Esempio n. 1
0
        // TODO: Use the imeplementation in the MainForm instead
        private void DrawHighResFeature(ImagePixel pixel, PlateConstStarPair selectedPair, LeastSquareFittedAstrometry astrometry)
        {
            int x0 = pixel.X;
            int y0 = pixel.Y;

            if (x0 < 15)
            {
                x0 = 15;
            }
            if (y0 < 15)
            {
                y0 = 15;
            }
            if (x0 > AstrometryContext.Current.FullFrame.Width - 15)
            {
                x0 = AstrometryContext.Current.FullFrame.Width - 15;
            }
            if (y0 > AstrometryContext.Current.FullFrame.Height - 15)
            {
                y0 = AstrometryContext.Current.FullFrame.Height - 15;
            }

            int bytes;
            int bytesPerPixel;
            int selIdx;

            Bitmap featureBitmap = new Bitmap(31 * 8, 31 * 8, PixelFormat.Format24bppRgb);

            m_VideoController.UpdateZoomedImage(featureBitmap, pixel);

            BitmapData zoomedData = featureBitmap.LockBits(new Rectangle(0, 0, 31 * 8, 31 * 8), ImageLockMode.ReadWrite, featureBitmap.PixelFormat);

            try
            {
                bytes = zoomedData.Stride * featureBitmap.Height;
                byte[] zoomedValues = new byte[bytes];

                Marshal.Copy(zoomedData.Scan0, zoomedValues, 0, bytes);

                bytesPerPixel = AstrometryContext.Current.BytesPerPixel;

                byte saturatedR = TangraConfig.Settings.Color.Saturation.R;
                byte saturatedG = TangraConfig.Settings.Color.Saturation.G;
                byte saturatedB = TangraConfig.Settings.Color.Saturation.B;

                selIdx = 0;
                for (int y = 0; y < 31; y++)
                {
                    for (int x = 0; x < 31; x++)
                    {
                        for (int i = 0; i < 8; i++)
                        {
                            for (int j = 0; j < 8; j++)
                            {
                                int zoomedX = 8 * x + i;
                                int zoomedY = 8 * y + j;

                                int zoomedIdx = zoomedData.Stride * zoomedY + zoomedX * bytesPerPixel;

                                if (zoomedValues[zoomedIdx] > TangraConfig.Settings.Photometry.Saturation.Saturation8Bit)
                                {
                                    // Saturation detected
                                    zoomedValues[zoomedIdx]     = saturatedR;
                                    zoomedValues[zoomedIdx + 1] = saturatedG;
                                    zoomedValues[zoomedIdx + 2] = saturatedB;
                                }
                            }
                        }

                        selIdx++;
                    }
                }

                Marshal.Copy(zoomedValues, 0, zoomedData.Scan0, bytes);
            }
            finally
            {
                featureBitmap.UnlockBits(zoomedData);
            }

            Pen starPen = catalogStarPen;

            double xFitUnscaled = pixel.XDouble;
            double yFitUnscaled = pixel.YDouble;

            if (selectedPair != null && selectedPair.FitInfo.UsedInSolution)
            {
                starPen = referenceStarPen;
                astrometry.GetImageCoordsFromRADE(selectedPair.RADeg, selectedPair.DEDeg, out xFitUnscaled, out yFitUnscaled);
            }
            else if (selectedPair != null && selectedPair.FitInfo.ExcludedForHighResidual)
            {
                starPen = rejectedStarPen;
                astrometry.GetImageCoordsFromRADE(selectedPair.RADeg, selectedPair.DEDeg, out xFitUnscaled, out yFitUnscaled);
            }
            else
            {
                starPen = unrecognizedStarPen;
            }

            double xFit = (8 * (xFitUnscaled - x0 + 16)) - 4;
            double yFit = (8 * (yFitUnscaled - y0 + 16)) - 4;
        }
Esempio n. 2
0
        private void ImproveSolution(LeastSquareFittedAstrometry fit, double coeff, int i, int j, int k)
		{
			m_SolutionSolver = new PlateConstantsSolver(m_PlateConfig);

			double ra0, de0;
			fit.GetRADEFromImageCoords(m_PlateConfig.CenterXImage, m_PlateConfig.CenterXImage, out ra0, out de0);
			m_SolutionSolver.InitPlateSolution(ra0, de0);

            List<IStar> consideredStars = new List<IStar>();
            List<ulong> nonStellarStars = new List<ulong>();

			foreach (IStar star in m_CelestialAllStars)
			{
				if (star.Mag < m_MinMag || star.Mag > m_MaxMag)
					continue;

				if (m_DetermineAutoLimitMagnitude && 
					!double.IsNaN(m_DetectedLimitingMagnitude) &&
					star.Mag > m_DetectedLimitingMagnitude)
				{
#if ASTROMETRY_DEBUG
					Trace.Assert(false);
#endif
					continue;
				}

				double x, y;
				fit.GetImageCoordsFromRADE(star.RADeg, star.DEDeg, out x, out y);
				if (x < 0 || x > m_PlateConfig.ImageWidth ||
					y < 0 || y > m_PlateConfig.ImageHeight)
					continue;


				ImagePixel pixel = null;
				PSFFit psfFit;
				PSFFit asymPsfFit = null; 
				//if (m_FitSettings.CenterDetectionMethod == StarCenterDetection.PSFFit)
				{
					if (m_Settings.PyramidRemoveNonStellarObject)
						m_StarMap.GetPSFFit((int)x, (int)y, PSFFittingMethod.NonLinearAsymetricFit, out asymPsfFit);

					pixel = m_StarMap.GetPSFFit((int)x, (int)y, PSFFittingMethod.NonLinearFit, out psfFit);
				}
				//else if (m_FitSettings.CenterDetectionMethod == StarCenterDetection.Centroid)
				{
					// NOTE: Centroid detection is way faster and PSF will not lead to big improvement considering the threshold for star matching
					//pixel = m_StarMap.GetCentroid((int)x, (int)y, (int)Math.Ceiling(m_Settings.SearchArea));
				}

				if (pixel != null &&
                    psfFit.Certainty >= CorePyramidConfig.Default.MinDetectionLimitForSolutionImprovement / coeff)
				{
					consideredStars.Add(star);

					double distance = fit.GetDistanceInArcSec(pixel.XDouble, pixel.YDouble, x, y);
                    if (distance < CorePyramidConfig.Default.MaxPreliminaryResidualForSolutionImprovement / coeff)
					{
#if ASTROMETRY_DEBUG
						Trace.Assert(!double.IsNaN(pixel.XDouble));
						Trace.Assert(!double.IsNaN(pixel.YDouble));
#endif

						if (
							Math.Sqrt((x - pixel.XDouble) * (x - pixel.XDouble) + (y - pixel.YDouble) * (y - pixel.YDouble)) >
                            CoreAstrometrySettings.Default.SearchArea)
							continue;

						pixel.SignalNoise = psfFit.Certainty;
						pixel.Brightness = psfFit.Brightness; 
						m_SolutionSolver.AddStar(pixel, star);

						if (m_Settings.PyramidRemoveNonStellarObject &&
							(
								asymPsfFit.FWHM < m_Settings.MinReferenceStarFWHM ||
								asymPsfFit.FWHM > m_Settings.MaxReferenceStarFWHM ||
								asymPsfFit.ElongationPercentage > m_Settings.MaximumPSFElongation)
							)
						{
							nonStellarStars.Add(star.StarNo);
						}
					}
				}
			}

			double ffl = fit.FitInfo.FittedFocalLength;
			m_ImprovedSolution = m_SolutionSolver.SolveWithLinearRegression(m_Settings, out m_FirstImprovedSolution);
            //if (m_ImprovedSolution != null && m_ImprovedSolution.FitInfo.AllStarPairs.Count < 12)
            //{
            //    // Attempt to reject errorous solutions with small number of fitted stars 
            //    int totalMatched = 0;
            //    var largeFeatures = m_StarMap.Features.Where(x => x.MaxBrightnessPixels > 1).ToList();
            //    if (largeFeatures.Count > 5)
            //    {
            //        foreach (var feature in largeFeatures)
            //        {
            //            var ftrCenter = feature.GetCenter();
            //            // TODO: PFS Fit on the feature?
            //            var matchedFittedStar = m_ImprovedSolution.FitInfo.AllStarPairs.FirstOrDefault(
            //                x =>
            //                    Math.Sqrt(Math.Pow(x.x - ftrCenter.XDouble, 2) + Math.Pow(x.x - ftrCenter.XDouble, 2)) <
            //                    2);
            //            if (matchedFittedStar != null) totalMatched++;
            //        }

            //        double percentLargeFeaturesMatched = 1.0*totalMatched/largeFeatures.Count;
            //        if (percentLargeFeaturesMatched < 0.75)
            //        {
            //            if (TangraConfig.Settings.TraceLevels.PlateSolving.TraceInfo())
            //                Trace.WriteLine(string.Format("Only {0:0.0}% ({1} features) of the large {2} features have been matched, where 75% is required.", percentLargeFeaturesMatched*100, totalMatched, largeFeatures.Count));
            //            // At least 75% of the bright features from the video need to be matched to stars for the solution to be accepted
            //            m_ImprovedSolution = null;
            //        }
            //    }
            //}
            
            if (m_ImprovedSolution != null)
			{
				m_ImprovedSolution.FitInfo.FittedFocalLength = ffl;

                if (TangraConfig.Settings.TraceLevels.PlateSolving.TraceWarning())
                    Trace.WriteLine(string.Format("Improved solution: {0} considered stars, UsedInSolution: {1}, ExcludedForHighResidual: {2}", 
                        m_ImprovedSolution.FitInfo.AllStarPairs.Count(), 
                        m_ImprovedSolution.FitInfo.AllStarPairs.Count(x => x.FitInfo.UsedInSolution),
                        m_ImprovedSolution.FitInfo.AllStarPairs.Count(x => x.FitInfo.ExcludedForHighResidual)));

				// Fit was successful, exclude all unused non stellar objects so they 
				// don't interfere with the included/excluded stars improved solution tests
				m_ImprovedSolution.FitInfo.AllStarPairs.RemoveAll(p =>
					(p.FitInfo.ExcludedForHighResidual || !p.FitInfo.UsedInSolution) &&
					nonStellarStars.Contains(p.StarNo));

				// NOTE: How excluding stars for FWHM/Elongation may lead to incorrectly accepted solutions that include small number of stars
				//       because the majority haven't been used for the fit. This is why we have another solution check here.
				if (m_ImprovedSolution.FitInfo.AllStarPairs.Count > 3)
				{
                    List<PlateConstStarPair> usedStarPairs = m_ImprovedSolution.FitInfo.AllStarPairs.Where(p => p.FitInfo.UsedInSolution).ToList();
                    double maxIncludedMag = usedStarPairs.Max(p => p.Mag);

                    int nonIncludedConsideredStars = consideredStars.Count(s => s.Mag <= maxIncludedMag) - usedStarPairs.Count;
                    if (nonIncludedConsideredStars > CorePyramidConfig.Default.MaxFWHMExcludedImprovemntStarsCoeff * usedStarPairs.Count)
                    {
                        LogUnsuccessfulFitImage(m_ImprovedSolution, i, j, k, 
                            string.Format("More than {0:0.0}% of the stars ({1} stars) down to mag {2:0.00} have not been matched. Attempted stars: {3}, Coeff: {4:0.00}", 
                                CorePyramidConfig.Default.MaxFWHMExcludedImprovemntStarsCoeff * 100,
                                nonIncludedConsideredStars,
                                maxIncludedMag, 
                                m_SolutionSolver.Pairs.Count, 
                                nonIncludedConsideredStars / m_SolutionSolver.Pairs.Count));
						m_ImprovedSolution = null;
						return;
					}

					List<double> intensities = usedStarPairs.Select(s => (double)s.Intensity).ToList();
					List<double> mags = usedStarPairs.Select(s => s.Mag).ToList();

                    if (usedStarPairs.Count > 3)
                    {
                        LinearRegression reg = new LinearRegression();
                        int pointsAdded = 0;
                        for (int ii = 0; ii < intensities.Count; ii++)
                        {
                            if (intensities[ii] > 0)
                            {
                                reg.AddDataPoint(intensities[ii], Math.Log10(mags[ii]));
                                pointsAdded++;
                            }
                        }

                        if (pointsAdded > 3)
                        {
                            reg.Solve();

                            if (Math.Pow(10, reg.StdDev) > CorePyramidConfig.Default.MagFitTestMaxStdDev || reg.A > CorePyramidConfig.Default.MagFitTestMaxInclination)
                            {
                                LogUnsuccessfulFitImage(m_ImprovedSolution, i, j, k, 
                                    string.Format("Failing solution for failed magnitude fit. Intensity(Log10(Magntude)) = {1} * x + {2}, StdDev = {0:0.0000}, ChiSquare = {3:0.000}", Math.Pow(10, reg.StdDev), reg.A, reg.B, reg.ChiSquare));

                                m_ImprovedSolution = null;
                                return;
                            }                            
                        }
                    }
				}
			}
		}
Esempio n. 3
0
        public LeastSquareFittedAstrometry SolvePlateConstantsPhase4(double pyramidLimitMag)
        {
            double ra0deg, de0Deg;

            m_SolvedPlate.GetRADEFromImageCoords(m_SolvedPlate.Image.CenterXImage, m_SolvedPlate.Image.CenterYImage, out ra0deg, out de0Deg);

            FocalLengthFit distFit = m_ConstantsSolver.ComputeFocalLengthFit();

            m_Context.PlateConfig.EffectiveFocalLength = m_Context.FieldSolveContext.FocalLength;
            distFit.GetFocalParameters(m_Context.PlateConfig.EffectiveFocalLength, out m_Context.PlateConfig.EffectivePixelWidth, out m_Context.PlateConfig.EffectivePixelHeight);

            DistanceBasedAstrometrySolver distMatch = new DistanceBasedAstrometrySolver(
                m_AstrometryController,
                m_Context.PlateConfig,
                m_AstrometrySettings,
                m_Context.FieldSolveContext.CatalogueStars,
                m_Context.FieldSolveContext.RADeg,
                m_Context.FieldSolveContext.DEDeg,
                m_Context.FieldSolveContext.DetermineAutoLimitMagnitude);

            distMatch.SetMinMaxMagOfStarsForAstrometry(CorePyramidConfig.Default.DefaultMinAstrometryMagnitude, 18);

            distMatch.SetMinMaxMagOfStarsForPyramidAlignment(CorePyramidConfig.Default.DefaultMinPyramidMagnitude, pyramidLimitMag);
            Trace.WriteLine(string.Format("Stars for alignment in range: {0:0.0} - {1:0.0} mag", CorePyramidConfig.Default.DefaultMinPyramidMagnitude, pyramidLimitMag));

            Dictionary <PSFFit, IStar> manualStars = null;
            var threeStarFit = m_Context.PreliminaryFit as ThreeStarAstrometry;

            if (threeStarFit != null)
            {
                manualStars = new Dictionary <PSFFit, IStar>();
                foreach (var kvp in threeStarFit.UserStars)
                {
                    PSFFit psfFit;
                    m_Context.StarMap.GetPSFFit(kvp.Key.X, kvp.Key.Y, PSFFittingMethod.NonLinearFit, out psfFit);
                    if (psfFit != null && psfFit.IsSolved)
                    {
                        manualStars.Add(psfFit, kvp.Value);
                    }
                }
            }

            distMatch.InitNewMatch(m_Context.StarMap, PyramidMatchType.PlateSolve, manualStars);

#if ASTROMETRY_DEBUG
            Dictionary <int, ulong> debugInfo = new Dictionary <int, ulong>();

            var starList = m_Context.SecondAstrometricFit.FitInfo.AllStarPairs
                           .Where(p => !p.FitInfo.ExcludedForHighResidual);

            foreach (var x in starList)
            {
                if (!debugInfo.ContainsKey(x.FeatureId))
                {
                    debugInfo.Add(x.FeatureId, x.StarNo);
                }
            }

            foreach (var f in m_Context.StarMap.Features)
            {
                Trace.WriteLine(string.Format("{0} - {1}", f.FeatureId, debugInfo.ContainsKey(f.FeatureId) ? "INCLUDED" : "MISSING"));
            }

            distMatch.SetDebugData(new DistanceBasedAstrometrySolver.PyramidDebugContext()
            {
                ResolvedStars       = debugInfo,
                ResolvedFocalLength = m_Context.SecondAstrometricFit.FitInfo.FittedFocalLength
            });
#endif

            LeastSquareFittedAstrometry fit         = null;
            LeastSquareFittedAstrometry improvedFit = null;
            PlateConstantsSolver        solver;
            distMatch.PerformMatch(out fit, out improvedFit, out solver);

            m_Context.DistanceBasedFit         = fit;
            m_Context.ImprovedDistanceBasedFit = improvedFit;

            if (fit != null)
            {
                m_Context.PlateConstants = new TangraConfig.PersistedPlateConstants
                {
                    EffectiveFocalLength = m_Context.PlateConfig.EffectiveFocalLength,
                    EffectivePixelWidth  = m_Context.PlateConfig.EffectivePixelWidth,
                    EffectivePixelHeight = m_Context.PlateConfig.EffectivePixelHeight
                };

                m_Context.ConstantsSolver = solver;

                if (improvedFit != null)
                {
                    foreach (var pair in improvedFit.FitInfo.AllStarPairs)
                    {
                        if (pair.FitInfo.ExcludedForHighResidual)
                        {
                            continue;
                        }

                        Trace.WriteLine(string.Format("{6}; {0}; {1}; {2}; {3}; ({4}\", {5}\")",
                                                      pair.RADeg, pair.DEDeg, pair.x.ToString("0.00"), pair.y.ToString("0.00"),
                                                      pair.FitInfo.ResidualRAArcSec.ToString("0.00"), pair.FitInfo.ResidualDEArcSec.ToString("0.00"),
                                                      pair.StarNo));

                        double x, y;
                        improvedFit.GetImageCoordsFromRADE(pair.RADeg, pair.DEDeg, out x, out y);
                        double dist = improvedFit.GetDistanceInArcSec(x, y, pair.x, pair.y);
                    }
                }
            }
            else
            {
                m_Context.PlateConstants = null;
            }

            return(fit);
        }