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Image Processing. What is Image Processing ?. Image Processing is any form of signal processing for which our input is an image, such as photographs or frames of video and our output can be either an image or a set of characteristics or parameters related to the image.
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What is Image Processing ? Image Processing is any form of signal processing for which our input is an image, such as photographs or frames of video and our output can be either an image or a set of characteristics or parameters related to the image.
Image Processing generally refers to processing of two dimensional picture and by two dimensional picture we implies a digital image. A digital image is an array of real or complex numbers represented by a finite number of bits. But now in these days optical and analog image processing is also possible.
Applications • Face detection • Feature detection • Non-photorealistic rendering • Medical image processing • Microscope image processing • Morphological image processing • Remote sensing • Automated Sieving Procedures • Finger print recognization
How image processing is done ? Image processing can be done using various softwaresand languages such as:- Software • Matlab • Adobe photoshop • Irfan view Language • VHDL • C/C++
MATLAB The name MATLAB stands for matrix laboratory . It is a high-performance language for technical computing. It is an interactive system whose basic data element is an array which does not require any dimensioning. This allows us to solve many technical computing problems, especially those with matrix and vector formulations, in a fraction of the time.
MATLAB features a family of add-on application-specific solutions called toolboxes. These toolboxes are comprehensive collections of matlab functions (M-files) that extend the matlab environment to solve particular classes of problems. Areas in which toolboxes are available include image processing, signal processing, control systems, neural networks, fuzzy logic, wavelets, simulation, and many others..
Image processing toolbox The Image Processing Toolbox is a collection of functions that extend the capability of the Matlab numeric computing environment. These functions are written on M-files and further we can extend the capabilities of the Image Processing Toolbox by writing our own M-files. This toolbox supports a wide range of image processing operations such as..
Operations of image processing • Color corrections such as brightness and contrast adjustments, quantization, or color translation to a different color space. • Image registration, the alignment of two or more images. • Image segmentation.
Neighborhood and block operations. • Linear filtering and filter design. • Transforms. • High dynamic range imaging by combining multiple images. • Deblurring.
Image formats supported by Matlab The following image formats are supported by Matlab: • BMP • HDF • JPEG • PCX • TIFF • XWB
Types of images Intensity image This is the equivalent to a "gray scale image“ . It represents an image as a matrix where every element has a value corresponding to how bright/dark (each element represent intensities). Binary image This image format also stores an image as a matrix but can only color a pixel black or white (and nothing in between). It assigns a 0 for black and a 1 for white.
Indexed image This is a practical way of representing color images. An indexed image stores an image as two matrices. The first matrix has the same size as the image and one number for each pixel. The second matrix is called the color map and its size may be different from the image. The numbers in the first matrix is an instruction of what number to use in the color map matrix.
RGB image It represents an image with three matrices of sizes matching the image format. Each matrix corresponds to one of the colors red, green or blue and gives an instruction of how much of each of these colors a certain pixel should use. A pixel whose color components are (255,255,255) is displayed as White. And whose color components are (0,0,0) is displayed as Black.
Commands for intensity Adjustment Histeq( ): This command is used to improve the contrast in the image. This function spreads the intensity values over the full range of the image, and this process is known as histogram equalization. Syntax histeq(‘Image_name.format’); After Before
Imadjust( ): This command is used to adjust the contrast of the image. Imadjust increases the contrast of the image by saturating 1% of the data at both low and high intensities of Image and by stretching the intensity. Syntax Imadjust(‘image_name.format’)
Adapthisteq( ): This command is used to perform contrast-limited adaptive histogram equalization (CLAHE). It is an alternative to function histeq, While histeq works on the entire image, adapthisteq operates on small regions in the image, called tiles. Syntax adapthisteq(‘Image_name.format’); Before After
Commands used for various file operations in image processing toolbox. • Imread( ): This command is used to read that image on which the operation has to be done. Imread returns the image data in the array. If the file contains a grayscale image, then it will return a two-dimensional (M-by-N) array and if the file contains a color image, it will return a three-dimensional (M-by-N-by-3) array. The class of the returned array depends on the data type used by the file format. Syntax Imread(‘image_name.format’)
Imview( ): This command is used to view the image on the screen. And this command is always used with the imread and imwrite command, because, it views only that image which is under process. Syntax Imview(‘image_name.format’)
Imwrite( , ): This command is used to change the format of read file. By using this command we can change the file formats from one to another. Syntax Imwrite(‘image_name.format2’, ‘image_name.format1’) • Imfinfo( ): This command is used to obtain the information about the image under process. It is used to obtain information such as size, position of pixels, number of rows and columns etc. Syntax Iminfo(‘image_name.format’)
Imsubtract( , ): This command is used to create a more uniform background, by subtracting the background image from the original image. To estimate the background image, we use following command: background=imopen(‘Image_name.format’,strel('disk',15)) To see the estimated background image, type: imview(background) Now subtract the background image from the original image, type: imsubtract(‘image_name.format’,background);
Imresize( , ): This command is used to resize the processed image. To enlarge an image, specify a magnification factor greater than 1 in the command. To reduce an image, specify a magnification factor between 0 and 1 in the command. Syntax imresize(‘Image_name.format’, value);
Image Rotation( , ): This command is used to rotate the given image. This command accepts two primary arguments, one is the image to be rotated and other one is rotation angle. We have to specify the rotation angle in degrees. If a positive value is specified then imrotate rotates the image counterclockwise and if a negative value then imrotate rotates the image clockwise. Syntax imrotate(‘Image_name.format’, angle_in_degree);
Imcrop( , ); This command is used to crop the particular image. It accepts two primary arguments: • The image to be cropped. • The coordinates of a rectangle that defines the crop area. If we call imcrop without specifying the crop rectangle, we can specify the crop rectangle interactively. In this case, the cursor changes to crosshairs when it is over the image. Position the crosshairs over a corner of the crop region and press and hold the left mouse button. When we drag the crosshairs over the image we specify the rectangular crop region. imcrop draws a rectangle around the area we are selecting. When we release the mouse button, imcrop creates a new image from the selected region.
Syntax Imcrop(‘image_name.format’); After Before If we call imcrop with specifying the crop rectangle, imcrop operates on the image in the current axes.SyntaxImcrop(‘Image_name.format’ , [rect]);
Imerode( , ): This command is used to erode the image. This function accepts two primary arguments: • The input image to be processed (grayscale, binary image), • A structuring element object, returned by the strel function, or a binary matrix defining the neighborhood of a structuring element. Syntax Imerode(‘binary_image.format’ , strel); Before After
Im2bw= This command is used to convert the given image in to binary image. This command is mainly followed by one another command i.e. level=graythresh(image_name.format). Syntax Level=graythresh(‘image_name.format’) Bw=im2bw(‘image_name.format’, level) Before After
Duller = This command is used to fade the image, so that, other image on which it is overlapped can be easily viewed. Syntax Duller= * ‘image_name.format’ This is the amount by which the fading is done. • Combine= This command is used to combine or overlap the two images. This is the command on which over all project stands. Syntax Combine= image1 +image2. 0.5
Image Conversions We can convert images in any of formats/types described above using the following commands. • Intensity format to Indexed format. gray2ind( ) Gray Indexed
indexed format to intensity format. ind2gray() Indexed Gray
RGB format to indexed format. rgb2ind( ) RGB Indexed
IMAGE ANALYSIS Image analysis return information about the structure of an image. This section describes toolbox functions that we can use for these image analysis techniques which includes: • Edge Detection • Boundary Tracing • Quadtree Decomposition
Edge Detection We can use the edge function to detect edges, which are those places in an image that correspond to object boundaries. To find edges, this function looks for places in the image where the intensity changes rapidly. Edge takes an intensity image I as its input, and returns a binary image BW of the same size as I, with 1's where the function finds edges in I and 0's elsewhere.
Canny Method The most powerful edge-detection method that edge provides is the Canny method. The Canny method differs from the other edge-detection methods in that it uses two different thresholds (to detect strong and weak edges), and includes the weak edges in the output only if they are connected to strong edges. This method is therefore less likely than the others to be fooled by noise, and more likely to detect true weak edges. Syntax Edge (‘image_name.fomat’,'canny'); Before After
Boundary Tracing The toolbox includes two functions you can use to find the boundaries of objects in a binary image: • Bwtraceboundary • Bwboundaries
Bwtraceboundary The bwtraceboundary function returns the row and column coordinates of all the pixels on the border of an object in an image. We must specify the location of a border pixel on the object as the starting point for the trace. Syntax boundary = bwtraceboundary(binary_image,[row, col],'N');
Bwboundaries The bwboundaries function returns the row and column coordinates of border pixels of all the objects in an image. Syntax binary_image _filled = imfill(binary_image,'holes'); boundaries = bwboundaries(binary_image _filled);
QuadtreeDecomposition Quadtreedecomposition is an analysis technique that involves subdividing an image into blocks that are more homogeneous than the image itself. This technique reveals information about the structure of the image. Syntax qtdecomp(‘Image_name.format’,threshold); Before After
Noise Removal Digital images are prone to a variety of types of noise. There are several ways that noise can be introduced into an image, depending on how the image is created. For example: If the image is scanned from a photograph made on film, the film grain is a source of noise. Noise can also be the result of damage to the film, or be introduced by the scanner itself. If the image is acquired directly in a digital format, the mechanism for gathering the data (such as a CCD detector) can introduce noise.Electronictransmission of image data can introduce noise. The Image Processing toolbox provides a number of different ways to remove or reduce noise in an image. Different methods are better for different kinds of noise. The method which is used mostly to remove noise is Filtering.
Filtering Filtering is a technique for modifying or enhancing an image. It is a neighborhood operation, in which the value of any given pixel in the output image is determined by applying some algorithm to the values of the pixels in the neighborhood of the corresponding input pixel. A pixel's neighborhood is some set of pixels, defined by their locations relative to that pixel. Filtering is further categories as following: • Linear Filtering • Median Filtering • Adaptive Filtering
Image Histogram An image histogram is a chart that shows the distribution of intensities in an indexed or intensity image. The image histogram function imhist creates this plot by making n equally spaced bins, each representing a range of data values. It then calculates the number of pixels within each range. Syntax Imhist(‘Image_name.format’);