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11: Sequential Circuits

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    969

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    • 11.1: Binary Count Sequence
      This page explains the behavior of a four-bit binary count sequence, detailing how each bit toggles at different frequencies, with the least significant bit toggling at every step and the most significant bit toggling only once. It also covers the design of digital counting circuits using J-K flip-flops, which respond to clock pulses to change states. The content establishes a basis for understanding various counter circuits based on these binary counting and frequency division principles.
    • 11.2: Asynchronous Counters
      This page covers the design and functionality of binary counters using J-K flip-flops, emphasizing both forward and backward counting. It addresses problems with ripple effects in asynchronous counters, explaining how delays can lead to incorrect counts. Solutions include enhanced counter circuits that improve speed and eliminate the need for strobing, allowing for smoother toggling and accurate count outputs.
    • 11.3: Synchronous Counters
      This page discusses synchronous counters that change output bits simultaneously without ripple effects by connecting clock inputs together. It explains the necessity of controlling J and K inputs to retain binary counting while toggling bits. The distinction between "up" and "down" counters is highlighted, as well as a selectable counter that incorporates both modes.
    • 11.4: Counter Modulus
    • 11.5: Finite State Machines
      This page covers the principles of sequential circuits, which use memory to handle current and past inputs. It details the design of a digital quiz game's circuit, including state diagrams, state tables, and the use of D or JK Flip Flops for implementation. It also explains utilizing Karnaugh Maps for output function determination and emphasizes the correct placement of Flip Flops and the clock connection.

    This page titled 11: Sequential Circuits 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.