/// <summary> /// Subtract b2 from b1 and normalize the image /// </summary> /// <param name="b1">Image</param> /// <param name="b2">Image</param> /// <returns>Normalized Image</returns> public static Bitmap Subtract(Bitmap b1, Bitmap b2) { if (b1.Width != b2.Width || b1.Height != b2.Height) throw new Exception("Images not the same size cannot subtract"); ImagerBitmap i = new ImagerBitmap(b1.Clone() as Bitmap); ImagerBitmap i2 = new ImagerBitmap(b2.Clone() as Bitmap); int[,] red = new int[i.Bitmap.Width, i.Bitmap.Height]; int[,] blue = new int[i.Bitmap.Width, i.Bitmap.Height]; int[,] green = new int[i.Bitmap.Width, i.Bitmap.Height]; int redMax = 0; int redMin = 0; int redRange = 0; int blueMax = 0; int blueMin = 0; int blueRange = 0; int greenMax = 0; int greenMin = 0; int greenRange = 0; //fill the arrays with the subtracted values //Keep track of the min and max values for later for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { Color c1 = i.GetPixel(column, row); Color c2 = i2.GetPixel(column, row); red[column, row] = c2.R - c1.R; blue[column, row] = c2.B - c1.B; green[column, row] = c2.G - c1.G; if (red[column, row] > redMax) redMax = red[column, row]; if (red[column, row] < redMin) redMin = red[column, row]; if (blue[column, row] > blueMax) blueMax = blue[column, row]; if (blue[column, row] < blueMin) blueMin = blue[column, row]; if (green[column, row] > greenMax) greenMax = green[column, row]; if (green[column, row] < greenMin) greenMin = green[column, row]; } } //find the range of the min an max redRange = Math.Abs(redMax - redMin); blueRange = Math.Abs(blueMax - blueMin); greenRange = Math.Abs(greenRange - greenMin); //Normalize the values in the arrays and load the result image for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { if (redRange != 0) red[column, row] = 255 - (((redMax - red[column, row]) * 255) / redRange); if (blueRange != 0) blue[column, row] = 255 - (((blueMax - blue[column, row]) * 255) / blueRange); if (greenRange != 0) green[column, row] = 255 - (((greenMax - green[column, row]) * 255) / greenRange); if (red[column, row] < 0) red[column, row] = 0; if (blue[column, row] < 0) blue[column, row] = 0; if (green[column, row] < 0) green[column, row] = 0; i2.SetPixel(column, row, Color.FromArgb(red[column, row], green[column, row], blue[column, row])); } } i.UnlockBitmap(); i2.UnlockBitmap(); return i2.Bitmap.Clone() as Bitmap; }
/// <summary> /// Perform a Bionomial filter using a 3x3 Mask /// </summary> /// <param name="b">Image to Process</param> /// <returns>Filtered Image</returns> public static Bitmap Binomial3x3(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); ImagerBitmap i2 = new ImagerBitmap(b.Clone() as Bitmap); for (int column = 1; column < i.Bitmap.Width - 1; column++) { for (int row = 1; row < i.Bitmap.Height - 1; row++) { Color[,] c = i.Get3x3(row, column); int red = ((c[0, 0].R * 1) + (c[0, 1].R * 2) + (c[0, 2].R * 1) + (c[1, 0].R * 2) + (c[1, 1].R * 4) + (c[1, 2].R * 2) + (c[2, 0].R * 1) + (c[2, 1].R * 2) + (c[2, 2].R * 1)) / 16; int green = ((c[0, 0].G * 1) + (c[0, 1].G * 2) + (c[0, 2].G * 1) + (c[1, 0].G * 2) + (c[1, 1].G * 4) + (c[1, 2].G * 2) + (c[2, 0].G * 1) + (c[2, 1].G * 2) + (c[2, 2].G * 1)) / 16; int blue = ((c[0, 0].B * 1) + (c[0, 1].B * 2) + (c[0, 2].B * 1) + (c[1, 0].B * 2) + (c[1, 1].B * 4) + (c[1, 2].B * 2) + (c[2, 0].B * 1) + (c[2, 1].B * 2) + (c[2, 2].B * 1)) / 16; i2.SetPixel(column, row, Color.FromArgb(red, green, blue)); } } i.UnlockBitmap(); i2.UnlockBitmap(); return i2.Bitmap.Clone() as Bitmap; }
public static Bitmap LaplaceGreyscale(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); ImagerBitmap i2 = new ImagerBitmap(b.Clone() as Bitmap); for (int column = 1; column < i.Bitmap.Width - 1; column++) { for (int row = 1; row < i.Bitmap.Height - 1; row++) { int[,] c = i.GetGrey3x3(row, column); int val = (((c[0, 0] + c[0, 1] + c[0, 2] + c[1, 0] + c[1, 2] + c[2, 0] + c[2, 1] + c[2, 2]) * -1) + (c[1, 1] * 8)) + 128; if (val >= 128) val = 0; else val = 255; i2.SetPixel(column, row, Color.FromArgb(val, val, val)); } } i.UnlockBitmap(); i2.UnlockBitmap(); return i2.Bitmap.Clone() as Bitmap; }
/// <summary> /// Perform a Median fiter using a 5x5 Mask /// </summary> /// <param name="b">Image to Process</param> /// <returns>Filtered Image</returns> public static Bitmap Median5x5(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); ImagerBitmap i2 = new ImagerBitmap(b.Clone() as Bitmap); for (int column = 2; column < i.Bitmap.Width - 2; column++) { for (int row = 2; row < i.Bitmap.Height - 2; row++) { Color[,] c = i.Get5x5(row, column); int red = Median(c[0, 0].R, c[0, 1].R, c[0, 2].R, c[0, 3].R, c[0, 4].R, c[1, 0].R, c[1, 1].R, c[1, 2].R, c[1, 3].R, c[1, 4].R, c[2, 0].R, c[2, 1].R, c[2, 2].R, c[2, 3].R, c[2, 4].R, c[3, 0].R, c[3, 1].R, c[3, 2].R, c[3, 3].R, c[3, 4].R, c[4, 0].R, c[4, 1].R, c[4, 2].R, c[4, 3].R, c[4, 4].R); int green = Median(c[0, 0].G, c[0, 1].G, c[0, 2].G, c[0, 3].G, c[0, 4].G, c[1, 0].G, c[1, 1].G, c[1, 2].G, c[1, 3].G, c[1, 4].G, c[2, 0].G, c[2, 1].G, c[2, 2].G, c[2, 3].G, c[2, 4].G, c[3, 0].G, c[3, 1].G, c[3, 2].G, c[3, 3].G, c[3, 4].G, c[4, 0].G, c[4, 1].G, c[4, 2].G, c[4, 3].G, c[4, 4].G); int blue = Median(c[0, 0].B, c[0, 1].B, c[0, 2].B, c[0, 3].B, c[0, 4].B, c[1, 0].B, c[1, 1].B, c[1, 2].B, c[1, 3].B, c[1, 4].B, c[2, 0].B, c[2, 1].B, c[2, 2].B, c[2, 3].B, c[2, 4].B, c[3, 0].B, c[3, 1].B, c[3, 2].B, c[3, 3].B, c[3, 4].B, c[4, 0].B, c[4, 1].B, c[4, 2].B, c[4, 3].B, c[4, 4].B); i2.SetPixel(column, row, Color.FromArgb(red, green, blue)); } } i.UnlockBitmap(); i2.UnlockBitmap(); return i2.Bitmap.Clone() as Bitmap; }
/// <summary> /// Get the red pixels from the bitmap /// </summary> /// <param name="b">Image to Process</param> /// <returns>Filtered Image</returns> public static Bitmap GetRedBitmap(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { i.SetPixel(column, row, Color.FromArgb(i.GetPixel(column, row).R, 0, 0)); } } i.UnlockBitmap(); return i.Bitmap.Clone() as Bitmap; }
/// <summary> /// Perform laplace edge detection on the image /// </summary> /// <param name="b">Source Image</param> /// <returns>Edges</returns> public static Bitmap Laplace(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); ImagerBitmap i2 = new ImagerBitmap(b.Clone() as Bitmap); for (int column = 1; column < i.Bitmap.Width - 1; column++) { for (int row = 1; row < i.Bitmap.Height - 1; row++) { Color[,] c = i.Get3x3(row, column); int red = (((c[0, 0].R + c[0, 1].R + c[0, 2].R + c[1, 0].R + c[1, 2].R + c[2, 0].R + c[2, 1].R + c[2, 2].R) * -1) + (c[1, 1].R * 8)) + 128; int green = (((c[0, 0].G + c[0, 1].G + c[0, 2].G + c[1, 0].G + c[1, 2].G + c[2, 0].G + c[2, 1].G + c[2, 2].G) * -1) + (c[1, 1].G * 8)) + 128; int blue = (((c[0, 0].B + c[0, 1].B + c[0, 2].B + c[1, 0].B + c[1, 2].B + c[2, 0].B + c[2, 1].B + c[2, 2].B) * -1) + (c[1, 1].B * 8)) + 128; if (red >= 128) red = 0; else red = 255; if (green >= 128) green = 0; else green = 255; if (blue >= 128) blue = 0; else blue = 255; i2.SetPixel(column, row, Color.FromArgb(red, green, blue)); } } i.UnlockBitmap(); i2.UnlockBitmap(); return i2.Bitmap.Clone() as Bitmap; }
/// <summary> /// Make the image Grey scale /// </summary> /// <param name="b">Image to Process</param> /// <returns>Filtered Image</returns> public static Bitmap GetGreyScaleBitmap(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { int val = i.GetGreyPixel(column, row); i.SetPixel(column, row, Color.FromArgb(val, val, val)); } } i.UnlockBitmap(); return i.Bitmap.Clone() as Bitmap; }
public static Bitmap GetBlackAndWhiteBitmap2(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); double[] histogram = new double[256]; for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { histogram[i.GetGreyPixel(column, row)]++; } } double k = b.Width * b.Height; double half = k / 2; int middle = 0; while (k > half) { k = k - histogram[middle]; middle++; } for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { int val = (i.GetPixel(column, row).R + i.GetPixel(column, row).G + i.GetPixel(column, row).B) / 3; if (val > middle) val = 255; else val = 0; i.SetPixel(column, row, Color.FromArgb(val, val, val)); } } i.UnlockBitmap(); return i.Bitmap.Clone() as Bitmap; }
/// <summary> /// Make the image black and white /// </summary> /// <param name="b">Image to Process</param> /// <returns>Filtered Image</returns> public static Bitmap GetBlackAndWhiteBitmap(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); double[] histogram = new double[256]; for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { histogram[i.GetGreyPixel(column, row)]++; } } //find the position of the max value on the left int leftK = 0; for (int k = 0; k < 128; k++) { if (histogram[k] > histogram[leftK]) leftK = k; } //find the position of the max value on the right int rightK = 0; for (int k = 128; k < 256; k++) { if (histogram[k] > histogram[rightK]) rightK = k; } //find the min value between the 2 local maxes int localMin = rightK; for (int k = leftK; k < rightK; k++) { if (histogram[k] < histogram[localMin]) localMin = k; } for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { int val = (i.GetPixel(column, row).R + i.GetPixel(column, row).G + i.GetPixel(column, row).B) / 3; if (val > localMin) val = 255; else val = 0; i.SetPixel(column, row, Color.FromArgb(val, val, val)); } } i.UnlockBitmap(); return i.Bitmap.Clone() as Bitmap; }
public static void GenerateExcelFile(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); string fileName = "output.txt"; int f = 0; using (StreamWriter sw = new StreamWriter(fileName, false)) { sw.WriteLine("{0}\t{1}\t{2}\t{3}\t{4}\t{5}\t{6}", "Index", "Row", "Column", "Red", "Green", "Blue", "Gray"); for (int column = 0; column < i.Bitmap.Width; column++) { for (int row = 0; row < i.Bitmap.Height; row++) { f++; Color c = i.GetPixel(column, row); int g = i.GetGreyPixel(column, row); sw.WriteLine("{0}\t{1}\t{2}\t{3}\t{4}\t{5}\t{6}", f, row, column, c.R, c.G, c.B, g); } } } i.UnlockBitmap(); System.Diagnostics.Process.Start(fileName); }
/// <summary> /// Perform a Binomial filter using a 5x5 Mask /// </summary> /// <param name="b">Image to Process</param> /// <returns>Filtered Image</returns> public static Bitmap Binomial5x5(Bitmap b) { ImagerBitmap i = new ImagerBitmap(b.Clone() as Bitmap); ImagerBitmap i2 = new ImagerBitmap(b.Clone() as Bitmap); for (int column = 2; column < i.Bitmap.Width - 2; column++) { for (int row = 2; row < i.Bitmap.Height - 2; row++) { Color[,] c = i.Get5x5(row, column); int red = ((c[0, 0].R * 1) + (c[0, 1].R * 4) + (c[0, 2].R * 6) + (c[0, 3].R * 4) + (c[0, 4].R * 1) + (c[1, 0].R * 4) + (c[1, 1].R * 16) + (c[1, 2].R * 24) + (c[1, 3].R * 16) + (c[1, 4].R * 4) + (c[2, 0].R * 6) + (c[2, 1].R * 24) + (c[2, 2].R * 36) + (c[2, 3].R * 24) + (c[2, 4].R * 6) + (c[3, 0].R * 4) + (c[3, 1].R * 16) + (c[3, 2].R * 24) + (c[3, 3].R * 16) + (c[3, 4].R * 4) + (c[4, 0].R * 1) + (c[4, 1].R * 4) + (c[4, 2].R * 6) + (c[4, 3].R * 4) + (c[4, 4].R * 1)) / 256; int green = ((c[0, 0].G * 1) + (c[0, 1].G * 4) + (c[0, 2].G * 6) + (c[0, 3].G * 4) + (c[0, 4].G * 1) + (c[1, 0].G * 4) + (c[1, 1].G * 16) + (c[1, 2].G * 24) + (c[1, 3].G * 16) + (c[1, 4].G * 4) + (c[2, 0].G * 6) + (c[2, 1].G * 24) + (c[2, 2].G * 36) + (c[2, 3].G * 24) + (c[2, 4].G * 6) + (c[3, 0].G * 4) + (c[3, 1].G * 16) + (c[3, 2].G * 24) + (c[3, 3].G * 16) + (c[3, 4].G * 4) + (c[4, 0].G * 1) + (c[4, 1].G * 4) + (c[4, 2].G * 6) + (c[4, 3].G * 4) + (c[4, 4].G * 1)) / 256; int blue = ((c[0, 0].B * 1) + (c[0, 1].B * 4) + (c[0, 2].B * 6) + (c[0, 3].B * 4) + (c[0, 4].B * 1) + (c[1, 0].B * 4) + (c[1, 1].B * 16) + (c[1, 2].B * 24) + (c[1, 3].B * 16) + (c[1, 4].B * 4) + (c[2, 0].B * 6) + (c[2, 1].B * 24) + (c[2, 2].B * 36) + (c[2, 3].B * 24) + (c[2, 4].B * 6) + (c[3, 0].B * 4) + (c[3, 1].B * 16) + (c[3, 2].B * 24) + (c[3, 3].B * 16) + (c[3, 4].B * 4) + (c[4, 0].B * 1) + (c[4, 1].B * 4) + (c[4, 2].B * 6) + (c[4, 3].B * 4) + (c[4, 4].B * 1)) / 256; i2.SetPixel(column, row, Color.FromArgb(red, green, blue)); } } i.UnlockBitmap(); i2.UnlockBitmap(); return i2.Bitmap.Clone() as Bitmap; }