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16: Principles Of Digital Computing

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  • Page ID
    1019

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    • 16.1: A Binary Adder
      This page explains the half-adder, a circuit that adds two binary bits, detailing its design and outputs—sum and carry. It highlights the fixed nature of such circuits for specific functions while noting that other operations need separate circuits. In contrast, programmable computers offer flexibility by using digital data to define operations. The page also covers look-up table memories and finite-state machines as part of this discussion on digital versus analog circuits.
    • 16.2: Look-up Tables
      This page covers the versatile use of Read-Only Memory (ROM) in digital memory, allowing for logical functions through programmed look-up tables, in contrast to traditional hardware-based logic circuits. It highlights ROM's benefits of modifiability and reusability, particularly in creating complex functions for applications like ALUs and control systems.
    • 16.3: Finite-state Machine
      This page discusses the role of feedback in engineering, emphasizing its ability to enhance system complexity and functionality. It describes the integration of feedback in circuits for devising advanced devices, such as controllable-gain amplifiers, and the use of negative feedback in closed-loop control systems.
    • 16.4: Microprocessors
      This page explores the evolution of computing, highlighting the contributions of pioneers like Turing and Von Neumann, and the shift to modern stored-program architecture. It details the advancement from older control systems to advanced Closed-loop Numerical Control (CNC) systems. Key CPU components such as read/write memory, ALUs, and control units are introduced, culminating in the fetch/execute cycle.
    • 16.5: Microprocessor Programming
      This page covers the unique vocabulary of microprocessors that complicates low-level programming. It explains machine and assembly languages, noting the ease of mnemonics over binary codes. Programs need to be loaded into memory for execution, either in ROM or RAM. The page also discusses high-level programming languages and their translation methods, including interpretation and compilation.

    This page titled 16: Principles Of Digital Computing is shared under a GNU Free Documentation License 1.3 license and was authored, remixed, and/or curated by Tony R. Kuphaldt (All About Circuits) via source content that was edited to the style and standards of the LibreTexts platform.