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Abstract:Digital image processing is the use of computer algorithms to perform image processing on digital images. Digital image processing has the same advantages over analog image processing as digital signal processing has over analog signal processing — it allows a much wider range of algorithms to be applied to the input data, and can avoid problems such as the build-up of noise and signal distortion during processing. The most common kind of digital image processing is digital image editing.Pattern recognition aims to classify data (patterns) based on either a priori knowledge or on statistical information extracted from the patterns. The patterns to be classified are usually groups of measurements or observations, defining points in an appropriate multidimensional space. This is in contrast to pattern matching, where the pattern is rigidly specified.Table of ContentsFront PageCandidate DeclarationCertificateCertificate (External, Internal)Acknowledgement 1.Fundamentals2.Image formats supported by Matlab3.Working formats in Matlab4.Intensity image (gray scale image)5.Binary image6.Indexed image7.RGB image8.Multiframe image9.How to convert between different formats10.Image format conversion. How to display an image in MatlabWorking with Strings in MATLAB Distance Measures in MATLABComputing Forming Pattern Vectors Recognition Based on Decision-Theoretic Methods Introduction:Image: An image may be defined as a two-dimensional function ( x,y ) ,where x and y are spatial (plane) coordinates, and the amplitude of f at any pair of coordinates (x,y)is called the intensity or gray level of the image at that point.Analog Image: Can be mathematically represented as a continuous range of values representing position and intensity.Digital Image: a digital image is restricted in both its spatial coordinates and in its allowed intensities. The field of digital image processing refers to processing digital images by means of a digital computer. Note that a digital image is composed of a finite number of elements, each of which has a particular location and value. These elements are referred to as picture elements, image elements, pels, and pixels. Pixel is the term most widely used to denote the elements of a digital imageFundamentalsA digital image is composed of?pixels?which can be thought of as small dots on the screen. A digital image is an instruction of how to color each pixel. We will see in detail later on how this is done in practice. A typical size of an image is 512-by-512 pixels. Later on in the course you will see that it is convenient to let the dimensions of the image to be a power of 2. For example, 29=512. In the general case we say that an image is of size?m-by-n?if it is composed of?m?pixels in the vertical direction and?n?pixels in the horizontal direction.Let us say that we have an image on the format 512-by-1024 pixels. This means that the data for the image must contain information about 524288 pixels, which requires a lot of memory! Hence,?compressing?images is essential for efficient image processing. You will later on see how Fourier analysis and Wavelet analysis can help us to compress an image significantly. There are also a few "computer scientific" tricks (for example entropy coding) to reduce the amount of data required to store an image.Image formats supported by MatlabThe following image formats are supported by Matlab:BMPHDFJPEGPCXTIFFXWBMost images you find on the Internet are JPEG-images which is the name for one of the most widely used compression standards for images. If you have stored an image you can usually see from the suffix what format it is stored in. For example, an image named?myimage.jpg?is stored in the JPEG format and we will see later on that we can load an image of this format into Matlab.Working formats in MatlabIf an image is stored as a JPEG-image on your disc we first read it into Matlab. However, in order to start working with an image, for example perform a wavelet transform on the image, we must convert it into a different format. This section explains four common formats.Intensity image (gray scale image)This is the equivalent to a "gray scale image" and this is the image we will mostly work with in this course. It represents an image as a matrix where every element has a value corresponding to how bright/dark the pixel at the corresponding position should be colored. There are two ways to represent the number that represents the brightness of the pixel: The?double?class (or data type). This assigns a floating number ("a number with decimals") between 0 and 1 to each pixel. The value 0 corresponds to black and the value 1 corresponds to white. The other class is called?uint8?which assigns an integer between 0 and 255 to represent the brightness of a pixel. The value 0 corresponds to black and 255 to white. The class?uint8?only requires roughly 1/8 of the storage compared to the class?double. On the other hand, many mathematical functions can only be applied to thedouble?class. We will see later how to convert between?double?and?uint8.Binary imageThis 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 imageThis is a practical way of representing color images. (In this course we will mostly work with gray scale images but once you have learned how to work with a gray scale image you will also know the principle how to work with color images.) An indexed image stores an image as two matrices. . e 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 imageThis is another format for color images. 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.Multiframe imageIn some applications we want to study a sequence of images. This is very common in biological and medical imaging where you might study a sequence of slices of a cell. For these cases, the multiframe format is a convenient way of working with a sequence of images. In case you choose to work with biological imaging later on in this course, you may use this format.How to convert between different formatsThe following table shows how to convert between the different formats given above.?All these commands require the Image processing tool box!Image format conversion(Within the parenthesis you type the name of the image you wish to convert.)Operation:Matlab command:Convert between intensity/indexed/RGB format to binary format.dither()Convert between intensity format to indexed format.gray2ind()Convert between indexed format to intensity format.ind2gray()Convert between indexed format to RGB format.ind2rgb()Convert a regular matrix to intensity format by scaling.mat2gray()Convert between RGB format to intensity format.rgb2gray()Convert between RGB format to indexed format.rgb2ind()The command?mat2gray?is useful if you have a matrix representing an image but the values representing the gray scale range between, let's say, 0 and 1000. The command?mat2gray?automatically re scales all entries so that they fall within 0 and 255 (if you use the?uint8?class) or 0 and 1 (if you use the?double?class).How to convert between?double?and?uint8When you store an image, you should store it as a?uint8?image since this requires far less memory than?double. When you are processing an image (that is performing mathematical operations on an image) you should convert it into a?double. Converting back and forth between these classes is easy.I=im2double(I);converts an image named?I?from?uint8?to?double.I=im2uint8(I);converts an image named?I?from?double?to?uint8.How to read filesWhen you encounter an image you want to work with, it is usually in form of a file (for example, if you down load an image from the web, it is usually stored as a JPEG-file). Once we are done processing an image, we may want to write it back to a JPEG-file so that we can, for example, post the processed image on the web. This is done using the?imread?and?imwrite?commands.These commands require the Image processing tool box!Reading and writing image filesOperation:Matlab command:Read an image.?(Within the parenthesis you type the name of the image file you wish to read.?Put the file name within single quotes ' '.)imread()Write an image to a file.?(As the first argument within the parenthesis you type the name of the image you have worked with.?As a second argument within the parenthesis you type the name of the file and format that you want to write the image to.?Put the file name within single quotes ' '.)imwrite( , )Make sure to use semi-colon ; after these commands, otherwise you will get LOTS OF number scrolling on you screen... The commands?imread?and?imwrite?support the formats given in the section "Image formats supported by Matlab" above.Loading and saving variables in MatlabThis section explains how to load and save variables in Matlab. Once you have read a file, you probably convert it into an intensity image (a matrix) and work with this matrix. Once you are done you may want to save the matrix representing the image in order to continue to work with this matrix at another time. This is easily done using the commands?save?and?load. Note thatsave?and?load?are commonly used Matlab commands, and works independently of what tool boxes that are installed.Loading and saving variablesOperation:Matlab command:Save the variable?X?.save XLoad the variable?X?.load XExamplesIn the first example we will down load an image from the web, read it into Matlab, investigate its format and save the matrix representing the image.Example 1.Down load the following image (by clicking on the image using the right mouse button) and save the file as?cell1.jpg.This is an image of a cell taken by an electron microscope at the Department of Molecular, Cellular and Developmental Biology at CU.Now open Matlab and make sure you are in the same directory as your stored file. (You can check what files your directory contains by typing?ls?at the Matlab prompt. You change directory using the command?cd.) Now type in the following commands and see what each command does. (Of course, you do not have to type in the comments given in the code after the%?signs.)I=imread('cell1.jpg'); % Load the image file and store it as the variable I.?whos % Type "whos" in order to find out the size and class of all stored variables.?save I % Save the variable I.?ls % List the files in your directory.?% There should now be a file named "I.mat" in you directory?% containing your variable I.?Note that all variables that you save in Matlab usually get the suffix?.mat.Next we will see that we can display an image using the command?imshow. This command requires the image processing tool box. Commands for displaying images will be explained in more detail in the section "How to display images in Matlab" below.clear % Clear Matlab's memory.?load I % Load the variable I that we saved above.?whos % Check that it was indeed loaded.?imshow(I) % Display the image?I=im2double(I); % Convert the variable into double.?whos % Check that the variable indeed was converted into double?% The next procedure cuts out the upper left corner of the image?% and stores the reduced image as Ired.?for i=1:256for j=1:256Ired(i,j)=I(i,j);endend?whos % Check what variables you now have stored.?imshow(Ired) % Display the reduced image.?Example 2Go to the?CU home page?and down load the image of campus with the Rockies in the background. Save the image as?pic-home.jpgNext, do the following in Matlab. (Make sure you are in the same directory as your image file).clear?A=imread('pic-home.jpg');?whos?imshow(A)?Note that when you typed?whos?it probably said that the size was?300x504x3. This means that the image was loaded as an RGB image (see the section "RGB image above"). However, in this course we will mostly work with gray scale images, so let us convert it into a gray scale (or "intensity") image.A=rgb2gray(A); % Convert to gray scale?whos?imshow(A)?Now the size indicates that our image is nothing else than a regular matrix.Note: In other cases when you down load a color image and type?whos?you might see that there is one matrix corresponding to the image size and one matrix called?map?stored in Matlab. In that case, you have loaded an indexed image (see section above). In order to convert the indexed image into an intensity (gray scale) image, use the?ind2gray?command described in the section "How to convert between different formats" above.How to display an image in MatlabHere are a couple of basic Matlab commands (do not require any tool box) for displaying an image.Displaying an image given on matrix formOperation:Matlab command:Display an image represented as the matrix?X.imagesc(X)Adjust the brightness. s is a parameter such that?-1<s<0 gives a darker image, 0<s<1 gives a brighter image.brighten(s)Change the colors to gray.colormap(gray)Sometimes your image may not be displayed in gray scale even though you might have converted it into a gray scale image. You can then use the command?colormap(gray)?to "force" Matlab to use a gray scale when displaying an image.If you are using Matlab with an Image processing tool box installed, I recommend you to use the command?imshow?to display an image.Displaying an image given on matrix form (with image processing tool box)Operation:Matlab command:Display an image represented as the matrix?X.imshow(X)Zoom in (using the left and right mouse button).zoom onTurn off the zoom function.zoom offAnalysis Objective of Project In this Project we are using an analog image and than converted into the digital image and than proceed by matlab toolRequirement Gathering In our project we are using the following matlab tools for digitalizing and processing an image List of the Matlab tools are given blowM-Files Operators Flow Control Code Optimization InteractiveRepresentation and Description Some Additional MATLAB and IPT Functions Used?Some Basic Utility M-Functions 433?x Contents?Chain Codes Polygonal Approximations Using Minimum-Perimeter?Polygons Shape Numbers Descriptors 463?11.4.1 Function Statistical Moments Fourier Descriptors Object Recognition Working with Strings in MATLAB Distance Measures in MATLABComputing Forming Pattern Vectors Recognition Based on Decision-Theoretic Methods Representation and Description Some Additional MATLAB and IPT Functions Used?Some Basic Utility M-Functions 433?x Contents?Chain Codes Polygonal Approximations Using Minimum-Perimeter?Polygons Shape Numbers Descriptors 463?11.4.1 Function Statistical Moments Fourier Descriptors Object Recognition Working with Strings in MATLAB Distance Measures in MATLABComputing Forming Pattern Vectors Recognition Based on Decision-Theoretic Methods Representation and Description Some Additional MATLAB and IPT Functions Used?Some Basic Utility M-Functions 433?x Contents?Chain Codes Polygonal Approximations Using Minimum-Perimeter?Polygons Shape Numbers Descriptors 463?11.4.1 Function Statistical Moments Fourier Descriptors Object Recognition Working with Strings in MATLAB Distance Measures in MATLABComputing Forming Pattern Vectors Recognition Based on Decision-Theoretic Methods Representation and Description Some Additional MATLAB and IPT Functions Used?Some Basic Utility M-Functions 433?x Contents?Chain Codes Polygonal Approximations Using Minimum-Perimeter?Polygons Shape Numbers Descriptors 463?11.4.1 Function Statistical Moments Fourier Descriptors Object Recognition Working with Strings in MATLAB Distance Measures in MATLABComputing Forming Pattern Vectors Recognition Based on Decision-Theoretic Methods 2 Logarithmic and Contrast-Stretching Transformations Generating and Plotting Image Histograms Histogram Equalization Obtaining Frequency Domain Filters from Spatial Filters Spatial Filtering Linear Spatial Filtering Nonlinear Spatial Filtering Image Processing Toolbox Standard Spatial Filters Linear Spatial Filters Nonlinear Spatial Filters FrequePreview Computing and Visualizing the 2-D DFT in MATLAB An M-function for Filtering in the Frequency Domain Histogram Matching (Specification) Restoration in the Presence of Noise Only—Spatial Filtering High-Frequency Emphasis Filtering 5 Image Restoration Model of the Image Degradation/Restoration Process Lowpass Frequency Domain Filters 129?4.5.3 Wireframe and Surface Plotting Modeling the Degradation Function Direct Inverse Filtering Constrained Least Squares (Regularized) Filtering Using the Lucy-Richardson?Algorithm Iterative Nonlinear Restoration 10.4.1 Basic Formulation 407?Segmentation Using the Watershed Transform -Controlled Watershed Segmentation Summary 425?Region Splitting and Merging Representation and Description Some Additional MATLAB and IPT Functions Used?Some Basic Utility M-Functions 433?x Contents?Chain Codes Polygonal Approximations Using Minimum-Perimeter?Polygons Representation and Description Some Additional MATLAB and IPT Functions Used?Some Basic Utility M-Functions 433?x Contents?Chain Codes Polygonal Approximations Using Minimum-Perimeter?Polygons Shape Numbers Descriptors 463?11.4.1 Function Statistical Moments Fourier Descriptors Representation and Description Some Additional MATLAB and IPT Functions Used?Some Basic Utility M-Functions 433?x Contents?Chain Codes Polygonal Approximations Using Minimum-Perimeter?Polygons Shape Numbers Descriptors 463?11.4.1 Function Statistical Moments Fourier Descriptors Object Recognition Design and simulate signal processing systemsSignal Processing Blockset? provides algorithms and tools for the design and simulation of signal processingsystems. You can develop DSP algorithms for speech and audio processing, radar tracking, basebandcommunications, and other applications. Most algorithms and tools are available as both System objects (for usein MATLAB?) and blocks (for use in Simulink?).The blockset provides techniques for FFTs, FIR and IIR digital filtering, spectral estimation, statistical and linearalgebra computations, streaming, and multirate processing. It also includes signal generators, interactive scopes,spectrum analyzers, and other tools for visualizing signals and simulation results.You can use the blockset to develop and validate real-time signal processing systems. For embedded system designand rapid prototyping, the blockset supports fixed-point arithmetic, C-code generation, and implementation onembedded hardware.Key Features? Simulation of streaming, frame-based, and multirate systems? System objects for use in MATLAB and blocks for use in Simulink? Algorithms for FFT and other transforms, spectral estimation, windowing, signal statistics, and linear algebra? Design and realization architectures for FIR, IIR, multirate, and LMS and RMS adaptive filters? Signal generators and I/O support for multimedia files and devices, including multichannel audio? Fixed-point data type modeling and bit-true simulation? Support for automatic C-code generation1Software RequirementOVERVIEW OF LANGUAGE USEDAbout J2EE & Microsoft AccessJAVAJava is a small, simple, safe, object oriented, interpreted or dynamically optimized, byte coded, architectural, garbage collected, multithreaded programming language with a strongly typed exception-handling for writing distributed and dynamically extensible programs.Java is an object oriented programming language. Java is a high-level, third generation language like C, FORTRAN, Small talk, Pearl and many others. You can use java to write computer applications that crunch numbers, process words, play games, store data or do any of the thousands of other things computer software can do.Special programs called applets that can be downloaded from the internet and played safely within a web browser. Java a supports this application and the follow features make it one of the best programming language.It is simple and object orientedIt helps to create user friendly interfaces.It is very dynamic.It supports multithreading.It is platform independentIt is highly secure and robust.It supports internet programmingJava is a programming language originally developed by Sun Microsystems and released in 1995 as a core component of Sun's Java platform. The language derives much of its syntax from C and C++ but has a simpler object model and fewer low-level facilities. Java applications are typically compiled to byte code which can run on any Java virtual machine (JVM) regardless of computer architecture.The original and reference implementation Java compilers, virtual machines, and class libraries were developed by Sun from 1995. As of May 2007, in compliance with the specifications of the Java Community Process, Sun made available most of their Java technologies as free software under the GNU General Public License. Others have also developed alternative implementations of these Sun technologies, such as the GNU Compiler for Java and GNU Classpath. The Java language was created by James Gosling in June 1991 for use in a set top box project. The language was initially called Oak, after an oak tree that stood outside Gosling's office - and also went by the name Green - and ended up later being renamed to Java, from a list of random words. Gosling's goals were to implement a virtual machine and a language that had a familiar C/C++ style of notation.Primary goalsThere were five primary goals in the creation of the Java language:It should use the object-oriented programming methodology.It should allow the same program to be executed on multiple operating systems.It should contain built-in support for using computer networks.It should be designed to execute code from remote sources securely.It should be easy to use by selecting what were considered the good parts of other object-oriented languages.The Java platform is the name for a bundle of related programs, or platform, from Sun which allow for developing and running programs written in the Java programming language. The platform is not specific to any one processor or operating system, but rather an execution engine (called a virtual machine) and a compiler with a set of standard libraries which are implemented for various hardware and operating systems so that Java programs can run identically on all of them.Different "editions" of the platform are available, including:Java ME (Micro Edition): Specifies several different sets of libraries (known as profiles) for devices which are sufficiently limited that supplying the full set of Java libraries would take up unacceptably large amounts of storage.Java SE (Standard Edition): For general purpose use on desktop PCs, servers and similar devices.Java EE (Enterprise Edition): Java SE plus various APIs useful for multi-tier client-server enterprise applications. The Java Platform consists of several programs, each of which provides a distinct portion of its overall capabilities. For example, the Java compiler, which converts Java source code into Java bytecode (an intermediate language for the Java Virtual Machine (JVM)), is provided as part of the Java Development Kit (JDK). The sophisticated Java Runtime Environment (JRE), complementing the JVM with a just-in-time (JIT) compiler, converts intermediate bytecode into native machine code on the fly. Also supplied are extensive libraries (pre-compiled into Java bytecode) containing reusable code, as well as numerous ways for Java applications to be deployed, including being embedded in a web page as an applet. There are several other components, some available only in certain editions.The essential components in the platform are the Java language compiler, the libraries, and the runtime environment in which Java intermediate bytecode "executes" according to the rules laid out in the virtual machine specification.Java Virtual Machine The heart of the Java Platform is the concept of a "virtual machine" that executes Java bytecode programs. This bytecode is the same no matter what hardware or operating system the program is running under. There is a JIT compiler within the Java Virtual Machine, or JVM. The JIT compiler translates the Java bytecode into native processor instructions at run-time and caches the native code in memory during execution. The use of bytecode as an intermediate language permits Java programs to run on any platform that has a virtual machine available. The use of a JIT compiler means that Java applications, after a short delay during loading and once they have "warmed up" by being all or mostly JIT-compiled, tend to run about as fast as native programs. Since JRE version 1.2, Sun's JVM implementation has included a just-in-time compiler instead of an interpreter. Although Java programs are Platform Independent, the code of the Java Virtual Machine (JVM) that execute these programs are not. Every Operating System has its own JVM.Class librariesIn most modern operating systems, a large body of reusable code is provided to simplify the programmer's job. This code is typically provided as a set of dynamically loadable libraries that applications can call at runtime. Because the Java Platform is not dependent on any specific operating system, applications cannot rely on any of the existing libraries. Instead, the Java Platform provides a comprehensive set of standard class libraries, containing much of the same reusable functions commonly found in modern operating systems. The Java class libraries serve three purposes within the Java Platform. Like other standard code libraries, they provide the programmer a well-known set of functions to perform common tasks, such as maintaining lists of items or performing complex string parsing. In addition, the class libraries provide an abstract interface to tasks that would normally depend heavily on the hardware and operating system. Tasks such as network access and file access are often heavily dependent on the native capabilities of the platform. The Java and java.io libraries implement the required native code internally, then provide a standard interface for the Java applications to perform those tasks. Finally, when some underlying platform does not support all of the features a Java application expects, the class libraries can either emulate those features using whatever is available, or at least provide a consistent way to check for the presence of a specific feature.Platform independenceOne characteristic, platform independence, means that programs written in the Java language must run similarly on any supported hardware/operating-system platform. One should be able to write a program once, compile it once, and run it anywhere.This is achieved by most Java compilers by compiling the Java language code halfway (to Java bytecode) – simplified machine instructions specific to the Java platform. The code is then run on a virtual machine (VM), a program written in native code on the host hardware that interprets and executes generic Java bytecode. (In some JVM versions, bytecode can also be compiled to native code, either before or during program execution, resulting in faster execution.) Further, standardized libraries are provided to allow access to features of the host machines (such as graphics, threading and networking) in unified ways. Note that, although there is an explicit compiling stage, at some point, the Java bytecode is interpreted or converted to native machine code by the JIT compiler.The first implementations of the language used an interpreted virtual machine to achieve portability. These implementations produced programs that ran more slowly than programs compiled to native executables, for instance written in C or C++, so the language suffered a reputation for poor performance. More recent JVM implementations produce programs that run significantly faster than before, using multiple techniques.One technique, known as just-in-time compilation (JIT), translates the Java bytecode into native code at the time that the program is run, which results in a program that executes faster than interpreted code but also incurs compilation overhead during execution. More sophisticated VMs use dynamic recompilation, in which the VM can analyze the behavior of the running program and selectively recompile and optimize critical parts of the program. Dynamic recompilation can achieve optimizations superior to static compilation because the dynamic compiler can base optimizations on knowledge about the runtime environment and the set of loaded classes, and can identify the hot spots (parts of the program, often inner loops, that take up the most execution time). JIT compilation and dynamic recompilation allow Java programs to take advantage of the speed of native code without losing portability.Another technique, commonly known as static compilation, is to compile directly into native code like a more traditional compiler. Static Java compilers, such as GCJ, translate the Java language code to native object code, removing the intermediate bytecode stage. This achieves good performance compared to interpretation, but at the expense of portability; the output of these compilers can only be run on a single architecture. Some see avoiding the VM in this manner as defeating the point of developing in Java; however it can be useful to provide both a generic bytecode version, as well as an optimised native code version of an application.Automatic memory managementOne of the ideas behind Java's automatic memory management model is that programmers be spared the burden of having to perform manual memory management. In some languages the programmer allocates memory for the creation of objects stored on the heap and the responsibility of later deal locating that memory also resides with the programmer. If the programmer forgets to deallocate memory or writes code that fails to do so, a memory leak occurs and the program can consume an arbitrarily large amount of memory. Additionally, if the program attempts to deallocate the region of memory more than once, the result is undefined and the program may become unstable and may crash. Finally, in non garbage collected environments, there is a certain degree of overhead and complexity of user-code to track and finalize allocations. Often developers may box themselves into certain designs to provide reasonable assurances that memory leaks will not occur.In Java, this potential problem is avoided by automatic garbage collection. The programmer determines when objects are created, and the Java runtime is responsible for managing the object's lifecycle. The program or other objects can reference an object by holding a reference to it (which, from a low-level point of view, is its address on the heap). When no references to an object remain, the Java garbage collector automatically deletes the unreachable object, freeing memory and preventing a memory leak. Memory leaks may still occur if a programmer's code holds a reference to an object that is no longer needed—in other words, they can still occur but at higher conceptual levels.The use of garbage collection in a language can also affect programming paradigms. If, for example, the developer assumes that the cost of memory allocation/recollection is low, they may choose to more freely construct objects instead of pre-initializing, holding and reusing them. With the small cost of potential performance penalties (inner-loop construction of large/complex objects), this facilitates thread-isolation (no need to synchronize as different threads work on different object instances) and data-hiding. The use of transient immutable value-objects minimizes side-effect paring Java and C++, it is possible in C++ to implement similar functionality (for example, a memory management model for specific classes can be designed in C++ to improve speed and lower memory fragmentation considerably), with the possible cost of adding comparable runtime overhead to that of Java's garbage collector, and of added development time and application complexity if one favors manual implementation over using an existing third-party library. In Java, garbage collection is built-in and virtually invisible to the developer. That is, developers may have no notion of when garbage collection will take place as it may not necessarily correlate with any actions being explicitly performed by the code they write. Depending on intended application, this can be beneficial or disadvantageous: the programmer is freed from performing low-level tasks, but at the same time loses the option of writing lower level code. Additionally, the garbage collection capability demands some attention to tuning the JVM, as large heaps will cause apparently random stalls in performance.Java does not support pointer arithmetic as is supported in, for example, C++. This is because the garbage collector may relocate referenced objects, invalidating such pointers. Another reason that Java forbids this is that type safety and security can no longer be guaranteed if arbitrary manipulation of pointers is allowed.Performance Java's performance has improved substantially since the early versions, and performance of JIT compilers relative to native compilers has in some tests been shown to be quite similar. The performance of the compilers does not necessarily indicate the performance of the compiled code; only careful testing can reveal the true performance issues in any system.Java Runtime EnvironmentThe Java Runtime Environment, or JRE, is the software required to run any application deployed on the Java Platform. End-users commonly use a JRE in software packages and Web browser plugins. Sun also distributes a superset of the JRE called the Java 2 SDK (more commonly known as the JDK), which includes development tools such as the Java compiler, Javadoc, Jar and debugger.One of the unique advantages of the concept of a runtime engine is that errors (exceptions) should not 'crash' the system. Moreover, in runtime engine environments such as Java there exist tools that attach to the runtime engine and every time that an exception of interest occurs they record debugging information that existed in memory at the time the exception was thrown (stack and heap values). These Automated Exception Handling tools provide 'root-cause' information for exceptions in Java programs that run in production, testing or development environments.?TECHNOLOGY SPECIFICATIONS Java Platform, Enterprise Edition (Java EE) builds on the solid foundation of Java Platform, Standard Edition (Java SE) and is the industry standard for implementing enterprise-class service-oriented architecture (SOA) and next-generation web applications. Java Platform, Enterprise Edition (Java EE) is a set of coordinated technologies that significantly reduces the cost and complexity of developing, deploying, and managing multitier, server-centric applications. Building on the Java Platform, Standard Edition (Java SE), Java EE adds the capabilities that provide a complete, stable, secure, and fast Java platform for the enterprise. Java 2 Enterprise Edition (J2EE) technology is becoming a pervasive platform for the development of Internet-based, transactional business applications. It provides a robust development platform upon which to build flexible, reusable components and applications. It is a powerful standard that is well-suited for Internet-based applications because it provides many of the underlying services such as HTTP request processing (Java Servlet API), transaction management (Enterprise JavaBeans), and messaging (Java Message Service), just to name a few. However, J2EE is also a complex and changing standard that leaves the technologist with many design decisions and performance considerations. Each component service adds a level of overhead to the application processing that must be considered. Additionally, there are a number of common business logic functions, such as error handling, that must be designed and de developed for each component and application. An application development effort using J2EE should give careful consideration to the services provided by the platform and how application components can best utilize them. There are a number of best practices one should consider in order to be highly effective in building J2EE components and integrating them into applications. These practices include evaluating and selecting the right set of software components and services to do the job. This is no different than in other professions; a carpenter or a steelworker both use an architecture plan to build things, although the tools they use to do so are quite different. A scalable, modular architecture built upon J2EE will likely comprise a selection of the appropriate set of J2EE services combined with a custom foundation of common business logic functions.OVERVIEW OF J2EEToday more and more developments want to write distributed transactional applications for the enterprise and leverage the speed, security and reliability of server side technology. J2EE is a platform independent, java centric environment from sun for developing, building and deploying web based enterprise application online. The J2EE platform consists of a set of services, API’s and protocols that provide functionality for developing multitiered web based application.At the client side tier, J2EE supports pure HTML as well as java applets or applications. It relies on JSP and Servlet codes to create HTML or other formatted data for the client. EJB provide another layer where the platform’s logic is stored. An EJB server provides functions such as threading, concurrency, security and memory management. To reduce costs and fast-track enterprise application design and development, the java2 platform, Enterprise edition (J2EE) technology provides a component-based approach to the design, development, assembly and distributed application model, the ability to reuse components, integrated Extensible Markup Language (XML) based data interchange, a unified security model, and flexible transaction control.DISTRIBUTED MULTI TIERED APPLICATIONS The J2EE platform uses a multi tiered distributed application model. Application logic is divided into components according to function, and the various application components that make up a J2EE application are installed on different machines depending on the tier in the multi tiered J2EE environment to which the application component belongs. The figure shown below shows two multi tiered j2EE applications divided into the tiers described in the following list. The J2EE application parts shown in FigureClient-tier components run on the client machine.Web-tier components run on the J2EE server.Business-tier components run on the J2EE server. Enterprise information system (EIS)-tier software runs the EIS server.DatabaseApplication ClientDynamic HTML PagesJSP PagesEnterprise BeansEnterprise BeansDatabaseJ2EE Application1J2EE Application2Client tierWeb TierBusiness TierEIS TierClientMachineJ2EEServerMachineDatabaseServerMachine J2EE COMPONENTS J2EE applications are made up of components. A J2EE component is a self-contained functional software unit that is assembled into a J2EE application with its related classes and files and that following J2EE components: Application clients and applets are components that run on the client.Java Servlet and Java Server Pages (JSP) technology components are Web components that run on the server.Enterprise Java Beans (EJB) components are business components that run on the server.J2EE components are written in the java programming language and are compiled in the same way as any program in the language. The difference between J2EE components and standard java classes is that J2EE components are assembled into a J2EE application. Verified to be well formed and in compliance with managed by the J2EE server.J2EE CONTAINERS Normally, thin-client multi tiered applications are hard to write because they involve many lines of intricate code to handle transaction and state management, multithreading, resource pooling, and other complex low-level details. The component-based and platform-independent J2EE architecture makes J2EE applications easy to write because business logic is organized into reusable components. In addition, the J2EE server provides underlying services in the form of a container for every component type. Because you do not have to develop these services yourself, you are free to concentrate on solving the business problem at hand.Containers provide the runtime support for J2EE application components.Containers provide a federated view of the underlying J2EE APIs to the application components. J2EE application components never interact directly with other J2EE application components. They use the protocols and methods of the container for interacting with each other and with platform services. Interposing a container between the application components and the J2EE services allows the container to transparently inject the services defined by the components deployment descriptors, such as declarative transaction management, security checks, resource pooling, and state management. A typical J2EE product will provide a container for each application component type: application client container, applet container, web component container, and enterprise bean container.Figure: J2EE Server and ContainersBrowserApplication ClientApplication client containerJ2EE ServerServletJSP PageWeb ContainerEnterprise BeanEJB ContainerEnterprise BeanDatabaseClient MachineJ2EE SERVER It is a runtime portion of a J2EE product. A J2EE server provides EJB and Web containers. The component-based and platform-independent J2EE architecture makes J2EE applications easy to write because business logic is organized into reusable components and the J2EE server provides underlying services in the form of a container for every component type.CONTAINERS AND SERVICES Components are installed in their containers during deployment and are the interface between a component and the low-level platform-specific functionality that supports the component. Before a web, enterprise bean, or application client component can be executed, it must be assembled onto a J2EE application and deployed into its container. The assembly process involves specifying container settings for each component in the J2EE application and for the J2EE application itself. Container settings customize the underlying support provided by the J2EE Server, which include services such as security, transaction management, Java Naming and Directory Interface (JNDI) lookups, and remote connectivity. Here are some of the highlights:The J2EE security model lets you configure a web component or enterprise bean so system resources are accessed only by authorized users.The J2EE transaction model lets you specify relationships among methods that make up a single transaction so all methods in one transaction are treated as a single unit.JNDI lookup services provide a unified interface to multiple naming and directory services in the enterprise so application components can access naming and directory services.The J2EE remote connectivity model manages low-level communications between clients and enterprise beans. After an enterprise bean is created, a client invokes methods on it as if it were in the same virtual machine. J2EE PLATFORM ROLES The J2EE platform also defines a number of distinct roles that are performed during the application development and deployment life cycle: The product provider designs and offers the J2EE platform, APIs, and other features that are defined in the J2EE specification for purchase. The tool provider offers tools that are used for the development and packaging of application components as part of the J2EE specifications. The application component provider creates Web components, enterprise beans, applets, or application clients to use in J2EE applications. The application assembler takes a set of components that are developed by component providers and assembles them in the form of an enterprise archive (EAR) file. The deployer is responsible for deploying an enterprise application into a specific operational environment that corresponds to a J2EE platform product. The system administrator is responsible for the operational environment in which the application runs. Product providers and tool providers have a product focus. Application component providers and application assemblers focus on the application. Deployers and system administrators focus on providing the J2EE application with platform-specific artifacts, and on the platform run time. These roles help identify the tasks and people involved. Understanding this separation of roles is important because it helps to determine the approach when developing and deploying J2EE applications.J2EE BENEFITS The J2EE specification provides customers a standard which can be used to ensure investment protection when purchasing or developing applications. Comprehensive, independent Compatibility Test Suites ensure vendor compliance with J2EEDigital image processing focuses on two major tasks:Improvement of pictorial information for human interpretation.Processing of image data for storage, transmission and representation for autonomous machine perception Application Areas of Image ProcessingTelevisionSignal ProcessingSatellite Image ProcessingMedical Image ProcessingRobot ControlVisual CommunicationsLawEnforcementCONCLUSION:Digital image processing has become a vast domain of modern signal technologies. Its applications pass far beyond simple aesthetical considerations, and they include medical imagery, television and multimedia signals, security, portable digital devices, video compression, and even digital movies. We have been flying over some elementary notions in image processing but there is yet a lot more to explore. Pattern recognition is the research area that studies the operation and design of systems that recognize patterns in data. It encloses subdisciplines like discriminant analysis, feature extraction, error estimation, cluster analysis, grammatical inference and parsing. Important application areas are image analysis, character recognition, speech analysis, man and machine diagnostics, person identification and industrial inspection.References:Digital Image Processing 2nd Edition Rafael C. Gonzalez Richard E. Woods .Duda, Heart: Pattern Classification and Scene Analysis. J. Wiley & Sons, New York, 1982. (2nd edition 2000). ................
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