Short, concise, and easily-accessible, this book uses the 8085A microprocessor and 8051 microcontroller to explain the fundamentals of microprocessor architecture, programming, and hardware. It features only practical, workable designs so that readers can develop a complete understanding of the application with no frustrating gaps in the explanations. An abundance of real-life hardware, software, and schematic interpretation problems prepare readers to troubleshoot and trace signals through situations they will likely encounter on the job.
Since its commercialization in 1971, the microprocessor, a modern and integrated form of the central processing unit, has continuously broken records in terms of its integrated functions, computing power, low costs and energy saving status. Today, it is present in almost all electronic devices. Sound knowledge of its internal mechanisms and programming is essential for electronics and computer engineers to understand and master computer operations and advanced programming concepts. This book in five volumes focuses more particularly on the first two generations of microprocessors, those that handle 4- and 8- bit integers. Microprocessor 4 – the fourth of five volumes – addresses the software aspects of this component. Coding of an instruction, addressing modes and the main features of the Instruction Set Architecture (ISA) of a generic component are presented. Futhermore, two approaches are discussed for altering the flow of execution using mechanisms of subprogram and interrupt. A comprehensive approach is used, with examples drawn from current and past technologies that illustrate theoretical concepts, making them accessible.
Embedded microprocessor systems are affecting our daily lives at a fast pace, mostly unrecognised by the general public. Most of us are aware of the part they are playing in increasing business efficiency through office applications such as personal computers, printers and copiers. Only a few people, however, fully appreciate the growing role of embedded systems in telecommunications and industrial environments, or even in everyday products like cars and home appliances. The challenge to engineers and managers is not only highlighted by the sheer size of the market, ' 1.5 billion microcontrollers and microprocessors are produced every year ' but also by the accelerating innovation in embedded systems towards higher complexity in hardware, software and tools as well as towards higher performance and lower consumption. To maintain competitiveness in this demanding environment, an optimum mix of innovation, time to market and system cost is required. Choosing the right options and strategies for products and companies is crucial and rarely obvious. In this book the editors have, therefore, skilfully brought together more than fifty contributions from some of the leading authorities in embedded systems. The papers are conveniently grouped in four sections.
Microprocessor Architectures and Systems: RISC, CISC, and DSP focuses on the developments of Motorola's CISC, RISC, and DSP processors and the advancements of the design, functions, and architecture of microprocessors. The publication first ponders on complex instruction set computers and 32-bit CISC processors. Discussions focus on MC68881 and MC68882 floating point coprocessors, debugging support, MC68020 32-bit performance standard, bus interfaces, MC68010 SUPERVISOR resource, and high-level language support. The manuscript then covers the RISC challenge, digital signal processing, and memory management and caches. Topics include implementing memory systems, multitasking and user/supervisor conflicts, partitioning the system, cache size and organization, DSP56000 family, MC88100 programming model, M88000 family, and the 80/20 rule. The text examines the selection of a microprocessor architecture, changing design cycle, semiconductor technology, multiprocessing, and real-time software, interrupts, and exceptions. Concerns include locating associated tasks, MC88100 interrupt service routines, single- and multiple-threaded operating systems, and the MC68300 family. The publication is a valuable reference for computer engineers and researchers interested in microprocessor architectures and systems.
Here's an entire learning solution in one book, complete with detailed coverage, questions, problems, and lab experiments! Microprocessor Architecture, Programming, and Systems Featuring the 8085 details the 8085 processor, from both a hardware and software standpoint. Readers will learn pseudo-code and flowcharting as tools in programming a microprocessor, with current, focused coverage that is perfectly written for the two-year college student. Comprehensive exposure to microprocessor architecture includes an entire chapter devoted to both the hardware and software of the 8051 Microcontroller not found in other books. Coverage also includes a uniquely thorough comparison of the 8085 microprocessor with other Motorola and Intel microprocessors.
A clear, detailed study of the microcomputer environment within a microprocessor system. The first book to provide an in-depth study of three fundamental topics: interfacing, programming in assembler, and the use of a development system. Material is illustrated with examples relating to the INTEL 8080A or 8085A microprocessors, and the MOTOROLA 6800 or 6802 microprocessors.
The Definitive Guide to the ARM® Cortex®-M0 and Cortex-M0+ Processors, Second Edition explains the architectures underneath ARM’s Cortex-M0 and Cortex-M0+ processors and their programming techniques. Written by ARM’s Senior Embedded Technology Manager, Joseph Yiu, the book is packed with examples on how to use the features in the Cortex-M0 and Cortex-M0+ processors. It provides detailed information on the instruction set architecture, how to use a number of popular development suites, an overview of the software development flow, and information on how to locate problems in the program code and software porting. This new edition includes the differences between the Cortex-M0 and Cortex-M0+ processors such as architectural features (e.g. unprivileged execution level, vector table relocation), new chapters on low power designs and the Memory Protection Unit (MPU), the benefits of the Cortex-M0+ processor, such as the new single cycle I/O interface, higher energy efficiency, better performance and the Micro Trace Buffer (MTB) feature, updated software development tools, updated Real Time Operating System examples using KeilTM RTX with CMSIS-RTOS APIs, examples of using various Cortex-M0 and Cortex-M0+ based microcontrollers, and much more. Provides detailed information on ARM® Cortex®-M0 and Cortex-M0+ Processors, including their architectures, programming model, instruction set, and interrupt handling Presents detailed information on the differences between the Cortex-M0 and Cortex-M0+ processors Covers software development flow, including examples for various development tools in both C and assembly languages Includes in-depth coverage of design approaches and considerations for developing ultra low power embedded systems, the benchmark for energy efficiency in microcontrollers, and examples of utilizing low power features in microcontrollers
