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Microprocessor System Design: A Practical Introduction describes the concepts and techniques incorporated into the design of electronic circuits, particularly microprocessor boards and their peripherals. The book reviews the basic building blocks of the electronic systems composed of digital (logic levels, gate output circuitry) and analog components (resistors, capacitors, diodes, transistors). The text also describes operational amplifiers (op-amp) that use a negative feedback technique to improve the parameters of the op-amp. The design engineer can use programmable array logic (PAL) to replace standard discrete TTL and CMOS gates in circuits. The PAL is programmable and configurable to match the requirement of a given circuit. Using PAL can save space, a very important factor in the miniaturization process. Examples of PAL applications include the BCD counter, the LS 138 emulator, and a priority interrupt encoder. The book also explains the operation and function of a microprocessor, the bus-based systems, analog-to-digital conversion, and vice-versa. The text is suitable for programmers, computer engineers, computer technicians, and computer instructors dealing with many aspects of computers such as programming, networking, engineering or design.
This textbook for courses in Embedded Systems introduces students to necessary concepts, through a hands-on approach. It gives a great introduction to FPGA-based microprocessor system design using state-of-the-art boards, tools, and microprocessors from Altera/Intel® and Xilinx®. HDL-based designs (soft-core), parameterized cores (Nios II and MicroBlaze), and ARM Cortex-A9 design are discussed, compared and explored using many hand-on designs projects. Custom IP for HDMI coder, Floating-point operations, and FFT bit-swap are developed, implemented, tested and speed-up is measured. Downloadable files include all design examples such as basic processor synthesizable code for Xilinx and Altera tools for PicoBlaze, MicroBlaze, Nios II and ARMv7 architectures in VHDL and Verilog code, as well as the custom IP projects. Each Chapter has a substantial number of short quiz questions, exercises, and challenging projects. Explains soft, parameterized, and hard core systems design tradeoffs; Demonstrates design of popular KCPSM6 8 Bit microprocessor step-by-step; Discusses the 32 Bit ARM Cortex-A9 and a basic processor is synthesized; Covers design flows for both FPGA Market leaders Nios II Altera/Intel and MicroBlaze Xilinx system; Describes Compiler-Compiler Tool development; Includes a substantial number of Homework’s and FPGA exercises and design projects in each chapter.
This book is intended for a first course on microprocessor-based systems design for engineering and computer science students. It starts with an introduction of the fundamental concepts, followed by a practical path that guides readers to developing a basic microprocessor example, using a step-by-step problem-solving approach. Then, a second microprocessor is presented, and readers are guided to the implementation and programming of microcomputer systems based on it. The numerous worked examples and solved exercises allow a better understanding and a more effective learning. All the examples and exercises were developed on Deeds (Digital Electronics Education and Design Suite), which is freely available online on a website developed and maintained by the authors. The discussed examples can be simulated by using Deeds and the solutions to all exercises and examples can be found on that website. Further, in the last part of this book, different microprocessor-based systems, which have been specifically thought for educational purposes, are extensively developed, simulated and implemented on FPGA-based platforms. This textbook draws on the authors’ extensive experience in teaching and developing learning materials for bachelor’s and master’s engineering courses. It can be used for self-study as well, and even independently from the simulator. Thanks to the learning-by-doing approach and the plentiful examples, no prior knowledge in computer programming is required.
The less-experienced engineer will be able to apply Ball's advice to everyday projects and challenges immediately with amazing results. In this new edition, the author has expanded the section on debug to include avoiding common hardware, software and interrupt problems. Other new features include an expanded section on system integration and debug to address the capabilities of more recent emulators and debuggers, a section about combination microcontroller/PLD devices, and expanded information on industry standard embedded platforms. Covers all 'species' of embedded system chips rather than specific hardware Learn how to cope with 'real world' problems Design embedded systems products that are reliable and work in real applications
Provides an introduction to microprocessor systems, their operation and design. The text covers topics needed by engineers and computer scientists who are interested in applying microprocessors in practical situations, such as computer hardware, software, and the design and testing of systems.
Microprocessors and Microcomputer-Based System Design, Second Edition, builds on the concepts of the first edition. It discusses the basics of microprocessors, various 32-bit microprocessors, the 8085 microprocessor, the fundamentals of peripheral interfacing, and Intel and Motorola microprocessors. This edition includes new topics such as floating-point arithmetic, Program Array Logic, and flash memories. It covers the popular Intel 80486/80960 and Motorola 68040 as well as the Pentium and PowerPC microprocessors. The final chapter presents system design concepts, applying the design principles covered in previous chapters to sample problems.
Appropriate for undergraduate and beginning graduate level courses on embedded systems or microprocessor based systems design in computer engineering, electrical engineering, and computer science. The basic structure, operation, and design of embedded systems is presented in a stepwise fashion. A balanced treatment of both hardware and software is provided. The Intel 80C188EB microprocessor is used as the instructional example. Hardware is covered starting from the component level. Software development focuses on assembly language. The only background required is an introductory course in digital systems design.
"This book … uniquely synthesizes Professor Milutinovi???’s thinking on the important issues in computer architecture … The result is a necessarily somewhat eclectic, personal statement by one of the leaders of the field." —Michael J. Flynn, Stanford University From the Foreword "How do we invest one billion transistors on a single chip?" asks Veljko Milutinovi??? as he ponders the ultimate goal of an entire distributed shared memory (DSM)—plus numerous specialized accelerators—on a single chip. He then goes on to present a lively personal account, complete with survival tips, of his experiences in the front line of the rapidly evolving arena of microprocessor and multimicroprocessor system design. Focusing on areas critical to the future of system-on-a-chip design, Milutinovi??? combines his unique perspective with authoritative discussions of cache, instruction level parallelism, prediction strategies, the I/O bottleneck, multithreading, and multiprocessors. He reinforces concepts using three case studies of his own computer system/accelerator implementations with additional details available through Web-based appendices. A key DSM concept, Reflective Memory System (RMS), and tools for evaluating new architectural ideas or characterizing applications are also covered in appendices. Designed for fast, easy comprehension, Surviving the Design of Microprocessor and Multimicroprocessor Systems integrates clear, up-to-date explanations with a wealth of figures and a thorough review of the technical literature. It brings readers up to speed with concepts essential for implementing their own ideas, while addressing the most important issues facing scientists and engineers in advanced computer design.
System Design; Digital to Analog Converters; Sensors; Time-Based Measurements; Output Control Methods; Solenoids, Relays, and Other Analog Outputs; Motors; EMI; High Precision Applications; Standard Interfaces.