATURE", "CCD_TEMPERATURE_VALUE", &min, &max, &step);
                 temperatureIN->setMinimum(min);
                 temperatureIN->setMaximum(max);
                 temperatureIN->setSingleStep(1);
                 bool isChecked = currentCCD->getDriverInfo()->getAuxInfo().value(QString("%1_TC").arg(currentCCD->getDeviceName()), false).toBool();
                 temperatureCheck->setChecked(isChecked);
             }
             else
             {
                 setTemperatureB->setEnabled(false);
                 temperatureIN->setReadOnly(true);
                 temperatureCheck->setEnabled(false);
                 temperatureCheck->setChecked(false);
             }
 
             double temperature = 0;
             if (currentCCD->getTemperature(&temperature))
             {
                 temperatureOUT->setText(QString("%L1").arg(temperature, 0, 'f', 2));
                 if (temperatureIN->cleanText().isEmpty())
                     temperatureIN->setValue(temperature);
             }
         }
         else
         {
             temperatureCheck->setEnabled(false);
             temperatureIN->setEnabled(false);
             temperatureIN->clear();
             temperatureOUT->clear();
             setTemperatureB->setEnabled(false);
         }
 
         updateFrameProperties();
 
         QStringList frameTypes = targetChip->getFrameTypes();
 
         frameTypeCombo->clear();
 
         if (frameTypes.isEmpty())
             frameTypeCombo->setEnabled(false);
         else
         {
             frameTypeCombo->setEnabled(true);
             frameTypeCombo->addItems(frameTypes);
             frameTypeCombo->setCurrentIndex(targetChip->getFrameType());
         }
 
         QStringList isoList = targetChip->getISOList();
         ISOCombo->clear();
 
         transferFormatCombo->blockSignals(true);
         transferFormatCombo->clear();
 
         if (isoList.isEmpty())
         {
             ISOCombo->setEnabled(false);
             ISOLabel->setEnabled(false);
             // Only one transfer format
             transferFormatCombo->addItem(i18n("FITS"));
         }
         else
         {
             ISOCombo->setEnabled(true);
             ISOLabel->setEnabled(true);
             ISOCombo->addItems(isoList);
             ISOCombo->setCurrentIndex(targetChip->getISOIndex());
 
             // DSLRs have two transfer formats
             transferFormatCombo->addItem(i18n("FITS"));
             transferFormatCombo->addItem(i18n("Native"));
 
             //transferFormatCombo->setCurrentIndex(currentCCD->getTargetTransferFormat());
             // 2018-05-07 JM: Set value to the value in options
             transferFormatCombo->setCurrentIndex(Options::captureFormatIndex());
 
             double pixelX = 0, pixelY = 0;
             bool rc = targetChip->getPixelSize(pixelX, pixelY);
             bool isModelInDB = isModelinDSLRInfo(QString(currentCCD->getDeviceName()));
             // If rc == true, then the property has been defined by the driver already
             // Only then we check if the pixels are zero
             if (rc == true && (pixelX == 0 || pixelY == 0 || isModelInDB == false))
             {
                 // If model is already in database, no need to show dialog
                 // The zeros above are the initial packets so we can safely ignore them
                 if (isModelInDB == false)
                 {
                     DSLRInfo infoDialog(this, currentCCD);
                     if (infoDialog.exec() == QDialog::Accepted)
                     {
                         addDSLRInfo(QString(currentCCD->getDeviceName()), infoDialog.sensorMaxWidth, infoDialog.sensorMaxHeight, infoDialog.sensorPixelW, infoDialog.sensorPixelH);
                     }
                 }
             }
         }
 
         transferFormatCombo->blockSignals(false);
 
         customPropertiesDialog->setCCD(currentCCD);
 
         liveVideoB->setEnabled(currentCCD->hasVideoStream());
         if (currentCCD->hasVideoStream())
             setVideoStreamEnabled(currentCCD->isStreamingEnabled());
         else
             liveVideoB->setIcon(QIcon::fromTheme("camera-off"));
 
         connect(currentCCD, &ISD::CCD::numberUpdated, this, &Ekos::Capture::processCCDNumber, Qt::UniqueConnection);
         connect(currentCCD, &ISD::CCD::newTemperatureValue, this, &Ekos::Capture::updateCCDTemperature, Qt::UniqueConnection);
         connect(currentCCD, &ISD::CCD::coolerToggled, this, &Ekos::Capture::setCoolerToggled, Qt::UniqueConnection);
         connect(currentCCD, &ISD::CCD::newRemoteFile, this, &Ekos::Capture::setNewRemoteFile);
         connect(currentCCD, &ISD::CCD::videoStreamToggled, this, &Ekos::Capture::setVideoStreamEnabled);
         connect(currentCCD, &ISD::CCD::ready, this, &Ekos::Capture::ready);
     }
 }
 
 void Capture::setGuideChip(ISD::CCDChip *chip)
 {
     guideChip = chip;
     // We should suspend guide in two scenarios:
     // 1. If guide chip is within the primary CCD, then we cannot download any data from guide chip while primary CCD is downloading.
     // 2. If we have two CCDs running from ONE driver (Multiple-Devices-Per-Driver mpdp is true). Same issue as above, only one download
     // at a time.
     // After primary CCD download is complete, we resume guiding.
     suspendGuideOnDownload =
             (currentCCD->getChip(ISD::CCDChip::GUIDE_CCD) == guideChip) ||
             (guideChip->getCCD() == currentCCD && currentCCD->getDriverInfo()->getAuxInfo().value("mdpd", false).toBool());
 }
 
 void Capture::resetFrameToZero()
 {
     frameXIN->setMinimum(0);
     frameXIN->setMaximum(0);
     frameXIN->setValue(0);
 
     frameYIN->setMinimum(0);
     frameYIN->setMaximum(0);
     frameYIN->setValue(0);
 
     frameWIN->setMinimum(0);
     frameWIN->setMaximum(0);
     frameWIN->setValue(0);
 
     frameHIN->setMinimum(0);
     frameHIN->setMaximum(0);
     frameHIN->setValue(0);
 }
 
 void Capture::updateFrameProperties(int reset)
 {
     int binx = 1, biny = 1;
     double min, max, step;
     int xstep = 0, ystep = 0;
 
     QString frameProp    = useGuideHead ? QString("GUIDER_FRAME") : QString("CCD_FRAME");
     QString exposureProp = useGuideHead ? QString("GUIDER_EXPOSURE") : QString("CCD_EXPOSURE");
     QString exposureElem = useGuideHead ? QString("GUIDER_EXPOSURE_VALUE") : QString("CCD_EXPOSURE_VALUE");
     targetChip =
             useGuideHead ? currentCCD->getChip(ISD::CCDChip::GUIDE_CCD) : currentCCD->getChip(ISD::CCDChip::PRIMARY_CCD);
 
     frameWIN->setEnabled(targetChip->canSubframe());
     frameHIN->setEnabled(targetChip->canSubframe());
     frameXIN->setEnabled(targetChip->canSubframe());
     frameYIN->setEnabled(targetChip->canSubframe());
 
     binXIN->setEnabled(targetChip->canBin());
     binYIN->setEnabled(targetChip->canBin());
 
     QList<double> exposureValues;
     exposureValues << 0.01 << 0.02 << 0.05 << 0.1 << 0.2 << 0.25 << 0.5 << 1 << 1.5 << 2 << 2.5 << 3 << 5 << 6 << 7 << 8 << 9 << 10 << 20 << 30 << 40 << 50 << 60 << 120 << 180 << 300 << 600 << 900 << 1200 << 1800;
 
     if (currentCCD->getMinMaxStep(exposureProp, exposureElem, &min, &max, &step))
     {
         if (min < 0.001)
             exposureIN->setDecimals(6);
         else
             exposureIN->setDecimals(3);
         for(int i = 0; i < exposureValues.count(); i++)
         {
             double value = exposureValues.at(i);
             if(value < min || value > max)
             {
                 exposureValues.removeAt(i);
                 i--; //So we don't skip one
             }
         }
 
         exposureValues.prepend(min);
         exposureValues.append(max);
     }
 
     exposureIN->setRecommendedValues(exposureValues);
 
     if (currentCCD->getMinMaxStep(frameProp, "WIDTH", &min, &max, &step))
     {
         if (min >= max)
         {
             resetFrameToZero();
             return;
         }
 
         if (step == 0)
             xstep = static_cast<int>(max * 0.05);
         else
             xstep = step;
 
         if (min >= 0 && max > 0)
         {
             frameWIN->setMinimum(min);
             frameWIN->setMaximum(max);
             frameWIN->setSingleStep(xstep);
         }
     }
     else
         return;
 
     if (currentCCD->getMinMaxStep(frameProp, "HEIGHT", &min, &max, &step))
     {
         if (min >= max)
         {
             resetFrameToZero();
             return;
         }
 
         if (step == 0)
             ystep = static_cast<int>(max * 0.05);
         else
             ystep = step;
 
         if (min >= 0 && max > 0)
         {
             frameHIN->setMinimum(min);
             frameHIN->setMaximum(max);
             frameHIN->setSingleStep(ystep);
         }
     }
     else
         return;
 
     if (currentCCD->getMinMaxStep(frameProp, "X", &min, &max, &step))
     {
         if (min >= max)
         {
             resetFrameToZero();
             return;
         }
 
         if (step == 0)
             step = xstep;
 
         if (min >= 0 && max > 0)
         {
             frameXIN->setMinimum(min);
             frameXIN->setMaximum(max);
             frameXIN->setSingleStep(step);
         }
     }
     else
         return;
 
     if (currentCCD->getMinMaxStep(frameProp, "Y", &min, &max, &step))
     {
         if (min >= max)
         {
             resetFrameToZero();
             return;
         }
 
         if (step == 0)
             step = ystep;
 
         if (min >= 0 && max > 0)
         {
             frameYIN->setMinimum(min);
             frameYIN->setMaximum(max);
             frameYIN->setSingleStep(step);
         }
     }
     else
         return;
 
     // cull to camera limits, if there are any
     if (useGuideHead == false)
         cullToDSLRLimits();
 
     if (reset == 1 || frameSettings.contains(targetChip) == false)
     {
         QVariantMap settings;
 
         settings["x"]    = 0;
         settings["y"]    = 0;
         settings["w"]    = frameWIN->maximum();
         settings["h"]    = frameHIN->maximum();
         settings["binx"] = 1;
         settings["biny"] = 1;
 
         frameSettings[targetChip] = settings;
     }
     else if (reset == 2 && frameSettings.contains(targetChip))
     {
         QVariantMap settings = frameSettings[targetChip];
         int x, y, w, h;
 
         x = settings["x"].toInt();
         y = settings["y"].toInt();
         w = settings["w"].toInt();
         h = settings["h"].toInt();
 
         // Bound them
         x = qBound(frameXIN->minimum(), x, frameXIN->maximum() - 1);
         y = qBound(frameYIN->minimum(), y, frameYIN->maximum() - 1);
         w = qBound(frameWIN->minimum(), w, frameWIN->maximum());
         h = qBound(frameHIN->minimum(), h, frameHIN->maximum());
 
         settings["x"] = x;
         settings["y"] = y;
         settings["w"] = w;
         settings["h"] = h;
 
         frameSettings[targetChip] = settings;
     }
 
     if (frameSettings.contains(targetChip))
     {
         QVariantMap settings = frameSettings[targetChip];
         int x = settings["x"].toInt();
         int y = settings["y"].toInt();
         int w = settings["w"].toInt();
         int h = settings["h"].toInt();
 
         if (targetChip->canBin())
         {
             targetChip->getMaxBin(&binx, &biny);
             binXIN->setMaximum(binx);
             binYIN->setMaximum(biny);
 
             binXIN->setValue(settings["binx"].toInt());
             binYIN->setValue(settings["biny"].toInt());
         }
         else
         {
             binXIN->setValue(1);
             binYIN->setValue(1);
         }
 
         if (x >= 0)
             frameXIN->setValue(x);
         if (y >= 0)
             frameYIN->setValue(y);
         if (w > 0)
             frameWIN->setValue(w);
         if (h > 0)
             frameHIN->setValue(h);
     }
 }
 
 void Capture::processCCDNumber(INumberVectorProperty *nvp)
 {
     if (currentCCD == nullptr)
         return;
 
     if ((!strcmp(nvp->name, "CCD_FRAME") && useGuideHead == false) ||
             (!strcmp(nvp->name, "GUIDER_FRAME") && useGuideHead))
         updateFrameProperties();
     else if ((!strcmp(nvp->name, "CCD_INFO") && useGuideHead == false) ||
              (!strcmp(nvp->name, "GUIDER_INFO") && useGuideHead))
         updateFrameProperties(2);
 }
 
 void Capture::resetFrame()
 {
     targetChip =
             useGuideHead ? currentCCD->getChip(ISD::CCDChip::GUIDE_CCD) : currentCCD->getChip(ISD::CCDChip::PRIMARY_CCD);
     targetChip->resetFrame();
     updateFrameProperties(1);
 }
 
 void Capture::syncFrameType(ISD::GDInterface *ccd)
 {
     if (strcmp(ccd->getDeviceName(), CCDCaptureCombo->currentText().toLatin1()))
         return;
 
     ISD::CCDChip *tChip = (static_cast<ISD::CCD *>(ccd))->getChip(ISD::CCDChip::PRIMARY_CCD);
 
     QStringList frameTypes = tChip->getFrameTypes();
 
     frameTypeCombo->clear();
 
     if (frameTypes.isEmpty())
         frameTypeCombo->setEnabled(false);
     else
     {
         frameTypeCombo->setEnabled(true);
         frameTypeCombo->addItems(frameTypes);
         frameTypeCombo->setCurrentIndex(tChip->getFrameType());
     }
 }
 
 bool Capture::setFilterWheel(const QString &device)
 {
     bool deviceFound = false;
 
     for (int i = 1; i < FilterDevicesCombo->count(); i++)
         if (device == FilterDevicesCombo->itemText(i))
         {
             checkFilter(i);
             deviceFound = true;
             break;
         }
 
     if (deviceFound == false)
         return false;
 
     return true;
 }
 
 QString Capture::filterWheel()
 {
     if (FilterDevicesCombo->currentIndex() >= 1)
         return FilterDevicesCombo->currentText();
 
     return QString();
 }
 
 bool Capture::setFilter(const QString &filter)
 {
     if (FilterDevicesCombo->currentIndex() >= 1)
     {
         FilterPosCombo->setCurrentText(filter);
         return true;
     }
 
     return false;
 }
 
 QString Capture::filter()
 {
     return FilterPosCombo->currentText();
 }
 
 void Capture::checkFilter(int filterNum)
 {
     if (filterNum == -1)
     {
         filterNum = FilterDevicesCombo->currentIndex();
         if (filterNum == -1)
             return;
     }
 
     // "--" is no filter
     if (filterNum == 0)
     {
         currentFilter = nullptr;
         m_CurrentFilterPosition=-1;
         FilterPosCombo->clear();
         syncFilterInfo();
         return;
     }
 
     if (filterNum <= Filters.count())
         currentFilter = Filters.at(filterNum-1);
 
     filterManager->setCurrentFilterWheel(currentFilter);
 
     syncFilterInfo();
 
     FilterPosCombo->clear();
 
     FilterPosCombo->addItems(filterManager->getFilterLabels());
 
     m_CurrentFilterPosition = filterManager->getFilterPosition();
 
     FilterPosCombo->setCurrentIndex(m_CurrentFilterPosition-1);
 
 
     /*if (activeJob &&
         (activeJob->getStatus() == SequenceJob::JOB_ABORTED || activeJob->getStatus() == SequenceJob::JOB_IDLE))
         activeJob->setCurrentFilter(currentFilterPosition);*/
 }
 
 void Capture::syncFilterInfo()
 {
     if (currentCCD)
     {
         ITextVectorProperty *activeDevices = currentCCD->getBaseDevice()->getText("ACTIVE_DEVICES");
         if (activeDevices)
         {
             IText *activeFilter = IUFindText(activeDevices, "ACTIVE_FILTER");
             if (activeFilter)
             {
                 if (currentFilter != nullptr && strcmp(activeFilter->text, currentFilter->getDeviceName()))
                 {
                     IUSaveText(activeFilter, currentFilter->getDeviceName());
                     currentCCD->getDriverInfo()->getClientManager()->sendNewText(activeDevices);
                 }
                 // Reset filter name in CCD driver
                 else if (currentFilter == nullptr && strlen(activeFilter->text) > 0)
                 {
                     IUSaveText(activeFilter, "");
                     currentCCD->getDriverInfo()->getClientManager()->sendNewText(activeDevices);
                 }
             }
         }
     }
 }
 
 bool Capture::startNextExposure()
 {
     if (m_State == CAPTURE_PAUSED)
     {
         pauseFunction = &Capture::startNextExposure;
         appendLogText(i18n("Sequence paused."));
         secondsLabel->setText(i18n("Paused..."));
         return false;
     }
 
     if (seqDelay > 0)
     {
         secondsLabel->setText(i18n("Waiting..."));
         m_State = CAPTURE_WAITING;
         emit newStatus(Ekos::CAPTURE_WAITING);
     }
 
     seqTimer->start(seqDelay);
 
     return true;
 }
 
 void Capture::newFITS(IBLOB *bp)
 {
     ISD::CCDChip *tChip = nullptr;
 
     // If there is no active job, ignore
     if (activeJob == nullptr || meridianFlipStage >= MF_ALIGNING)
         return;
 
     if (currentCCD->getUploadMode() != ISD::CCD::UPLOAD_LOCAL)
     {
         if (bp == nullptr)
         {
             appendLogText(i18n("Failed to save file to %1", activeJob->getSignature()));
             abort();
             return;
         }
 
         if (!strcmp(bp->name, "CCD2"))
             tChip = currentCCD->getChip(ISD::CCDChip::GUIDE_CCD);
         else
             tChip = currentCCD->getChip(ISD::CCDChip::PRIMARY_CCD);
 
         if (tChip != targetChip)
             return;
 
         if (targetChip->getCaptureMode() == FITS_FOCUS || targetChip->getCaptureMode() == FITS_GUIDE)
             return;
 
         // If this is a preview job, make sure to enable preview button after
         // we receive the FITS
         if (activeJob->isPreview() && previewB->isEnabled() == false)
             previewB->setEnabled(true);
 
         // If the FITS is not for our device, simply ignore
         //if (QString(bp->bvp->device)  != currentCCD->getDeviceName() || (startB->isEnabled() && previewB->isEnabled()))
         if (QString(bp->bvp->device) != currentCCD->getDeviceName() || m_State == CAPTURE_IDLE || m_State == CAPTURE_ABORTED)
             return;
 
         if (currentCCD->isLooping() == false)
         {
-            disconnect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Capture::newFITS);            
+            disconnect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Capture::newFITS);
 
             if (useGuideHead == false && darkSubCheck->isChecked() && activeJob->isPreview())
             {
                 FITSView *currentImage = targetChip->getImageView(FITS_NORMAL);
                 FITSData *darkData     = DarkLibrary::Instance()->getDarkFrame(targetChip, activeJob->getExposure());
                 uint16_t offsetX       = activeJob->getSubX() / activeJob->getXBin();
                 uint16_t offsetY       = activeJob->getSubY() / activeJob->getYBin();
 
                 connect(DarkLibrary::Instance(), &DarkLibrary::darkFrameCompleted, this, &Ekos::Capture::setCaptureComplete);
                 connect(DarkLibrary::Instance(), &DarkLibrary::newLog, this, &Ekos::Capture::appendLogText);
 
                 if (darkData)
                     DarkLibrary::Instance()->subtract(darkData, currentImage, activeJob->getCaptureFilter(), offsetX, offsetY);
                 else
                     DarkLibrary::Instance()->captureAndSubtract(targetChip, currentImage, activeJob->getExposure(), offsetX, offsetY);
 
                 return;
             }
-        }        
+        }
     }
 
     blobChip    = bp ? static_cast<ISD::CCDChip*>(bp->aux0) : nullptr;
     blobFilename= bp ? static_cast<const char *>(bp->aux2) : QString();
 
     setCaptureComplete();
 }
 
 bool Capture::setCaptureComplete()
 {
     captureTimeout.stop();
     captureTimeoutCounter = 0;
 
     if (currentCCD->isLooping() == false)
     {
         disconnect(currentCCD, &ISD::CCD::newExposureValue, this, &Ekos::Capture::setExposureProgress);
         DarkLibrary::Instance()->disconnect(this);
     }
 
     secondsLabel->setText(i18n("Complete."));
 
     // Do not display notifications for very short captures
     if (activeJob->getExposure() >= 1)
         KSNotification::event(QLatin1String("EkosCaptureImageReceived"), i18n("Captured image received"), KSNotification::EVENT_INFO);
 
     // If it was initially set as pure preview job and NOT as preview for calibration
     if (activeJob->isPreview() && calibrationStage != CAL_CALIBRATION)
     {
         sendNewImage(blobFilename, blobChip);
         jobs.removeOne(activeJob);
         // Reset upload mode if it was changed by preview
         currentCCD->setUploadMode(rememberUploadMode);
         delete (activeJob);
         // Reset active job pointer
         activeJob = nullptr;
         abort();
         if (guideState == GUIDE_SUSPENDED && suspendGuideOnDownload)
             emit resumeGuiding();
 
         m_State = CAPTURE_IDLE;
         emit newStatus(Ekos::CAPTURE_IDLE);
         return true;
     }
 
     if (m_State == CAPTURE_PAUSED)
     {
         pauseFunction = &Capture::setCaptureComplete;
         appendLogText(i18n("Sequence paused."));
         secondsLabel->setText(i18n("Paused..."));
         return false;
     }
 
     /* Increase the sequence's current capture count */
     if (! activeJob->isPreview())
         activeJob->setCompleted(activeJob->getCompleted() + 1);
 
     sendNewImage(blobFilename, blobChip);
 
     /* If we were assigned a captured frame map, also increase the relevant counter for prepareJob */
     SchedulerJob::CapturedFramesMap::iterator frame_item = capturedFramesMap.find(activeJob->getSignature());
     if (capturedFramesMap.end() != frame_item)
         frame_item.value()++;
 
     if (activeJob->getFrameType() != FRAME_LIGHT)
     {
         if (processPostCaptureCalibrationStage() == false)
             return true;
 
         if (calibrationStage == CAL_CALIBRATION_COMPLETE)
             calibrationStage = CAL_CAPTURING;
     }
 
     /* The image progress has now one more capture */
     imgProgress->setValue(activeJob->getCompleted());
 
     appendLogText(i18n("Received image %1 out of %2.", activeJob->getCompleted(), activeJob->getCount()));
 
     m_State = CAPTURE_IMAGE_RECEIVED;
     emit newStatus(Ekos::CAPTURE_IMAGE_RECEIVED);
 
     currentImgCountOUT->setText(QString("%L1").arg(activeJob->getCompleted()));
 
     // Check if we need to execute post capture script first
     if (activeJob->getPostCaptureScript().isEmpty() == false)
     {
         postCaptureScript.start(activeJob->getPostCaptureScript());
         appendLogText(i18n("Executing post capture script %1", activeJob->getPostCaptureScript()));
         return true;
     }
 
     // if we're done
     if (activeJob->getCount() <= activeJob->getCompleted())
     {
         processJobCompletion();
         return true;
     }
 
     // Check if meridian condition is met
     if (checkMeridianFlip())
         return true;
 
     return resumeSequence();
 }
 
 void Capture::processJobCompletion()
 {
     activeJob->done();
 
     if (activeJob->isPreview() == false)
     {
         int index = jobs.indexOf(activeJob);
         QJsonObject oneSequence = m_SequenceArray[index].toObject();
         oneSequence["Status"] = "Complete";
         m_SequenceArray.replace(index, oneSequence);
         emit sequenceChanged(m_SequenceArray);
     }
 
     stop();
 
     // Check if meridian condition is met IF there are more pending jobs in the queue
     // Otherwise, no need to check meridian flip is all jobs are over.
     if (getPendingJobCount() > 0 && checkMeridianFlip())
         return;
 
     // Check if there are more pending jobs and execute them
     if (resumeSequence())
         return;
     // Otherwise, we're done. We park if required and resume guiding if no parking is done and autoguiding was engaged before.
     else
     {
         //KNotification::event(QLatin1String("CaptureSuccessful"), i18n("CCD capture sequence completed"));
         KSNotification::event(QLatin1String("CaptureSuccessful"), i18n("CCD capture sequence completed"), KSNotification::EVENT_INFO);
 
         abort();
 
         m_State = CAPTURE_COMPLETE;
         emit newStatus(Ekos::CAPTURE_COMPLETE);
 
         //Resume guiding if it was suspended before
         //if (isAutoGuiding && currentCCD->getChip(ISD::CCDChip::GUIDE_CCD) == guideChip)
         if (guideState == GUIDE_SUSPENDED && suspendGuideOnDownload)
             emit resumeGuiding();
     }
 }
 
 bool Capture::resumeSequence()
 {
     if (m_State == CAPTURE_PAUSED)
     {
         pauseFunction = &Capture::resumeSequence;
         appendLogText(i18n("Sequence paused."));
         secondsLabel->setText(i18n("Paused..."));
         return false;
     }
 
     // If no job is active, we have to find if there are more pending jobs in the queue
     if (!activeJob)
     {
         SequenceJob *next_job = nullptr;
 
         foreach (SequenceJob *job, jobs)
         {
             if (job->getStatus() == SequenceJob::JOB_IDLE || job->getStatus() == SequenceJob::JOB_ABORTED)
             {
                 next_job = job;
                 break;
             }
         }
 
         if (next_job)
         {
             prepareJob(next_job);
 
             //Resume guiding if it was suspended before
             //if (isAutoGuiding && currentCCD->getChip(ISD::CCDChip::GUIDE_CCD) == guideChip)
             if (guideState == GUIDE_SUSPENDED && suspendGuideOnDownload)
             {
                 qCDebug(KSTARS_EKOS_CAPTURE) << "Resuming guiding...";
                 emit resumeGuiding();
             }
 
             return true;
         }
         else
         {
             qCDebug(KSTARS_EKOS_CAPTURE) << "All capture jobs complete.";
             return false;
         }
     }
     // Otherwise, let's prepare for next exposure after making sure in-sequence focus and dithering are complete if applicable.
     else
     {
         isInSequenceFocus = (autoFocusReady && autofocusCheck->isChecked()/* && HFRPixels->value() > 0*/);
-        if (isInSequenceFocus)
-            requiredAutoFocusStarted = false;
+//        if (isInSequenceFocus)
+//            requiredAutoFocusStarted = false;
 
         // Reset HFR pixels to file value after meridian flip
         if (isInSequenceFocus && meridianFlipStage != MF_NONE)
         {
             qCDebug(KSTARS_EKOS_CAPTURE) << "Resetting HFR value to file value of" << fileHFR << "pixels after meridian flip.";
             //firstAutoFocus = true;
             HFRPixels->setValue(fileHFR);
         }
 
-        // check if time for forced refocus
-        if (autoFocusReady && refocusEveryNCheck->isChecked())
-        {
-            qCDebug(KSTARS_EKOS_CAPTURE) << "NFocus Elapsed Time (secs): " << getRefocusEveryNTimerElapsedSec() << " Requested Interval (secs): " << refocusEveryN->value()*60;
-            isRefocus = getRefocusEveryNTimerElapsedSec() >= refocusEveryN->value()*60;
-        }
-
         // If we suspended guiding due to primary chip download, resume guide chip guiding now
         if (guideState == GUIDE_SUSPENDED && suspendGuideOnDownload)
         {
             qCInfo(KSTARS_EKOS_CAPTURE) << "Resuming guiding...";
             emit resumeGuiding();
         }
 
         // Dither either when guiding or IF Non-Guide either option is enabled
         if ( Options::ditherEnabled()
              // 2017-09-20 Jasem: No need to dither after post meridian flip guiding
              && meridianFlipStage != MF_GUIDING
              // If CCD is looping, we cannot dither UNLESS a different camera and NOT a guide chip is doing the guiding for us.
              && (currentCCD->isLooping() == false || guideChip == nullptr)
              // We must be either in guide mode or if non-guide dither (via pulsing) is enabled
              && (guideState == GUIDE_GUIDING || Options::ditherNoGuiding())
              // Must be only done for light frames
              && activeJob->getFrameType() == FRAME_LIGHT
              // Check dither counter
              && --ditherCounter == 0)
         {
             ditherCounter = Options::ditherFrames();
 
             secondsLabel->setText(i18n("Dithering..."));
 
             qCInfo(KSTARS_EKOS_CAPTURE) << "Dithering...";
 
             if (currentCCD->isLooping())
                 targetChip->abortExposure();
 
             m_State = CAPTURE_DITHERING;
             emit newStatus(Ekos::CAPTURE_DITHERING);
         }
+#if 0
         else if (isRefocus && activeJob->getFrameType() == FRAME_LIGHT)
         {
             appendLogText(i18n("Scheduled refocus starting after %1 seconds...",getRefocusEveryNTimerElapsedSec()));
 
             secondsLabel->setText(i18n("Focusing..."));
 
             if (currentCCD->isLooping())
                 targetChip->abortExposure();
 
             // If we are over 30 mins since last autofocus, we'll reset frame.
             if (refocusEveryN->value() >= 30)
                 emit resetFocus();
 
             // force refocus
             emit checkFocus(0.1);
 
             m_State = CAPTURE_FOCUSING;
             emit newStatus(Ekos::CAPTURE_FOCUSING);
         }
         else if (isInSequenceFocus && activeJob->getFrameType() == FRAME_LIGHT && --inSequenceFocusCounter == 0)
         {
             inSequenceFocusCounter = Options::inSequenceCheckFrames();
 
             // Post meridian flip we need to reset filter _before_ running in-sequence focusing
             // as it could have changed for whatever reason (e.g. alignment used a different filter).
             // Then when focus process begins with the _target_ filter in place, it should take all the necessary actions to make it
             // work for the next set of captures. This is direct reset to the filter device, not via Filter Manager.
             if (meridianFlipStage != MF_NONE && currentFilter)
             {
                 int targetFilterPosition = activeJob->getTargetFilter();
                 int currentFilterPosition= filterManager->getFilterPosition();
                 if (targetFilterPosition > 0 && targetFilterPosition != currentFilterPosition)
                     currentFilter->runCommand(INDI_SET_FILTER, &targetFilterPosition);
             }
 
             secondsLabel->setText(i18n("Focusing..."));
 
             if (currentCCD->isLooping())
                 targetChip->abortExposure();
 
             if (HFRPixels->value() == 0)
                 emit checkFocus(0.1);
             else
                 emit checkFocus(HFRPixels->value());
 
             qCDebug(KSTARS_EKOS_CAPTURE) << "In-sequence focusing started...";
 
             m_State = CAPTURE_FOCUSING;
             emit newStatus(Ekos::CAPTURE_FOCUSING);
         }
-        else
+#endif
+        // Check if we need to do autofocus, if not let's check if we need looping or start next exposure
+        else if (startFocusIfRequired() == false)
         {
             // If looping, we just increment the file system image count
             if (currentCCD->isLooping())
             {
                 if (currentCCD->getUploadMode() != ISD::CCD::UPLOAD_LOCAL)
                 {
                     checkSeqBoundary(activeJob->getSignature());
                     currentCCD->setNextSequenceID(nextSequenceID);
                 }
             }
             else
                 startNextExposure();
         }
     }
 
     return true;
 }
 
+bool Capture::startFocusIfRequired()
+{
+    if (activeJob->getFrameType() != FRAME_LIGHT)
+        return false;
+
+//    if (autoFocusReady == false)
+//        return false;
+
+    // check if time for forced refocus
+    if (refocusEveryNCheck->isChecked())
+    {
+        qCDebug(KSTARS_EKOS_CAPTURE) << "NFocus Elapsed Time (secs): " << getRefocusEveryNTimerElapsedSec() << " Requested Interval (secs): " << refocusEveryN->value()*60;
+        isRefocus = getRefocusEveryNTimerElapsedSec() >= refocusEveryN->value()*60;
+    }
+    else
+        isRefocus = false;
+
+    if (isRefocus)
+    {
+        appendLogText(i18n("Scheduled refocus starting after %1 seconds...",getRefocusEveryNTimerElapsedSec()));
+
+        secondsLabel->setText(i18n("Focusing..."));
+
+        if (currentCCD->isLooping())
+            targetChip->abortExposure();
+
+        // If we are over 30 mins since last autofocus, we'll reset frame.
+        if (refocusEveryN->value() >= 30)
+            emit resetFocus();
+
+        // force refocus
+        emit checkFocus(0.1);
+
+        m_State = CAPTURE_FOCUSING;
+        emit newStatus(Ekos::CAPTURE_FOCUSING);
+        return true;
+    }
+    else if (isInSequenceFocus && --inSequenceFocusCounter == 0)
+    {
+        inSequenceFocusCounter = Options::inSequenceCheckFrames();
+
+        // Post meridian flip we need to reset filter _before_ running in-sequence focusing
+        // as it could have changed for whatever reason (e.g. alignment used a different filter).
+        // Then when focus process begins with the _target_ filter in place, it should take all the necessary actions to make it
+        // work for the next set of captures. This is direct reset to the filter device, not via Filter Manager.
+        if (meridianFlipStage != MF_NONE && currentFilter)
+        {
+            int targetFilterPosition = activeJob->getTargetFilter();
+            int currentFilterPosition= filterManager->getFilterPosition();
+            if (targetFilterPosition > 0 && targetFilterPosition != currentFilterPosition)
+                currentFilter->runCommand(INDI_SET_FILTER, &targetFilterPosition);
+        }
+
+        secondsLabel->setText(i18n("Focusing..."));
+
+        if (currentCCD->isLooping())
+            targetChip->abortExposure();
+
+        if (HFRPixels->value() == 0)
+            emit checkFocus(0.1);
+        else
+            emit checkFocus(HFRPixels->value());
+
+        qCDebug(KSTARS_EKOS_CAPTURE) << "In-sequence focusing started...";
+
+        m_State = CAPTURE_FOCUSING;
+        emit newStatus(Ekos::CAPTURE_FOCUSING);
+        return true;
+    }
+
+    return false;
+}
+
 void Capture::captureOne()
-{    
+{
 
     //if (currentCCD->getUploadMode() == ISD::CCD::UPLOAD_LOCAL)
     /*if (uploadModeCombo->currentIndex() != ISD::CCD::UPLOAD_CLIENT)
     {
         appendLogText(i18n("Cannot take preview image while CCD upload mode is set to local or both. Please change "
                            "upload mode to client and try again."));
         return;
     }*/
 
     if (transferFormatCombo->currentIndex() == ISD::CCD::FORMAT_NATIVE && darkSubCheck->isChecked())
     {
         appendLogText(i18n("Cannot perform auto dark subtraction of native DSLR formats."));
         return;
     }
 
     if (addJob(true))
         prepareJob(jobs.last());
 }
 
 void Capture::captureImage()
 {
     if (activeJob == nullptr)
         return;
 
     captureTimeout.stop();
 
     seqTimer->stop();
     SequenceJob::CAPTUREResult rc = SequenceJob::CAPTURE_OK;
 
     if (currentCCD->isConnected() == false)
     {
         appendLogText(i18n("Error: Lost connection to CCD."));
         abort();
         return;
     }
 
     if (focusState >= FOCUS_PROGRESS)
     {
         appendLogText(i18n("Cannot capture while focus module is busy."));
         abort();
         return;
     }
 
     /*
     if (filterSlot != nullptr)
     {
         currentFilterPosition = (int)filterSlot->np[0].value;
         activeJob->setCurrentFilter(currentFilterPosition);
     }*/
 
     if (currentFilter != nullptr)
     {
         m_CurrentFilterPosition = filterManager->getFilterPosition();
         activeJob->setCurrentFilter(m_CurrentFilterPosition);
     }
 
     if (currentCCD->hasCooler())
     {
         double temperature = 0;
         currentCCD->getTemperature(&temperature);
         activeJob->setCurrentTemperature(temperature);
     }
 
     if (currentCCD->isLooping())
     {
         int remaining = activeJob->getCount() - activeJob->getCompleted();
         if (remaining > 1)
             currentCCD->setExposureLoopCount(remaining);
     }
 
-    connect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Capture::newFITS, Qt::UniqueConnection);    
+    connect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Capture::newFITS, Qt::UniqueConnection);
 
     if (activeJob->getFrameType() == FRAME_FLAT)
     {
         // If we have to calibrate ADU levels, first capture must be preview and not in batch mode
         if (activeJob->isPreview() == false && activeJob->getFlatFieldDuration() == DURATION_ADU &&
                 calibrationStage == CAL_PRECAPTURE_COMPLETE)
         {
             if (currentCCD->getTransferFormat() == ISD::CCD::FORMAT_NATIVE)
             {
                 appendLogText(i18n("Cannot calculate ADU levels in non-FITS images."));
                 abort();
                 return;
             }
 
             calibrationStage = CAL_CALIBRATION;
             // We need to be in preview mode and in client mode for this to work
             activeJob->setPreview(true);
         }
     }
 
     // Temporary change upload mode to client when requesting previews
     if (activeJob->isPreview())
     {
         rememberUploadMode = activeJob->getUploadMode();
         currentCCD->setUploadMode(ISD::CCD::UPLOAD_CLIENT);
     }
 
     if (currentCCD->getUploadMode() != ISD::CCD::UPLOAD_LOCAL)
     {
         checkSeqBoundary(activeJob->getSignature());
         currentCCD->setNextSequenceID(nextSequenceID);
     }
 
     m_State = CAPTURE_CAPTURING;
 
     //if (activeJob->isPreview() == false)
     // NOTE: Why we didn't emit this before for preview?
     emit newStatus(Ekos::CAPTURE_CAPTURING);
 
     if (frameSettings.contains(activeJob->getActiveChip()))
     {
         QVariantMap settings;
         settings["x"]    = activeJob->getSubX();
         settings["y"]    = activeJob->getSubY();
         settings["w"]    = activeJob->getSubW();
         settings["h"]    = activeJob->getSubH();
         settings["binx"] = activeJob->getXBin();
         settings["biny"] = activeJob->getYBin();
 
         frameSettings[activeJob->getActiveChip()] = settings;
     }
 
     // If using DSLR, make sure it is set to correct transfer format
     currentCCD->setTransformFormat(activeJob->getTransforFormat());
 
     connect(currentCCD, &ISD::CCD::newExposureValue, this, &Ekos::Capture::setExposureProgress, Qt::UniqueConnection);
 
     rc = activeJob->capture(darkSubCheck->isChecked() ? true : false);
 
     if (rc != SequenceJob::CAPTURE_OK)
     {
         disconnect(currentCCD, &ISD::CCD::newExposureValue, this, &Ekos::Capture::setExposureProgress);
     }
     switch (rc)
     {
     case SequenceJob::CAPTURE_OK:
     {
         appendLogText(i18n("Capturing %1-second %2 image...", QString("%L1").arg(activeJob->getExposure(), 0, 'f', 3), activeJob->getFilterName()));
         captureTimeout.start(activeJob->getExposure() * 1000 + CAPTURE_TIMEOUT_THRESHOLD);
         if (activeJob->isPreview() == false)
         {
             int index = jobs.indexOf(activeJob);
             QJsonObject oneSequence = m_SequenceArray[index].toObject();
             oneSequence["Status"] = "In Progress";
             m_SequenceArray.replace(index, oneSequence);
             emit sequenceChanged(m_SequenceArray);
         }
     }
         break;
 
     case SequenceJob::CAPTURE_FRAME_ERROR:
         appendLogText(i18n("Failed to set sub frame."));
         abort();
         break;
 
     case SequenceJob::CAPTURE_BIN_ERROR:
         appendLogText(i18n("Failed to set binning."));
         abort();
         break;
 
     case SequenceJob::CAPTURE_FILTER_BUSY:
         // Try again in 1 second if filter is busy
         QTimer::singleShot(1000, this, &Ekos::Capture::captureImage);
         break;
 
     case SequenceJob::CAPTURE_FOCUS_ERROR:
         appendLogText(i18n("Cannot capture while focus module is busy."));
         abort();
         break;
     }
 }
 
 bool Capture::resumeCapture()
 {
     if (m_State == CAPTURE_PAUSED)
     {
         pauseFunction = &Capture::resumeCapture;
         appendLogText(i18n("Sequence paused."));
         secondsLabel->setText(i18n("Paused..."));
         return false;
     }
 
+#if 0
     /* Refresh isRefocus when resuming */
     if (autoFocusReady && refocusEveryNCheck->isChecked())
     {
         qCDebug(KSTARS_EKOS_CAPTURE) << "NFocus Elapsed Time (secs): " << getRefocusEveryNTimerElapsedSec() << " Requested Interval (secs): " << refocusEveryN->value()*60;
         isRefocus = getRefocusEveryNTimerElapsedSec() >= refocusEveryN->value()*60;
     }
 
     // FIXME ought to be able to combine these - only different is value passed
     //       to checkFocus()
     // 2018-08-23 Jasem: For now in-sequence-focusing takes precedense.
     if (isInSequenceFocus && requiredAutoFocusStarted == false)
     {
         requiredAutoFocusStarted = true;
         secondsLabel->setText(i18n("Focusing..."));
         qCDebug(KSTARS_EKOS_CAPTURE) << "Requesting focusing if HFR >" << HFRPixels->value();
         emit checkFocus(HFRPixels->value());
         m_State = CAPTURE_FOCUSING;
         emit newStatus(Ekos::CAPTURE_FOCUSING);
         return true;
     }
     else if (isRefocus)
     {
         appendLogText(i18n("Scheduled refocus started..."));
 
         secondsLabel->setText(i18n("Focusing..."));
         emit checkFocus(0.1);
         m_State = CAPTURE_FOCUSING;
         emit newStatus(Ekos::CAPTURE_FOCUSING);
         return true;
     }
+#endif
+
+    if (m_State == CAPTURE_DITHERING && autoFocusReady && startFocusIfRequired())
+        return true;
 
     startNextExposure();
 
     return true;
 }
 
 /*******************************************************************************/
 /* Update the prefix for the sequence of images to be captured                 */
 /*******************************************************************************/
 void Capture::updateSequencePrefix(const QString &newPrefix, const QString &dir)
 {
     seqPrefix = newPrefix;
 
     // If it doesn't exist, create it
     QDir().mkpath(dir);
 
     nextSequenceID = 1;
 }
 
 /*******************************************************************************/
 /* Determine the next file number sequence. That is, if we have file1.png      */
 /* and file2.png, then the next sequence should be file3.png		       */
 /*******************************************************************************/
 void Capture::checkSeqBoundary(const QString &path)
 {
     int newFileIndex = -1;
     QFileInfo const path_info(path);
     QString const sig_dir(path_info.dir().path());
     QString const sig_file(path_info.baseName());
     QString tempName;
     // seqFileCount = 0;
 
     // No updates during meridian flip
     if (meridianFlipStage >= MF_ALIGNING)
         return;
 
     QDirIterator it(sig_dir, QDir::Files);
 
     while (it.hasNext())
     {
         tempName = it.next();
         QFileInfo info(tempName);
         //tempName = info.baseName();
         tempName = info.completeBaseName();
 
         QString finalSeqPrefix = seqPrefix;
         finalSeqPrefix.remove(SequenceJob::ISOMarker);
         // find the prefix first
         if (tempName.startsWith(finalSeqPrefix, Qt::CaseInsensitive) == false)
             continue;
 
         /* Do not change the number of captures.
          * - If the sequence is required by the end-user, unconditionally run what each sequence item is requiring.
          * - If the sequence is required by the scheduler, use capturedFramesMap to determine when to stop capturing.
          */
         //seqFileCount++;
 
         int lastUnderScoreIndex = tempName.lastIndexOf("_");
         if (lastUnderScoreIndex > 0)
         {
             bool indexOK = false;
 
             newFileIndex = tempName.midRef(lastUnderScoreIndex + 1).toInt(&indexOK);
             if (indexOK && newFileIndex >= nextSequenceID)
                 nextSequenceID = newFileIndex + 1;
         }
     }
 }
 
 void Capture::appendLogText(const QString &text)
 {
     m_LogText.insert(0, i18nc("log entry; %1 is the date, %2 is the text", "%1 %2",
                             QDateTime::currentDateTime().toString("yyyy-MM-ddThh:mm:ss"), text));
 
     qCInfo(KSTARS_EKOS_CAPTURE) << text;
 
     emit newLog(text);
 }
 
 void Capture::clearLog()
 {
     m_LogText.clear();
     emit newLog(QString());
 }
 
 void Capture::setExposureProgress(ISD::CCDChip *tChip, double value, IPState state)
 {
     if (targetChip != tChip || targetChip->getCaptureMode() != FITS_NORMAL || meridianFlipStage >= MF_ALIGNING)
         return;
 
     exposeOUT->setText(QString("%L1").arg(value, 0, 'd', 2));
 
     if (activeJob)
     {
         activeJob->setExposeLeft(value);
 
         emit newExposureProgress(activeJob);
     }
 
     if (activeJob && state == IPS_ALERT)
     {
         int retries = activeJob->getCaptureRetires() + 1;
 
         activeJob->setCaptureRetires(retries);
 
         appendLogText(i18n("Capture failed. Check INDI Control Panel for details."));
 
         if (retries == 3)
         {
             abort();
             return;
         }
 
         appendLogText(i18n("Restarting capture attempt #%1", retries));
 
         nextSequenceID = 1;
 
         captureImage();
         return;
     }
 
     //qDebug() << "Exposure with value " << value << "state" << pstateStr(state);
 
     if (activeJob != nullptr && state == IPS_OK)
     {
         activeJob->setCaptureRetires(0);
         activeJob->setExposeLeft(0);
 
         if (currentCCD && currentCCD->getUploadMode() == ISD::CCD::UPLOAD_LOCAL)
         {
             if (activeJob && activeJob->getStatus() == SequenceJob::JOB_BUSY)
             {
                 newFITS(nullptr);
                 return;
             }
         }
 
         //if (isAutoGuiding && Options::useEkosGuider() && currentCCD->getChip(ISD::CCDChip::GUIDE_CCD) == guideChip)
         if (guideState == GUIDE_GUIDING && Options::guiderType() == 0 && suspendGuideOnDownload)
         {
             qCDebug(KSTARS_EKOS_CAPTURE) << "Autoguiding suspended until primary CCD chip completes downloading...";
             emit suspendGuiding();
         }
 
         secondsLabel->setText(i18n("Downloading..."));
 
         //disconnect(currentCCD, &ISD::CCD::newExposureValue(ISD::CCDChip*,double,IPState)), this, &Ekos::Capture::updateCaptureProgress(ISD::CCDChip*,double,IPState)));
     }
     // JM: Don't change to i18np, value is DOUBLE, not Integer.
     else if (value <= 1)
         secondsLabel->setText(i18n("second left"));
     else
         secondsLabel->setText(i18n("seconds left"));
 }
 
 void Capture::updateCCDTemperature(double value)
 {
     if (temperatureCheck->isEnabled() == false)
     {
         if (currentCCD->getBaseDevice()->getPropertyPermission("CCD_TEMPERATURE") != IP_RO)
             checkCCD();
     }
 
     temperatureOUT->setText(QString("%L1").arg(value, 0, 'f', 2));
 
     if (temperatureIN->cleanText().isEmpty())
         temperatureIN->setValue(value);
 
     //if (activeJob && (activeJob->getStatus() == SequenceJob::JOB_ABORTED || activeJob->getStatus() == SequenceJob::JOB_IDLE))
     if (activeJob)
         activeJob->setCurrentTemperature(value);
 }
 
 void Capture::updateRotatorNumber(INumberVectorProperty *nvp)
 {
     if (!strcmp(nvp->name, "ABS_ROTATOR_ANGLE"))
     {
         // Update widget rotator position
         rotatorSettings->setCurrentAngle(nvp->np[0].value);
 
         //if (activeJob && (activeJob->getStatus() == SequenceJob::JOB_ABORTED || activeJob->getStatus() == SequenceJob::JOB_IDLE))
         if (activeJob)
             activeJob->setCurrentRotation(rotatorSettings->getCurrentRotationPA());
     }
 }
 
 bool Capture::addJob(bool preview)
 {
     if (m_State != CAPTURE_IDLE && m_State != CAPTURE_ABORTED && m_State != CAPTURE_COMPLETE)
         return false;
 
     SequenceJob *job = nullptr;
     QString imagePrefix;
 
     if (preview == false && darkSubCheck->isChecked())
     {
         KMessageBox::error(this, i18n("Auto dark subtract is not supported in batch mode."));
         return false;
     }
 
     if (uploadModeCombo->currentIndex() != ISD::CCD::UPLOAD_CLIENT && remoteDirIN->text().isEmpty())
     {
         KMessageBox::error(this, i18n("You must set remote directory for Local & Both modes."));
         return false;
     }
 
     if (uploadModeCombo->currentIndex() != ISD::CCD::UPLOAD_LOCAL && fitsDir->text().isEmpty())
     {
         KMessageBox::error(this, i18n("You must set local directory for Client & Both modes."));
         return false;
     }
 
     if (m_JobUnderEdit)
         job = jobs.at(queueTable->currentRow());
     else
     {
         job = new SequenceJob();
         job->setFilterManager(filterManager);
     }
 
     if (job == nullptr)
     {
         qWarning() << "Job is nullptr!" << endl;
         return false;
     }
 
     if (ISOCombo->isEnabled())
         job->setISOIndex(ISOCombo->currentIndex());
 
     job->setTransforFormat(static_cast<ISD::CCD::TransferFormat>(transferFormatCombo->currentIndex()));
 
     job->setPreview(preview);
 
     if (temperatureIN->isEnabled())
     {
         double currentTemperature;
         currentCCD->getTemperature(&currentTemperature);
         job->setEnforceTemperature(temperatureCheck->isChecked());
         job->setTargetTemperature(temperatureIN->value());
         job->setCurrentTemperature(currentTemperature);
     }
 
     job->setCaptureFilter(static_cast<FITSScale>(filterCombo->currentIndex()));
 
     job->setUploadMode(static_cast<ISD::CCD::UploadMode>(uploadModeCombo->currentIndex()));
     job->setPostCaptureScript(postCaptureScriptIN->text());
     job->setFlatFieldDuration(flatFieldDuration);
     job->setFlatFieldSource(flatFieldSource);
     job->setPreMountPark(preMountPark);
     job->setPreDomePark(preDomePark);
     job->setWallCoord(wallCoord);
     job->setTargetADU(targetADU);
     job->setTargetADUTolerance(targetADUTolerance);
 
     imagePrefix = prefixIN->text();
 
     constructPrefix(imagePrefix);
 
     job->setPrefixSettings(prefixIN->text(), filterCheck->isChecked(), expDurationCheck->isChecked(),
                            ISOCheck->isChecked());
     job->setFrameType(static_cast<CCDFrameType>(frameTypeCombo->currentIndex()));
     job->setFullPrefix(imagePrefix);
 
     //if (filterSlot != nullptr && currentFilter != nullptr)
     if (FilterPosCombo->currentIndex() != -1 && currentFilter != nullptr)
         job->setTargetFilter(FilterPosCombo->currentIndex() + 1, FilterPosCombo->currentText());
 
     job->setExposure(exposureIN->value());
 
     job->setCount(countIN->value());
 
     job->setBin(binXIN->value(), binYIN->value());
 
     job->setDelay(delayIN->value() * 1000); /* in ms */
 
     job->setActiveChip(targetChip);
     job->setActiveCCD(currentCCD);
     job->setActiveFilter(currentFilter);
 
     // Custom Properties
     job->setCustomProperties(customPropertiesDialog->getCustomProperties());
 
     if (currentRotator && rotatorSettings->isRotationEnforced())
     {
         job->setActiveRotator(currentRotator);
         job->setTargetRotation(rotatorSettings->getTargetRotationPA());
         job->setCurrentRotation(rotatorSettings->getCurrentRotationPA());
     }
 
     job->setFrame(frameXIN->value(), frameYIN->value(), frameWIN->value(), frameHIN->value());
     job->setRemoteDir(remoteDirIN->text());
     job->setLocalDir(fitsDir->text());
 
     if (m_JobUnderEdit == false)
     {
         // JM 2018-09-24: If this is the first job added
         // We always ignore job progress by default.
         if (jobs.isEmpty() && preview == false)
             ignoreJobProgress = true;
 
         jobs.append(job);
 
         // Nothing more to do if preview
         if (preview)
-            return true;        
+            return true;
     }
 
     QJsonObject jsonJob = {{"Status", "Idle"}};
 
     QString directoryPostfix;
 
     /* FIXME: Refactor directoryPostfix assignment, whose code is duplicated in scheduler.cpp */
     if (m_TargetName.isEmpty())
         directoryPostfix = QLatin1Literal("/") + frameTypeCombo->currentText();
     else
         directoryPostfix = QLatin1Literal("/") + m_TargetName + QLatin1Literal("/") + frameTypeCombo->currentText();
     if ((job->getFrameType() == FRAME_LIGHT || job->getFrameType() == FRAME_FLAT) &&  job->getFilterName().isEmpty() == false)
         directoryPostfix += QLatin1Literal("/") + job->getFilterName();
 
     job->setDirectoryPostfix(directoryPostfix);
 
     int currentRow = 0;
     if (m_JobUnderEdit == false)
     {
         currentRow = queueTable->rowCount();
         queueTable->insertRow(currentRow);
     }
     else
         currentRow = queueTable->currentRow();
 
     QTableWidgetItem *status = m_JobUnderEdit ? queueTable->item(currentRow, 0) : new QTableWidgetItem();
     job->setStatusCell(status);
 
     QTableWidgetItem *filter = m_JobUnderEdit ? queueTable->item(currentRow, 1) : new QTableWidgetItem();
     filter->setText("--");
     jsonJob.insert("Filter", "--");
     /*if (frameTypeCombo->currentText().compare("Bias", Qt::CaseInsensitive) &&
             frameTypeCombo->currentText().compare("Dark", Qt::CaseInsensitive) &&
             FilterPosCombo->count() > 0)*/
     if (FilterPosCombo->count() > 0 &&
             (frameTypeCombo->currentIndex() == FRAME_LIGHT || frameTypeCombo->currentIndex() == FRAME_FLAT))
     {
         filter->setText(FilterPosCombo->currentText());
         jsonJob.insert("Filter", FilterPosCombo->currentText());
     }
 
     filter->setTextAlignment(Qt::AlignHCenter);
     filter->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
 
     QTableWidgetItem *type = m_JobUnderEdit ? queueTable->item(currentRow, 2) : new QTableWidgetItem();
     type->setText(frameTypeCombo->currentText());
     type->setTextAlignment(Qt::AlignHCenter);
     type->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
     jsonJob.insert("Type", type->text());
 
     QTableWidgetItem *bin = m_JobUnderEdit ? queueTable->item(currentRow, 3) : new QTableWidgetItem();
     bin->setText(QString("%1x%2").arg(binXIN->value()).arg(binYIN->value()));
     bin->setTextAlignment(Qt::AlignHCenter);
     bin->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
     jsonJob.insert("Bin", bin->text());
 
     QTableWidgetItem *exp = m_JobUnderEdit ? queueTable->item(currentRow, 4) : new QTableWidgetItem();
     exp->setText(QString("%L1").arg(exposureIN->value(), 0, 'f', exposureIN->decimals()));
     exp->setTextAlignment(Qt::AlignHCenter);
     exp->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
     jsonJob.insert("Exp", exp->text());
 
     QTableWidgetItem *iso = m_JobUnderEdit ? queueTable->item(currentRow, 5) : new QTableWidgetItem();
     if (ISOCombo->currentIndex() != -1)
     {
         iso->setText(ISOCombo->currentText());
         jsonJob.insert("ISO", iso->text());
     }
     else
     {
         iso->setText("--");
         jsonJob.insert("ISO", "--");
     }
     iso->setTextAlignment(Qt::AlignHCenter);
     iso->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
 
     QTableWidgetItem *count = m_JobUnderEdit ? queueTable->item(currentRow, 6) : new QTableWidgetItem();
     job->setCountCell(count);
     jsonJob.insert("Count", count->text());
 
     if (m_JobUnderEdit == false)
     {
         queueTable->setItem(currentRow, 0, status);
         queueTable->setItem(currentRow, 1, filter);
         queueTable->setItem(currentRow, 2, type);
         queueTable->setItem(currentRow, 3, bin);
         queueTable->setItem(currentRow, 4, exp);
         queueTable->setItem(currentRow, 5, iso);
         queueTable->setItem(currentRow, 6, count);
 
         m_SequenceArray.append(jsonJob);
         emit sequenceChanged(m_SequenceArray);
     }
 
     removeFromQueueB->setEnabled(true);
 
     if (queueTable->rowCount() > 0)
     {
         queueSaveAsB->setEnabled(true);
         queueSaveB->setEnabled(true);
         resetB->setEnabled(true);
         m_Dirty = true;
     }
 
     if (queueTable->rowCount() > 1)
     {
         queueUpB->setEnabled(true);
         queueDownB->setEnabled(true);
     }
 
     if (m_JobUnderEdit)
     {
         m_JobUnderEdit = false;
         resetJobEdit();
         appendLogText(i18n("Job #%1 changes applied.", currentRow + 1));
 
         m_SequenceArray.replace(currentRow, jsonJob);
         emit sequenceChanged(m_SequenceArray);
     }
 
     return true;
 }
 
 void Capture::removeJob(int index)
 {
     if (m_State != CAPTURE_IDLE && m_State != CAPTURE_ABORTED && m_State != CAPTURE_COMPLETE)
         return;
 
     if (m_JobUnderEdit)
     {
         resetJobEdit();
         return;
     }
 
     int currentRow = queueTable->currentRow();
     if (index >= 0)
         currentRow = index;
 
     if (currentRow < 0)
     {
         currentRow = queueTable->rowCount() - 1;
         if (currentRow < 0)
             return;
     }
 
     queueTable->removeRow(currentRow);
 
     m_SequenceArray.removeAt(currentRow);
     emit sequenceChanged(m_SequenceArray);
 
     SequenceJob *job = jobs.at(currentRow);
     jobs.removeOne(job);
     if (job == activeJob)
         activeJob = nullptr;
 
     delete job;
 
     if (queueTable->rowCount() == 0)
         removeFromQueueB->setEnabled(false);
 
     if (queueTable->rowCount() == 1)
     {
         queueUpB->setEnabled(false);
         queueDownB->setEnabled(false);
     }
 
     for (int i = 0; i < jobs.count(); i++)
         jobs.at(i)->setStatusCell(queueTable->item(i, 0));
 
     queueTable->selectRow(queueTable->currentRow());
 
     if (queueTable->rowCount() == 0)
     {
         queueSaveAsB->setEnabled(false);
         queueSaveB->setEnabled(false);
         resetB->setEnabled(false);
     }
 
     m_Dirty = true;
 }
 
 void Capture::moveJobUp()
 {
     int currentRow = queueTable->currentRow();
 
     int columnCount = queueTable->columnCount();
 
     if (currentRow <= 0 || queueTable->rowCount() == 1)
         return;
 
     int destinationRow = currentRow - 1;
 
     for (int i = 0; i < columnCount; i++)
     {
         QTableWidgetItem *downItem = queueTable->takeItem(currentRow, i);
         QTableWidgetItem *upItem   = queueTable->takeItem(destinationRow, i);
 
         queueTable->setItem(destinationRow, i, downItem);
         queueTable->setItem(currentRow, i, upItem);
     }
 
     SequenceJob *job = jobs.takeAt(currentRow);
 
     jobs.removeOne(job);
     jobs.insert(destinationRow, job);
 
     QJsonObject currentJob = m_SequenceArray[currentRow].toObject();
     m_SequenceArray.replace(currentRow, m_SequenceArray[destinationRow]);
     m_SequenceArray.replace(destinationRow, currentJob);
     emit sequenceChanged(m_SequenceArray);
 
     queueTable->selectRow(destinationRow);
 
     for (int i = 0; i < jobs.count(); i++)
         jobs.at(i)->setStatusCell(queueTable->item(i, 0));
 
     m_Dirty = true;
 }
 
 void Capture::moveJobDown()
 {
     int currentRow = queueTable->currentRow();
 
     int columnCount = queueTable->columnCount();
 
     if (currentRow < 0 || queueTable->rowCount() == 1 || (currentRow + 1) == queueTable->rowCount())
         return;
 
     int destinationRow = currentRow + 1;
 
     for (int i = 0; i < columnCount; i++)
     {
         QTableWidgetItem *downItem = queueTable->takeItem(currentRow, i);
         QTableWidgetItem *upItem   = queueTable->takeItem(destinationRow, i);
 
         queueTable->setItem(destinationRow, i, downItem);
         queueTable->setItem(currentRow, i, upItem);
     }
 
     SequenceJob *job = jobs.takeAt(currentRow);
 
     jobs.removeOne(job);
     jobs.insert(destinationRow, job);
 
     QJsonObject currentJob = m_SequenceArray[currentRow].toObject();
     m_SequenceArray.replace(currentRow, m_SequenceArray[destinationRow]);
     m_SequenceArray.replace(destinationRow, currentJob);
     emit sequenceChanged(m_SequenceArray);
 
     queueTable->selectRow(destinationRow);
 
     for (int i = 0; i < jobs.count(); i++)
         jobs.at(i)->setStatusCell(queueTable->item(i, 0));
 
     m_Dirty = true;
 }
 
 void Capture::setBusy(bool enable)
 {
     isBusy = enable;
 
     enable ? pi->startAnimation() : pi->stopAnimation();
     previewB->setEnabled(!enable);
 
     foreach (QAbstractButton *button, queueEditButtonGroup->buttons())
         button->setEnabled(!enable);
 }
 
 void Capture::prepareJob(SequenceJob *job)
 {
     activeJob = job;
 
     qCDebug(KSTARS_EKOS_CAPTURE) << "Preparing capture job" << job->getSignature() << "for execution.";
 
     if (activeJob->getActiveCCD() != currentCCD)
     {
         setCamera(activeJob->getActiveCCD()->getDeviceName());
     }
 
     /*if (activeJob->isPreview())
         seqTotalCount = -1;
     else
         seqTotalCount = activeJob->getCount();*/
 
     seqDelay = activeJob->getDelay();
 
     // seqCurrentCount = activeJob->getCompleted();
 
     if (activeJob->isPreview() == false)
     {
         fullImgCountOUT->setText(QString("%L1").arg(activeJob->getCount()));
         currentImgCountOUT->setText(QString("%L1").arg(activeJob->getCompleted()));
 
         // set the progress info
         imgProgress->setEnabled(true);
         imgProgress->setMaximum(activeJob->getCount());
         imgProgress->setValue(activeJob->getCompleted());
 
         if (currentCCD->getUploadMode() != ISD::CCD::UPLOAD_LOCAL)
             updateSequencePrefix(activeJob->getFullPrefix(), QFileInfo(activeJob->getSignature()).path());
     }
 
     // We check if the job is already fully or partially complete by checking how many files of its type exist on the file system
     if (activeJob->isPreview() == false)
     {
         // The signature is the unique identification path in the system for a particular job. Format is "<storage path>/<target>/<frame type>/<filter name>".
         // If the Scheduler is requesting the Capture tab to process a sequence job, a target name will be inserted after the sequence file storage field (e.g. /path/to/storage/target/Light/...)
         // If the end-user is requesting the Capture tab to process a sequence job, the sequence file storage will be used as is (e.g. /path/to/storage/Light/...)
         QString signature = activeJob->getSignature();
 
         // Now check on the file system ALL the files that exist with the above signature
         // If 29 files exist for example, then nextSequenceID would be the NEXT file number (30)
         // Therefore, we know how to number the next file.
         // However, we do not deduce the number of captures to process from this function.
         checkSeqBoundary(signature);
 
         // Captured Frames Map contains a list of signatures:count of _already_ captured files in the file system.
         // This map is set by the Scheduler in order to complete efficiently the required captures.
         // When the end-user requests a sequence to be processed, that map is empty.
         //
         // Example with a 5xL-5xR-5xG-5xB sequence
         //
         // When the end-user loads and runs this sequence, each filter gets to capture 5 frames, then the procedure stops.
         // When the Scheduler executes a job with this sequence, the procedure depends on what is in the storage.
-        // 
+        //
         // Let's consider the Scheduler has 3 instances of this job to run.
-        // 
+        //
         // When the first job completes the sequence, there are 20 images in the file system (5 for each filter).
         // When the second job starts, Scheduler finds those 20 images but requires 20 more images, thus sets the frames map counters to 0 for all LRGB frames.
         // When the third job starts, Scheduler now has 40 images, but still requires 20 more, thus again sets the frames map counters to 0 for all LRGB frames.
-        // 
+        //
         // Now let's consider something went wrong, and the third job was aborted before getting to 60 images, say we have full LRG, but only 1xB.
         // When Scheduler attempts to run the aborted job again, it will count captures in storage, subtract previous job requirements, and set the frames map counters to 0 for LRG, and 4 for B.
         // When the sequence runs, the procedure will bypass LRG and proceed to capture 4xB.
         if (capturedFramesMap.contains(signature))
         {
             // Get the current capture count from the map
             int count = capturedFramesMap[signature];
 
             // Count how many captures this job has to process, given that previous jobs may have done some work already
             foreach (SequenceJob *a_job, jobs)
                 if (a_job == activeJob)
                     break;
                 else if (a_job->getSignature() == activeJob->getSignature())
                     count -= a_job->getCompleted();
 
             // This is the current completion count of the current job
             activeJob->setCompleted(count);
         }
         // JM 2018-09-24: Only set completed jobs to 0 IF the scheduler set captured frames map to begin with
         // If the map is empty, then no scheduler is used and it should proceed as normal.
         else if (capturedFramesMap.count() > 0)
         {
             // No preliminary information, we reset the job count and run the job unconditionally to clarify the behavior
             activeJob->setCompleted(0);
         }
         // JM 2018-09-24: In case ignoreJobProgress is enabled
         // We check if this particular job progress ignore flag is set. If not,
         // then we set it and reset completed to zero. Next time it is evaluated here again
         // It will maintain its count regardless
         else if (ignoreJobProgress && activeJob->getJobProgressIgnored() == false)
         {
             activeJob->setJobProgressIgnored(true);
             activeJob->setCompleted(0);
         }
         // We cannot rely on sequenceID to give us a count - if we don't ignore job progress, we leave the count as it was originally
 #if 0
         // If we cannot ignore job progress, then we set completed job number according to what
         // was found on the file system.
         else if (ignoreJobProgress == false)
         {
             int count = nextSequenceID - 1;
             if (count < activeJob->getCount())
                 activeJob->setCompleted(count);
             else
                 activeJob->setCompleted(activeJob->getCount());
         }
 #endif
 
         // Check whether active job is complete by comparing required captures to what is already available
         if (activeJob->getCount() <= activeJob->getCompleted())
         {
             activeJob->setCompleted(activeJob->getCount());
             appendLogText(i18n("Job requires %1-second %2 images, has already %3/%4 captures and does not need to run.",
                     QString("%L1").arg(job->getExposure(), 0, 'f', 3), job->getFilterName(),
                     activeJob->getCompleted(), activeJob->getCount()));
             processJobCompletion();
 
             /* FIXME: find a clearer way to exit here */
             return;
         }
         else
         {
             // There are captures to process
             currentImgCountOUT->setText(QString("%L1").arg(activeJob->getCompleted()));
             appendLogText(i18n("Job requires %1-second %2 images, has %3/%4 frames captured and will be processed.",
                     QString("%L1").arg(job->getExposure(), 0, 'f', 3), job->getFilterName(),
                     activeJob->getCompleted(), activeJob->getCount()));
 
             // Emit progress update - done a few lines below
             // emit newImage(nullptr, activeJob);
 
             currentCCD->setNextSequenceID(nextSequenceID);
         }
     }
 
     if (currentCCD->isBLOBEnabled() == false)
     {
         // FIXME: Move this warning pop-up elsewhere, it will interfere with automation.
         if (Options::guiderType() != Ekos::Guide::GUIDE_INTERNAL || KMessageBox::questionYesNo(nullptr, i18n("Image transfer is disabled for this camera. Would you like to enable it?")) ==
                 KMessageBox::Yes)
         {
             currentCCD->setBLOBEnabled(true);
         }
         else
         {
             setBusy(false);
             return;
         }
     }
 
     // Just notification of active job stating up
     emit newImage(activeJob);
 
     //connect(job, SIGNAL(checkFocus()), this, &Ekos::Capture::startPostFilterAutoFocus()));
 
     // Reset calibration stage
     if (calibrationStage == CAL_CAPTURING)
     {
         if (job->getFrameType() != FRAME_LIGHT)
             calibrationStage = CAL_PRECAPTURE_COMPLETE;
         else
             calibrationStage = CAL_NONE;
     }
 
     /* Disable this restriction, let the sequence run even if focus did not run prior to the capture.
      * Besides, this locks up the Scheduler when the Capture module starts a sequence without any prior focus procedure done.
      * This is quite an old code block. The message "Manual scheduled" seems to even refer to some manual intervention?
      * With the new HFR threshold, it might be interesting to prevent the execution because we actually need an HFR value to
      * begin capturing, but even there, on one hand it makes sense for the end-user to know what HFR to put in the edit box,
      * and on the other hand the focus procedure will deduce the next HFR automatically.
      * But in the end, it's not entirely clear what the intent was. Note there is still a warning that a preliminary autofocus
      * procedure is important to avoid any surprise that could make the whole schedule ineffective.
      */
 #if 0
     // If we haven't performed a single autofocus yet, we stop
     //if (!job->isPreview() && Options::enforceRefocusEveryN() && autoFocusReady && isInSequenceFocus == false && firstAutoFocus == true)
     if (!job->isPreview() && Options::enforceRefocusEveryN() && autoFocusReady == false && isInSequenceFocus == false)
     {
         appendLogText(i18n("Manual scheduled focusing is not supported. Run Autofocus process before trying again."));
         abort();
         return;
     }
 #endif
 
 #if 0
     if (currentFilterPosition > 0)
     {
         // If we haven't performed a single autofocus yet, we stop
         if (!job->isPreview() && Options::autoFocusOnFilterChange() && (isInSequenceFocus == false && firstAutoFocus == true))
         {
             appendLogText(i18n(
                               "Manual focusing post filter change is not supported. Run Autofocus process before trying again."));
             abort();
             return;
         }
 
         /*
         if (currentFilterPosition != activeJob->getTargetFilter() && filterFocusOffsets.empty() == false)
         {
             int16_t targetFilterOffset = 0;
             foreach (FocusOffset *offset, filterFocusOffsets)
             {
                 if (offset->filter == activeJob->getFilterName())
                 {
                     targetFilterOffset = offset->offset - lastFilterOffset;
                     lastFilterOffset   = offset->offset;
                     break;
                 }
             }
 
             if (targetFilterOffset != 0 &&
                 (activeJob->getFrameType() == FRAME_LIGHT || activeJob->getFrameType() == FRAME_FLAT))
             {
                 appendLogText(i18n("Adjust focus offset by %1 steps", targetFilterOffset));
                 secondsLabel->setText(i18n("Adjusting filter offset"));
 
                 if (activeJob->isPreview() == false)
                 {
                     state = CAPTURE_FILTER_FOCUS;
                     emit newStatus(Ekos::CAPTURE_FILTER_FOCUS);
                 }
 
                 setBusy(true);
 
                 emit newFocusOffset(targetFilterOffset);
 
                 return;
             }
         }
         */
     }
 #endif
 
     preparePreCaptureActions();
 }
 
 void Capture::preparePreCaptureActions()
 {
     // Update position
     if (m_CurrentFilterPosition > 0)
         activeJob->setCurrentFilter(m_CurrentFilterPosition);
 
     // update temperature
     if (currentCCD->hasCooler() && activeJob->getEnforceTemperature())
     {
         double temperature = 0;
         currentCCD->getTemperature(&temperature);
         activeJob->setCurrentTemperature(temperature);
     }
 
     // update rotator angle
     if (currentRotator != nullptr && activeJob->getTargetRotation() != Ekos::INVALID_VALUE)
         activeJob->setCurrentRotation(rotatorSettings->getCurrentRotationPA());
 
     setBusy(true);
 
     if (activeJob->isPreview())
     {
         startB->setIcon(
                     QIcon::fromTheme("media-playback-stop"));
         startB->setToolTip(i18n("Stop"));
     }
 
     connect(activeJob, &SequenceJob::prepareState, this, &Ekos::Capture::updatePrepareState);
     connect(activeJob, &SequenceJob::prepareComplete, this, &Ekos::Capture::executeJob);
 
     activeJob->prepareCapture();
 }
 
 void Capture::updatePrepareState(Ekos::CaptureState prepareState)
 {
     m_State = prepareState;
     emit newStatus(prepareState);
 
     switch (prepareState)
     {
     case CAPTURE_SETTING_TEMPERATURE:
         appendLogText(i18n("Setting temperature to %1 C...", activeJob->getTargetTemperature()));
         secondsLabel->setText(i18n("Set %1 C...", activeJob->getTargetTemperature()));
         break;
 
     case CAPTURE_SETTING_ROTATOR:
         appendLogText(i18n("Setting rotation to %1 degrees E of N...", activeJob->getTargetRotation()));
         secondsLabel->setText(i18n("Set Rotator %1...", activeJob->getTargetRotation()));
         break;
 
     default:
         break;
 
     }
 }
 
 void Capture::executeJob()
 {
     activeJob->disconnect(this);
 
     QMap<QString, QString> FITSHeader;
     if (m_ObserverName.isEmpty() == false)
         FITSHeader["FITS_OBSERVER"] = m_ObserverName;
     if (m_TargetName.isEmpty() == false)
         FITSHeader["FITS_OBJECT"] = m_TargetName;
     else if (activeJob->getRawPrefix().isEmpty() == false)
     {
         FITSHeader["FITS_OBJECT"] = activeJob->getRawPrefix();
     }
 
     if (FITSHeader.count() > 0)
         currentCCD->setFITSHeader(FITSHeader);
 
     // Update button status
     setBusy(true);
 
     useGuideHead = (activeJob->getActiveChip()->getType() == ISD::CCDChip::PRIMARY_CCD) ? false : true;
 
     syncGUIToJob(activeJob);
 
     updatePreCaptureCalibrationStatus();
 
     // Check calibration frame requirements
 #if 0
     if (activeJob->getFrameType() != FRAME_LIGHT && activeJob->isPreview() == false)
     {
         updatePreCaptureCalibrationStatus();
         return;
     }
 
     captureImage();
 #endif
 }
 
 void Capture::updatePreCaptureCalibrationStatus()
 {
     // If process was aborted or stopped by the user
     if (isBusy == false)
     {
         appendLogText(i18n("Warning: Calibration process was prematurely terminated."));
         return;
     }
 
     IPState rc = processPreCaptureCalibrationStage();
 
     if (rc == IPS_ALERT)
         return;
     else if (rc == IPS_BUSY)
     {
         secondsLabel->clear();
         QTimer::singleShot(1000, this, &Ekos::Capture::updatePreCaptureCalibrationStatus);
         return;
     }
 
     captureImage();
 }
 
 void Capture::setGuideDeviation(double delta_ra, double delta_dec)
 {
 //    if (activeJob == nullptr)
 //    {
 //        if (deviationDetected == false)
 //            return;
 
 //        // Try to find first job that was aborted due to deviation
 //        for(SequenceJob *job : jobs)
 //        {
 //            if (job->getStatus() == SequenceJob::JOB_ABORTED)
 //            {
 //                activeJob = job;
 //                break;
 //            }
 //        }
 
 //        if (activeJob == nullptr)
 //            return;
 //    }
 
     // If guiding is started after a meridian flip we will start getting guide deviations again
     // if the guide deviations are within our limits, we resume the sequence
     if (meridianFlipStage == MF_GUIDING)
     {
         double deviation_rms = sqrt(delta_ra * delta_ra + delta_dec * delta_dec);
         // If the user didn't select any guiding deviation, we fall through
         // otherwise we can for deviation RMS
         if (guideDeviationCheck->isChecked() == false || deviation_rms < guideDeviation->value())
         {
             initialHA = getCurrentHA();
             appendLogText(i18n("Post meridian flip calibration completed successfully."));
             resumeSequence();
             // N.B. Set meridian flip stage AFTER resumeSequence() always
             meridianFlipStage = MF_NONE;
             return;
         }
     }
 
     // We don't enforce limit on previews
     if (guideDeviationCheck->isChecked() == false || (activeJob && (activeJob->isPreview() || activeJob->getExposeLeft() == 0)))
         return;
 
     double deviation_rms = sqrt(delta_ra * delta_ra + delta_dec * delta_dec);
 
     QString deviationText = QString("%1").arg(deviation_rms, 0, 'f', 3);
 
     // If we have an active busy job, let's abort it if guiding deviation is exceeded.
     // And we accounted for the spike
     if (activeJob && activeJob->getStatus() == SequenceJob::JOB_BUSY && activeJob->getFrameType() == FRAME_LIGHT)
     {
         if (deviation_rms > guideDeviation->value())
         {
             // Ignore spikes ONCE
             if (m_SpikeDetected == false)
             {
                 m_SpikeDetected = true;
                 return;
             }
 
             appendLogText(i18n("Guiding deviation %1 exceeded limit value of %2 arcsecs, "
                                "suspending exposure and waiting for guider up to %3 seconds.",
                                deviationText, guideDeviation->value(),
                                QString("%L1").arg(guideDeviationTimer.interval()/1000.0,0,'f',3)));
 
             suspend();
 
             m_SpikeDetected     = false;
 
             // Check if we need to start meridian flip
             if (checkMeridianFlip())
                 return;
 
             m_DeviationDetected = true;
 
             guideDeviationTimer.start();
         }
         return;
     }
 
     // Find the first aborted job
     SequenceJob * abortedJob = nullptr;
     for(SequenceJob *job : jobs)
     {
         if (job->getStatus() == SequenceJob::JOB_ABORTED)
         {
             abortedJob = job;
             break;
         }
     }
 
     if (abortedJob && m_DeviationDetected)
     {
         if (deviation_rms <= guideDeviation->value())
         {
             guideDeviationTimer.stop();
 
             if (seqDelay == 0)
                 appendLogText(i18n("Guiding deviation %1 is now lower than limit value of %2 arcsecs, "
                                    "resuming exposure.",
                                    deviationText, guideDeviation->value()));
             else
                 appendLogText(i18n("Guiding deviation %1 is now lower than limit value of %2 arcsecs, "
                                    "resuming exposure in %3 seconds.",
                                    deviationText, guideDeviation->value(), seqDelay / 1000.0));
 
             QTimer::singleShot(seqDelay, this, &Ekos::Capture::start);
             return;
         }
         else appendLogText(i18n("Guiding deviation %1 is still higher than limit value of %2 arcsecs.",
                                 deviationText, guideDeviation->value()));
     }
 }
 
 void Capture::setFocusStatus(FocusState state)
 {
     // Do NOT update state if in the process of meridian flip
     if (meridianFlipStage != MF_NONE)
         return;
 
     focusState = state;
 
     if (focusState > FOCUS_ABORTED)
         return;
 
     if (focusState == FOCUS_COMPLETE)
     {
         // enable option to have a refocus event occur if HFR goes over threshold
         autoFocusReady = true;
 
         //if (HFRPixels->value() == 0.0 && fileHFR == 0.0)
         if (fileHFR == 0.0)
         {
             QList<double> filterHFRList;
             if (m_CurrentFilterPosition > 0)
             {
                 // If we are using filters, then we retrieve which filter is currently active.
                 // We check if filter lock is used, and store that instead of the current filter.
                 // e.g. If current filter HA, but lock filter is L, then the HFR value is stored for L filter.
                 // If no lock filter exists, then we store as is (HA)
                 QString currentFilterText = FilterPosCombo->itemText(m_CurrentFilterPosition-1);
                 //QString filterLock = filterManager.data()->getFilterLock(currentFilterText);
                 //QString finalFilter = (filterLock == "--" ? currentFilterText : filterLock);
 
                 //filterHFRList = HFRMap[finalFilter];
                 filterHFRList = HFRMap[currentFilterText];
                 filterHFRList.append(focusHFR);
                 //HFRMap[finalFilter] = filterHFRList;
                 HFRMap[currentFilterText] = filterHFRList;
             }
             // No filters
             else
             {
                 filterHFRList = HFRMap["--"];
                 filterHFRList.append(focusHFR);
                 HFRMap["--"] = filterHFRList;
             }
 
             double median = focusHFR;
             int count = filterHFRList.size();
             if (Options::useMedianFocus() && count > 1)
                 median = (count % 2) ? filterHFRList[count/2] : (filterHFRList[count/2-1] + filterHFRList[count/2])/2.0;
 
             // Add 2.5% (default) to the automatic initial HFR value to allow for minute changes in HFR without need to refocus
             // in case in-sequence-focusing is used.
             HFRPixels->setValue(median + (median * (Options::hFRThresholdPercentage() / 100.0)));
         }
 
 #if 0
         if (focusHFR > 0 && firstAutoFocus && HFRPixels->value() == 0 && fileHFR == 0)
         {
             firstAutoFocus = false;
             // Add 2.5% (default) to the automatic initial HFR value to allow for minute changes in HFR without need to refocus
             // in case in-sequence-focusing is used.
             HFRPixels->setValue(focusHFR + (focusHFR * (Options::hFRThresholdPercentage() / 100.0)));
         }
 #endif
 
         // successful focus so reset elapsed time
         restartRefocusEveryNTimer();
     }
 
 #if 0
     if (activeJob &&
             (activeJob->getStatus() == SequenceJob::JOB_ABORTED || activeJob->getStatus() == SequenceJob::JOB_IDLE))
     {
         if (focusState == FOCUS_COMPLETE)
         {
             //HFRPixels->setValue(focusHFR + (focusHFR * 0.025));
             appendLogText(i18n("Focus complete."));
         }
         else if (focusState == FOCUS_FAILED)
         {
             appendLogText(i18n("Autofocus failed. Aborting exposure..."));
             secondsLabel->setText("");
             abort();
         }
         return;
     }
 #endif
 
     if ((isRefocus || isInSequenceFocus) && activeJob && activeJob->getStatus() == SequenceJob::JOB_BUSY)
     {
         secondsLabel->setText(QString());
 
         if (focusState == FOCUS_COMPLETE)
         {
             appendLogText(i18n("Focus complete."));
             startNextExposure();
         }
         else if (focusState == FOCUS_FAILED)
         {
             appendLogText(i18n("Autofocus failed. Aborting exposure..."));
             abort();
         }
     }
 }
 
 void Capture::updateHFRThreshold()
 {
     if (fileHFR != 0.0)
         return;
 
     QList<double> filterHFRList;
     if (FilterPosCombo->currentIndex() != -1)
     {
         // If we are using filters, then we retrieve which filter is currently active.
         // We check if filter lock is used, and store that instead of the current filter.
         // e.g. If current filter HA, but lock filter is L, then the HFR value is stored for L filter.
         // If no lock filter exists, then we store as is (HA)
         QString currentFilterText = FilterPosCombo->currentText();
         QString filterLock = filterManager.data()->getFilterLock(currentFilterText);
         QString finalFilter = (filterLock == "--" ? currentFilterText : filterLock);
 
         filterHFRList = HFRMap[finalFilter];
     }
     // No filters
     else
     {
         filterHFRList = HFRMap["--"];
     }
 
     double median = 0;
     int count = filterHFRList.size();
     if (count > 1)
         median = (count % 2) ? filterHFRList[count/2] : (filterHFRList[count/2-1] + filterHFRList[count/2])/2.0;
     else if (count == 1)
         median = filterHFRList[0];
 
     // Add 2.5% (default) to the automatic initial HFR value to allow for minute changes in HFR without need to refocus
     // in case in-sequence-focusing is used.
     HFRPixels->setValue(median + (median * (Options::hFRThresholdPercentage() / 100.0)));
 }
 
 int Capture::getTotalFramesCount(QString signature)
 {
     int  result = 0;
     bool found  = false;
 
     foreach (SequenceJob *job, jobs)
     {
         // FIXME: this should be part of SequenceJob
         QString sig = job->getSignature();
         if (sig == signature)
         {
             result += job->getCount();
             found = true;
         }
     }
 
     if (found)
         return result;
     else
         return -1;
 }
 
 
 void Capture::setRotator(ISD::GDInterface *newRotator)
 {
     currentRotator = newRotator;
     connect(currentRotator, &ISD::GDInterface::numberUpdated, this, &Ekos::Capture::updateRotatorNumber, Qt::UniqueConnection);
     rotatorB->setEnabled(true);
 
     rotatorSettings->setRotator(newRotator);
 
     INumberVectorProperty *nvp = newRotator->getBaseDevice()->getNumber("ABS_ROTATOR_ANGLE");
     rotatorSettings->setCurrentAngle(nvp->np[0].value);
 }
 
 void Capture::setTelescope(ISD::GDInterface *newTelescope)
 {
     currentTelescope = static_cast<ISD::Telescope *>(newTelescope);
 
     connect(currentTelescope, &ISD::GDInterface::numberUpdated, this, &Ekos::Capture::processTelescopeNumber, Qt::UniqueConnection);
 
     meridianHours->setEnabled(true);
 
     syncTelescopeInfo();
 }
 
 void Capture::syncTelescopeInfo()
 {
     if (currentTelescope && currentTelescope->isConnected())
     {
         // Sync ALL CCDs to current telescope
         for (ISD::CCD *oneCCD : CCDs)
         {
             ITextVectorProperty *activeDevices = oneCCD->getBaseDevice()->getText("ACTIVE_DEVICES");
             if (activeDevices)
             {
                 IText *activeTelescope = IUFindText(activeDevices, "ACTIVE_TELESCOPE");
                 if (activeTelescope)
                 {
                     IUSaveText(activeTelescope, currentTelescope->getDeviceName());
                     oneCCD->getDriverInfo()->getClientManager()->sendNewText(activeDevices);
                 }
             }
         }
     }
 }
 
 void Capture::saveFITSDirectory()
 {
     QString dir =
             QFileDialog::getExistingDirectory(KStars::Instance(), i18n("FITS Save Directory"), dirPath.toLocalFile());
 
     if (dir.isEmpty())
         return;
 
     fitsDir->setText(dir);
 }
 
 void Capture::loadSequenceQueue()
 {
     QUrl fileURL = QFileDialog::getOpenFileUrl(KStars::Instance(), i18n("Open Ekos Sequence Queue"), dirPath, "Ekos Sequence Queue (*.esq)");
     if (fileURL.isEmpty())
         return;
 
     if (fileURL.isValid() == false)
     {
         QString message = i18n("Invalid URL: %1", fileURL.toLocalFile());
         KMessageBox::sorry(nullptr, message, i18n("Invalid URL"));
         return;
     }
 
     dirPath = QUrl(fileURL.url(QUrl::RemoveFilename));
 
     loadSequenceQueue(fileURL.toLocalFile());
 }
 
 bool Capture::loadSequenceQueue(const QString &fileURL)
 {
     QFile sFile(fileURL);
     if (!sFile.open(QIODevice::ReadOnly))
     {
         QString message = i18n("Unable to open file %1", fileURL);
         KMessageBox::sorry(nullptr, message, i18n("Could Not Open File"));
         return false;
     }
 
     capturedFramesMap.clear();
     clearSequenceQueue();
 
     LilXML *xmlParser = newLilXML();
 
     char errmsg[MAXRBUF];
     XMLEle *root = nullptr;
     XMLEle *ep   = nullptr;
     char c;
 
     // We expect all data read from the XML to be in the C locale - QLocale::c().
     QLocale cLocale = QLocale::c();
 
     while (sFile.getChar(&c))
     {
         root = readXMLEle(xmlParser, c, errmsg);
 
         if (root)
         {
             double sqVersion = cLocale.toFloat(findXMLAttValu(root, "version"));
             if (sqVersion < SQ_COMPAT_VERSION)
             {
                 appendLogText(i18n("Deprecated sequence file format version %1. Please construct a new sequence file.",
                                    sqVersion));
                 return false;
             }
 
             for (ep = nextXMLEle(root, 1); ep != nullptr; ep = nextXMLEle(root, 0))
             {
                 if (!strcmp(tagXMLEle(ep), "Observer"))
                 {
                     m_ObserverName = QString(pcdataXMLEle(ep));
                 }
                 else if (!strcmp(tagXMLEle(ep), "GuideDeviation"))
                 {
                     guideDeviationCheck->setChecked(!strcmp(findXMLAttValu(ep, "enabled"), "true"));
                     guideDeviation->setValue(cLocale.toDouble(pcdataXMLEle(ep)));
                 }
                 else if (!strcmp(tagXMLEle(ep), "Autofocus"))
                 {
                     autofocusCheck->setChecked(!strcmp(findXMLAttValu(ep, "enabled"), "true"));
                     double const HFRValue = cLocale.toDouble(pcdataXMLEle(ep));
                     // Set the HFR value from XML, or reset it to zero, don't let another unrelated older HFR be used
                     // Note that HFR value will only be serialized to XML when option "Save Sequence HFR to File" is enabled
                     fileHFR = HFRValue > 0.0 ? HFRValue : 0.0;
                     HFRPixels->setValue(fileHFR);
                 }
                 else if (!strcmp(tagXMLEle(ep), "RefocusEveryN"))
                 {
                     refocusEveryNCheck->setChecked(!strcmp(findXMLAttValu(ep, "enabled"), "true"));
                     int const minutesValue = cLocale.toInt(pcdataXMLEle(ep));
                     // Set the refocus period from XML, or reset it to zero, don't let another unrelated older refocus period be used.
                     refocusEveryNMinutesValue = minutesValue > 0 ? minutesValue : 0;
                     refocusEveryN->setValue(refocusEveryNMinutesValue);
                 }
                 else if (!strcmp(tagXMLEle(ep), "MeridianFlip"))
                 {
                     meridianCheck->setChecked(!strcmp(findXMLAttValu(ep, "enabled"), "true"));
                     meridianHours->setValue(cLocale.toDouble(pcdataXMLEle(ep)));
                 }
                 else if (!strcmp(tagXMLEle(ep), "CCD"))
                 {
                     CCDCaptureCombo->setCurrentText(pcdataXMLEle(ep));
                     // Signal "activated" of QComboBox does not fire when changing the text programmatically
                     setCamera(pcdataXMLEle(ep));
                 }
                 else if (!strcmp(tagXMLEle(ep), "FilterWheel"))
                 {
                     FilterDevicesCombo->setCurrentText(pcdataXMLEle(ep));
                     checkFilter();
                 }
                 else
                 {
                     processJobInfo(ep);
                 }
             }
             delXMLEle(root);
         }
         else if (errmsg[0])
         {
             appendLogText(QString(errmsg));
             delLilXML(xmlParser);
             return false;
         }
     }
 
     m_SequenceURL = QUrl::fromLocalFile(fileURL);
     m_Dirty      = false;
     delLilXML(xmlParser);
 
     return true;
 }
 
 bool Capture::processJobInfo(XMLEle *root)
 {
     XMLEle *ep;
     XMLEle *subEP;
     rotatorSettings->setRotationEnforced(false);
 
     QLocale cLocale = QLocale::c();
 
     for (ep = nextXMLEle(root, 1); ep != nullptr; ep = nextXMLEle(root, 0))
     {
         if (!strcmp(tagXMLEle(ep), "Exposure"))
             exposureIN->setValue(cLocale.toDouble(pcdataXMLEle(ep)));
         else if (!strcmp(tagXMLEle(ep), "Binning"))
         {
             subEP = findXMLEle(ep, "X");
             if (subEP)
                 binXIN->setValue(cLocale.toInt(pcdataXMLEle(subEP)));
             subEP = findXMLEle(ep, "Y");
             if (subEP)
                 binYIN->setValue(cLocale.toInt(pcdataXMLEle(subEP)));
         }
         else if (!strcmp(tagXMLEle(ep), "Frame"))
         {
             subEP = findXMLEle(ep, "X");
             if (subEP)
                 frameXIN->setValue(cLocale.toInt(pcdataXMLEle(subEP)));
             subEP = findXMLEle(ep, "Y");
             if (subEP)
                 frameYIN->setValue(cLocale.toInt(pcdataXMLEle(subEP)));
             subEP = findXMLEle(ep, "W");
             if (subEP)
                 frameWIN->setValue(cLocale.toInt(pcdataXMLEle(subEP)));
             subEP = findXMLEle(ep, "H");
             if (subEP)
                 frameHIN->setValue(cLocale.toInt(pcdataXMLEle(subEP)));
         }
         else if (!strcmp(tagXMLEle(ep), "Temperature"))
         {
             if (temperatureIN->isEnabled())
                 temperatureIN->setValue(cLocale.toDouble(pcdataXMLEle(ep)));
 
             // If force attribute exist, we change temperatureCheck, otherwise do nothing.
             if (!strcmp(findXMLAttValu(ep, "force"), "true"))
                 temperatureCheck->setChecked(true);
             else if (!strcmp(findXMLAttValu(ep, "force"), "false"))
                 temperatureCheck->setChecked(false);
         }
         else if (!strcmp(tagXMLEle(ep), "Filter"))
         {
             //FilterPosCombo->setCurrentIndex(atoi(pcdataXMLEle(ep))-1);
             FilterPosCombo->setCurrentText(pcdataXMLEle(ep));
         }
         else if (!strcmp(tagXMLEle(ep), "Type"))
         {
             frameTypeCombo->setCurrentText(pcdataXMLEle(ep));
         }
         else if (!strcmp(tagXMLEle(ep), "Prefix"))
         {
             subEP = findXMLEle(ep, "RawPrefix");
             if (subEP)
                 prefixIN->setText(pcdataXMLEle(subEP));
             subEP = findXMLEle(ep, "FilterEnabled");
             if (subEP)
                 filterCheck->setChecked(!strcmp("1", pcdataXMLEle(subEP)));
             subEP = findXMLEle(ep, "ExpEnabled");
             if (subEP)
                 expDurationCheck->setChecked(!strcmp("1", pcdataXMLEle(subEP)));
             subEP = findXMLEle(ep, "TimeStampEnabled");
             if (subEP)
                 ISOCheck->setChecked(!strcmp("1", pcdataXMLEle(subEP)));
         }
         else if (!strcmp(tagXMLEle(ep), "Count"))
         {
             countIN->setValue(cLocale.toInt(pcdataXMLEle(ep)));
         }
         else if (!strcmp(tagXMLEle(ep), "Delay"))
         {
             delayIN->setValue(cLocale.toInt(pcdataXMLEle(ep)));
         }
         else if (!strcmp(tagXMLEle(ep), "PostCaptureScript"))
         {
             postCaptureScriptIN->setText(pcdataXMLEle(ep));
         }
         else if (!strcmp(tagXMLEle(ep), "FITSDirectory"))
         {
             fitsDir->setText(pcdataXMLEle(ep));
         }
         else if (!strcmp(tagXMLEle(ep), "RemoteDirectory"))
         {
             remoteDirIN->setText(pcdataXMLEle(ep));
         }
         else if (!strcmp(tagXMLEle(ep), "UploadMode"))
         {
             uploadModeCombo->setCurrentIndex(cLocale.toInt(pcdataXMLEle(ep)));
         }
         else if (!strcmp(tagXMLEle(ep), "ISOIndex"))
         {
             if (ISOCombo->isEnabled())
                 ISOCombo->setCurrentIndex(cLocale.toInt(pcdataXMLEle(ep)));
         }
         else if (!strcmp(tagXMLEle(ep), "FormatIndex"))
         {
             transferFormatCombo->setCurrentIndex(cLocale.toInt(pcdataXMLEle(ep)));
         }
         else if (!strcmp(tagXMLEle(ep), "Rotation"))
         {
             rotatorSettings->setRotationEnforced(true);
             rotatorSettings->setTargetRotationPA(cLocale.toDouble(pcdataXMLEle(ep)));
         }
         else if (!strcmp(tagXMLEle(ep), "Properties"))
         {
             QMap<QString, QMap<QString,double>> propertyMap;
 
             for (subEP = nextXMLEle(ep, 1); subEP != nullptr; subEP = nextXMLEle(ep, 0))
             {
                 QMap<QString,double> numbers;
                 XMLEle *oneNumber = nullptr;
                 for (oneNumber = nextXMLEle(subEP, 1); oneNumber != nullptr; oneNumber = nextXMLEle(subEP, 0))
                 {
                     const char *name = findXMLAttValu(oneNumber, "name");
                     numbers[name] = cLocale.toDouble(pcdataXMLEle(oneNumber));
                 }
 
                 const char *name = findXMLAttValu(subEP, "name");
                 propertyMap[name] = numbers;
             }
 
             customPropertiesDialog->setCustomProperties(propertyMap);
         }
         else if (!strcmp(tagXMLEle(ep), "Calibration"))
         {
             subEP = findXMLEle(ep, "FlatSource");
             if (subEP)
             {
                 XMLEle *typeEP = findXMLEle(subEP, "Type");
                 if (typeEP)
                 {
                     if (!strcmp(pcdataXMLEle(typeEP), "Manual"))
                         flatFieldSource = SOURCE_MANUAL;
                     else if (!strcmp(pcdataXMLEle(typeEP), "FlatCap"))
                         flatFieldSource = SOURCE_FLATCAP;
                     else if (!strcmp(pcdataXMLEle(typeEP), "DarkCap"))
                         flatFieldSource = SOURCE_DARKCAP;
                     else if (!strcmp(pcdataXMLEle(typeEP), "Wall"))
                     {
                         XMLEle *azEP  = findXMLEle(subEP, "Az");
                         XMLEle *altEP = findXMLEle(subEP, "Alt");
 
                         if (azEP && altEP)
                         {
                             flatFieldSource = SOURCE_WALL;
                             wallCoord.setAz(cLocale.toDouble(pcdataXMLEle(azEP)));
                             wallCoord.setAlt(cLocale.toDouble(pcdataXMLEle(altEP)));
                         }
                     }
                     else
                         flatFieldSource = SOURCE_DAWN_DUSK;
                 }
             }
 
             subEP = findXMLEle(ep, "FlatDuration");
             if (subEP)
             {
                 XMLEle *typeEP = findXMLEle(subEP, "Type");
                 if (typeEP)
                 {
                     if (!strcmp(pcdataXMLEle(typeEP), "Manual"))
                         flatFieldDuration = DURATION_MANUAL;
                 }
 
                 XMLEle *aduEP = findXMLEle(subEP, "Value");
                 if (aduEP)
                 {
                     flatFieldDuration = DURATION_ADU;
                     targetADU         = cLocale.toDouble(pcdataXMLEle(aduEP));
                 }
 
                 aduEP = findXMLEle(subEP, "Tolerance");
                 if (aduEP)
                 {
                     targetADUTolerance = cLocale.toDouble(pcdataXMLEle(aduEP));
                 }
             }
 
             subEP = findXMLEle(ep, "PreMountPark");
             if (subEP)
             {
                 if (!strcmp(pcdataXMLEle(subEP), "True"))
                     preMountPark = true;
                 else
                     preMountPark = false;
             }
 
             subEP = findXMLEle(ep, "PreDomePark");
             if (subEP)
             {
                 if (!strcmp(pcdataXMLEle(subEP), "True"))
                     preDomePark = true;
                 else
                     preDomePark = false;
             }
         }
     }
 
-    addJob(false);    
+    addJob(false);
 
     return true;
 }
 
 void Capture::saveSequenceQueue()
 {
     QUrl backupCurrent = m_SequenceURL;
 
     if (m_SequenceURL.toLocalFile().startsWith(QLatin1String("/tmp/")) || m_SequenceURL.toLocalFile().contains("/Temp"))
         m_SequenceURL.clear();
 
     // If no changes made, return.
     if (m_Dirty == false && !m_SequenceURL.isEmpty())
         return;
 
     if (m_SequenceURL.isEmpty())
     {
         m_SequenceURL = QFileDialog::getSaveFileUrl(KStars::Instance(), i18n("Save Ekos Sequence Queue"), dirPath,
                                                   "Ekos Sequence Queue (*.esq)");
         // if user presses cancel
         if (m_SequenceURL.isEmpty())
         {
             m_SequenceURL = backupCurrent;
             return;
         }
 
         dirPath = QUrl(m_SequenceURL.url(QUrl::RemoveFilename));
 
         if (m_SequenceURL.toLocalFile().endsWith(QLatin1String(".esq")) == false)
             m_SequenceURL.setPath(m_SequenceURL.toLocalFile() + ".esq");
 
         /*if (QFile::exists(sequenceURL.toLocalFile()))
         {
             int r = KMessageBox::warningContinueCancel(0,
                                                        i18n("A file named \"%1\" already exists. "
                                                             "Overwrite it?",
                                                             sequenceURL.fileName()),
                                                        i18n("Overwrite File?"), KStandardGuiItem::overwrite());
             if (r == KMessageBox::Cancel)
                 return;
         }*/
     }
 
     if (m_SequenceURL.isValid())
     {
         if ((saveSequenceQueue(m_SequenceURL.toLocalFile())) == false)
         {
             KMessageBox::error(KStars::Instance(), i18n("Failed to save sequence queue"), i18n("Save"));
             return;
         }
 
         m_Dirty = false;
     }
     else
     {
         QString message = i18n("Invalid URL: %1", m_SequenceURL.url());
         KMessageBox::sorry(KStars::Instance(), message, i18n("Invalid URL"));
     }
 }
 
 void Capture::saveSequenceQueueAs()
 {
     m_SequenceURL.clear();
     saveSequenceQueue();
 }
 
 bool Capture::saveSequenceQueue(const QString &path)
 {
     QFile file;
     QString rawPrefix;
     bool filterEnabled, expEnabled, tsEnabled;
     const QMap<QString, CCDFrameType> frameTypes = {
         { "Light", FRAME_LIGHT }, { "Dark", FRAME_DARK }, { "Bias", FRAME_BIAS }, { "Flat", FRAME_FLAT }
     };
 
     file.setFileName(path);
 
     if (!file.open(QIODevice::WriteOnly))
     {
         QString message = i18n("Unable to write to file %1", path);
         KMessageBox::sorry(nullptr, message, i18n("Could not open file"));
         return false;
     }
 
     QTextStream outstream(&file);
 
     // We serialize sequence data to XML using the C locale
     QLocale cLocale = QLocale::c();
 
     outstream << "<?xml version=\"1.0\" encoding=\"UTF-8\"?>" << endl;
     outstream << "<SequenceQueue version='" << SQ_FORMAT_VERSION << "'>" << endl;
     if (m_ObserverName.isEmpty() == false)
         outstream << "<Observer>" << m_ObserverName << "</Observer>" << endl;
     outstream << "<CCD>" << CCDCaptureCombo->currentText() << "</CCD>" << endl;
     outstream << "<FilterWheel>" << FilterDevicesCombo->currentText() << "</FilterWheel>" << endl;
     outstream << "<GuideDeviation enabled='" << (guideDeviationCheck->isChecked() ? "true" : "false") << "'>"
               << cLocale.toString(guideDeviation->value()) << "</GuideDeviation>" << endl;
     // Issue a warning when autofocus is enabled but Ekos options prevent HFR value from being written
     if (autofocusCheck->isChecked() && !Options::saveHFRToFile())
         appendLogText(i18n(
                     "Warning: HFR-based autofocus is set but option \"Save Sequence HFR Value to File\" is not enabled. "
                     "Current HFR value will not be written to sequence file."));
     outstream << "<Autofocus enabled='" << (autofocusCheck->isChecked() ? "true" : "false") << "'>"
               << cLocale.toString(Options::saveHFRToFile() ? HFRPixels->value() : 0) << "</Autofocus>" << endl;
     outstream << "<RefocusEveryN enabled='" << (refocusEveryNCheck->isChecked() ? "true" : "false") << "'>"
               << cLocale.toString(refocusEveryN->value()) << "</RefocusEveryN>" << endl;
     outstream << "<MeridianFlip enabled='" << (meridianCheck->isChecked() ? "true" : "false") << "'>"
               << cLocale.toString(meridianHours->value()) << "</MeridianFlip>" << endl;
     foreach (SequenceJob *job, jobs)
     {
         job->getPrefixSettings(rawPrefix, filterEnabled, expEnabled, tsEnabled);
 
         outstream << "<Job>" << endl;
 
         outstream << "<Exposure>" << cLocale.toString(job->getExposure()) << "</Exposure>" << endl;
         outstream << "<Binning>" << endl;
         outstream << "<X>" << cLocale.toString(job->getXBin()) << "</X>" << endl;
         outstream << "<Y>" << cLocale.toString(job->getXBin()) << "</Y>" << endl;
         outstream << "</Binning>" << endl;
         outstream << "<Frame>" << endl;
         outstream << "<X>" << cLocale.toString(job->getSubX()) << "</X>" << endl;
         outstream << "<Y>" << cLocale.toString(job->getSubY()) << "</Y>" << endl;
         outstream << "<W>" << cLocale.toString(job->getSubW()) << "</W>" << endl;
         outstream << "<H>" << cLocale.toString(job->getSubH()) << "</H>" << endl;
         outstream << "</Frame>" << endl;
         if (job->getTargetTemperature() != Ekos::INVALID_VALUE)
             outstream << "<Temperature force='" << (job->getEnforceTemperature() ? "true" : "false") << "'>"
                       << cLocale.toString(job->getTargetTemperature()) << "</Temperature>" << endl;
         if (job->getTargetFilter() >= 0)
             //outstream << "<Filter>" << job->getTargetFilter() << "</Filter>" << endl;
             outstream << "<Filter>" << job->getFilterName() << "</Filter>" << endl;
         outstream << "<Type>" << frameTypes.key(job->getFrameType()) << "</Type>" << endl;
         outstream << "<Prefix>" << endl;
         //outstream << "<CompletePrefix>" << job->getPrefix() << "</CompletePrefix>" << endl;
         outstream << "<RawPrefix>" << rawPrefix << "</RawPrefix>" << endl;
         outstream << "<FilterEnabled>" << (filterEnabled ? 1 : 0) << "</FilterEnabled>" << endl;
         outstream << "<ExpEnabled>" << (expEnabled ? 1 : 0) << "</ExpEnabled>" << endl;
         outstream << "<TimeStampEnabled>" << (tsEnabled ? 1 : 0) << "</TimeStampEnabled>" << endl;
         outstream << "</Prefix>" << endl;
         outstream << "<Count>" << cLocale.toString(job->getCount()) << "</Count>" << endl;
         // ms to seconds
         outstream << "<Delay>" << cLocale.toString(job->getDelay() / 1000.0) << "</Delay>" << endl;
         if (job->getPostCaptureScript().isEmpty() == false)
             outstream << "<PostCaptureScript>" << job->getPostCaptureScript() << "</PostCaptureScript>" << endl;
         outstream << "<FITSDirectory>" << job->getLocalDir() << "</FITSDirectory>" << endl;
         outstream << "<UploadMode>" << job->getUploadMode() << "</UploadMode>" << endl;
         if (job->getRemoteDir().isEmpty() == false)
             outstream << "<RemoteDirectory>" << job->getRemoteDir() << "</RemoteDirectory>" << endl;
         if (job->getISOIndex() != -1)
             outstream << "<ISOIndex>" << (job->getISOIndex()) << "</ISOIndex>" << endl;
         outstream << "<FormatIndex>" << (job->getTransforFormat()) << "</FormatIndex>" << endl;
         if (job->getTargetRotation() != Ekos::INVALID_VALUE)
             outstream << "<Rotation>" << (job->getTargetRotation()) << "</Rotation>" << endl;
         QMapIterator<QString, QMap<QString,double>> customIter(job->getCustomProperties());
         outstream << "<Properties>" << endl;
         while (customIter.hasNext())
         {
             customIter.next();
             outstream << "<NumberVector name='" << customIter.key() << "'>" << endl;
             QMap<QString,double> numbers = customIter.value();
             QMapIterator<QString,double> numberIter(numbers);
             while (numberIter.hasNext())
             {
                 numberIter.next();
                 outstream << "<OneNumber name='" << numberIter.key()
                     << "'>" << cLocale.toString(numberIter.value()) << "</OneNumber>" << endl;
             }
             outstream << "</NumberVector>" << endl;
         }
         outstream << "</Properties>" << endl;
 
         outstream << "<Calibration>" << endl;
         outstream << "<FlatSource>" << endl;
         if (job->getFlatFieldSource() == SOURCE_MANUAL)
             outstream << "<Type>Manual</Type>" << endl;
         else if (job->getFlatFieldSource() == SOURCE_FLATCAP)
             outstream << "<Type>FlatCap</Type>" << endl;
         else if (job->getFlatFieldSource() == SOURCE_DARKCAP)
             outstream << "<Type>DarkCap</Type>" << endl;
         else if (job->getFlatFieldSource() == SOURCE_WALL)
         {
             outstream << "<Type>Wall</Type>" << endl;
             outstream << "<Az>" << cLocale.toString(job->getWallCoord().az().Degrees()) << "</Az>" << endl;
             outstream << "<Alt>" << cLocale.toString(job->getWallCoord().alt().Degrees()) << "</Alt>" << endl;
         }
         else
             outstream << "<Type>DawnDust</Type>" << endl;
         outstream << "</FlatSource>" << endl;
 
         outstream << "<FlatDuration>" << endl;
         if (job->getFlatFieldDuration() == DURATION_MANUAL)
             outstream << "<Type>Manual</Type>" << endl;
         else
         {
             outstream << "<Type>ADU</Type>" << endl;
             outstream << "<Value>" << cLocale.toString(job->getTargetADU()) << "</Value>" << endl;
             outstream << "<Tolerance>" << cLocale.toString(job->getTargetADUTolerance()) << "</Tolerance>" << endl;
         }
         outstream << "</FlatDuration>" << endl;
 
         outstream << "<PreMountPark>" << (job->isPreMountPark() ? "True" : "False") << "</PreMountPark>" << endl;
         outstream << "<PreDomePark>" << (job->isPreDomePark() ? "True" : "False") << "</PreDomePark>" << endl;
         outstream << "</Calibration>" << endl;
 
         outstream << "</Job>" << endl;
     }
 
     outstream << "</SequenceQueue>" << endl;
 
     appendLogText(i18n("Sequence queue saved to %1", path));
     file.close();
     return true;
 }
 
 void Capture::resetJobs()
 {
     // Stop any running capture
     stop();
 
     // If a job is selected for edit, reset only that job
     if (m_JobUnderEdit == true)
     {
         SequenceJob * job = jobs.at(queueTable->currentRow());
         if (nullptr != job)
             job->resetStatus();
     }
     else
     {
         if (KMessageBox::warningContinueCancel(
                     nullptr, i18n("Are you sure you want to reset status of all jobs?"), i18n("Reset job status"),
                     KStandardGuiItem::cont(), KStandardGuiItem::cancel(), "reset_job_status_warning") != KMessageBox::Continue)
         {
             return;
         }
 
         foreach (SequenceJob *job, jobs)
             job->resetStatus();
     }
 
     // Also reset the storage count for all jobs
     capturedFramesMap.clear();
 
     // We're not controlled by the Scheduler, restore progress option
     ignoreJobProgress = Options::alwaysResetSequenceWhenStarting();
 }
 
 void Capture::ignoreSequenceHistory()
 {
     // This function is called independently from the Scheduler or the UI, so honor the change
     ignoreJobProgress = true;
 }
 
 void Capture::syncGUIToJob(SequenceJob *job)
 {
     QString rawPrefix;
     bool filterEnabled, expEnabled, tsEnabled;
 
     job->getPrefixSettings(rawPrefix, filterEnabled, expEnabled, tsEnabled);
 
     exposureIN->setValue(job->getExposure());
     binXIN->setValue(job->getXBin());
     binYIN->setValue(job->getYBin());
     frameXIN->setValue(job->getSubX());
     frameYIN->setValue(job->getSubY());
     frameWIN->setValue(job->getSubW());
     frameHIN->setValue(job->getSubH());
     FilterPosCombo->setCurrentIndex(job->getTargetFilter() - 1);
     frameTypeCombo->setCurrentIndex(job->getFrameType());
     prefixIN->setText(rawPrefix);
     filterCheck->setChecked(filterEnabled);
     expDurationCheck->setChecked(expEnabled);
     ISOCheck->setChecked(tsEnabled);
     countIN->setValue(job->getCount());
     delayIN->setValue(job->getDelay() / 1000);
     postCaptureScriptIN->setText(job->getPostCaptureScript());
     uploadModeCombo->setCurrentIndex(job->getUploadMode());
     remoteDirIN->setEnabled(uploadModeCombo->currentIndex() != 0);
     remoteDirIN->setText(job->getRemoteDir());
     fitsDir->setText(job->getLocalDir());
 
     // Temperature Options
     temperatureCheck->setChecked(job->getEnforceTemperature());
     if (job->getEnforceTemperature())
         temperatureIN->setValue(job->getTargetTemperature());
 
     // Flat field options
     calibrationB->setEnabled(job->getFrameType() != FRAME_LIGHT);
     flatFieldDuration  = job->getFlatFieldDuration();
     flatFieldSource    = job->getFlatFieldSource();
     targetADU          = job->getTargetADU();
     targetADUTolerance = job->getTargetADUTolerance();
     wallCoord          = job->getWallCoord();
     preMountPark       = job->isPreMountPark();
     preDomePark        = job->isPreDomePark();
 
     // Custom Properties
     customPropertiesDialog->setCustomProperties(job->getCustomProperties());
 
     if (ISOCombo->isEnabled())
         ISOCombo->setCurrentIndex(job->getISOIndex());
 
     transferFormatCombo->setCurrentIndex(job->getTransforFormat());
 
     if (job->getTargetRotation() != Ekos::INVALID_VALUE)
     {
         rotatorSettings->setRotationEnforced(true);
         rotatorSettings->setTargetRotationPA(job->getTargetRotation());
     }
     else
         rotatorSettings->setRotationEnforced(false);
 
     QJsonObject settings;
 
     settings.insert("camera", CCDCaptureCombo->currentText());
     settings.insert("fw", FilterDevicesCombo->currentText());
     settings.insert("filter", FilterPosCombo->currentText());
     settings.insert("exp", exposureIN->value());
     settings.insert("bin", binXIN->value());
     settings.insert("iso", ISOCombo->currentIndex());
     settings.insert("frameType", frameTypeCombo->currentIndex());
     settings.insert("targetTemperature", temperatureIN->value());
 
     emit settingsUpdated(settings);
 }
 
 void Capture::editJob(QModelIndex i)
 {
     SequenceJob *job = jobs.at(i.row());
 
     if (job == nullptr)
         return;
 
     syncGUIToJob(job);
 
     appendLogText(i18n("Editing job #%1...", i.row() + 1));
 
     addToQueueB->setIcon(QIcon::fromTheme("dialog-ok-apply"));
     addToQueueB->setToolTip(i18n("Apply job changes."));
     removeFromQueueB->setToolTip(i18n("Cancel job changes."));
 
     m_JobUnderEdit = true;
 }
 
 void Capture::resetJobEdit()
 {
     if (m_JobUnderEdit)
         appendLogText(i18n("Editing job canceled."));
 
     m_JobUnderEdit = false;
     addToQueueB->setIcon(QIcon::fromTheme("list-add"));
 
     addToQueueB->setToolTip(i18n("Add job to sequence queue"));
     removeFromQueueB->setToolTip(i18n("Remove job from sequence queue"));
 }
 
 void Capture::constructPrefix(QString &imagePrefix)
 {
     if (imagePrefix.isEmpty() == false)
         imagePrefix += '_';
 
     imagePrefix += frameTypeCombo->currentText();
 
     /*if (filterCheck->isChecked() && FilterPosCombo->currentText().isEmpty() == false &&
             frameTypeCombo->currentText().compare("Bias", Qt::CaseInsensitive) &&
             frameTypeCombo->currentText().compare("Dark", Qt::CaseInsensitive))*/
     if (filterCheck->isChecked() && FilterPosCombo->currentText().isEmpty() == false &&
             (frameTypeCombo->currentIndex() == FRAME_LIGHT || frameTypeCombo->currentIndex() == FRAME_FLAT))
     {
         imagePrefix += '_';
         imagePrefix += FilterPosCombo->currentText();
     }
     if (expDurationCheck->isChecked())
     {
         //if (imagePrefix.isEmpty() == false || frameTypeCheck->isChecked())
         imagePrefix += '_';
 
         double exposureValue = exposureIN->value();
 
         // Don't use the locale for exposure value in the capture file name, so that we get a "." as decimal separator
         if (exposureValue == static_cast<int>(exposureValue))
             // Whole number
             imagePrefix += QString::number(exposureIN->value(), 'd', 0) + QString("_secs");
         else
             // Decimal
             imagePrefix += QString::number(exposureIN->value(), 'f', 3) + QString("_secs");
     }
     if (ISOCheck->isChecked())
     {
         imagePrefix += SequenceJob::ISOMarker;
     }
 }
 
 double Capture::getProgressPercentage()
 {
     int totalImageCount     = 0;
     int totalImageCompleted = 0;
 
     foreach (SequenceJob *job, jobs)
     {
         totalImageCount += job->getCount();
         totalImageCompleted += job->getCompleted();
     }
 
     if (totalImageCount != 0)
         return ((static_cast<double>(totalImageCompleted) / totalImageCount) * 100.0);
     else
         return -1;
 }
 
 int Capture::getActiveJobID()
 {
     if (activeJob == nullptr)
         return -1;
 
     for (int i = 0; i < jobs.count(); i++)
     {
         if (activeJob == jobs[i])
             return i;
     }
 
     return -1;
 }
 
 int Capture::getPendingJobCount()
 {
     int completedJobs = 0;
 
     foreach (SequenceJob *job, jobs)
     {
         if (job->getStatus() == SequenceJob::JOB_DONE)
             completedJobs++;
     }
 
     return (jobs.count() - completedJobs);
 }
 
 QString Capture::getJobState(int id)
 {
     if (id < jobs.count())
     {
         SequenceJob *job = jobs.at(id);
         return job->getStatusString();
     }
 
     return QString();
 }
 
 int Capture::getJobImageProgress(int id)
 {
     if (id < jobs.count())
     {
         SequenceJob *job = jobs.at(id);
         return job->getCompleted();
     }
 
     return -1;
 }
 
 int Capture::getJobImageCount(int id)
 {
     if (id < jobs.count())
     {
         SequenceJob *job = jobs.at(id);
         return job->getCount();
     }
 
     return -1;
 }
 
 double Capture::getJobExposureProgress(int id)
 {
     if (id < jobs.count())
     {
         SequenceJob *job = jobs.at(id);
         return job->getExposeLeft();
     }
 
     return -1;
 }
 
 double Capture::getJobExposureDuration(int id)
 {
     if (id < jobs.count())
     {
         SequenceJob *job = jobs.at(id);
         return job->getExposure();
     }
 
     return -1;
 }
 
 int Capture::getJobRemainingTime(SequenceJob *job)
 {
     int remaining = 0;
 
     if (job->getStatus() == SequenceJob::JOB_BUSY)
         remaining += (job->getExposure() + job->getDelay() / 1000) * (job->getCount() - job->getCompleted()) +
                 job->getExposeLeft();
     else
         remaining += (job->getExposure() + job->getDelay() / 1000) * (job->getCount() - job->getCompleted());
 
     return remaining;
 }
 
 int Capture::getOverallRemainingTime()
 {
     double remaining = 0;
 
     foreach (SequenceJob *job, jobs)
         remaining += getJobRemainingTime(job);
 
     return remaining;
 }
 
 int Capture::getActiveJobRemainingTime()
 {
     if (activeJob == nullptr)
         return -1;
 
     return getJobRemainingTime(activeJob);
 }
 
 void Capture::setMaximumGuidingDeviation(bool enable, double value)
 {
     guideDeviationCheck->setChecked(enable);
     if (enable)
         guideDeviation->setValue(value);
 }
 
 void Capture::setInSequenceFocus(bool enable, double HFR)
 {
     autofocusCheck->setChecked(enable);
     if (enable)
         HFRPixels->setValue(HFR);
 }
 
 void Capture::setTargetTemperature(double temperature)
 {
     temperatureIN->setValue(temperature);
 }
 
 void Capture::clearSequenceQueue()
 {
     activeJob = nullptr;
     //m_TargetName.clear();
     //stop();
     qDeleteAll(jobs);
     jobs.clear();
     while (queueTable->rowCount() > 0)
         queueTable->removeRow(0);
 }
 
 QString Capture::getSequenceQueueStatus()
 {
     if (jobs.count() == 0)
         return "Invalid";
 
     if (isBusy)
         return "Running";
 
     int idle = 0, error = 0, complete = 0, aborted = 0, running = 0;
 
     foreach (SequenceJob *job, jobs)
     {
         switch (job->getStatus())
         {
         case SequenceJob::JOB_ABORTED:
             aborted++;
             break;
         case SequenceJob::JOB_BUSY:
             running++;
             break;
         case SequenceJob::JOB_DONE:
             complete++;
             break;
         case SequenceJob::JOB_ERROR:
             error++;
             break;
         case SequenceJob::JOB_IDLE:
             idle++;
             break;
         }
     }
 
     if (error > 0)
         return "Error";
 
     if (aborted > 0)
     {
         //if (guideState >= GUIDE_GUIDING && deviationDetected)
         if (m_State == CAPTURE_SUSPENDED)
             return "Suspended";
         else
             return "Aborted";
     }
 
     if (running > 0)
         return "Running";
 
     if (idle == jobs.count())
         return "Idle";
 
     if (complete == jobs.count())
         return "Complete";
 
     return "Invalid";
 }
 
 void Capture::processTelescopeNumber(INumberVectorProperty *nvp)
 {
     // If it is not ours, return.
     if (strcmp(nvp->device, currentTelescope->getDeviceName()) || strstr(nvp->name, "EQUATORIAL_") == nullptr)
         return;
 
     switch (meridianFlipStage)
     {
     case MF_NONE:
         break;
     case MF_INITIATED:
     {
         if (nvp->s == IPS_BUSY)
             meridianFlipStage = MF_FLIPPING;
     }
         break;
 
     case MF_FLIPPING:
     {
         double ra, dec;
         currentTelescope->getEqCoords(&ra, &dec);
         double diffRA = initialMountCoords.ra().Hours() - ra;
         // If the mount is actually flipping then we should see a difference in RA
         // which if it exceeded MF_RA_DIFF_LIMIT (4 hours) then we consider it to be
         // undertaking the flip. Otherwise, it's not flipping and let timeout takes care of
         // of that
         // Are there any mounts that do NOT change RA while flipping? i.e. do it silently?
         // Need to investigate that bit
         if (fabs(diffRA) > MF_RA_DIFF_LIMIT /* || nvp->s == IPS_OK*/)
             meridianFlipStage = MF_SLEWING;
     }
         break;
 
     case MF_SLEWING:
 
         if (nvp->s != IPS_OK)
             break;
 
         // If dome is syncing, wait until it stops
         if (dome && dome->isMoving())
             break;
 
         // We are at a new initialHA
         initialHA = getCurrentHA();
 
         appendLogText(i18n("Telescope completed the meridian flip."));
 
         //KNotification::event(QLatin1String("MeridianFlipCompleted"), i18n("Meridian flip is successfully completed"));
         KSNotification::event(QLatin1String("MeridianFlipCompleted"), i18n("Meridian flip is successfully completed"), KSNotification::EVENT_INFO);
 
         if (resumeAlignmentAfterFlip == true)
         {
             appendLogText(i18n("Performing post flip re-alignment..."));
             secondsLabel->setText(i18n("Aligning..."));
 
             retries = 0;
             m_State   = CAPTURE_ALIGNING;
             emit newStatus(Ekos::CAPTURE_ALIGNING);
 
             meridianFlipStage = MF_ALIGNING;
             //QTimer::singleShot(Options::settlingTime(), [this]() {emit meridialFlipTracked();});
             //emit meridialFlipTracked();
             return;
         }
 
         retries = 0;
         checkGuidingAfterFlip();
         break;
 
     default:
         break;
     }
 }
 
 void Capture::checkGuidingAfterFlip()
 {
     // If we're not autoguiding then we're done
     if (resumeGuidingAfterFlip == false)
     {
         resumeSequence();
         // N.B. Set meridian flip stage AFTER resumeSequence() always
         meridianFlipStage = MF_NONE;
     }
     else
     {
         appendLogText(i18n("Performing post flip re-calibration and guiding..."));
         secondsLabel->setText(i18n("Calibrating..."));
 
         m_State = CAPTURE_CALIBRATING;
         emit newStatus(Ekos::CAPTURE_CALIBRATING);
 
         meridianFlipStage = MF_GUIDING;
         emit meridianFlipCompleted();
     }
 }
 
 double Capture::getCurrentHA()
 {
     double currentRA, currentDEC;
 
     if (currentTelescope == nullptr)
         return Ekos::INVALID_VALUE;
 
     if (currentTelescope->getEqCoords(&currentRA, &currentDEC) == false)
     {
         appendLogText(i18n("Failed to retrieve telescope coordinates. Unable to calculate telescope's hour angle."));
         return Ekos::INVALID_VALUE;
     }
 
     /* Edge case: undefined HA at poles */
     if (90.0f == currentDEC || -90.0f == currentDEC)
         return Ekos::INVALID_VALUE;
 
     dms lst = KStarsData::Instance()->geo()->GSTtoLST(KStarsData::Instance()->clock()->utc().gst());
 
     dms ha = (lst - dms(currentRA * 15.0));
     double HA = ha.Hours();
     if (HA > 12)
         HA -= 24;
     return HA;
 }
 
 bool Capture::checkMeridianFlip()
 {
     if (currentTelescope == nullptr || meridianCheck->isChecked() == false || initialHA > 0)
         return false;
 
     // If active job is taking flat field image at a wall source
     // then do not flip.
     if (activeJob && activeJob->getFrameType() == FRAME_FLAT && activeJob->getFlatFieldSource() == SOURCE_WALL)
         return false;
 
     double currentHA = getCurrentHA();
 
     //appendLogText(i18n("Current hour angle %1", currentHA));
 
     if (currentHA == Ekos::INVALID_VALUE)
         return false;
 
     if (currentHA > meridianHours->value())
     {
         //NOTE: DO NOT make the follow sentence PLURAL as the value is in double
         appendLogText(
                 i18n("Current hour angle %1 hours exceeds meridian flip limit of %2 hours. Auto meridian flip is initiated.",
                     QString("%L1").arg(currentHA, 0, 'f', 2), QString("%L1").arg(meridianHours->value(), 0, 'f', 2)));
         meridianFlipStage = MF_INITIATED;
 
         //KNotification::event(QLatin1String("MeridianFlipStarted"), i18n("Meridian flip started"));
         KSNotification::event(QLatin1String("MeridianFlipStarted"), i18n("Meridian flip started"), KSNotification::EVENT_INFO);
 
         // Suspend guiding first before commanding a meridian flip
         //if (isAutoGuiding && currentCCD->getChip(ISD::CCDChip::GUIDE_CCD) == guideChip)
         //            emit suspendGuiding(false);
 
         // If we are autoguiding, we should resume autoguiding after flip
         resumeGuidingAfterFlip = (guideState == GUIDE_GUIDING);
 
         emit meridianFlipStarted();
 
         // Reset frame if we need to do focusing later on
         if (isInSequenceFocus || (refocusEveryNCheck->isChecked() && getRefocusEveryNTimerElapsedSec() > 0))
             emit resetFocus();
 
         //double dec;
         //currentTelescope->getEqCoords(&initialRA, &dec);
         currentTelescope->Slew(&initialMountCoords);
         secondsLabel->setText(i18n("Meridian Flip..."));
 
         retries = 0;
 
         m_State = CAPTURE_MERIDIAN_FLIP;
         emit newStatus(Ekos::CAPTURE_MERIDIAN_FLIP);
 
         QTimer::singleShot(MF_TIMER_TIMEOUT, this, &Ekos::Capture::checkMeridianFlipTimeout);
         return true;
     }
 
     return false;
 }
 
 void Capture::checkMeridianFlipTimeout()
 {
     if (meridianFlipStage == MF_NONE)
         return;
 
     if (meridianFlipStage < MF_ALIGNING)
     {
         appendLogText(i18n("Telescope meridian flip timed out. Please make sure your mount supports meridian flip."));
 
         if (++retries == 3)
         {
             //KNotification::event(QLatin1String("MeridianFlipFailed"), i18n("Meridian flip failed"));
             KSNotification::event(QLatin1String("MeridianFlipFailed"), i18n("Meridian flip failed"), KSNotification::EVENT_ALERT);
             abort();
         }
         else
         {
             //double dec;
             //currentTelescope->getEqCoords(&initialRA, &dec);
             //currentTelescope->Slew(initialRA, dec);
             currentTelescope->Slew(&initialMountCoords);
             appendLogText(i18n("Retrying meridian flip again..."));
         }
     }
 }
 
 void Capture::checkGuideDeviationTimeout()
 {
     if (activeJob && activeJob->getStatus() == SequenceJob::JOB_ABORTED && m_DeviationDetected)
     {
         appendLogText(i18n("Guide module timed out."));
         m_DeviationDetected = false;
 
         // If capture was suspended, it should be aborted (failed) now.
         if (m_State == CAPTURE_SUSPENDED)
         {
             m_State = CAPTURE_ABORTED;
             emit newStatus(m_State);
         }
     }
 }
 
 void Capture::setAlignStatus(AlignState state)
 {
     alignState = state;
 
     resumeAlignmentAfterFlip = true;
 
     switch (state)
     {
     case ALIGN_COMPLETE:
         if (meridianFlipStage == MF_ALIGNING)
         {
             appendLogText(i18n("Post flip re-alignment completed successfully."));
             retries = 0;
             checkGuidingAfterFlip();
         }
         break;
 
     case ALIGN_FAILED:
         // TODO run it 3 times before giving up
         if (meridianFlipStage == MF_ALIGNING)
         {
             if (++retries == 3)
             {
                 appendLogText(i18n("Post-flip alignment failed."));
                 abort();
             }
             else
             {
                 appendLogText(i18n("Post-flip alignment failed. Retrying..."));
                 secondsLabel->setText(i18n("Aligning..."));
 
                 this->m_State = CAPTURE_ALIGNING;
                 emit newStatus(Ekos::CAPTURE_ALIGNING);
 
                 meridianFlipStage = MF_ALIGNING;
             }
         }
         break;
 
     default:
         break;
     }
 }
 
 void Capture::setGuideStatus(GuideState state)
 {
     switch (state)
     {
     case GUIDE_IDLE:
     case GUIDE_ABORTED:
         // If Autoguiding was started before and now stopped, let's abort (unless we're doing a meridian flip)
         if (guideState == GUIDE_GUIDING && meridianFlipStage == MF_NONE && activeJob &&
                 activeJob->getStatus() == SequenceJob::JOB_BUSY)
         {
             appendLogText(i18n("Autoguiding stopped. Aborting..."));
             abort();
             autoGuideAbortedCapture = true;
         }
         break;
 
     case GUIDE_GUIDING:
     case GUIDE_CALIBRATION_SUCESS:
         // If capture was aborted due to guide abort
         // then let's resume capture once we are guiding again.
         if (autoGuideAbortedCapture &&
            (guideState == GUIDE_ABORTED || guideState == GUIDE_IDLE) &&
            (this->m_State == CAPTURE_ABORTED || this->m_State == CAPTURE_SUSPENDED))
         {
             start();
             autoGuideAbortedCapture = false;
         }
 
         autoGuideReady = true;
         break;
 
     case GUIDE_CALIBRATION_ERROR:
         // TODO try restarting calibration a couple of times before giving up
         if (meridianFlipStage == MF_GUIDING)
         {
             if (++retries == 3)
             {
                 appendLogText(i18n("Post meridian flip calibration error. Aborting..."));
                 abort();
             }
             else
             {
                 appendLogText(i18n("Post meridian flip calibration error. Restarting..."));
                 checkGuidingAfterFlip();
             }
         }
         autoGuideReady = false;
         break;
 
     case GUIDE_DITHERING_SUCCESS:
         if (Options::guidingSettle() > 0)
         {
             // N.B. Do NOT convert to i18np since guidingRate is DOUBLE value (e.g. 1.36) so we always use plural with that.
             appendLogText(i18n("Dither complete. Resuming capture in %1 seconds...", Options::guidingSettle()));
             QTimer::singleShot(Options::guidingSettle()*1000, this, &Ekos::Capture::resumeCapture);
         }
         else
         {
             appendLogText(i18n("Dither complete."));
             resumeCapture();
         }
         break;
 
     case GUIDE_DITHERING_ERROR:
         if (Options::guidingSettle() > 0)
         {
             // N.B. Do NOT convert to i18np since guidingRate is DOUBLE value (e.g. 1.36) so we always use plural with that.
             appendLogText(i18n("Warning: Dithering failed. Resuming capture in %1 seconds...", Options::guidingSettle()));
             QTimer::singleShot(Options::guidingSettle()*1000, this, &Ekos::Capture::resumeCapture);
         }
         else
         {
             appendLogText(i18n("Warning: Dithering failed."));
             resumeCapture();
         }
 
         break;
 
     default:
         break;
     }
 
     guideState = state;
 }
 
 void Capture::checkFrameType(int index)
 {
     if (index == FRAME_LIGHT)
         calibrationB->setEnabled(false);
     else
         calibrationB->setEnabled(true);
 }
 
 double Capture::setCurrentADU(double value)
 {
     double nextExposure = 0;
     double targetADU    = activeJob->getTargetADU();
     std::vector<double> coeff;
 
     // Check if saturated, then take shorter capture and discard value
     ExpRaw.append(activeJob->getExposure());
     ADURaw.append(value);
 
     qCDebug(KSTARS_EKOS_CAPTURE) << "Capture: Current ADU = " << value << " targetADU = " << targetADU
                                  << " Exposure Count: " << ExpRaw.count();
 
     // Most CCDs are quite linear so 1st degree polynomial is quite sufficient
     // But DSLRs can exhibit non-linear response curve and so a 2nd degree polynomial is more appropriate
     if (ExpRaw.count() >= 2)
     {
         if (ExpRaw.count() >= 5)
         {
             double chisq = 0;
 
             coeff = gsl_polynomial_fit(ADURaw.data(), ExpRaw.data(), ExpRaw.count(), 2, chisq);
             qCDebug(KSTARS_EKOS_CAPTURE) << "Running polynomial fitting. Found " << coeff.size() << " coefficients.";
             for (size_t i = 0; i < coeff.size(); i++)
                 qCDebug(KSTARS_EKOS_CAPTURE) << "Coeff #" << i << "=" << coeff[i];
         }
 
         bool looping = false;
         if (ExpRaw.count() >= 10)
         {
             int size = ExpRaw.count();
             looping  = (ExpRaw[size - 1] == ExpRaw[size - 2]) && (ExpRaw[size - 2] == ExpRaw[size - 3]);
             if (looping)
                 qWarning(KSTARS_EKOS_CAPTURE) << "Detected looping in polynomial results. Falling back to llsqr.";
         }
 
         // If we get invalid data, let's fall back to llsq
         // Since polyfit can be unreliable at low counts, let's only use it at the 5th exposure
         // if we don't have results already.
         if (looping || ExpRaw.count() < 5 || std::isnan(coeff[0]) || std::isinf(coeff[0]))
         {
             double a = 0, b = 0;
             llsq(ExpRaw, ADURaw, a, b);
 
             qWarning(KSTARS_EKOS_CAPTURE) << "Polynomial fitting invalid, falling back to llsq. a=" << a << " b=" << b;
 
             // If we have valid results, let's calculate next exposure
             if (a != 0)
             {
                 nextExposure = (targetADU - b) / a;
                 // If we get invalid value, let's just proceed iteratively
                 if (nextExposure < 0)
                     nextExposure = 0;
             }
         }
         else if (coeff.size() == 3)
         {
             nextExposure = coeff[0] + (coeff[1] * targetADU) + (coeff[2] * pow(targetADU, 2));
             // If we get invalid exposure time, let's try to capture again and discard last point.
             if (nextExposure < 0)
             {
                 qCDebug(KSTARS_EKOS_CAPTURE) << "Invalid polynomial exposure" << nextExposure << "Will discard last result.";
                 ExpRaw.removeLast();
                 ADURaw.removeLast();
                 nextExposure = activeJob->getExposure();
             }
         }
     }
 
     if (nextExposure == 0)
     {
         if (value < targetADU)
             nextExposure = activeJob->getExposure() * 1.25;
         else
             nextExposure = activeJob->getExposure() * .75;
     }
 
     qCDebug(KSTARS_EKOS_CAPTURE) << "next flat exposure is" << nextExposure;
 
     return nextExposure;
 }
 
 //  Based on  John Burkardt LLSQ (LGPL)
 void Capture::llsq(QVector<double> x, QVector<double> y, double &a, double &b)
 {
     double bot;
     int i;
     double top;
     double xbar;
     double ybar;
     int n = x.count();
     //
     //  Special case.
     //
     if (n == 1)
     {
         a = 0.0;
         b = y[0];
         return;
     }
     //
     //  Average X and Y.
     //
     xbar = 0.0;
     ybar = 0.0;
     for (i = 0; i < n; i++)
     {
         xbar = xbar + x[i];
         ybar = ybar + y[i];
     }
     xbar = xbar / static_cast<double>(n);
     ybar = ybar / static_cast<double>(n);
     //
     //  Compute Beta.
     //
     top = 0.0;
     bot = 0.0;
     for (i = 0; i < n; i++)
     {
         top = top + (x[i] - xbar) * (y[i] - ybar);
         bot = bot + (x[i] - xbar) * (x[i] - xbar);
     }
 
     a = top / bot;
 
     b = ybar - a * xbar;
 }
 
 void Capture::setDirty()
 {
     m_Dirty = true;
 }
 
 void Capture::setMeridianFlip(bool enable)
 {
     meridianCheck->setChecked(enable);
 }
 
 void Capture::setMeridianFlipHour(double hours)
 {
     meridianHours->setValue(hours);
 }
 
 bool Capture::hasCoolerControl()
 {
     if (currentCCD && currentCCD->hasCoolerControl())
         return true;
 
     return false;
 }
 
 bool Capture::setCoolerControl(bool enable)
 {
     if (currentCCD && currentCCD->hasCoolerControl())
         return currentCCD->setCoolerControl(enable);
 
     return false;
 }
 
 void Capture::clearAutoFocusHFR()
 {
     // If HFR limit was set from file, we cannot override it.
     if (fileHFR > 0)
         return;
 
     HFRPixels->setValue(0);
     //firstAutoFocus = true;
 }
 
 void Capture::openCalibrationDialog()
 {
     QDialog calibrationDialog;
 
     Ui_calibrationOptions calibrationOptions;
     calibrationOptions.setupUi(&calibrationDialog);
 
     if (currentTelescope)
     {
         calibrationOptions.parkMountC->setEnabled(currentTelescope->canPark());
         calibrationOptions.parkMountC->setChecked(preMountPark);
     }
     else
         calibrationOptions.parkMountC->setEnabled(false);
 
     if (dome)
     {
         calibrationOptions.parkDomeC->setEnabled(dome->canPark());
         calibrationOptions.parkDomeC->setChecked(preDomePark);
     }
     else
         calibrationOptions.parkDomeC->setEnabled(false);
 
     //connect(calibrationOptions.wallSourceC, SIGNAL(toggled(bool)), calibrationOptions.parkC, &Ekos::Capture::setDisabled(bool)));
 
     switch (flatFieldSource)
     {
     case SOURCE_MANUAL:
         calibrationOptions.manualSourceC->setChecked(true);
         break;
 
     case SOURCE_FLATCAP:
         calibrationOptions.flatDeviceSourceC->setChecked(true);
         break;
 
     case SOURCE_DARKCAP:
         calibrationOptions.darkDeviceSourceC->setChecked(true);
         break;
 
     case SOURCE_WALL:
         calibrationOptions.wallSourceC->setChecked(true);
         calibrationOptions.azBox->setText(wallCoord.az().toDMSString());
         calibrationOptions.altBox->setText(wallCoord.alt().toDMSString());
         break;
 
     case SOURCE_DAWN_DUSK:
         calibrationOptions.dawnDuskFlatsC->setChecked(true);
         break;
     }
 
     switch (flatFieldDuration)
     {
     case DURATION_MANUAL:
         calibrationOptions.manualDurationC->setChecked(true);
         break;
 
     case DURATION_ADU:
         calibrationOptions.ADUC->setChecked(true);
         calibrationOptions.ADUValue->setValue(targetADU);
         calibrationOptions.ADUTolerance->setValue(targetADUTolerance);
         break;
     }
 
     if (calibrationDialog.exec() == QDialog::Accepted)
     {
         if (calibrationOptions.manualSourceC->isChecked())
             flatFieldSource = SOURCE_MANUAL;
         else if (calibrationOptions.flatDeviceSourceC->isChecked())
             flatFieldSource = SOURCE_FLATCAP;
         else if (calibrationOptions.darkDeviceSourceC->isChecked())
             flatFieldSource = SOURCE_DARKCAP;
         else if (calibrationOptions.wallSourceC->isChecked())
         {
             dms wallAz, wallAlt;
             bool azOk = false, altOk = false;
 
             wallAz  = calibrationOptions.azBox->createDms(true, &azOk);
             wallAlt = calibrationOptions.altBox->createDms(true, &altOk);
 
             if (azOk && altOk)
             {
                 flatFieldSource = SOURCE_WALL;
                 wallCoord.setAz(wallAz);
                 wallCoord.setAlt(wallAlt);
             }
             else
             {
                 calibrationOptions.manualSourceC->setChecked(true);
                 KMessageBox::error(this, i18n("Wall coordinates are invalid."));
             }
         }
         else
             flatFieldSource = SOURCE_DAWN_DUSK;
 
         if (calibrationOptions.manualDurationC->isChecked())
             flatFieldDuration = DURATION_MANUAL;
         else
         {
             flatFieldDuration  = DURATION_ADU;
             targetADU          = calibrationOptions.ADUValue->value();
             targetADUTolerance = calibrationOptions.ADUTolerance->value();
         }
 
         preMountPark = calibrationOptions.parkMountC->isChecked();
         preDomePark  = calibrationOptions.parkDomeC->isChecked();
 
         setDirty();
 
         Options::setCalibrationFlatSourceIndex(flatFieldSource);
         Options::setCalibrationFlatDurationIndex(flatFieldDuration);
         Options::setCalibrationWallAz(wallCoord.az().Degrees());
         Options::setCalibrationWallAlt(wallCoord.alt().Degrees());
         Options::setCalibrationADUValue(targetADU);
         Options::setCalibrationADUValueTolerance(targetADUTolerance);
     }
 }
 
 IPState Capture::processPreCaptureCalibrationStage()
-{    
+{
     // Unpark dust cap if we have to take light images.
     if (activeJob->getFrameType() == FRAME_LIGHT && dustCap)
     {
         if (dustCap->isLightOn() == true)
         {
             dustCapLightEnabled = false;
             dustCap->SetLightEnabled(false);
         }
 
         // If cap is not unparked, unpark it
         if (calibrationStage < CAL_DUSTCAP_UNPARKING && dustCap->isParked())
         {
             if (dustCap->UnPark())
             {
                 calibrationStage = CAL_DUSTCAP_UNPARKING;
                 appendLogText(i18n("Unparking dust cap..."));
                 return IPS_BUSY;
             }
             else
             {
                 appendLogText(i18n("Unparking dust cap failed, aborting..."));
                 abort();
                 return IPS_ALERT;
             }
         }
 
         // Wait until cap is unparked
         if (calibrationStage == CAL_DUSTCAP_UNPARKING)
         {
             if (dustCap->isUnParked() == false)
                 return IPS_BUSY;
             else
             {
                 calibrationStage = CAL_DUSTCAP_UNPARKED;
                 appendLogText(i18n("Dust cap unparked."));
             }
         }
 
         calibrationStage = CAL_PRECAPTURE_COMPLETE;
 
         if (guideState == GUIDE_SUSPENDED)
         {
             appendLogText(i18n("Autoguiding resumed."));
             emit resumeGuiding();
         }
 
 
         return IPS_OK;
     }
 
     if (activeJob->getFrameType() != FRAME_LIGHT && guideState == GUIDE_GUIDING)
     {
         appendLogText(i18n("Autoguiding suspended."));
         emit suspendGuiding();
     }
 
     // Let's check what actions to be taken, if any, for the flat field source
     switch (activeJob->getFlatFieldSource())
     {
     case SOURCE_MANUAL:
     case SOURCE_DAWN_DUSK: // Not yet implemented
         break;
 
         // For Dark, Flat, Bias: Park cap, if not parked. Turn on Light For Flat. Turn off Light for Bias + Darks
         // For Lights: Unpark cap and turn off light
     case SOURCE_FLATCAP:
         if (dustCap)
         {
             // If cap is not park, park it
             if (calibrationStage < CAL_DUSTCAP_PARKING && dustCap->isParked() == false)
             {
                 if (dustCap->Park())
                 {
                     calibrationStage = CAL_DUSTCAP_PARKING;
                     appendLogText(i18n("Parking dust cap..."));
                     return IPS_BUSY;
                 }
                 else
                 {
                     appendLogText(i18n("Parking dust cap failed, aborting..."));
                     abort();
                     return IPS_ALERT;
                 }
             }
 
             // Wait until cap is parked
             if (calibrationStage == CAL_DUSTCAP_PARKING)
             {
                 if (dustCap->isParked() == false)
                     return IPS_BUSY;
                 else
                 {
                     calibrationStage = CAL_DUSTCAP_PARKED;
                     appendLogText(i18n("Dust cap parked."));
                 }
             }
 
             // If light is not on, turn it on. For flat frames only
             if (activeJob->getFrameType() == FRAME_FLAT && dustCap->isLightOn() == false)
             {
                 dustCapLightEnabled = true;
                 dustCap->SetLightEnabled(true);
             }
             else if (activeJob->getFrameType() != FRAME_FLAT && dustCap->isLightOn() == true)
             {
                 dustCapLightEnabled = false;
                 dustCap->SetLightEnabled(false);
             }
         }
         break;
 
         // Park cap, if not parked and not flat frame
         // Unpark cap, if flat frame
         // Turn on Light
     case SOURCE_DARKCAP:
         if (dustCap)
         {
             // If cap is not park, park it if not flat frame. (external lightsource)
             if (calibrationStage < CAL_DUSTCAP_PARKING && dustCap->isParked() == false &&
                     activeJob->getFrameType() != FRAME_FLAT)
             {
                 if (dustCap->Park())
                 {
                     calibrationStage = CAL_DUSTCAP_PARKING;
                     appendLogText(i18n("Parking dust cap..."));
                     return IPS_BUSY;
                 }
                 else
                 {
                     appendLogText(i18n("Parking dust cap failed, aborting..."));
                     abort();
                     return IPS_ALERT;
                 }
             }
 
             // Wait until  cap is parked
             if (calibrationStage == CAL_DUSTCAP_PARKING)
             {
                 if (dustCap->isParked() == false)
                     return IPS_BUSY;
                 else
                 {
                     calibrationStage = CAL_DUSTCAP_PARKED;
                     appendLogText(i18n("Dust cap parked."));
                 }
             }
 
             // If cap is parked, unpark it if flat frame. (external lightsource)
             if (calibrationStage < CAL_DUSTCAP_UNPARKING && dustCap->isParked() == true &&
                     activeJob->getFrameType() == FRAME_FLAT)
             {
                 if (dustCap->UnPark())
                 {
                     calibrationStage = CAL_DUSTCAP_UNPARKING;
                     appendLogText(i18n("UnParking dust cap..."));
                     return IPS_BUSY;
                 }
                 else
                 {
                     appendLogText(i18n("UnParking dust cap failed, aborting..."));
                     abort();
                     return IPS_ALERT;
                 }
             }
 
             // Wait until  cap is parked
             if (calibrationStage == CAL_DUSTCAP_UNPARKING)
             {
                 if (dustCap->isParked() == true)
                     return IPS_BUSY;
                 else
                 {
                     calibrationStage = CAL_DUSTCAP_UNPARKED;
                     appendLogText(i18n("Dust cap unparked."));
                 }
             }
 
             // If light is not on, turn it on. For flat frames only
             if (activeJob->getFrameType() == FRAME_FLAT && dustCap->isLightOn() == false)
             {
                 dustCapLightEnabled = true;
                 dustCap->SetLightEnabled(true);
             }
             else if (activeJob->getFrameType() != FRAME_FLAT && dustCap->isLightOn() == true)
             {
                 dustCapLightEnabled = false;
                 dustCap->SetLightEnabled(false);
             }
         }
         break;
 
         // Go to wall coordinates
     case SOURCE_WALL:
         if (currentTelescope && activeJob->getFrameType() == FRAME_FLAT)
         {
             if (calibrationStage < CAL_SLEWING)
             {
                 wallCoord = activeJob->getWallCoord();
                 wallCoord.HorizontalToEquatorial(KStarsData::Instance()->lst(),
                                                  KStarsData::Instance()->geo()->lat());
                 currentTelescope->Slew(&wallCoord);
                 appendLogText(i18n("Mount slewing to wall position..."));
                 calibrationStage = CAL_SLEWING;
                 return IPS_BUSY;
             }
 
             // Check if slewing is complete
             if (calibrationStage == CAL_SLEWING)
             {
                 if (currentTelescope->isSlewing() == false)
                 {
                     // Disable mount tracking if supported by the driver.
                     currentTelescope->setTrackEnabled(false);
                     calibrationStage = CAL_SLEWING_COMPLETE;
                     appendLogText(i18n("Slew to wall position complete."));
                 }
                 else
                     return IPS_BUSY;
             }
 
             if (lightBox)
             {
                 // Check if we have a light box to turn on
                 if (activeJob->getFrameType() == FRAME_FLAT && lightBox->isLightOn() == false)
                 {
                     lightBoxLightEnabled = true;
                     lightBox->SetLightEnabled(true);
                 }
                 else if (activeJob->getFrameType() != FRAME_FLAT && lightBox->isLightOn() == true)
                 {
                     lightBoxLightEnabled = false;
                     lightBox->SetLightEnabled(false);
                 }
             }
         }
         break;
     }
 
     // Check if we need to perform mount prepark
     if (preMountPark && currentTelescope && activeJob->getFlatFieldSource() != SOURCE_WALL)
     {
         if (calibrationStage < CAL_MOUNT_PARKING && currentTelescope->isParked() == false)
         {
             if (currentTelescope->Park())
             {
                 calibrationStage = CAL_MOUNT_PARKING;
                 //emit mountParking();
                 appendLogText(i18n("Parking mount prior to calibration frames capture..."));
                 return IPS_BUSY;
             }
             else
             {
                 appendLogText(i18n("Parking mount failed, aborting..."));
                 abort();
                 return IPS_ALERT;
             }
         }
 
         if (calibrationStage == CAL_MOUNT_PARKING)
         {
             // If not parked yet, check again in 1 second
             // Otherwise proceed to the rest of the algorithm
             if (currentTelescope->isParked() == false)
                 return IPS_BUSY;
             else
             {
                 calibrationStage = CAL_MOUNT_PARKED;
                 appendLogText(i18n("Mount parked."));
             }
         }
     }
 
     // Check if we need to perform dome prepark
     if (preDomePark && dome)
     {
         if (calibrationStage < CAL_DOME_PARKING && dome->isParked() == false)
         {
             if (dome->Park())
             {
                 calibrationStage = CAL_DOME_PARKING;
                 //emit mountParking();
                 appendLogText(i18n("Parking dome..."));
                 return IPS_BUSY;
             }
             else
             {
                 appendLogText(i18n("Parking dome failed, aborting..."));
                 abort();
                 return IPS_ALERT;
             }
         }
 
         if (calibrationStage == CAL_DOME_PARKING)
         {
             // If not parked yet, check again in 1 second
             // Otherwise proceed to the rest of the algorithm
             if (dome->isParked() == false)
                 return IPS_BUSY;
             else
             {
                 calibrationStage = CAL_DOME_PARKED;
                 appendLogText(i18n("Dome parked."));
             }
         }
     }
 
     // If we used AUTOFOCUS before for a specific frame (e.g. Lum)
     // then the absolute focus position for Lum is recorded in the filter manager
     // when we take flats again, we always go back to the same focus position as the light frames to ensure
     // near identical focus for both frames.
     if (activeJob->getFrameType() == FRAME_FLAT && Options::flatSyncFocus())
     {
         if (currentFilter != nullptr)
         {
             if (filterManager->syncAbsoluteFocusPosition(activeJob->getTargetFilter()-1) == false)
                 return IPS_BUSY;
         }
     }
 
     calibrationStage = CAL_PRECAPTURE_COMPLETE;
 
     return IPS_OK;
 }
 
 bool Capture::processPostCaptureCalibrationStage()
 {
     // If there are no more images to capture, do not bother calculating next exposure
     if (calibrationStage == CAL_CALIBRATION_COMPLETE)
         if (activeJob && activeJob->getCount() <= activeJob->getCompleted())
             return true;
 
     // Check if we need to do flat field slope calculation if the user specified a desired ADU value
     if (activeJob->getFrameType() == FRAME_FLAT && activeJob->getFlatFieldDuration() == DURATION_ADU &&
             activeJob->getTargetADU() > 0)
     {
         if (Options::useFITSViewer() == false)
         {
             Options::setUseFITSViewer(true);
             qCInfo(KSTARS_EKOS_CAPTURE) << "Enabling FITS Viewer...";
         }
 
         FITSData *image_data   = nullptr;
         FITSView *currentImage = targetChip->getImageView(FITS_NORMAL);
 
         if (currentImage)
         {
             image_data        = currentImage->getImageData();
             double currentADU = image_data->getADU();
             bool outOfRange=false, saturated=false;
 
             switch (image_data->bpp())
             {
                 case 8:
                  if (activeJob->getTargetADU() > UINT8_MAX)
                      outOfRange = true;
                  else if (currentADU/UINT8_MAX > 0.95)
                      saturated = true;
                 break;
 
                 case 16:
                 if (activeJob->getTargetADU() > UINT16_MAX)
                     outOfRange = true;
                 else if (currentADU/UINT16_MAX > 0.95)
                     saturated = true;
                 break;
 
                 case 32:
                 if (activeJob->getTargetADU() > UINT32_MAX)
                     outOfRange = true;
                 else if (currentADU/UINT32_MAX > 0.95)
                     saturated = true;
                 break;
 
             default:
                 break;
             }
 
             if (outOfRange)
             {
                 appendLogText(i18n("Flat calibration failed. Captured image is only %1-bit while requested ADU is %2.", QString::number(image_data->bpp())
                                    , QString::number(activeJob->getTargetADU(), 'f', 2)));
                 abort();
                 return false;
             }
             else if (saturated)
             {
                 double nextExposure = activeJob->getExposure() * 0.1;
                 nextExposure = qBound(exposureIN->minimum(), nextExposure, exposureIN->maximum());
 
                 appendLogText(i18n("Current image is saturated (%1). Next exposure is %2 seconds.",
                                    QString::number(currentADU, 'f', 0), QString("%L1").arg(nextExposure, 0, 'f', 6)));
 
                 calibrationStage = CAL_CALIBRATION;
                 activeJob->setExposure(nextExposure);
                 activeJob->setPreview(true);
                 rememberUploadMode = activeJob->getUploadMode();
                 currentCCD->setUploadMode(ISD::CCD::UPLOAD_CLIENT);
                 startNextExposure();
                 return false;
             }
 
             double ADUDiff = fabs(currentADU - activeJob->getTargetADU());
 
             // If it is within tolerance range of target ADU
             if (ADUDiff <= targetADUTolerance)
             {
                 if (calibrationStage == CAL_CALIBRATION)
                 {
                     appendLogText(
                                 i18n("Current ADU %1 within target ADU tolerance range.", QString::number(currentADU, 'f', 0)));
                     activeJob->setPreview(false);
                     currentCCD->setUploadMode(rememberUploadMode);
 
                     // Get raw prefix
                     exposureIN->setValue(activeJob->getExposure());
                     QString imagePrefix = activeJob->getRawPrefix();
                     constructPrefix(imagePrefix);
                     activeJob->setFullPrefix(imagePrefix);
                     seqPrefix = imagePrefix;
                     currentCCD->setSeqPrefix(imagePrefix);
 
                     currentCCD->updateUploadSettings(activeJob->getRemoteDir() + activeJob->getDirectoryPostfix());
 
                     calibrationStage = CAL_CALIBRATION_COMPLETE;
                     startNextExposure();
                     return false;
                 }
 
                 return true;
             }
 
             double nextExposure = -1;
 
             // If value is saturated, try to reduce it to valid range first
             if (std::fabs(image_data->getMax(0) - image_data->getMin(0)) < 10)
                 nextExposure = activeJob->getExposure() * 0.5;
             else
                 nextExposure = setCurrentADU(currentADU);
 
             if (nextExposure <= 0 || std::isnan(nextExposure))
             {
                 appendLogText(
                             i18n("Unable to calculate optimal exposure settings, please capture the flats manually."));
                 //activeJob->setTargetADU(0);
                 //targetADU = 0;
                 abort();
                 return false;
             }
 
             // Limit to minimum and maximum values
             nextExposure = qBound(exposureIN->minimum(), nextExposure, exposureIN->maximum());
 
             appendLogText(i18n("Current ADU is %1 Next exposure is %2 seconds.", QString::number(currentADU, 'f', 0),
                                QString("%L1").arg(nextExposure, 0, 'f', 6)));
 
             calibrationStage = CAL_CALIBRATION;
             activeJob->setExposure(nextExposure);
             activeJob->setPreview(true);
             rememberUploadMode = activeJob->getUploadMode();
             currentCCD->setUploadMode(ISD::CCD::UPLOAD_CLIENT);
 
             startNextExposure();
             return false;
 
             // Start next exposure in case ADU Slope is not calculated yet
             /*if (currentSlope == 0)
             {
                 startNextExposure();
                 return;
             }*/
         }
         else
         {
             appendLogText(i18n("An empty image is received, aborting..."));
             abort();
             return false;
         }
     }
 
     calibrationStage = CAL_CALIBRATION_COMPLETE;
     return true;
 }
 
 void Capture::setNewRemoteFile(QString file)
 {
     appendLogText(i18n("Remote image saved to %1", file));
     emit newSequenceImage(file);
 }
 
 /*
 void Capture::startPostFilterAutoFocus()
 {
     if (focusState >= FOCUS_PROGRESS || state == CAPTURE_FOCUSING)
         return;
 
     secondsLabel->setText(i18n("Focusing..."));
 
     state = CAPTURE_FOCUSING;
     emit newStatus(Ekos::CAPTURE_FOCUSING);
 
     appendLogText(i18n("Post filter change Autofocus..."));
 
     // Force it to always run autofocus routine
     emit checkFocus(0.1);
 }
 */
 
 void Capture::postScriptFinished(int exitCode)
 {
     appendLogText(i18n("Post capture script finished with code %1.", exitCode));
 
     // If we're done, proceed to completion.
     if (activeJob->getCount() <= activeJob->getCompleted())
     {
         processJobCompletion();
     }
     // Else check if meridian condition is met.
     else if (checkMeridianFlip())
     {
         appendLogText(i18n("Processing meridian flip..."));
     }
     // Then if nothing else, just resume sequence.
     else
     {
         appendLogText(i18n("Resuming sequence..."));
         resumeSequence();
     }
 }
 
 // FIXME Migrate to Filter Manager
 #if 0
 void Capture::loadFilterOffsets()
-{    
+{
     // Get all OAL equipment filter list
     KStarsData::Instance()->userdb()->GetAllFilters(m_filterList);
     filterFocusOffsets.clear();
 
     for (int i = 0; i < FilterPosCombo->count(); i++)
     {
         FocusOffset *oneOffset = new FocusOffset;
         oneOffset->filter      = FilterPosCombo->itemText(i);
         oneOffset->offset      = 0;
 
         // Find matching filter if any and loads its offset
         foreach (OAL::Filter *o, m_filterList)
         {
             if (o->vendor() == FilterCaptureCombo->currentText() && o->color() == oneOffset->filter)
             {
                 oneOffset->offset = o->offset().toInt();
                 break;
             }
         }
 
         filterFocusOffsets.append(oneOffset);
     }
 }
 
 void Capture::showFilterOffsetDialog()
 {
     loadFilterOffsets();
 
     QDialog filterOffsetDialog;
 
     filterOffsetDialog.setWindowTitle(i18n("Filter Focus Offsets"));
 
     QDialogButtonBox *buttonBox =
             new QDialogButtonBox(QDialogButtonBox::Ok | QDialogButtonBox::Cancel, Qt::Horizontal, &filterOffsetDialog);
 
     connect(buttonBox, SIGNAL(accepted()), &filterOffsetDialog, &Ekos::Capture::accept()));
     connect(buttonBox, SIGNAL(rejected()), &filterOffsetDialog, &Ekos::Capture::reject()));
 
     QVBoxLayout *mainLayout = new QVBoxLayout(&filterOffsetDialog);
     QGridLayout *grid       = new QGridLayout(&filterOffsetDialog);
     QHBoxLayout *tipLayout  = new QHBoxLayout(&filterOffsetDialog);
 
     QLabel *tipIcon = new QLabel(&filterOffsetDialog);
     QLabel *tipText = new QLabel(&filterOffsetDialog);
 
     tipIcon->setPixmap(
                 QIcon::fromTheme("kstars_flag").pixmap(QSize(32, 32)));
     tipIcon->setFixedSize(32, 32);
 
     tipText->setText(i18n("Set <em>relative</em> filter focus offset in steps."));
 
     tipLayout->addWidget(tipIcon);
     tipLayout->addWidget(tipText);
 
     mainLayout->addLayout(grid);
     mainLayout->addLayout(tipLayout);
     mainLayout->addWidget(buttonBox);
 
     //filterOffsetDialog.setLayout(mainLayout);
 
     for (int i = 0; i < filterFocusOffsets.count(); i++)
     {
         FocusOffset *oneOffset = filterFocusOffsets.at(i);
 
         QLabel *label  = new QLabel(oneOffset->filter, &filterOffsetDialog);
         QSpinBox *spin = new QSpinBox(&filterOffsetDialog);
         spin->setMinimum(-10000);
         spin->setMaximum(10000);
         spin->setSingleStep(100);
         spin->setValue(oneOffset->offset);
 
         grid->addWidget(label, i, 0);
         grid->addWidget(spin, i, 1);
     }
 
     if (filterOffsetDialog.exec() == QDialog::Accepted)
     {
         for (int i = 0; i < filterFocusOffsets.count(); i++)
         {
             FocusOffset *oneOffset = filterFocusOffsets.at(i);
             oneOffset->offset      = static_cast<QSpinBox *>(grid->itemAtPosition(i, 1)->widget())->value();
 
             // Find matching filter if any and save its offset
             OAL::Filter *matchedFilter = nullptr;
 
             foreach (OAL::Filter *o, m_filterList)
             {
                 if (o->vendor() == FilterCaptureCombo->currentText() && o->color() == oneOffset->filter)
                 {
                     o->setOffset(QString::number(oneOffset->offset));
                     matchedFilter = o;
                     break;
                 }
             }
 
 #if 0
             // If no filter exists, let's create one
             if (matchedFilter == nullptr)
             {
                 KStarsData::Instance()->userdb()->AddFilter(FilterCaptureCombo->currentText(), "", "",
                                                             QString::number(oneOffset->offset), oneOffset->filter, "1");
             }
             // Or update Existing one
             else
             {
                 KStarsData::Instance()->userdb()->AddFilter(FilterCaptureCombo->currentText(), "", "",
                                                             QString::number(oneOffset->offset), oneOffset->filter,
                                                             matchedFilter->exposure(), matchedFilter->id());
             }
 #endif
         }
     }
 }
 #endif
 
 void Capture::toggleVideo(bool enabled)
 {
     if (currentCCD == nullptr)
         return;
 
     if (currentCCD->isBLOBEnabled() == false)
     {
 
         if (Options::guiderType() != Ekos::Guide::GUIDE_INTERNAL || KMessageBox::questionYesNo(nullptr, i18n("Image transfer is disabled for this camera. Would you like to enable it?")) ==
                 KMessageBox::Yes)
             currentCCD->setBLOBEnabled(true);
         else
             return;
     }
 
     currentCCD->setVideoStreamEnabled(enabled);
 }
 
 void Capture::setVideoStreamEnabled(bool enabled)
 {
     if (enabled)
     {
         liveVideoB->setChecked(true);
         liveVideoB->setIcon(QIcon::fromTheme("camera-on"));
         //liveVideoB->setStyleSheet("color:red;");
     }
     else
     {
         liveVideoB->setChecked(false);
         liveVideoB->setIcon(QIcon::fromTheme("camera-ready"));
         //liveVideoB->setStyleSheet(QString());
     }
 }
 
 void Capture::setMountStatus(ISD::Telescope::Status newState)
 {
     switch (newState)
     {
     case ISD::Telescope::MOUNT_PARKING:
     case ISD::Telescope::MOUNT_SLEWING:
     case ISD::Telescope::MOUNT_MOVING:
         previewB->setEnabled(false);
         liveVideoB->setEnabled(false);
         // Only disable when button is "Start", and not "Stopped"
         // If mount is in motion, Stopped button should always be enabled to terminate
         // the sequence
         if (pi->isAnimated() == false)
             startB->setEnabled(false);
         break;
 
     default:
         if (pi->isAnimated() == false)
         {
             previewB->setEnabled(true);
             if (currentCCD)
                 liveVideoB->setEnabled(currentCCD->hasVideoStream());
             startB->setEnabled(true);
         }
 
         break;
     }
 }
 
 void Capture::showObserverDialog()
 {
     QList<OAL::Observer *> m_observerList;
     KStars::Instance()->data()->userdb()->GetAllObservers(m_observerList);
     QStringList observers;
     for (auto &o : m_observerList)
         observers << QString("%1 %2").arg(o->name(), o->surname());
 
     QDialog observersDialog(this);
     observersDialog.setWindowTitle(i18n("Select Current Observer"));
 
     QLabel label(i18n("Current Observer:"));
 
     QComboBox observerCombo(&observersDialog);
     observerCombo.addItems(observers);
     observerCombo.setCurrentText(m_ObserverName);
     observerCombo.setSizePolicy(QSizePolicy::Expanding, QSizePolicy::Fixed);
 
     QPushButton manageObserver(&observersDialog);
     manageObserver.setFixedSize(QSize(32, 32));
     manageObserver.setIcon(QIcon::fromTheme("document-edit"));
     manageObserver.setAttribute(Qt::WA_LayoutUsesWidgetRect);
     manageObserver.setToolTip(i18n("Manage Observers"));
     connect(&manageObserver, &QPushButton::clicked, this, [&]() {
         ObserverAdd add;
         add.exec();
 
         QList<OAL::Observer *> m_observerList;
         KStars::Instance()->data()->userdb()->GetAllObservers(m_observerList);
         QStringList observers;
         for (auto &o : m_observerList)
             observers << QString("%1 %2").arg(o->name(), o->surname());
 
         observerCombo.clear();
         observerCombo.addItems(observers);
         observerCombo.setCurrentText(m_ObserverName);
 
     });
 
     QHBoxLayout *layout = new QHBoxLayout;
     layout->addWidget(&label);
     layout->addWidget(&observerCombo);
     layout->addWidget(&manageObserver);
 
     observersDialog.setLayout(layout);
 
     observersDialog.exec();
 
     m_ObserverName = observerCombo.currentText();
 
     Options::setDefaultObserver(m_ObserverName);
 }
 
 
 void Capture::startRefocusTimer(bool forced)
 {
     /* If refocus is requested, only restart timer if not already running in order to keep current elapsed time since last refocus */
     if (refocusEveryNCheck->isChecked())
     {
         // How much time passed since we last started the time
         uint32_t elapsedSecs = refocusEveryNTimer.elapsed()/1000;
         // How many seconds do we wait for between focusing (60 mins ==> 3600 secs)
         uint32_t totalSecs   = refocusEveryN->value()*60;
 
         if (!refocusEveryNTimer.isValid() || forced)
         {
             appendLogText(i18n("Ekos will refocus in %1 seconds.", totalSecs));
             refocusEveryNTimer.restart();
         }
         else if (elapsedSecs < totalSecs)
         {
             //appendLogText(i18n("Ekos will refocus in %1 seconds, last procedure was %2 seconds ago.", refocusEveryNTimer.elapsed()/1000-refocusEveryNTimer.elapsed()*60, refocusEveryNTimer.elapsed()/1000));
             appendLogText(i18n("Ekos will refocus in %1 seconds, last procedure was %2 seconds ago.", totalSecs - elapsedSecs, elapsedSecs));
         }
         else
         {
             appendLogText(i18n("Ekos will refocus as soon as possible, last procedure was %1 seconds ago.", elapsedSecs));
         }
     }
 }
 
 int Capture::getRefocusEveryNTimerElapsedSec()
 {
     /* If timer isn't valid, consider there is no focus to be done, that is, that focus was just done */
     return refocusEveryNTimer.isValid() ? refocusEveryNTimer.elapsed()/1000 : 0;
 }
 
 void Capture::setAlignResults(double orientation, double ra, double de, double pixscale)
 {
     Q_UNUSED(orientation);
     Q_UNUSED(ra);
     Q_UNUSED(de);
     Q_UNUSED(pixscale);
 
     if (currentRotator == nullptr)
         return;
 
     rotatorSettings->refresh();
 }
 
 void Capture::setFilterManager(const QSharedPointer<FilterManager> &manager)
 {
     filterManager = manager;
     connect(filterManagerB, &QPushButton::clicked, [this]()
     {
         filterManager->show();
         filterManager->raise();
     });
 
     connect(filterManager.data(), &FilterManager::ready, [this]()
     {
         m_CurrentFilterPosition = filterManager->getFilterPosition();
         // Due to race condition,
         focusState = FOCUS_IDLE;
         if (activeJob)
             activeJob->setCurrentFilter(m_CurrentFilterPosition);
 
     }
     );
 
     connect(filterManager.data(), &FilterManager::failed, [this]()
     {
         if (activeJob)
         {
             appendLogText(i18n("Filter operation failed."));
             abort();
         }
     }
     );
 
     connect(filterManager.data(), &FilterManager::newStatus, [this](Ekos::FilterState filterState)
     {
         if (m_State == CAPTURE_CHANGING_FILTER)
         {
             secondsLabel->setText(Ekos::getFilterStatusString(filterState));
             switch (filterState)
             {
             case FILTER_OFFSET:
                 appendLogText(i18n("Changing focus offset by %1 steps...", filterManager->getTargetFilterOffset()));
                 break;
 
             case FILTER_CHANGE:
                 appendLogText(i18n("Changing filter to %1...", FilterPosCombo->itemText(filterManager->getTargetFilterPosition()-1)));
                 break;
 
             case FILTER_AUTOFOCUS:
                 appendLogText(i18n("Auto focus on filter change..."));
                 clearAutoFocusHFR();
                 break;
 
             default:
                 break;
             }
         }
     });
 
     connect(filterManager.data(), &FilterManager::labelsChanged, this, [this]()
     {
         FilterPosCombo->clear();
         FilterPosCombo->addItems(filterManager->getFilterLabels());
         m_CurrentFilterPosition = filterManager->getFilterPosition();
         FilterPosCombo->setCurrentIndex(m_CurrentFilterPosition-1);
     });
     connect(filterManager.data(), &FilterManager::positionChanged, this, [this]()
     {
         m_CurrentFilterPosition = filterManager->getFilterPosition();
         FilterPosCombo->setCurrentIndex(m_CurrentFilterPosition-1);
     });
 }
 
 void Capture::addDSLRInfo(const QString &model, uint32_t maxW, uint32_t maxH, double pixelW, double pixelH)
 {
     // Check if model already exists
     auto pos = std::find_if(DSLRInfos.begin(), DSLRInfos.end(), [model](QMap<QString,QVariant> &oneDSLRInfo)
     { return (oneDSLRInfo["Model"] == model);});
 
 if (pos != DSLRInfos.end())
 {
     KStarsData::Instance()->userdb()->DeleteDSLRInfo(model);
     DSLRInfos.removeOne(*pos);
 }
 
 QMap<QString, QVariant> oneDSLRInfo;
 oneDSLRInfo["Model"] = model;
 oneDSLRInfo["Width"] = maxW;
 oneDSLRInfo["Height"] = maxH;
 oneDSLRInfo["PixelW"] = pixelW;
 oneDSLRInfo["PixelH"] = pixelH;
 
 KStarsData::Instance()->userdb()->AddDSLRInfo(oneDSLRInfo);
 
 KStarsData::Instance()->userdb()->GetAllDSLRInfos(DSLRInfos);
 }
 
 bool Capture::isModelinDSLRInfo(const QString &model)
 {
     auto pos = std::find_if(DSLRInfos.begin(), DSLRInfos.end(), [model](QMap<QString,QVariant> &oneDSLRInfo)
     { return (oneDSLRInfo["Model"] == model);});
 
 return (pos != DSLRInfos.end());
 }
 
 #if 0
 void Capture::syncDriverToDSLRLimits()
 {
     if (targetChip == nullptr)
         return;
 
     QString model(currentCCD->getDeviceName());
 
     // Check if model already exists
     auto pos = std::find_if(DSLRInfos.begin(), DSLRInfos.end(), [model](QMap<QString,QVariant> &oneDSLRInfo)
     { return (oneDSLRInfo["Model"] == model);});
 
 if (pos != DSLRInfos.end())
 targetChip->setImageInfo((*pos)["Width"].toInt(), (*pos)["Height"].toInt(), (*pos)["PixelW"].toDouble(), (*pos)["PixelH"].toDouble(), 8);
 }
 #endif
 
 void Capture::cullToDSLRLimits()
 {
     QString model(currentCCD->getDeviceName());
 
     // Check if model already exists
     auto pos = std::find_if(DSLRInfos.begin(), DSLRInfos.end(), [model](QMap<QString,QVariant> &oneDSLRInfo)
     { return (oneDSLRInfo["Model"] == model);});
 
 if (pos != DSLRInfos.end())
 {
     if (frameWIN->maximum() == 0 || frameWIN->maximum() > (*pos)["Width"].toInt())
     {
         frameWIN->setValue((*pos)["Width"].toInt());
         frameWIN->setMaximum((*pos)["Width"].toInt());
     }
 
     if (frameHIN->maximum() == 0 || frameHIN->maximum() > (*pos)["Height"].toInt())
     {
         frameHIN->setValue((*pos)["Height"].toInt());
         frameHIN->setMaximum((*pos)["Height"].toInt());
     }
 }
 }
 
 void Capture::setCapturedFramesMap(const QString &signature, int count)
 {
     capturedFramesMap[signature] = count;
     qCDebug(KSTARS_EKOS_CAPTURE) << QString("Client module indicates that storage for '%1' has already %2 captures processed.").arg(signature).arg(count);
     // Scheduler's captured frame map overrides the progress option of the Capture module
     ignoreJobProgress = false;
 }
 
 void Capture::setSettings(const QJsonObject &settings)
 {
     // FIXME: QComboBox signal "activated" does not trigger when setting text programmatically.
     CCDCaptureCombo->setCurrentText(settings["camera"].toString());
     FilterDevicesCombo->setCurrentText(settings["fw"].toString());
     FilterPosCombo->setCurrentText(settings["filter"].toString());
     exposureIN->setValue(settings["exp"].toDouble(1));
 
     int bin = settings["bin"].toInt(1);
     setBinning(bin,bin);
 
     double temperature = settings["temperature"].toDouble(Ekos::INVALID_VALUE);
     if (temperature != Ekos::INVALID_VALUE)
     {
         setForceTemperature(true);
         setTargetTemperature(temperature);
     }
 
     double gain = settings["gain"].toDouble(Ekos::INVALID_VALUE);
     if (gain != Ekos::INVALID_VALUE && currentCCD)
     {
          QMap<QString, QMap<QString, double> > customProps = customPropertiesDialog->getCustomProperties();
 
          // Gain is manifested in two forms
          // Property CCD_GAIN and
          // Part of CCD_CONTROLS properties.
          // Therefore, we have to find what the currently camera supports first.
          if (currentCCD->getProperty("CCD_GAIN"))
          {
              QMap<QString, double> ccdGain;
              ccdGain["GAIN"] = gain;
              customProps["CCD_GAIN"] = ccdGain;
          }
          else if (currentCCD->getProperty("CCD_CONTROLS"))
          {
              QMap<QString, double> ccdGain;
              ccdGain["Gain"] = gain;
              customProps["CCD_CONTROLS"] = ccdGain;
          }
 
          customPropertiesDialog->setCustomProperties(customProps);
     }
 
     frameTypeCombo->setCurrentIndex(settings["frameType"].toInt(0));
 
     // ISO
     int isoIndex = settings["iso"].toInt(-1);
     if (isoIndex >= 0)
         setISO(isoIndex);
 }
 
 void Capture::clearCameraConfiguration()
 {
     if (KMessageBox::questionYesNo(nullptr, i18n("Reset %1 configuration to default?", currentCCD->getDeviceName()), i18n("Confirmation")) == KMessageBox::No)
         return;
 
     currentCCD->setConfig(LOAD_DEFAULT_CONFIG);
     KStarsData::Instance()->userdb()->DeleteDSLRInfo(currentCCD->getDeviceName());
 
 }
 
 void Capture::setCoolerToggled(bool enabled)
 {
     coolerOnB->blockSignals(true);
     coolerOnB->setChecked(enabled);
     coolerOnB->blockSignals(false);
 
     coolerOffB->blockSignals(true);
     coolerOffB->setChecked(!enabled);
     coolerOffB->blockSignals(false);
 
     appendLogText(enabled ? i18n("Cooler is on") : i18n("Cooler is off"));
 }
 
 void Capture::processCaptureTimeout()
 {
     captureTimeoutCounter++;
 
     if (captureTimeoutCounter >= 3)
     {
         captureTimeoutCounter = 0;
         appendLogText(i18n("Exposure timeout. Aborting..."));
         abort();
         return;
     }
 
     appendLogText(i18n("Exposure timeout. Restarting exposure..."));
     ISD::CCDChip *targetChip = currentCCD->getChip(ISD::CCDChip::PRIMARY_CCD);
     targetChip->abortExposure();
     targetChip->capture(exposureIN->value());
     captureTimeout.start(exposureIN->value() * 1000 + CAPTURE_TIMEOUT_THRESHOLD);
 }
 
 }
diff --git a/kstars/ekos/capture/capture.h b/kstars/ekos/capture/capture.h
index 077c669dc..c40a41283 100644
--- a/kstars/ekos/capture/capture.h
+++ b/kstars/ekos/capture/capture.h
@@ -1,785 +1,787 @@
 /*  Ekos Capture tool
     Copyright (C) 2012 Jasem Mutlaq <mutlaqja@ikarustech.com>
 
     This application is free software; you can redistribute it and/or
     modify it under the terms of the GNU General Public
     License as published by the Free Software Foundation; either
     version 2 of the License, or (at your option) any later version.
  */
 
 #pragma once
 
 #include "ui_capture.h"
 #include "customproperties.h"
 #include "oal/filter.h"
 #include "ekos/ekos.h"
 #include "indi/indiccd.h"
 #include "indi/indicap.h"
 #include "indi/indidome.h"
 #include "indi/indilightbox.h"
 #include "indi/inditelescope.h"
 #include "ekos/auxiliary/filtermanager.h"
 #include "ekos/scheduler/schedulerjob.h"
 
 #include <QTimer>
 #include <QUrl>
 #include <QtDBus>
 
 #include <memory>
 
 class QProgressIndicator;
 class QTableWidgetItem;
 class KDirWatch;
 class RotatorSettings;
 
 /**
  * @namespace Ekos
  * @short Ekos is an advanced Astrophotography tool for Linux.
  * It is based on a modular extensible framework to perform common astrophotography tasks. This includes highly accurate GOTOs using astrometry solver, ability to measure and correct polar alignment errors ,
  * auto-focus & auto-guide capabilities, and capture of single or stack of images with filter wheel support.\n
  * Features:
  * - Control your telescope, CCD (& DSLRs), filter wheel, focuser, guider, adaptive optics unit, and any INDI-compatible auxiliary device from Ekos.
  * - Extremely accurate GOTOs using astrometry.net solver (both Online and Offline solvers supported).
  * - Load & Slew: Load a FITS image, slew to solved coordinates, and center the mount on the exact image coordinates in order to get the same desired frame.
  * - Measure & Correct Polar Alignment errors using astromety.net solver.
  * - Auto and manual focus modes using Half-Flux-Radius (HFR) method.
  * - Automated unattended meridian flip. Ekos performs post meridian flip alignment, calibration, and guiding to resume the capture session.
  * - Automatic focus between exposures when a user-configurable HFR limit is exceeded.
  * - Auto guiding with support for automatic dithering between exposures and support for Adaptive Optics devices in addition to traditional guiders.
  * - Powerful sequence queue for batch capture of images with optional prefixes, timestamps, filter wheel selection, and much more!
  * - Export and import sequence queue sets as Ekos Sequence Queue (.esq) files.
  * - Center the telescope anywhere in a captured FITS image or any FITS with World Coordinate System (WCS) header.
  * - Automatic flat field capture, just set the desired ADU and let Ekos does the rest!
  * - Automatic abort and resumption of exposure tasks if guiding errors exceed a user-configurable value.
  * - Support for dome slaving.
  * - Complete integration with KStars Observation Planner and SkyMap
  * - Integrate with all INDI native devices.
  * - Powerful scripting capabilities via \ref EkosDBusInterface "DBus."
  *
  * The primary class is Ekos::Manager. It handles startup and shutdown of local and remote INDI devices, manages and orchesterates the various Ekos modules, and provides advanced DBus
  * interface to enable unattended scripting.
  *
  * @author Jasem Mutlaq
  * @version 1.7
  */
 namespace Ekos
 {
 class SequenceJob;
 
 /**
  *@class Capture
  *@short Captures single or sequence of images from a CCD.
  * The capture class support capturing single or multiple images from a CCD, it provides a powerful sequence queue with filter wheel selection. Any sequence queue can be saved as Ekos Sequence Queue (.esq).
  * All image capture operations are saved as Sequence Jobs that encapsulate all the different options in a capture process. The user may select in sequence autofocusing by setting a maximum HFR limit. When the limit
  * is exceeded, it automatically trigger autofocus operation. The capture process can also be linked with guide module. If guiding deviations exceed a certain threshold, the capture operation aborts until
  * the guiding deviation resume to acceptable levels and the capture operation is resumed.
  *@author Jasem Mutlaq
  *@version 1.3
  */
 class Capture : public QWidget, public Ui::Capture
 {
     Q_OBJECT
     Q_CLASSINFO("D-Bus Interface", "org.kde.kstars.Ekos.Capture")
     Q_PROPERTY(Ekos::CaptureState status READ status NOTIFY newStatus)
     Q_PROPERTY(QString targetName MEMBER m_TargetName)
     Q_PROPERTY(QString observerName MEMBER m_ObserverName)
     Q_PROPERTY(QString camera READ camera WRITE setCamera)
     Q_PROPERTY(QString filterWheel READ filterWheel WRITE setFilterWheel)
     Q_PROPERTY(QString filter READ filter WRITE setFilter)
     Q_PROPERTY(bool coolerControl READ hasCoolerControl WRITE setCoolerControl)
     Q_PROPERTY(QStringList logText READ logText NOTIFY newLog)
 
   public:
     typedef enum { MF_NONE, MF_INITIATED, MF_FLIPPING, MF_SLEWING, MF_ALIGNING, MF_GUIDING } MFStage;
     typedef enum {
         CAL_NONE,
         CAL_DUSTCAP_PARKING,
         CAL_DUSTCAP_PARKED,
         CAL_LIGHTBOX_ON,
         CAL_SLEWING,
         CAL_SLEWING_COMPLETE,
         CAL_MOUNT_PARKING,
         CAL_MOUNT_PARKED,
         CAL_DOME_PARKING,
         CAL_DOME_PARKED,
         CAL_PRECAPTURE_COMPLETE,
         CAL_CALIBRATION,
         CAL_CALIBRATION_COMPLETE,
         CAL_CAPTURING,
         CAL_DUSTCAP_UNPARKING,
         CAL_DUSTCAP_UNPARKED
     } CalibrationStage;
     typedef bool (Capture::*PauseFunctionPointer)();
 
     Capture();
     ~Capture();
 
     /** @defgroup CaptureDBusInterface Ekos DBus Interface - Capture Module
          * Ekos::Capture interface provides advanced scripting capabilities to capture image sequences.
         */
 
     /*@{*/
 
     /** DBUS interface function.
          * select the CCD device from the available CCD drivers.
          * @param device The CCD device name
          */
     Q_SCRIPTABLE bool setCamera(const QString &device);
     Q_SCRIPTABLE QString camera();
 
     /** DBUS interface function.
          * select the filter device from the available filter drivers. The filter device can be the same as the CCD driver if the filter functionality was embedded within the driver.
          * @param device The filter device name
          */
     Q_SCRIPTABLE bool setFilterWheel(const QString &device);
     Q_SCRIPTABLE QString filterWheel();
 
     /** DBUS interface function.
          * select the filter name from the available filters in case a filter device is active.
          * @param filter The filter name
          */
     Q_SCRIPTABLE bool setFilter(const QString &filter);
     Q_SCRIPTABLE QString filter();
 
     /** DBUS interface function.
          * Aborts any current jobs and remove all sequence queue jobs.
          */
     Q_SCRIPTABLE Q_NOREPLY void clearSequenceQueue();
 
     /** DBUS interface function.
          * Returns the overall sequence queue status. If there are no jobs pending, it returns "Invalid". If all jobs are idle, it returns "Idle". If all jobs are complete, it returns "Complete". If one or more jobs are aborted
          * it returns "Aborted" unless it was temporarily aborted due to guiding deviations, then it would return "Suspended". If one or more jobs have errors, it returns "Error". If any jobs is under progress, returns "Running".
          */
     Q_SCRIPTABLE QString getSequenceQueueStatus();
 
     /** DBUS interface function.
          * Loads the Ekos Sequence Queue file in the Sequence Queue. Jobs are appended to existing jobs.
          * @param fileURL full URL of the filename
          */
-    Q_SCRIPTABLE bool loadSequenceQueue(const QString &fileURL);    
+    Q_SCRIPTABLE bool loadSequenceQueue(const QString &fileURL);
 
     /** DBUS interface function.
          * Enables or disables the maximum guiding deviation and sets its value.
          * @param enable If true, enable the guiding deviation check, otherwise, disable it.
          * @param value if enable is true, it sets the maximum guiding deviation in arcsecs. If the value is exceeded, the capture operation is aborted until the value falls below the value threshold.
          */
     Q_SCRIPTABLE Q_NOREPLY void setMaximumGuidingDeviation(bool enable, double value);
 
     /** DBUS interface function.
          * Enables or disables the in sequence focus and sets Half-Flux-Radius (HFR) limit.
          * @param enable If true, enable the in sequence auto focus check, otherwise, disable it.
          * @param HFR if enable is true, it sets HFR in pixels. After each exposure, the HFR is re-measured and if it exceeds the specified value, an autofocus operation will be commanded.
          */
     Q_SCRIPTABLE Q_NOREPLY void setInSequenceFocus(bool enable, double HFR);
 
     /** DBUS interface function.
          * Enable or Disable meridian flip, and sets its activation hour.
          * @param enable If true, meridian flip will be command after user-configurable number of hours.
          */
     Q_SCRIPTABLE Q_NOREPLY void setMeridianFlip(bool enable);
 
     /** DBUS interface function.
          * Sets meridian flip trigger hour.
          * @param hours Number of hours after the meridian at which the mount is commanded to flip.
          */
     Q_SCRIPTABLE Q_NOREPLY void setMeridianFlipHour(double hours);
 
     /** DBUS interface function.
          * Does the CCD has a cooler control (On/Off) ?
          */
     Q_SCRIPTABLE bool hasCoolerControl();
 
     /** DBUS interface function.
          * Set the CCD cooler ON/OFF
          *
          */
     Q_SCRIPTABLE bool setCoolerControl(bool enable);
 
     /** DBUS interface function.
          * @return Returns the percentage of completed captures in all active jobs
          */
     Q_SCRIPTABLE double getProgressPercentage();
 
     /** DBUS interface function.
          * @return Returns the number of jobs in the sequence queue.
          */
     Q_SCRIPTABLE int getJobCount() { return jobs.count(); }
 
     /** DBUS interface function.
          * @return Returns the number of pending uncompleted jobs in the sequence queue.
          */
     Q_SCRIPTABLE int getPendingJobCount();
 
     /** DBUS interface function.
          * @return Returns ID of current active job if any, or -1 if there are no active jobs.
          */
     Q_SCRIPTABLE int getActiveJobID();
 
     /** DBUS interface function.
          * @return Returns time left in seconds until active job is estimated to be complete.
          */
     Q_SCRIPTABLE int getActiveJobRemainingTime();
 
     /** DBUS interface function.
          * @return Returns overall time left in seconds until all jobs are estimated to be complete
          */
     Q_SCRIPTABLE int getOverallRemainingTime();
 
     /** DBUS interface function.
          * @param id job number. Job IDs start from 0 to N-1.
          * @return Returns the job state (Idle, In Progress, Error, Aborted, Complete)
          */
     Q_SCRIPTABLE QString getJobState(int id);
 
     /** DBUS interface function.
          * @param id job number. Job IDs start from 0 to N-1.
          * @return Returns The number of images completed capture in the job.
          */
     Q_SCRIPTABLE int getJobImageProgress(int id);
 
     /** DBUS interface function.
          * @param id job number. Job IDs start from 0 to N-1.
          * @return Returns the total number of images to capture in the job.
          */
     Q_SCRIPTABLE int getJobImageCount(int id);
 
     /** DBUS interface function.
          * @param id job number. Job IDs start from 0 to N-1.
          * @return Returns the number of seconds left in an exposure operation.
          */
     Q_SCRIPTABLE double getJobExposureProgress(int id);
 
     /** DBUS interface function.
          * @param id job number. Job IDs start from 0 to N-1.
          * @return Returns the total requested exposure duration in the job.
          */
     Q_SCRIPTABLE double getJobExposureDuration(int id);
 
     /** DBUS interface function.
          * Clear in-sequence focus settings. It sets the autofocus HFR to zero so that next autofocus value is remembered for the in-sequence focusing.
          */
     Q_SCRIPTABLE Q_NOREPLY void clearAutoFocusHFR();
 
     /** DBUS interface function.
          * Jobs will NOT be checked for progress against the file system and will be always assumed as new jobs.
          */
     Q_SCRIPTABLE Q_NOREPLY void ignoreSequenceHistory();
 
     /** DBUS interface function.
          * Set count of already completed frames. This is required when we have identical external jobs
          * with identical paths, but we need to continue where we left off. For example, if we have 3 identical
          * jobs, each capturing 5 images. Let's suppose 9 images were captured before. If the count for this signature
          * is set to 1, then we continue to capture frame #2 even though the number of completed images is already
          * larger than required count (5). It is mostly used in conjunction with Ekos Scheduler.
          */
     Q_SCRIPTABLE Q_NOREPLY void setCapturedFramesMap(const QString &signature, int count);
 
     Q_SCRIPTABLE QStringList logText() { return m_LogText; }
 
     Q_SCRIPTABLE Ekos::CaptureState status() { return m_State; }
 
     /** @}*/
 
     void addCCD(ISD::GDInterface *newCCD);
     void addFilter(ISD::GDInterface *newFilter);
     void setDome(ISD::GDInterface *device) { dome = dynamic_cast<ISD::Dome *>(device); }
     void setDustCap(ISD::GDInterface *device) { dustCap = dynamic_cast<ISD::DustCap *>(device); }
     void setLightBox(ISD::GDInterface *device) { lightBox = dynamic_cast<ISD::LightBox *>(device); }
     void addGuideHead(ISD::GDInterface *newCCD);
     void syncFrameType(ISD::GDInterface *ccd);
     void setTelescope(ISD::GDInterface *newTelescope);
     void setRotator(ISD::GDInterface *newRotator);
     void setFilterManager(const QSharedPointer<FilterManager> &manager);
     void syncTelescopeInfo();
     void syncFilterInfo();
 
     void clearLog();
     QString getLogText() { return m_LogText.join("\n"); }
 
     /* Capture */
     void updateSequencePrefix(const QString &newPrefix, const QString &dir);
 
     /**
      * @brief getSequence Return the JSON representation of the current sequeue queue
      * @return Reference to JSON array containing sequence queue jobs.
      */
     const QJsonArray &getSequence() const { return m_SequenceArray;}
 
     /**
      * @brief setSettings Set capture settings
      * @param settings list of settings
      */
     void setSettings(const QJsonObject &settings);
 
   public slots:
 
     /** \addtogroup CaptureDBusInterface
          *  @{
          */
 
     /* Capture */
     /** DBUS interface function.
          * Starts the sequence queue capture procedure sequentially by starting all jobs that are either Idle or Aborted in order.
          */
     Q_SCRIPTABLE Q_NOREPLY void start();
 
     /** DBUS interface function.
          * Stop all jobs and set current job status to aborted if abort is set to true, otherwise status is idle until
          * sequence is resumed or restarted.
          * @param targetState status of the job after abortion
          */
     Q_SCRIPTABLE Q_NOREPLY void stop(CaptureState targetState = CAPTURE_IDLE);
 
     /** DBUS interface function.
          * Aborts all jobs and mark current state as ABORTED. It simply calls stop(CAPTURE_ABORTED)
          */
     Q_SCRIPTABLE Q_NOREPLY void abort() { stop(CAPTURE_ABORTED); }
 
     /** DBUS interface function.
          * Aborts all jobs and mark current state as SUSPENDED. It simply calls stop(CAPTURE_SUSPENDED)
          * The only difference between SUSPENDED and ABORTED it that capture module can automatically resume a suspended
          * state on its own without external trigger once the right conditions are met. When whatever reason caused the module
          * to go into suspended state ceases to exist, the capture module automatically resumes. On the other hand, ABORTED state
          * must be started via an external programmatic or user trigger (e.g. click the start button again).
          */
     Q_SCRIPTABLE Q_NOREPLY void suspend() { stop(CAPTURE_SUSPENDED); }
 
     /** DBUS interface function.
          * Toggle video streaming if supported by the device.
          * @param enabled Set to true to start video streaming, false to stop it if active.
          */
     Q_SCRIPTABLE Q_NOREPLY void toggleVideo(bool enabled);
 
     /** @}*/
 
     /**
          * @brief captureOne Capture one preview image
          */
     void captureOne();
 
     /**
      * @brief setExposure Set desired exposure value in seconds
      * @param value exposure values in seconds
      */
     void setExposure(double value) { exposureIN->setValue(value);}
 
     /**
      * @brief seqCount Set required number of images to capture in one sequence job
      * @param count number of images to capture
      */
     void setCount(uint16_t count) { countIN->setValue(count); }
 
     /**
      * @brief setDelay Set delay between capturing images within a sequence in seconds
      * @param delay numbers of seconds to wait before starting the next image.
      */
     void setDelay(uint16_t delay) { delayIN->setValue(delay);}
 
     /**
      * @brief setPrefix Set target or prefix name used in constructing the generated file name
      * @param prefix Leading text of the generated image name.
      */
     void setPrefix(const QString &prefix) { prefixIN->setText(prefix);}
 
     /**
      * @brief setBinning Set binning
      * @param horBin Horizontal binning
      * @param verBin Vertical binning
      */
     void setBinning(int horBin, int verBin) { binXIN->setValue(horBin); binYIN->setValue(verBin); }
 
     /**
      * @brief setISO Set index of ISO list.
      * @param index index of ISO list.
      */
     void setISO(int index) { ISOCombo->setCurrentIndex(index);}
 
     /**
          * @brief captureImage Initiates image capture in the active job.
          */
     void captureImage();
 
     /**
          * @brief newFITS process new FITS data received from camera. Update status of active job and overall sequence.
          * @param bp pointer to blob containing FITS data
          */
     void newFITS(IBLOB *bp);
 
     /**
          * @brief checkCCD Refreshes the CCD information in the capture module.
          * @param CCDNum The CCD index in the CCD combo box to select as the active CCD.
          */
     void checkCCD(int CCDNum = -1);
 
     /**
          * @brief checkFilter Refreshes the filter wheel information in the capture module.
          * @param filterNum The filter wheel index in the filter device combo box to set as the active filter.
          */
     void checkFilter(int filterNum = -1);
 
     /**
          * @brief processCCDNumber Process number properties arriving from CCD. Currently, only CCD and Guider frames are processed.
          * @param nvp pointer to number property.
          */
     void processCCDNumber(INumberVectorProperty *nvp);
 
     /**
          * @brief processTelescopeNumber Process number properties arriving from telescope for meridian flip purposes.
          * @param nvp pointer to number property.
          */
     void processTelescopeNumber(INumberVectorProperty *nvp);
 
     /**
          * @brief addJob Add a new job to the sequence queue given the settings in the GUI.
          * @param preview True if the job is a preview job, otherwise, it is added as a batch job.
          * @return True if job is added successfully, false otherwise.
          */
     bool addJob(bool preview = false);
 
     /**
      * @brief removeJob Remove a job sequence from the queue
      * @param index Row index for job to remove, if left as -1 (default), the currently selected row will be removed.
      *        if no row is selected, the last job shall be removed.
      */
     void removeJob(int index=-1);
 
     /**
          * @brief moveJobUp Move the job in the sequence queue one place up.
          */
     void moveJobUp();
 
     /**
          * @brief moveJobDown Move the job in the sequence queue one place down.
          */
     void moveJobDown();
 
     /**
          * @brief setGuideDeviation Set the guiding deviation as measured by the guiding module. Abort capture if deviation exceeds user value. Resume capture if capture was aborted and guiding deviations are below user value.
          * @param delta_ra Deviation in RA in arcsecs from the selected guide star.
          * @param delta_dec Deviation in DEC in arcsecs from the selected guide star.
          */
     void setGuideDeviation(double delta_ra, double delta_dec);
 
     /**
          * @brief resumeCapture Resume capture after dither and/or focusing processes are complete.
          */
     bool resumeCapture();
 
     /**
          * @brief updateCCDTemperature Update CCD temperature in capture module.
          * @param value Temperature in celcius.
          */
     void updateCCDTemperature(double value);
 
     /**
          * @brief setTemperature Set the target CCD temperature in the GUI settings.
          */
     void setTargetTemperature(double temperature);
 
     void setForceTemperature(bool enabled) {temperatureCheck->setChecked(enabled);}
 
     /**
          * @brief preparePreCaptureActions Check if we need to update filter position or CCD temperature before starting capture process
          */
     void preparePreCaptureActions();
 
     void setFrameType(const QString& type) {frameTypeCombo->setCurrentText(type);}
 
     // Pause Sequence Queue
     void pause();
 
     // Logs
     void appendLogText(const QString &);
 
     // Auto Focus
     void setFocusStatus(Ekos::FocusState state);
     void setHFR(double newHFR, int) { focusHFR = newHFR; }
+    // Return TRUE if we need to run focus/autofocus. Otherwise false if not necessary
+    bool startFocusIfRequired();
 
     // Guide
     void setGuideStatus(Ekos::GuideState state);
     // Align
     void setAlignStatus(Ekos::AlignState state);
     void setAlignResults(double orientation, double ra, double de, double pixscale);
     // Update Mount module status
     void setMountStatus(ISD::Telescope::Status newState);
 
     void setGuideChip(ISD::CCDChip *chip);
 
     // Clear Camera Configuration
     void clearCameraConfiguration();
 
   private slots:
 
     /**
          * @brief setDirty Set dirty bit to indicate sequence queue file was modified and needs saving.
          */
     void setDirty();
 
     void toggleSequence();
 
     void checkFrameType(int index);
     void resetFrame();
     void setExposureProgress(ISD::CCDChip *tChip, double value, IPState state);
     void checkSeqBoundary(const QString &path);
     void saveFITSDirectory();
     void setDefaultCCD(QString ccd);
     void setNewRemoteFile(QString file);
 
     // Sequence Queue
     void loadSequenceQueue();
     void saveSequenceQueue();
     void saveSequenceQueueAs();
 
     // Jobs
     void resetJobs();
     void editJob(QModelIndex i);
     void resetJobEdit();
     void executeJob();
 
     // Meridian Flip
     void checkMeridianFlipTimeout();
     //void checkAlignmentSlewComplete();
 
     // AutoGuide
     void checkGuideDeviationTimeout();
 
     // Auto Focus
     // Timed refocus
     void startRefocusEveryNTimer() { startRefocusTimer(false); }
     void restartRefocusEveryNTimer() { startRefocusTimer(true); }
     int getRefocusEveryNTimerElapsedSec();
 
     // Flat field
     void openCalibrationDialog();
     IPState processPreCaptureCalibrationStage();
     bool processPostCaptureCalibrationStage();
     void updatePreCaptureCalibrationStatus();
 
     // Send image info
     void sendNewImage(const QString &filename, ISD::CCDChip *myChip);
 
     // Capture
     bool setCaptureComplete();
 
     // post capture script
     void postScriptFinished(int exitCode);
 
     void setVideoStreamEnabled(bool enabled);
 
     // Observer
     void showObserverDialog();
 
     // Active Job Prepare State
     void updatePrepareState(Ekos::CaptureState prepareState);
 
     // Rotator
     void updateRotatorNumber(INumberVectorProperty *nvp);
 
     // Cooler
     void setCoolerToggled(bool enabled);
 
   signals:
     Q_SCRIPTABLE void newLog(const QString &text);
     Q_SCRIPTABLE void meridianFlipStarted();
     Q_SCRIPTABLE void meridianFlipCompleted();
     Q_SCRIPTABLE void newStatus(Ekos::CaptureState status);
     Q_SCRIPTABLE void newSequenceImage(const QString &filename);
 
     void ready();
 
     void checkFocus(double);
     void resetFocus();
     void suspendGuiding();
-    void resumeGuiding();    
+    void resumeGuiding();
     void newImage(Ekos::SequenceJob *job);
     void newExposureProgress(Ekos::SequenceJob *job);
     void sequenceChanged(const QJsonArray &sequence);
     void settingsUpdated(const QJsonObject &settings);
 
   private:
     void setBusy(bool enable);
     bool resumeSequence();
     bool startNextExposure();
     // reset = 0 --> Do not reset
     // reset = 1 --> Full reset
     // reset = 2 --> Only update limits if needed
     void updateFrameProperties(int reset = 0);
     void prepareJob(SequenceJob *job);
     void syncGUIToJob(SequenceJob *job);
     bool processJobInfo(XMLEle *root);
     void processJobCompletion();
     bool saveSequenceQueue(const QString &path);
     void constructPrefix(QString &imagePrefix);
     double setCurrentADU(double value);
     void llsq(QVector<double> x, QVector<double> y, double &a, double &b);
 
     // DSLR Info
     void addDSLRInfo(const QString &model, uint32_t maxW, uint32_t maxH, double pixelW, double pixelH);
     void cullToDSLRLimits();
     //void syncDriverToDSLRLimits();
     bool isModelinDSLRInfo(const QString &model);
 
     /* Meridian Flip */
     bool checkMeridianFlip();
     void checkGuidingAfterFlip();
     double getCurrentHA();
 
     // Remaining Time in seconds
     int getJobRemainingTime(SequenceJob *job);
 
     void resetFrameToZero();
 
     /* Refocus */
     void startRefocusTimer(bool forced = false);
 
     // If exposure timed out, let's handle it.
     void processCaptureTimeout();
 
     /* Capture */
 
     /**
      * @brief Determine the overall number of target frames with the same signature.
      *        Assume capturing RGBLRGB, where in each sequence job there is only one frame.
      *        For "L" the result will be 1, for "R" it will be 2 etc.
      * @param frame signature (typically the filter name)
      * @return
      */
     int getTotalFramesCount(QString signature);
 
     double seqExpose { 0 };
     int seqTotalCount;
     int seqCurrentCount { 0 };
     int seqDelay { 0 };
     int retries { 0 };
     QTimer *seqTimer { nullptr };
     QString seqPrefix;
     int nextSequenceID { 0 };
     int seqFileCount { 0 };
     bool isBusy { false };
 
     // Capture timeout timer
     QTimer captureTimeout;
     uint8_t captureTimeoutCounter { 0 };
 
     bool useGuideHead { false };
     bool autoGuideReady { false};
     bool autoGuideAbortedCapture { false };
 
     QString m_TargetName;
     QString m_ObserverName;
 
     SequenceJob *activeJob { nullptr };
 
     QList<ISD::CCD *> CCDs;
 
     ISD::CCDChip *targetChip { nullptr };
     ISD::CCDChip *guideChip { nullptr };
     ISD::CCDChip *blobChip { nullptr };
     QString blobFilename;
 
 
     // They're generic GDInterface because they could be either ISD::CCD or ISD::Filter
     QList<ISD::GDInterface *> Filters;
 
     QList<SequenceJob *> jobs;
 
     ISD::Telescope *currentTelescope { nullptr };
     ISD::CCD *currentCCD { nullptr };
     ISD::GDInterface *currentFilter { nullptr };
     ISD::GDInterface *currentRotator { nullptr };
     ISD::DustCap *dustCap { nullptr };
     ISD::LightBox *lightBox { nullptr };
     ISD::Dome *dome { nullptr };
 
     QStringList m_LogText;
     QUrl m_SequenceURL;
     bool m_Dirty { false };
     bool m_JobUnderEdit { false };
     int m_CurrentFilterPosition { -1 };
     QProgressIndicator *pi { nullptr };
 
     // Guide Deviation
     bool m_DeviationDetected { false };
     bool m_SpikeDetected { false };
     QTimer guideDeviationTimer;
 
     // Autofocus
     /**
      * @brief updateHFRThreshold calculate new HFR threshold based on median value for current selected filter
      */
     void updateHFRThreshold();
     bool isInSequenceFocus { false };
     bool autoFocusReady { false };
-    bool requiredAutoFocusStarted { false };
+    //bool requiredAutoFocusStarted { false };
     //bool firstAutoFocus { true };
     double focusHFR { 0 }; // HFR value as received from the Ekos focus module
     QMap<QString,QList<double>> HFRMap;
     double fileHFR { 0 };  // HFR value as loaded from the sequence file
 
     // Refocus every N minutes
     bool isRefocus { false };
     int refocusEveryNMinutesValue { 0 };  // number of minutes between forced refocus
     QElapsedTimer refocusEveryNTimer; // used to determine when next force refocus should occur
 
     // Meridian flip
     double initialHA { 0 };
     //double initialRA { 0 };
     SkyPoint initialMountCoords;
     bool resumeAlignmentAfterFlip { false };
     bool resumeGuidingAfterFlip { false };
     MFStage meridianFlipStage { MF_NONE };
 
     // Flat field automation
     QVector<double> ExpRaw, ADURaw;
     double targetADU { 0 };
     double targetADUTolerance { 1000 };
     SkyPoint wallCoord;
     bool preMountPark { false };
     bool preDomePark { false };
     FlatFieldDuration flatFieldDuration { DURATION_MANUAL };
     FlatFieldSource flatFieldSource { SOURCE_MANUAL };
     CalibrationStage calibrationStage { CAL_NONE };
     bool dustCapLightEnabled { false };
     bool lightBoxLightEnabled { false };
     ISD::CCD::UploadMode rememberUploadMode { ISD::CCD::UPLOAD_CLIENT };
 
     QUrl dirPath;
 
     // Misc
     bool ignoreJobProgress { true };
     bool suspendGuideOnDownload { false };
     QJsonArray m_SequenceArray;
 
     // State
     CaptureState m_State { CAPTURE_IDLE };
     FocusState focusState { FOCUS_IDLE };
     GuideState guideState { GUIDE_IDLE };
     AlignState alignState { ALIGN_IDLE };
 
     PauseFunctionPointer pauseFunction;
 
     // CCD Chip frame settings
     QMap<ISD::CCDChip *, QVariantMap> frameSettings;
 
     // Post capture script
     QProcess postCaptureScript;
 
     // Rotator Settings
     std::unique_ptr<RotatorSettings> rotatorSettings;
 
     // How many images to capture before dithering operation is executed?
     uint8_t ditherCounter { 0 };
     uint8_t inSequenceFocusCounter { 0 };
 
     std::unique_ptr<CustomProperties> customPropertiesDialog;
 
     // Filter Manager
     QSharedPointer<FilterManager> filterManager;
 
     // DSLR Infos
     QList<QMap<QString,QVariant>> DSLRInfos;
 
     // Captured Frames Map
     SchedulerJob::CapturedFramesMap capturedFramesMap;
 };
 }