Lectures related to Finite State Machines: Design and Analysis Techniques

Digital Systems: Finite State Machines Overview

Covers finite state machines, their types, structures, and practical applications in digital systems.

Logic Systems: Sequential and Combinatorial Circuits

Covers fundamental concepts of logic systems, including sequential and combinatorial circuits, state diagrams, and finite state machines.

Finite State Machines: Basics and Design

Introduces finite state machines, covering basics, design, and practical applications like decoders and encoders.

Finite State Machines: Medvedev vs. Moore vs. Mealy

Compares Medvedev, Moore, and Mealy FSM models and their structures.

Digital Systems: Flip-Flops, Registers, and Counters

Provides an overview of flip-flops, registers, and counters in digital systems.

Logic Systems: Finite State Machines

Explores Boolean algebra, optimization, sequential systems, and finite state machines design.

Synchronous Logic Circuits: Modeling and Optimization

Explores synchronous logic circuits, state-based modeling, optimization techniques, and finite-state machine state minimization.

Digital Logic Circuits: Memory Elements and Sequential Logic

Introduces sequential logic circuits and memory elements, focusing on their role in digital systems and practical applications.

Synchronous Logic Circuits: Modeling and Optimization

Explores synchronous logic circuits, modeling techniques, state minimization, and finite-state machine optimization for area reduction.

Arbiter FSM & FPGA Implementation

Covers the design of an Arbiter FSM in VHDL for digital system design, emphasizing access timing management.

Fundamentals of Digital Systems: Sequential Logic and Memory Elements

Introduces the fundamentals of digital systems, focusing on sequential logic and memory elements like latches and flip-flops.

Digital Logic Circuits: Memory and Decoder Fundamentals

Provides an overview of digital logic circuits, focusing on memory systems and binary decoders, including their operation and access protocols.

Timing Analysis: Synchronous Circuit Design

Covers timing analysis of synchronous circuits, focusing on flip-flops, timing constraints, and metastability issues.

Full Adder: Binary Addition Logic

Explains the full adder's role in binary addition and its design using transistors.

Sequential Logic Designs

Introduces clocked systems, sequential circuits, bistable-state devices, metastable states, and D-type flip-flops.

Digital Logic Circuits: Memory Fundamentals

Discusses digital logic circuits, focusing on memory systems and their implementation in Verilog.

Logic Gates and Hazard Elimination

Explores logic gates, hazard elimination, ALUs, counters, and shift registers in semiconductor technology.

Digital Systems: Registers and Counters Overview

Provides an overview of registers and counters in digital systems design.

Logic Systems: Technology Overview

Provides an overview of the technology behind logic gates, covering TTL and CMOS families and addressing static and dynamic hazards, gated clocks, and switch debouncing.

Logic Systems: Multiplexers and Flip-Flops

Explains SR latch circuits, D-latches, D-flip-flops, clock signals, and multiplexers in logic systems.