Exemple #1
0
        public void Correlate(Image tiltStack, Image reference, int size, float lowpassAngstrom, float highpassAngstrom, int3 volumeDimensions, int healpixOrder, string symmetry = "C1")
        {
            if (!Directory.Exists(CorrelationDir))
                Directory.CreateDirectory(CorrelationDir);

            float DownscaleFactor = lowpassAngstrom / (float)(CTF.PixelSize * 2);
            Image DownscaledStack = tiltStack.AsScaledMassive(new int2(tiltStack.Dims) / DownscaleFactor / 2 * 2);
            tiltStack.FreeDevice();

            float HighpassNyquist = (float)(CTF.PixelSize * 2) * DownscaleFactor / highpassAngstrom;
            DownscaledStack.Bandpass(HighpassNyquist, 1, false);

            Image ScaledReference = reference.AsScaled(reference.Dims / DownscaleFactor / 2 * 2);
            reference.FreeDevice();
            Image PaddedReference = ScaledReference.AsPadded(new int3(size, size, size));
            ScaledReference.Dispose();
            PaddedReference.Bandpass(HighpassNyquist, 1, true);
            Projector ProjectorReference = new Projector(PaddedReference, 2);
            PaddedReference.Dispose();

            VolumeDimensions = volumeDimensions / DownscaleFactor / 2 * 2;
            int SizeCropped = size / 2;

            int3 Grid = (VolumeDimensions + SizeCropped - 1) / SizeCropped;
            List<float3> GridCoords = new List<float3>();
            for (int z = 0; z < Grid.Z; z++)
                for (int y = 0; y < Grid.Y; y++)
                    for (int x = 0; x < Grid.X; x++)
                        GridCoords.Add(new float3(x * SizeCropped + SizeCropped / 2,
                                                  y * SizeCropped + SizeCropped / 2,
                                                  z * SizeCropped + SizeCropped / 2));

            float3[] HealpixAngles = Helper.GetHealpixAngles(healpixOrder, symmetry).Select(a => a * Helper.ToRad).ToArray();

            Image CTFCoords = GetCTFCoords(size, (int)(size * DownscaleFactor));

            float[] OutputCorr = new float[VolumeDimensions.Elements()];

            int PlanForw, PlanBack, PlanForwCTF;
            Projector.GetPlans(new int3(size, size, size), 2, out PlanForw, out PlanBack, out PlanForwCTF);

            int BatchSize = 16;
            for (int b = 0; b < GridCoords.Count; b += BatchSize)
            {
                int CurBatch = Math.Min(BatchSize, GridCoords.Count - b);

                Image Subtomos = new Image(IntPtr.Zero, new int3(size, size, size * CurBatch), true, true);
                Image SubtomoCTFs = new Image(IntPtr.Zero, new int3(size, size, size * CurBatch), true);

                for (int st = 0; st < CurBatch; st++)
                {
                    Image ImagesFT = GetSubtomoImages(DownscaledStack, size, GridCoords[b + st], true);
                    Image CTFs = GetSubtomoCTFs(GridCoords[b + st], CTFCoords);
                    //Image CTFWeights = GetSubtomoCTFs(GridCoords[b + st], CTFCoords, true, true);

                    ImagesFT.Multiply(CTFs);    // Weight and phase-flip image FTs by CTF, which still has its sign here
                    //ImagesFT.Multiply(CTFWeights);
                    CTFs.Abs();                 // CTF has to be positive from here on since image FT phases are now flipped

                    // CTF has to be converted to complex numbers with imag = 0, and weighted by itself
                    float2[] CTFsComplexData = new float2[CTFs.ElementsComplex];
                    float[] CTFsContinuousData = CTFs.GetHostContinuousCopy();
                    for (int i = 0; i < CTFsComplexData.Length; i++)
                        CTFsComplexData[i] = new float2(CTFsContinuousData[i] * CTFsContinuousData[i], 0);

                    Image CTFsComplex = new Image(CTFsComplexData, CTFs.Dims, true);

                    Projector ProjSubtomo = new Projector(new int3(size, size, size), 2);
                    lock (GPU.Sync)
                        ProjSubtomo.BackProject(ImagesFT, CTFs, GetAngleInImages(GridCoords[b + st]));
                    Image Subtomo = ProjSubtomo.Reconstruct(false, PlanForw, PlanBack, PlanForwCTF);
                    ProjSubtomo.Dispose();

                    /*Image CroppedSubtomo = Subtomo.AsPadded(new int3(SizeCropped, SizeCropped, SizeCropped));
                    CroppedSubtomo.WriteMRC(ParticlesDir + RootName + "_" + (b + st).ToString("D5") + ".mrc");
                    CroppedSubtomo.Dispose();*/

                    Projector ProjCTF = new Projector(new int3(size, size, size), 2);
                    lock (GPU.Sync)
                        ProjCTF.BackProject(CTFsComplex, CTFs, GetAngleInImages(GridCoords[b + st]));
                    Image SubtomoCTF = ProjCTF.Reconstruct(true, PlanForw, PlanBack, PlanForwCTF);
                    ProjCTF.Dispose();

                    GPU.FFT(Subtomo.GetDevice(Intent.Read), Subtomos.GetDeviceSlice(size * st, Intent.Write), Subtomo.Dims, 1);
                    GPU.CopyDeviceToDevice(SubtomoCTF.GetDevice(Intent.Read), SubtomoCTFs.GetDeviceSlice(size * st, Intent.Write), SubtomoCTF.ElementsReal);

                    ImagesFT.Dispose();
                    CTFs.Dispose();
                    //CTFWeights.Dispose();
                    CTFsComplex.Dispose();

                    Subtomo.Dispose();
                    SubtomoCTF.Dispose();
                }

                Image BestCorrelation = new Image(IntPtr.Zero, new int3(size, size, size * CurBatch));
                Image BestRot = new Image(IntPtr.Zero, new int3(size, size, size * CurBatch));
                Image BestTilt = new Image(IntPtr.Zero, new int3(size, size, size * CurBatch));
                Image BestPsi = new Image(IntPtr.Zero, new int3(size, size, size * CurBatch));

                GPU.CorrelateSubTomos(ProjectorReference.Data.GetDevice(Intent.Read),
                                      ProjectorReference.Oversampling,
                                      ProjectorReference.Data.Dims,
                                      Subtomos.GetDevice(Intent.Read),
                                      SubtomoCTFs.GetDevice(Intent.Read),
                                      new int3(size, size, size),
                                      (uint)CurBatch,
                                      Helper.ToInterleaved(HealpixAngles),
                                      (uint)HealpixAngles.Length,
                                      MainWindow.Options.ExportParticleRadius / ((float)CTF.PixelSize * DownscaleFactor),
                                      BestCorrelation.GetDevice(Intent.Write),
                                      BestRot.GetDevice(Intent.Write),
                                      BestTilt.GetDevice(Intent.Write),
                                      BestPsi.GetDevice(Intent.Write));

                for (int st = 0; st < CurBatch; st++)
                {
                    Image ThisCorrelation = new Image(BestCorrelation.GetDeviceSlice(size * st, Intent.Read), new int3(size, size, size));
                    Image CroppedCorrelation = ThisCorrelation.AsPadded(new int3(SizeCropped, SizeCropped, SizeCropped));

                    //CroppedCorrelation.WriteMRC(CorrelationDir + RootName + "_" + (b + st).ToString("D5") + ".mrc");
                    float[] SubCorr = CroppedCorrelation.GetHostContinuousCopy();
                    int3 Origin = new int3(GridCoords[b + st]) - SizeCropped / 2;
                    for (int z = 0; z < SizeCropped; z++)
                    {
                        int zVol = Origin.Z + z;
                        if (zVol >= VolumeDimensions.Z)
                            continue;

                        for (int y = 0; y < SizeCropped; y++)
                        {
                            int yVol = Origin.Y + y;
                            if (yVol >= VolumeDimensions.Y)
                                continue;

                            for (int x = 0; x < SizeCropped; x++)
                            {
                                int xVol = Origin.X + x;
                                if (xVol >= VolumeDimensions.X)
                                    continue;

                                OutputCorr[(zVol * VolumeDimensions.Y + yVol) * VolumeDimensions.X + xVol] = SubCorr[(z * SizeCropped + y) * SizeCropped + x];
                            }
                        }
                    }

                    CroppedCorrelation.Dispose();
                    ThisCorrelation.Dispose();
                }

                Subtomos.Dispose();
                SubtomoCTFs.Dispose();

                BestCorrelation.Dispose();
                BestRot.Dispose();
                BestTilt.Dispose();
                BestPsi.Dispose();
            }

            GPU.DestroyFFTPlan(PlanForw);
            GPU.DestroyFFTPlan(PlanBack);
            GPU.DestroyFFTPlan(PlanForwCTF);

            CTFCoords.Dispose();
            ProjectorReference.Dispose();
            DownscaledStack.Dispose();

            Image OutputCorrImage = new Image(OutputCorr, VolumeDimensions);
            OutputCorrImage.WriteMRC(CorrelationDir + RootName + ".mrc");
            OutputCorrImage.Dispose();
        }
Exemple #2
0
        public void Reconstruct(Image tiltStack, int size, float lowpassAngstrom, int3 volumeDimensions)
        {
            if (!Directory.Exists(ReconstructionDir))
                Directory.CreateDirectory(ReconstructionDir);

            if (File.Exists(ReconstructionDir + RootName + ".mrc"))
                return;

            VolumeDimensions = volumeDimensions;

            float DownscaleFactor = lowpassAngstrom / (float)(CTF.PixelSize * 2);
            Image DownscaledStack = tiltStack.AsScaledMassive(new int2(tiltStack.Dims) / DownscaleFactor / 2 * 2);
            tiltStack.FreeDevice();

            GPU.Normalize(DownscaledStack.GetDevice(Intent.Read),
                          DownscaledStack.GetDevice(Intent.Write),
                          (uint)DownscaledStack.ElementsSliceReal,
                          (uint)DownscaledStack.Dims.Z);

            int3 VolumeDimensionsCropped = volumeDimensions / DownscaleFactor / 2 * 2;
            int SizeCropped = size / 4;

            int3 Grid = (VolumeDimensionsCropped + SizeCropped - 1) / SizeCropped;
            List<float3> GridCoords = new List<float3>();
            for (int z = 0; z < Grid.Z; z++)
                for (int y = 0; y < Grid.Y; y++)
                    for (int x = 0; x < Grid.X; x++)
                        GridCoords.Add(new float3(x * SizeCropped + SizeCropped / 2,
                                                  y * SizeCropped + SizeCropped / 2,
                                                  z * SizeCropped + SizeCropped / 2));

            Image CTFCoords = GetCTFCoords(size, (int)(size * DownscaleFactor));

            float[] OutputRec = new float[VolumeDimensionsCropped.Elements()];

            int PlanForw, PlanBack, PlanForwCTF;
            Projector.GetPlans(new int3(size, size, size), 2, out PlanForw, out PlanBack, out PlanForwCTF);

            for (int p = 0; p < GridCoords.Count; p++)
            {
                Image ImagesFT = GetSubtomoImages(DownscaledStack, size, GridCoords[p] * DownscaleFactor, false, 1f / DownscaleFactor);
                Image CTFs = GetSubtomoCTFs(GridCoords[p] * DownscaleFactor, CTFCoords);
                //Image CTFWeights = GetSubtomoCTFs(GridCoords[p], CTFCoords, true, true);

                ImagesFT.Multiply(CTFs);    // Weight and phase-flip image FTs by CTF, which still has its sign here
                //ImagesFT.Multiply(CTFWeights);
                CTFs.Abs();                 // Since everything is already phase-flipped, weights are positive

                Projector ProjSubtomo = new Projector(new int3(size, size, size), 2);
                lock (GPU.Sync)
                    ProjSubtomo.BackProject(ImagesFT, CTFs, GetAngleInImages(GridCoords[p] * DownscaleFactor));
                Image Subtomo = ProjSubtomo.Reconstruct(false, PlanForw, PlanBack, PlanForwCTF);

                Image SubtomoCropped = Subtomo.AsPadded(new int3(SizeCropped, SizeCropped, SizeCropped));
                Subtomo.Dispose();
                ProjSubtomo.Dispose();

                /*Image CroppedSubtomo = Subtomo.AsPadded(new int3(SizeCropped, SizeCropped, SizeCropped));
                CroppedSubtomo.WriteMRC(ParticlesDir + RootName + "_" + (b + st).ToString("D5") + ".mrc");
                CroppedSubtomo.Dispose();*/

                ImagesFT.Dispose();
                CTFs.Dispose();
                //CTFWeights.Dispose();

                float[] SubtomoData = SubtomoCropped.GetHostContinuousCopy();
                int3 Origin = new int3(GridCoords[p]) - SizeCropped / 2;
                for (int z = 0; z < SizeCropped; z++)
                {
                    int zVol = Origin.Z + z;
                    if (zVol >= VolumeDimensionsCropped.Z)
                        continue;

                    for (int y = 0; y < SizeCropped; y++)
                    {
                        int yVol = Origin.Y + y;
                        if (yVol >= VolumeDimensionsCropped.Y)
                            continue;

                        for (int x = 0; x < SizeCropped; x++)
                        {
                            int xVol = Origin.X + x;
                            if (xVol >= VolumeDimensionsCropped.X)
                                continue;

                            OutputRec[(zVol * VolumeDimensionsCropped.Y + yVol) * VolumeDimensionsCropped.X + xVol] = -SubtomoData[(z * SizeCropped + y) * SizeCropped + x];
                        }
                    }
                }

                SubtomoCropped.Dispose();
            }

            GPU.DestroyFFTPlan(PlanForw);
            GPU.DestroyFFTPlan(PlanBack);
            GPU.DestroyFFTPlan(PlanForwCTF);

            CTFCoords.Dispose();
            DownscaledStack.Dispose();

            Image OutputRecImage = new Image(OutputRec, VolumeDimensionsCropped);
            OutputRecImage.WriteMRC(ReconstructionDir + RootName + ".mrc");
            OutputRecImage.Dispose();
        }
Exemple #3
0
        public Tuple<Image, Image> MakeReconstructionOneTomogram(Image tiltStack, int subset, int size, float3[] particleOrigins, float3[] particleOrigins2, float3[] particleAngles, float3[] particleAngles2, int[] particleSubset)
        {
            Projector MapProjector = new Projector(new int3(size, size, size), 2);
            Projector WeightProjector = new Projector(new int3(size, size, size), 2);

            List<int> ParticleIDs = new List<int>();
            for (int i = 0; i < particleSubset.Length; i++)
                if (particleSubset[i] == subset)
                    ParticleIDs.Add(i);
            int NParticles = ParticleIDs.Count;

            particleOrigins = ParticleIDs.Select(i => particleOrigins[i]).ToArray();
            particleOrigins2 = ParticleIDs.Select(i => particleOrigins2[i]).ToArray();
            particleAngles = ParticleIDs.Select(i => particleAngles[i]).ToArray();
            particleAngles2 = ParticleIDs.Select(i => particleAngles2[i]).ToArray();

            Image CTFCoords = GetCTFCoords(size, size);

            for (int angleID = 0; angleID < NTilts; angleID++)
            {
                float DoseID = IndicesSortedDose[angleID] / (float)(NTilts - 1);

                for (int b = 0; b < NParticles; b += 1024)
                {
                    int NBatch = Math.Min(1024, NParticles - b);

                    float3[] ParticleOriginsInterp = new float3[NBatch];
                    float3[] ParticleAnglesInterp = new float3[NBatch];
                    for (int n = 0; n < NBatch; n++)
                    {
                        float3 OriginDiff = particleOrigins2[b + n] - particleOrigins[b + n];
                        float3 AngleDiff = particleAngles2[b + n] - particleAngles[b + n];
                        ParticleOriginsInterp[n] = particleOrigins[b + n] + OriginDiff * DoseID;
                        ParticleAnglesInterp[n] = particleAngles[b + n] + AngleDiff * DoseID;
                    }

                    Image ParticleImages = GetImagesOneAngle(tiltStack, size, ParticleOriginsInterp, angleID, true);
                    Image ParticleCTFs = GetCTFsOneAngle(tiltStack, CTFCoords, ParticleOriginsInterp, angleID, true);

                    ParticleImages.Multiply(ParticleCTFs);
                    //ParticleCTFs.Multiply(ParticleCTFs);
                    ParticleCTFs.Abs();

                    MapProjector.BackProject(ParticleImages,
                                             ParticleCTFs,
                                             GetAnglesInOneAngle(ParticleOriginsInterp,
                                                                 ParticleAnglesInterp,
                                                                 angleID));

                    ParticleImages.Dispose();
                    ParticleCTFs.Dispose();

                    // Now reconstruct the weights which will be needed during optimization later
                    ParticleCTFs = GetCTFsOneAngle(tiltStack, CTFCoords, ParticleOriginsInterp, angleID, true);

                    // CTF has to be converted to complex numbers with imag = 0
                    float2[] CTFsComplexData = new float2[ParticleCTFs.ElementsComplex];
                    float[] CTFWeightsData = new float[ParticleCTFs.ElementsComplex];
                    float[] CTFsContinuousData = ParticleCTFs.GetHostContinuousCopy();
                    for (int i = 0; i < CTFsComplexData.Length; i++)
                    {
                        CTFsComplexData[i] = new float2(Math.Abs(CTFsContinuousData[i] * CTFsContinuousData[i]), 0);
                        CTFWeightsData[i] = Math.Abs(CTFsContinuousData[i]);
                    }

                    Image CTFsComplex = new Image(CTFsComplexData, ParticleCTFs.Dims, true);
                    Image CTFWeights = new Image(CTFWeightsData, ParticleCTFs.Dims, true);

                    WeightProjector.BackProject(CTFsComplex,
                                                CTFWeights,
                                                GetAnglesInOneAngle(ParticleOriginsInterp,
                                                                    ParticleAnglesInterp,
                                                                    angleID));

                    ParticleCTFs.Dispose();
                    CTFsComplex.Dispose();
                    CTFWeights.Dispose();
                }
            }

            CTFCoords.Dispose();

            //MapProjector.Weights.WriteMRC($"d_weights{angleID:D3}.mrc");
            Image Reconstruction = MapProjector.Reconstruct(false);
            MapProjector.Dispose();

            foreach (var slice in WeightProjector.Weights.GetHost(Intent.ReadWrite))
                for (int i = 0; i < slice.Length; i++)
                    slice[i] = Math.Min(slice[i], 1);

            Image ReconstructionWeights = WeightProjector.Reconstruct(true);
            WeightProjector.Dispose();

            return new Tuple<Image, Image>(Reconstruction, ReconstructionWeights);
        }
Exemple #4
0
        public void AddToReconstructionOneAngle(Image tiltStack,
                                                int subset,
                                                int size,
                                                float3[] particleOrigins,
                                                float3[] particleOrigins2,
                                                float3[] particleAngles,
                                                float3[] particleAngles2,
                                                int[] particleSubset,
                                                int angleID,
                                                Projector mapProjector,
                                                Projector weightProjector)
        {
            List<int> ParticleIDs = new List<int>();
            for (int i = 0; i < particleSubset.Length; i++)
                if (particleSubset[i] == subset)
                    ParticleIDs.Add(i);
            int NParticles = ParticleIDs.Count;

            particleOrigins = ParticleIDs.Select(i => particleOrigins[i]).ToArray();
            particleOrigins2 = ParticleIDs.Select(i => particleOrigins2[i]).ToArray();
            particleAngles = ParticleIDs.Select(i => particleAngles[i]).ToArray();
            particleAngles2 = ParticleIDs.Select(i => particleAngles2[i]).ToArray();

            Image CTFCoords = GetCTFCoords(size, size);

            float DoseID = IndicesSortedDose[angleID] / (float)(NTilts - 1);

            for (int b = 0; b < NParticles; b += 1024)
            {
                int NBatch = Math.Min(1024, NParticles - b);

                float3[] ParticleOriginsInterp = new float3[NBatch];
                float3[] ParticleAnglesInterp = new float3[NBatch];
                for (int n = 0; n < NBatch; n++)
                {
                    float3 OriginDiff = particleOrigins2[b + n] - particleOrigins[b + n];
                    float3 AngleDiff = particleAngles2[b + n] - particleAngles[b + n];
                    ParticleOriginsInterp[n] = particleOrigins[b + n] + OriginDiff * DoseID;
                    ParticleAnglesInterp[n] = particleAngles[b + n] + AngleDiff * DoseID;
                }

                Image ParticleImages = GetImagesOneAngle(tiltStack, size, ParticleOriginsInterp, angleID, true);
                Image ParticleCTFs = GetCTFsOneAngle(tiltStack, CTFCoords, ParticleOriginsInterp, angleID, false);

                ParticleImages.Multiply(ParticleCTFs);
                //ParticleCTFs.Multiply(ParticleCTFs);
                ParticleCTFs.Abs();

                mapProjector.BackProject(ParticleImages,
                                         ParticleCTFs,
                                         GetAnglesInOneAngle(ParticleOriginsInterp,
                                                             ParticleAnglesInterp,
                                                             angleID));

                ParticleImages.Dispose();
                ParticleCTFs.Dispose();

                // Now reconstruct the weights which will be needed during optimization later
                ParticleCTFs = GetCTFsOneAngle(tiltStack, CTFCoords, ParticleOriginsInterp, angleID, false);

                // CTF has to be converted to complex numbers with imag = 0
                float2[] CTFsComplexData = new float2[ParticleCTFs.ElementsComplex];
                float[] CTFWeightsData = new float[ParticleCTFs.ElementsComplex];
                float[] CTFsContinuousData = ParticleCTFs.GetHostContinuousCopy();
                for (int i = 0; i < CTFsComplexData.Length; i++)
                {
                    CTFsComplexData[i] = new float2(Math.Abs(CTFsContinuousData[i] * CTFsContinuousData[i]), 0);
                    CTFWeightsData[i] = Math.Abs(CTFsContinuousData[i]);
                }

                Image CTFsComplex = new Image(CTFsComplexData, ParticleCTFs.Dims, true);
                Image CTFWeights = new Image(CTFWeightsData, ParticleCTFs.Dims, true);

                weightProjector.BackProject(CTFsComplex,
                                            CTFWeights,
                                            GetAnglesInOneAngle(ParticleOriginsInterp,
                                                                ParticleAnglesInterp,
                                                                angleID));

                ParticleCTFs.Dispose();
                CTFsComplex.Dispose();
                CTFWeights.Dispose();
            }

            CTFCoords.Dispose();
        }
Exemple #5
0
        public void GetSubtomo(Image tiltStack, float3 coords, float3 angles, Image ctfCoords, out Image subtomo, out Image subtomoCTF, int planForw = -1, int planBack = -1, int planForwCTF = -1)
        {
            int Size = ctfCoords.Dims.X;
            float3[] ImageAngles = GetAngleInImages(coords);

            Image ImagesFT = GetSubtomoImages(tiltStack, Size, coords, true);
            Image CTFs = GetSubtomoCTFs(coords, ctfCoords, true, false, false);
            //Image CTFWeights = GetSubtomoCTFs(coords, ctfCoords, true, true);

            ImagesFT.Multiply(CTFs);    // Weight and phase-flip image FTs by CTF, which still has its sign here
            //ImagesFT.Multiply(CTFWeights);
            CTFs.Abs();                 // CTF has to be positive from here on since image FT phases are now flipped

            // CTF has to be converted to complex numbers with imag = 0, and weighted by itself
            float2[] CTFsComplexData = new float2[CTFs.ElementsComplex];
            float[] CTFsContinuousData = CTFs.GetHostContinuousCopy();
            for (int i = 0; i < CTFsComplexData.Length; i++)
                CTFsComplexData[i] = new float2(CTFsContinuousData[i] * CTFsContinuousData[i], 0);

            Image CTFsComplex = new Image(CTFsComplexData, CTFs.Dims, true);

            Projector ProjSubtomo = new Projector(new int3(Size, Size, Size), 2);
            lock (GPU.Sync)
                ProjSubtomo.BackProject(ImagesFT, CTFs, ImageAngles);
            subtomo = ProjSubtomo.Reconstruct(false, planForw, planBack, planForwCTF);
            ProjSubtomo.Dispose();

            GPU.NormParticles(subtomo.GetDevice(Intent.Read),
                              subtomo.GetDevice(Intent.Write),
                              subtomo.Dims,
                              (uint)(MainWindow.Options.ExportParticleRadius / CTF.PixelSize),
                              false,
                              1);
            //subtomo = new Image(new int3(1, 1, 1));

            Projector ProjCTF = new Projector(new int3(Size, Size, Size), 2);
            lock (GPU.Sync)
                ProjCTF.BackProject(CTFsComplex, CTFs, ImageAngles);
            subtomoCTF = ProjCTF.Reconstruct(true, planForw, planBack, planForwCTF);
            ProjCTF.Dispose();
            //subtomoCTF = new Image(new int3(1, 1, 1));

            ImagesFT.Dispose();
            CTFs.Dispose();
            //CTFWeights.Dispose();
            CTFsComplex.Dispose();
        }