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Thea Smartt Henry / Digital Design and Computer Architecture (ARM Edition)

Digital Design and Computer Architecture (ARM Edition)

$ 80.31

DescriptionDigital Design and Computer Architecture: ARM Edition covers the fundamentals of digital logic design and reinforces logic concepts through the design of an ARM microprocessor. Combining an engaging and humorous writing style with an updated and hands-on approach to digital design, this book takes the reader from the fundamentals of digital logic to the actual design of an ARM processor. By the end of this book, readers will be able to build their own microprocessor and will have a top-to-bottom understanding of how it works. Beginning with digital logic gates and progressing to the design of combinational and sequential circuits, this book uses these fundamental building blocks as the basis for designing an ARM processor. SystemVerilog and VHDL are integrated throughout the text in examples illustrating the methods and techniques for CAD-based circuit design. The companion website includes a chapter on I/O systems with practical examples that show how to use the Raspberry Pi computer to communicate with peripheral devices such as LCDs, Bluetooth radios, and motors. This book will be a valuable resource for students taking a course that combines digital logic and computer architecture or students taking a two-quarter sequence in digital logic and computer organization/architecture.Key FeaturesCovers the fundamentals of digital logic design and reinforces logic concepts through the design of an ARM microprocessor.Features side-by-side examples of the two most prominent Hardware Description Languages (HDLs)—SystemVerilog and VHDL—which illustrate and compare the ways each can be used in the design of digital systems.Includes examples throughout the text that enhance the reader’s understanding and retention of key concepts and techniques.The Companion website includes a chapter on I/O systems with practical examples that show how to use the Raspberry Pi computer to communicate with peripheral devices such as LCDs, Bluetooth radios, and motors.The Companion website also includes appendices covering practical digital design issues and C programming as well as links to CAD tools, lecture slides, laboratory projects, and solutions to exercises.ReadershipStudents taking a course that combines digital logic and computer architecture or students taking a two-quarter sequence in digital logic and computer organization/architectureTable of ContentsPrefaceFeaturesOnline SupplementsHow to Use the Software Tools in a CourseLabsBugsAcknowledgmentsFrom Zero to OneThe Game PlanThe Art of Managing ComplexityThe Digital AbstractionNumber SystemsLogic GatesBeneath the Digital AbstractionCMOS Transistors*Power Consumption*Summary and a Look AheadExercisesInterview QuestionsCombinational Logic DesignIntroductionBoolean EquationsBoolean AlgebraFrom Logic to GatesMultilevel Combinational LogicX’s and Z’s, Oh MyKarnaugh MapsCombinational Building BlocksTimingSummaryExercisesInterview QuestionsSequential Logic DesignIntroductionLatches and Flip-FlopsSynchronous Logic DesignFinite State MachinesTiming of Sequential LogicParallelismSummaryExercisesInterview QuestionsHardware Description LanguagesIntroductionCombinational LogicStructural ModelingSequential LogicMore Combinational LogicFinite State MachinesData Types*Parameterized Modules*Test benchesSummaryExercisesSystem Verilog ExercisesVHDL ExercisesInterview QuestionsDigital Building BlocksIntroductionArithmetic CircuitsNumber SystemsSequential Building BlocksMemory ArraysLogic ArraysSummaryExercisesInterview QuestionsArchitectureIntroductionAssembly LanguageProgrammingMachine LanguageLights, Camera, Action: Compiling, Assembling, and Loading*Odds and Ends*Evolution of ARM ArchitectureAnother Perspective: x86 ArchitectureSummaryExercisesInterview QuestionsMicroarchitectureIntroductionPerformance AnalysisSingle-Cycle ProcessorMulticycle ProcessorPipelined ProcessorHDL Representation*Advanced Microarchitecture*Real-World Perspective: Evolution of ARM Microarchitecture*SummaryExercisesInterview QuestionsMemory SystemsIntroductionMemory System Performance AnalysisCachesVirtual MemorySummaryEpilogueExercisesInterview QuestionsI/O SystemsIntroductionI/O SystemsMemory-Mapped I/OEmbedded I/O SystemsOther Microcontroller PeripheralsBus InterfacesPC I/O SystemsSummaryA. Digital System ImplementationA.1 IntroductionA.2 74xx LogicA.3 Programmable LogicA.4 Application-Specific Integrated CircuitsA.5 Data SheetsA.6 Logic FamiliesA.7 Packaging and AssemblyA.8 Transmission LinesA.9 EconomicsB. ARM InstructionsB.1 Data-processing InstructionsB.2 Memory InstructionsB.3 Branch InstructionsB.4 Miscellaneous InstructionsB.5 Condition FlagsC. C ProgrammingC.1 IntroductionSummaryC.2 Welcome to CSummaryC.3 CompilationSummaryC.4 VariablesSummaryC.5 OperatorsC.6 Function CallsC.7 Control-Flow StatementsSummaryC.8 More Data TypesSummaryC.9 Standard LibrariesC.10 Compiler and Command Line OptionsC.11 Common Mistakes Authors BiographySarah L. Harris is an Assistant Professor of Engineering at Harvey Mudd College. She received her Ph.D. and M.S. in Electrical Engineering from Stanford University. Before attending Stanford, she received a B.S. in Electrical and Computer Engineering from Brigham Young University. Sarah has also worked with Hewlett-Packard, the San Diego Supercomputer Center, Nvidia, and Microsoft Research in Beijing. Sarah loves teaching, exploring and developing new technologies, traveling, wind surfing, rock climbing, and playing the guitar. Her recent exploits include researching sketching interfaces for digital circuit design, acting as a science correspondent for a National Public Radio affiliate, and learning how to kite surf. She speaks four languages and looks forward to learning more in the near future.Affiliations and Expertise Assistant Professor of Engineering, Harvey Mudd College, Claremont, CA, USADavid Harris is the Harvey S. Mudd Professor of Engineering Design at Harvey Mudd College. He received his Ph.D. in electrical engineering from Stanford University and his M.Eng. in electrical engineering and computer science from MIT. Before attending Stanford, he worked at Intel as a logic and circuit designer on the Itanium and Pentium II processors. Since then, he has consulted at Sun Microsystems, Hewlett-Packard, Broadcom, and other design companies. David holds more than a dozen patents and is the author of three other textbooks on chip design, as well as many Southern California hiking guidebooks. When he is not working, he enjoys hiking, flying, and making things with his three sons.Affiliations and Expertise Associate Professor of Engineering, Harvey Mudd College, Claremont, CA, USA

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