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This blog post going over the basic image manipulation things you can |
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do with Open CV. [Open CV](https://opencv.org/) is an open-source |
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library of computer vision tools. Open CV is written to be used in |
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conjunction with deep learning frameworks like |
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[TensorFlow](https://www.tensorflow.org/). This tutorial is going to |
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be using Python3, although you can also use Open CV with C++, Java, |
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and [Matlab](https://www.mathworks.com/products/matlab.html) |
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# Reading and Displaying Images |
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The first thing that you want to do when you start playing around with |
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open cv is to import the dependencies required. Most basic computer |
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vision projects with OpenCV will use NumPy and matplotlib. All images |
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in Open CV are represented as NumPy matrices with shape (x, y, 3), |
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with the data type uint8. This essentially means that every image is a |
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2d matrix with three color channels for BGR where each pixel can have |
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an intensity between 0 and 255. Zero is black where 255 is white in |
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grayscale. |
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```python |
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# Open cv library |
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import cv2 |
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# numpy library for matrix manipulation |
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import numpy as np |
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# matplotlib for displaying the images |
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from matplotlib import pyplot as plt |
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``` |
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Reading an image is as easy as using the "cv2.imread" function. If |
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you simply try to print the image with Python's print function, you |
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will flood your terminal with a massive matrix. In this post, we are |
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going to be using the infamous |
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[Lenna](https://en.wikipedia.org/wiki/Lenna) image which has been used |
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in the Computer Vision field since 1973. |
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```python |
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lenna = cv2.imread('lenna.jpg') |
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# Prints a single pixel value |
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print(lenna[50][50]) |
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# Prints the image dimensions |
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# (width, height, 3 -- BRG) |
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print(lenna.shape) |
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``` |
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[ 89 104 220] |
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(440, 440, 3) |
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By now you might have noticed that I am saying "BRG" instead of "RGB"; |
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in Open CV colors are in the order of "BRG" instead of "RGB". This |
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makes it particularly difficult when printing the images using a |
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different library like matplotlib because they expect images to be in |
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the form "RGB". Thankfully for us we can use some functions in the |
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Open CV library to convert the color scheme. |
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```python |
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def printI(img): |
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rgb = cv2.cvtColor(img, cv2.COLOR_BGR2RGB) |
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plt.imshow(rgb) |
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printI(lenna) |
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``` |
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Going a step further with image visualization, we can use matplotlib |
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to view images side by side to each other. This makes it easier to |
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make comparisons when running different algorithms on the same image. |
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```python |
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def printI3(i1, i2, i3): |
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fig = plt.figure() |
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ax1 = fig.add_subplot(1,3,1) |
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ax1.imshow(cv2.cvtColor(i1, cv2.COLOR_BGR2RGB)) |
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ax2 = fig.add_subplot(1,3,2) |
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ax2.imshow(cv2.cvtColor(i2, cv2.COLOR_BGR2RGB)) |
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ax3 = fig.add_subplot(1,3,3) |
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ax3.imshow(cv2.cvtColor(i3, cv2.COLOR_BGR2RGB)) |
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def printI2(i1, i2): |
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fig = plt.figure() |
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ax1 = fig.add_subplot(1,2,1) |
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ax1.imshow(cv2.cvtColor(i1, cv2.COLOR_BGR2RGB)) |
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ax2 = fig.add_subplot(1,2,2) |
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ax2.imshow(cv2.cvtColor(i2, cv2.COLOR_BGR2RGB)) |
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``` |
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If we zero out the other colored layers and only left one channel, we |
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can visualize each channel individually. In the following example |
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notice that image.copy() generates a deep-copy of the image matrix -- |
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this is a useful NumPy function. |
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```python |
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def generateBlueImage(image): |
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b = image.copy() |
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# set the green and red channels to 0 |
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# note images are in BGR |
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b[:, :, 1] = 0 |
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b[:, :, 2] = 0 |
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return b |
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def generateGreenImage(image): |
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g = image.copy() |
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# sets the blue and red channels to 0 |
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g[:, :, 0] = 0 |
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g[:, :, 2] = 0 |
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return g |
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def generateRedImage(image): |
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r = image.copy() |
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# sets the blue and green channels to 0 |
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r[:, :, 0] = 0 |
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r[:, :, 1] = 0 |
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return r |
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def visualizeRGB(image): |
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printI3(generateRedImage(image), generateGreenImage(image), generateBlueImage(image)) |
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``` |
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```python |
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visualizeRGB(lenna) |
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``` |
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# Grayscale Images |
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Converting a color image to grayscale reduces the dimensionality |
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because you are squishing each color layer into one channel. Open CV |
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has a built-in function to do this. |
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```python |
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glenna = cv2.cvtColor(lenna, cv2.COLOR_BGR2GRAY) |
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printI(glenna) |
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``` |
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The builtin function works in most applications, however, you |
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sometimes want more control in which color layers are weighted more in |
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generating the grayscale image. To do that you can |
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```python |
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def generateGrayScale(image, rw = 0.25, gw = 0.5, bw = 0.25): |
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""" |
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Image is the open cv image |
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w = weight to apply to each color layer |
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""" |
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w = np.array([[[ bw, gw, rw]]]) |
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gray2 = cv2.convertScaleAbs(np.sum(image*w, axis=2)) |
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return gray2 |
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``` |
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```python |
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printI(generateGrayScale(lenna)) |
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``` |
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Notice that the sum of the weights is equal to 1 if it above 1, it |
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would brighten the image but if it was below 1, it would darken the |
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image. |
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```python |
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printI2(generateGrayScale(lenna, 0.1, 0.3, 0.1), generateGrayScale(lenna, 0.5, 0.6, 0.5)) |
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``` |
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We could also use our function to display the grayscale output of each |
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color layer. |
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```python |
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printI3(generateGrayScale(lenna, 1.0, 0.0, 0.0), generateGrayScale(lenna, 0.0, 1.0, 0.0), generateGrayScale(lenna, 0.0, 0.0, 1.0)) |
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``` |
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Based on this output, the red layer is the brightest which makes sense |
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because the majority of the image is in a pinkish/red tone. |
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# Pixel Operations |
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Pixel operations are simply things that you do to every pixel in the |
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image. |
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## Negative |
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To take the negative of an image, you simply invert the image. Ie: if |
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the pixel was 0, it would now be 255, if the pixel was 0 it would now |
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be 255. Since all the images are unsigned ints of length 8, right |
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once, a pixel hits a boundary, it would automatically wrap over which |
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is convenient for us. With NumPy, if you subtract a number from a |
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matrix, it would do that for every element in that matrix -- neat. |
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Therefore if we wanted to invert an image we could just take 255 and |
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subtract it from the image. |
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```python |
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invert_lenna = 255 - lenna |
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printI(invert_lenna) |
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``` |
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## Darken And Lighten |
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To brighten and darken an image you can add constants to the image |
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because that would push the image closer twords 0 and 255 which is |
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black and white. |
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```python |
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bright_bad_lenna = lenna + 25 |
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printI(bright_bad_lenna) |
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``` |
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Notice that the image got brighter but in some parts the image got |
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inverted. This is because when we add two images, and we don't want to |
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wrap, we have to set a clipping threshold to be the 0 and 255. IE: |
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when we add a constant to the image at pixel 240, we don't want it to |
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wrap back to 0, we just want it to retain a value of 255. Open CV has |
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built-in functions for this. |
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```python |
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def brightenImg(img, num): |
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a = np.zeros(img.shape, dtype=np.uint8) |
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a[:] = num |
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return cv2.add(img, a) |
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def darkenImg(img, num): |
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a = np.zeros(img.shape, dtype=np.uint8) |
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a[:] = num |
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return cv2.subtract(img, a) |
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brighten_lenna = brightenImg(lenna, 50) |
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darken_lenna = darkenImg(lenna, 50) |
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printI2(brighten_lenna, darken_lenna) |
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``` |
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## Contrast |
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Adjusting the contrast of an image is a matter of multiplying the |
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image by a constant. Multiplying by a number greater than 1 would |
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increase the contrast and multiplying by a number lower than 1 would |
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decrease the contrast. |
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```python |
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def adjustContrast(img, amount): |
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""" |
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changes the data type to float32 so we can adjust the contrast by |
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more than integers, then we need to clip the values and |
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convert data types at the end. |
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""" |
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a = np.zeros(img.shape, dtype=np.float32) |
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a[:] = amount |
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b = img.astype(float) |
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c = np.multiply(a, b) |
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np.clip(c, 0, 255, out=c) # clips between 0 and 255 |
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return c.astype(np.uint8) |
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``` |
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```python |
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printI2(adjustContrast(lenna, 0.8) ,adjustContrast(lenna, 1.3)) |
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``` |
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# Noise |
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I most cases you don't want to add random noise to your image, |
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however, in some algorithms, it becomes necessary to do for testing. |
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Noise is anything that makes the image imperfect. In the "real world" |
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this is usually in the form of dead pixels on your camera lens or |
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other things distorting your view. |
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## Salt and Pepper |
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Salt and pepper noise is adding random black and white pixels to your |
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image. |
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```python |
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import random |
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def uniformNoise(image, num): |
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img = image.copy() |
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h, w, c = img.shape |
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x = np.random.uniform(0,w,num) |
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y = np.random.uniform(0,h,num) |
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for i in range(0, num): |
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r = 0 if random.randrange(0,2) == 0 else 255 |
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img[int(x[i])][int(y[i])] = np.asarray([r, r, r]) |
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return img |
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printI2(uniformNoise(lenna, 1000), uniformNoise(lenna, 7000)) |
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``` |
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# Image Denoising |
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It is possible to remove the salt and pepper noise from an image to |
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clean it up. Unlike how my professor worded it, this is not |
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"enhancing" the image, this is merely using filters that remove the |
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noise from the image by blurring it. |
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## Moving Average |
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The moving average technique sets each pixel equal to the average of |
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its neighborhood. The bigger your neighborhood the more the image is |
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blurred. |
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```python |
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bad_lenna = uniformNoise(lenna, 6000) |
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blur_lenna = cv2.blur(bad_lenna,(3,3)) |
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printI2(bad_lenna, blur_lenna) |
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``` |
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As you can see, most of the noise was removed from the image but, |
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imperfections were left. To see the effects of the filter size, you |
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can play around with it. |
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```python |
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blur_lenna_3 = cv2.blur(bad_lenna,(3,3)) |
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blur_lenna_8 = cv2.blur(bad_lenna,(8,8)) |
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printI2(blur_lenna_3, blur_lenna_8) |
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``` |
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## Median Filtering |
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Median filters transform every pixel by taking the median value of its |
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neighborhood. This is a lot better than average filters for noise |
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reduction because it has less of a blurring effect and it is extremely |
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well at removing outliers like salt and pepper noise. |
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```python |
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median_lenna = cv2.medianBlur(bad_lenna,3) |
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printI2(bad_lenna, median_lenna) |
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``` |
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# Remarks |
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Open CV is a vastly powerful framework for image manipulation. This |
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post only covered some of the more basic applications of Open CV. |
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Future posts might explore some of the more advanced techniques in |
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computer vision like filters, Canny edge detection, template matching, |
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and Harris Corner detection. |
