/// <summary> /// Prepares the CORRELATION kernel in Fourier space. It inverts the PSF and applies the FFT. (multiplication in fourier space == convolution, multiplication with inverted kernel in fourier space == correlation) /// its padded, otherwise the FFT would calculate the circular convolution which is physically implausible /// </summary> /// <param name="psf"></param> /// <param name="padding">padding to be used. Use the total image size as padding</param> /// <returns></returns> public static Complex[,] CalcPaddedFourierCorrelation(float[,] psf, Rectangle padding) { var yPadding = padding.YEnd; var xPadding = padding.XEnd; var psfPadded = new double[yPadding + psf.GetLength(0), xPadding + psf.GetLength(1)]; var yPsfHalf = yPadding / 2; var xPsfHalf = xPadding / 2; for (int y = 0; y < psf.GetLength(0); y++) { for (int x = 0; x < psf.GetLength(1); x++) { if (y + yPsfHalf + 1 < psfPadded.GetLength(0) & x + xPsfHalf + 1 < psfPadded.GetLength(1)) { psfPadded[y + yPsfHalf + 1, x + xPsfHalf + 1] = psf[psf.GetLength(0) - y - 1, psf.GetLength(1) - x - 1]; } } } FFT.Shift(psfPadded); var PSFPadded = FFT.Forward(psfPadded, 1.0); return(PSFPadded); }
public PaddedConvolver(Complex[,] kernel, Rectangle kernelSize) { fft = new FFT(kernel.GetLength(0), kernel.GetLength(1)); this.kernel = kernel; this.kernelSize = kernelSize; }
public static void DebugdWStack() { var frequencies = FitsIO.ReadFrequencies(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\freq.fits"); var uvw = FitsIO.ReadUVW(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\uvw0.fits"); var flags = FitsIO.ReadFlags(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\flags0.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length); double norm = 2.0; var visibilities = FitsIO.ReadVisibilities(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\vis0.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length, norm); for (int i = 1; i < 8; i++) { var uvw0 = FitsIO.ReadUVW(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\uvw" + i + ".fits"); var flags0 = FitsIO.ReadFlags(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\flags" + i + ".fits", uvw0.GetLength(0), uvw0.GetLength(1), frequencies.Length); var visibilities0 = FitsIO.ReadVisibilities(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\vis" + i + ".fits", uvw0.GetLength(0), uvw0.GetLength(1), frequencies.Length, norm); uvw = FitsIO.Stitch(uvw, uvw0); flags = FitsIO.Stitch(flags, flags0); visibilities = FitsIO.Stitch(visibilities, visibilities0); } var maxW = 0.0; for (int i = 0; i < uvw.GetLength(0); i++) { for (int j = 0; j < uvw.GetLength(1); j++) { maxW = Math.Max(maxW, Math.Abs(uvw[i, j, 2])); } } maxW = Partitioner.MetersToLambda(maxW, frequencies[frequencies.Length - 1]); var visCount2 = 0; for (int i = 0; i < flags.GetLength(0); i++) { for (int j = 0; j < flags.GetLength(1); j++) { for (int k = 0; k < flags.GetLength(2); k++) { if (!flags[i, j, k]) { visCount2++; } } } } var visibilitiesCount = visCount2; int gridSize = 4096; int subgridsize = 16; int kernelSize = 8; int max_nr_timesteps = 1024; double cellSize = 1.6 / 3600.0 * PI / 180.0; int wLayerCount = 32; double wStep = maxW / (wLayerCount); var c = new GriddingConstants(visibilitiesCount, gridSize, subgridsize, kernelSize, max_nr_timesteps, (float)cellSize, wLayerCount, wStep); var c2 = new GriddingConstants(visibilitiesCount, gridSize, subgridsize, kernelSize, max_nr_timesteps, (float)cellSize, 1, 0.0); var metadata = Partitioner.CreatePartition(c, uvw, frequencies); var psfVis = new Complex[uvw.GetLength(0), uvw.GetLength(1), frequencies.Length]; for (int i = 0; i < visibilities.GetLength(0); i++) { for (int j = 0; j < visibilities.GetLength(1); j++) { for (int k = 0; k < visibilities.GetLength(2); k++) { if (!flags[i, j, k]) { psfVis[i, j, k] = new Complex(1.0, 0); } else { psfVis[i, j, k] = new Complex(0, 0); } } } } var psfGrid = IDG.GridW(c, metadata, psfVis, uvw, frequencies); var psf = FFT.WStackIFFTFloat(psfGrid, c.VisibilitiesCount); FFT.Shift(psf); FitsIO.Write(psf, "psfWStack.fits"); var totalSize = new Rectangle(0, 0, gridSize, gridSize); var bMapCalculator = new PaddedConvolver(PSF.CalcPaddedFourierCorrelation(psf, totalSize), new Rectangle(0, 0, psf.GetLength(0), psf.GetLength(1))); var fastCD = new FastSerialCD(totalSize, psf); var lambda = 0.4f * fastCD.MaxLipschitz; var alpha = 0.1f; var xImage = new float[gridSize, gridSize]; var residualVis = visibilities; for (int cycle = 0; cycle < 8; cycle++) { var dirtyGrid = IDG.GridW(c, metadata, residualVis, uvw, frequencies); var dirty = FFT.WStackIFFTFloat(dirtyGrid, c.VisibilitiesCount); FFT.Shift(dirty); FitsIO.Write(dirty, "dirty_" + cycle + ".fits"); bMapCalculator.ConvolveInPlace(dirty); FitsIO.Write(dirty, "bMap_" + cycle + ".fits"); var result = fastCD.Deconvolve(xImage, dirty, lambda, alpha, 10000, 1e-4f); FitsIO.Write(xImage, "xImageGreedy" + cycle + ".fits"); FFT.Shift(xImage); var xGrid = FFT.Forward(xImage); FFT.Shift(xImage); var modelVis = IDG.DeGridW(c, metadata, xGrid, uvw, frequencies); var modelGrid = IDG.GridW(c, metadata, modelVis, uvw, frequencies); var model = FFT.WStackIFFTFloat(modelGrid, c.VisibilitiesCount); FFT.Shift(model); FitsIO.Write(model, "model_" + cycle + ".fits"); residualVis = Visibilities.Substract(visibilities, modelVis, flags); } }
public static void DebugILGPU() { var frequencies = FitsIO.ReadFrequencies(@"C:\dev\GitHub\p9-data\small\fits\simulation_point\freq.fits"); var uvw = FitsIO.ReadUVW(@"C:\dev\GitHub\p9-data\small\fits\simulation_point\uvw.fits"); var flags = new bool[uvw.GetLength(0), uvw.GetLength(1), frequencies.Length]; //completely unflagged dataset double norm = 2.0; var visibilities = FitsIO.ReadVisibilities(@"C:\dev\GitHub\p9-data\small\fits\simulation_point\vis.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length, norm); var visibilitiesCount = visibilities.Length; int gridSize = 256; int subgridsize = 8; int kernelSize = 4; int max_nr_timesteps = 1024; double cellSize = 1.0 / 3600.0 * PI / 180.0; var c = new GriddingConstants(visibilitiesCount, gridSize, subgridsize, kernelSize, max_nr_timesteps, (float)cellSize, 1, 0.0f); var watchTotal = new Stopwatch(); var watchForward = new Stopwatch(); var watchBackwards = new Stopwatch(); var watchDeconv = new Stopwatch(); watchTotal.Start(); var metadata = Partitioner.CreatePartition(c, uvw, frequencies); var psfGrid = IDG.GridPSF(c, metadata, uvw, flags, frequencies); var psf = FFT.Backward(psfGrid, c.VisibilitiesCount); FFT.Shift(psf); var psfCutDouble = CutImg(psf); var psfCut = ToFloatImage(psfCutDouble); FitsIO.Write(psfCut, "psfCut.fits"); var totalSize = new Rectangle(0, 0, gridSize, gridSize); var imageSection = new Rectangle(0, 128, gridSize, gridSize); var bMapCalculator = new PaddedConvolver(PSF.CalcPaddedFourierCorrelation(psfCut, totalSize), new Rectangle(0, 0, psfCut.GetLength(0), psfCut.GetLength(1))); var fastCD = new FastSerialCD(totalSize, psfCut); fastCD.ResetLipschitzMap(ToFloatImage(psf)); var gpuCD = new GPUSerialCD(totalSize, psfCut, 100); var lambda = 0.5f * fastCD.MaxLipschitz; var alpha = 0.8f; var xImage = new float[gridSize, gridSize]; var residualVis = visibilities; /*var truth = new double[gridSize, gridSize]; * truth[30, 30] = 1.0; * truth[35, 36] = 1.5; * var truthVis = IDG.ToVisibilities(c, metadata, truth, uvw, frequencies); * visibilities = truthVis; * var residualVis = truthVis;*/ for (int cycle = 0; cycle < 4; cycle++) { //FORWARD watchForward.Start(); var dirtyGrid = IDG.Grid(c, metadata, residualVis, uvw, frequencies); var dirtyImage = FFT.BackwardFloat(dirtyGrid, c.VisibilitiesCount); FFT.Shift(dirtyImage); FitsIO.Write(dirtyImage, "dirty_" + cycle + ".fits"); watchForward.Stop(); //DECONVOLVE watchDeconv.Start(); bMapCalculator.ConvolveInPlace(dirtyImage); FitsIO.Write(dirtyImage, "bMap_" + cycle + ".fits"); //var result = fastCD.Deconvolve(xImage, dirtyImage, lambda, alpha, 1000, 1e-4f); var result = gpuCD.Deconvolve(xImage, dirtyImage, lambda, alpha, 1000, 1e-4f); if (result.Converged) { Console.WriteLine("-----------------------------CONVERGED!!!!------------------------"); } else { Console.WriteLine("-------------------------------not converged----------------------"); } FitsIO.Write(xImage, "xImageGreedy" + cycle + ".fits"); FitsIO.Write(dirtyImage, "residualDebug_" + cycle + ".fits"); watchDeconv.Stop(); //BACKWARDS watchBackwards.Start(); FFT.Shift(xImage); var xGrid = FFT.Forward(xImage); FFT.Shift(xImage); var modelVis = IDG.DeGrid(c, metadata, xGrid, uvw, frequencies); residualVis = Visibilities.Substract(visibilities, modelVis, flags); watchBackwards.Stop(); var hello = FFT.Forward(xImage, 1.0); hello = Common.Fourier2D.Multiply(hello, psfGrid); var hImg = FFT.Backward(hello, (double)(128 * 128)); //FFT.Shift(hImg); FitsIO.Write(hImg, "modelDirty_FFT.fits"); var imgRec = IDG.ToImage(c, metadata, modelVis, uvw, frequencies); FitsIO.Write(imgRec, "modelDirty" + cycle + ".fits"); } }
public static void DebugSimulatedApprox() { var frequencies = FitsIO.ReadFrequencies(@"C:\dev\GitHub\p9-data\small\fits\simulation_point\freq.fits"); var uvw = FitsIO.ReadUVW(@"C:\dev\GitHub\p9-data\small\fits\simulation_point\uvw.fits"); var flags = new bool[uvw.GetLength(0), uvw.GetLength(1), frequencies.Length]; //completely unflagged dataset double norm = 2.0; var visibilities = FitsIO.ReadVisibilities(@"C:\dev\GitHub\p9-data\small\fits\simulation_point\vis.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length, norm); var visibilitiesCount = visibilities.Length; int gridSize = 256; int subgridsize = 8; int kernelSize = 4; int max_nr_timesteps = 1024; double cellSize = 1.0 / 3600.0 * PI / 180.0; var c = new GriddingConstants(visibilitiesCount, gridSize, subgridsize, kernelSize, max_nr_timesteps, (float)cellSize, 1, 0.0f); var watchTotal = new Stopwatch(); var watchForward = new Stopwatch(); var watchBackwards = new Stopwatch(); var watchDeconv = new Stopwatch(); watchTotal.Start(); var metadata = Partitioner.CreatePartition(c, uvw, frequencies); var psfGrid = IDG.GridPSF(c, metadata, uvw, flags, frequencies); var psf = FFT.BackwardFloat(psfGrid, c.VisibilitiesCount); FFT.Shift(psf); var psfCut = PSF.Cut(psf); FitsIO.Write(psfCut, "psfCut.fits"); var random = new Random(123); var totalSize = new Rectangle(0, 0, gridSize, gridSize); var bMapCalculator = new PaddedConvolver(PSF.CalcPaddedFourierCorrelation(psfCut, totalSize), new Rectangle(0, 0, psfCut.GetLength(0), psfCut.GetLength(1))); var fastCD = new FastSerialCD(totalSize, psfCut); //fastCD.ResetAMap(psf); var lambda = 0.5f * fastCD.MaxLipschitz; var alpha = 0.8f; var approx = new ApproxParallel(); var approx2 = new ApproxFast(totalSize, psfCut, 4, 8, 0f, 0.25f, false, true); var xImage = new float[gridSize, gridSize]; var residualVis = visibilities; /*var truth = new double[gridSize, gridSize]; * truth[30, 30] = 1.0; * truth[35, 36] = 1.5; * var truthVis = IDG.ToVisibilities(c, metadata, truth, uvw, frequencies); * visibilities = truthVis; * var residualVis = truthVis;*/ var data = new ApproxFast.TestingData(new StreamWriter("approxConvergence.txt")); for (int cycle = 0; cycle < 4; cycle++) { //FORWARD watchForward.Start(); var dirtyGrid = IDG.Grid(c, metadata, residualVis, uvw, frequencies); var dirtyImage = FFT.BackwardFloat(dirtyGrid, c.VisibilitiesCount); FFT.Shift(dirtyImage); FitsIO.Write(dirtyImage, "dirty_" + cycle + ".fits"); watchForward.Stop(); //DECONVOLVE watchDeconv.Start(); //approx.ISTAStep(xImage, dirtyImage, psf, lambda, alpha); //FitsIO.Write(xImage, "xIsta.fits"); //FitsIO.Write(dirtyImage, "dirtyFista.fits"); //bMapCalculator.ConvolveInPlace(dirtyImage); //FitsIO.Write(dirtyImage, "bMap_" + cycle + ".fits"); //var result = fastCD.Deconvolve(xImage, dirtyImage, 0.5f * fastCD.MaxLipschitz, 0.8f, 1000, 1e-4f); //var converged = approx.DeconvolveActiveSet(xImage, dirtyImage, psfCut, lambda, alpha, random, 8, 1, 1); //var converged = approx.DeconvolveGreedy(xImage, dirtyImage, psfCut, lambda, alpha, random, 4, 4, 500); //var converged = approx.DeconvolveApprox(xImage, dirtyImage, psfCut, lambda, alpha, random, 1, threads, 500, 1e-4f, cycle == 0); approx2.DeconvolveTest(data, cycle, 0, xImage, dirtyImage, psfCut, psf, lambda, alpha, random, 10, 1e-4f); if (data.converged) { Console.WriteLine("-----------------------------CONVERGED!!!!------------------------"); } else { Console.WriteLine("-------------------------------not converged----------------------"); } FitsIO.Write(xImage, "xImageApprox_" + cycle + ".fits"); watchDeconv.Stop(); //BACKWARDS watchBackwards.Start(); FFT.Shift(xImage); var xGrid = FFT.Forward(xImage); FFT.Shift(xImage); var modelVis = IDG.DeGrid(c, metadata, xGrid, uvw, frequencies); residualVis = Visibilities.Substract(visibilities, modelVis, flags); watchBackwards.Stop(); } var dirtyGridCheck = IDG.Grid(c, metadata, residualVis, uvw, frequencies); var dirtyCheck = FFT.Backward(dirtyGridCheck, c.VisibilitiesCount); FFT.Shift(dirtyCheck); var l2Penalty = Residuals.CalcPenalty(ToFloatImage(dirtyCheck)); var elasticPenalty = ElasticNet.CalcPenalty(xImage, (float)lambda, (float)alpha); var sum = l2Penalty + elasticPenalty; data.writer.Close(); }
public static void MeerKATFull() { var frequencies = FitsIO.ReadFrequencies(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\freq.fits"); var uvw = FitsIO.ReadUVW(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\uvw0.fits"); var flags = FitsIO.ReadFlags(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\flags0.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length); double norm = 2.0; var visibilities = FitsIO.ReadVisibilities(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\vis0.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length, norm); for (int i = 1; i < 8; i++) { var uvw0 = FitsIO.ReadUVW(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\uvw" + i + ".fits"); var flags0 = FitsIO.ReadFlags(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\flags" + i + ".fits", uvw0.GetLength(0), uvw0.GetLength(1), frequencies.Length); var visibilities0 = FitsIO.ReadVisibilities(@"C:\dev\GitHub\p9-data\large\fits\meerkat_tiny\vis" + i + ".fits", uvw0.GetLength(0), uvw0.GetLength(1), frequencies.Length, norm); uvw = FitsIO.Stitch(uvw, uvw0); flags = FitsIO.Stitch(flags, flags0); visibilities = FitsIO.Stitch(visibilities, visibilities0); } /* * var frequencies = FitsIO.ReadFrequencies(@"freq.fits"); * var uvw = FitsIO.ReadUVW("uvw0.fits"); * var flags = FitsIO.ReadFlags("flags0.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length); * double norm = 2.0; * var visibilities = FitsIO.ReadVisibilities("vis0.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length, norm); */ var visCount2 = 0; for (int i = 0; i < flags.GetLength(0); i++) { for (int j = 0; j < flags.GetLength(1); j++) { for (int k = 0; k < flags.GetLength(2); k++) { if (!flags[i, j, k]) { visCount2++; } } } } var visibilitiesCount = visCount2; int gridSize = 1024; int subgridsize = 16; int kernelSize = 4; //cell = image / grid int max_nr_timesteps = 512; double scaleArcSec = 2.5 / 3600.0 * PI / 180.0; var watchTotal = new Stopwatch(); var watchForward = new Stopwatch(); var watchBackwards = new Stopwatch(); var watchDeconv = new Stopwatch(); watchTotal.Start(); var c = new GriddingConstants(visibilitiesCount, gridSize, subgridsize, kernelSize, max_nr_timesteps, (float)scaleArcSec, 1, 0.0f); var metadata = Partitioner.CreatePartition(c, uvw, frequencies); var psf = IDG.CalculatePSF(c, metadata, uvw, flags, frequencies); FitsIO.Write(psf, "psf.fits"); var psfCut = CutImg(psf, 2); FitsIO.Write(psfCut, "psfCut.fits"); var maxSidelobe = CommonDeprecated.PSF.CalcMaxSidelobe(psf); var psfCorrelated = CommonDeprecated.PSF.CalculateFourierCorrelation(psfCut, c.GridSize, c.GridSize); var xImage = new double[gridSize, gridSize]; var residualVis = visibilities; var maxCycle = 2; for (int cycle = 0; cycle < maxCycle; cycle++) { watchForward.Start(); var dirtyImage = IDG.ToImage(c, metadata, residualVis, uvw, frequencies); watchForward.Stop(); FitsIO.Write(dirtyImage, "dirty" + cycle + ".fits"); watchDeconv.Start(); var sideLobe = maxSidelobe * GetMax(dirtyImage); Console.WriteLine("sideLobeLevel: " + sideLobe); var b = CommonDeprecated.Residuals.CalculateBMap(dirtyImage, psfCorrelated, psfCut.GetLength(0), psfCut.GetLength(1)); var lambda = 0.8; var alpha = 0.05; var currentLambda = Math.Max(1.0 / alpha * sideLobe, lambda); var converged = SerialCDReference.DeconvolvePath(xImage, b, psfCut, currentLambda, 4.0, alpha, 5, 1000, 2e-5); //var converged = GreedyCD2.Deconvolve(xImage, b, psfCut, currentLambda, alpha, 5000); if (converged) { Console.WriteLine("-----------------------------CONVERGED!!!! with lambda " + currentLambda + "------------------------"); } else { Console.WriteLine("-------------------------------not converged with lambda " + currentLambda + "----------------------"); } watchDeconv.Stop(); FitsIO.Write(xImage, "xImage_" + cycle + ".fits"); watchBackwards.Start(); FFT.Shift(xImage); var xGrid = FFT.Forward(xImage); FFT.Shift(xImage); var modelVis = IDG.DeGrid(c, metadata, xGrid, uvw, frequencies); residualVis = Visibilities.Substract(visibilities, modelVis, flags); watchBackwards.Stop(); } watchBackwards.Stop(); watchTotal.Stop(); var timetable = "total elapsed: " + watchTotal.Elapsed; timetable += "\n" + "idg forward elapsed: " + watchForward.Elapsed; timetable += "\n" + "idg backwards elapsed: " + watchBackwards.Elapsed; timetable += "\n" + "devonvolution: " + watchDeconv.Elapsed; File.WriteAllText("watches_single.txt", timetable); }
public static void DebugSimulatedMixed() { var frequencies = FitsIO.ReadFrequencies(@"C:\dev\GitHub\p9-data\small\fits\simulation_mixed\freq.fits"); var uvw = FitsIO.ReadUVW(@"C:\dev\GitHub\p9-data\small\fits\simulation_mixed\uvw.fits"); var flags = new bool[uvw.GetLength(0), uvw.GetLength(1), frequencies.Length]; //completely unflagged dataset double norm = 2.0; var visibilities = FitsIO.ReadVisibilities(@"C:\dev\GitHub\p9-data\small\fits\simulation_mixed\vis.fits", uvw.GetLength(0), uvw.GetLength(1), frequencies.Length, norm); var visibilitiesCount = visibilities.Length; int gridSize = 1024; int subgridsize = 16; int kernelSize = 4; //cell = image / grid int max_nr_timesteps = 512; double scaleArcSec = 0.5 / 3600.0 * PI / 180.0; var watchTotal = new Stopwatch(); var watchForward = new Stopwatch(); var watchBackwards = new Stopwatch(); var watchDeconv = new Stopwatch(); watchTotal.Start(); var c = new GriddingConstants(visibilitiesCount, gridSize, subgridsize, kernelSize, max_nr_timesteps, (float)scaleArcSec, 1, 0.0f); var metadata = Partitioner.CreatePartition(c, uvw, frequencies); var psf = IDG.CalculatePSF(c, metadata, uvw, flags, frequencies); FitsIO.Write(psf, "psf.fits"); var psfCut = CutImg(psf, 2); FitsIO.Write(psfCut, "psfCut.fits"); var maxSidelobe = CommonDeprecated.PSF.CalcMaxSidelobe(psf); var xImage = new double[gridSize, gridSize]; var residualVis = visibilities; var maxCycle = 10; for (int cycle = 0; cycle < maxCycle; cycle++) { watchForward.Start(); var dirtyImage = IDG.ToImage(c, metadata, residualVis, uvw, frequencies); watchForward.Stop(); FitsIO.Write(dirtyImage, "dirty" + cycle + ".fits"); watchDeconv.Start(); var sideLobe = maxSidelobe * GetMax(dirtyImage); Console.WriteLine("sideLobeLevel: " + sideLobe); var PsfCorrelation = CommonDeprecated.PSF.CalculateFourierCorrelation(psfCut, c.GridSize, c.GridSize); var b = CommonDeprecated.Residuals.CalculateBMap(dirtyImage, PsfCorrelation, psfCut.GetLength(0), psfCut.GetLength(1)); var lambda = 100.0; var alpha = 0.95; var currentLambda = Math.Max(1.0 / alpha * sideLobe, lambda); var converged = SerialCDReference.DeconvolvePath(xImage, b, psfCut, currentLambda, 5.0, alpha, 5, 6000, 1e-3); //var converged = GreedyCD2.Deconvolve(xImage, b, psfCut, currentLambda, alpha, 5000); if (converged) { Console.WriteLine("-----------------------------CONVERGED!!!! with lambda " + currentLambda + "------------------------"); } else { Console.WriteLine("-------------------------------not converged with lambda " + currentLambda + "----------------------"); } watchDeconv.Stop(); FitsIO.Write(xImage, "xImage_" + cycle + ".fits"); watchBackwards.Start(); FFT.Shift(xImage); var xGrid = FFT.Forward(xImage); FFT.Shift(xImage); var modelVis = IDG.DeGrid(c, metadata, xGrid, uvw, frequencies); residualVis = Visibilities.Substract(visibilities, modelVis, flags); watchBackwards.Stop(); } watchBackwards.Stop(); watchTotal.Stop(); var timetable = "total elapsed: " + watchTotal.Elapsed; timetable += "\n" + "idg forward elapsed: " + watchForward.Elapsed; timetable += "\n" + "idg backwards elapsed: " + watchBackwards.Elapsed; timetable += "\n" + "devonvolution: " + watchDeconv.Elapsed; File.WriteAllText("watches_single.txt", timetable); }