Lectures related to Ambipolar Devices: Logic Circuit Design Paradigms

Logic Design: Basic Rules and Shannon's Expansion

Covers basic rules of logic design and Shannon's expansion in Boolean functions.

Covers the basic principles and architecture of Field Programmable Gate Arrays (FPGAs) and their implementation options for digital circuits.

Logic Gates and Hazard Elimination

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

Digital Systems: Finite State Machines Overview

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

Timing Analysis: Synchronous Circuit Design

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

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.

Logic Synthesis: Designing Efficient Digital Circuits

Discusses logic synthesis techniques for designing efficient digital circuits from functional descriptions and truth tables.

Full Adder: Binary Addition Logic

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

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.

Synchronous Digital Circuits: Principles and Design

Covers principles of synchronous RTL design, custom digital circuits, Y-Diagram visualization, signal classes, and hierarchy management.

Programmable Logic Devices: PAL, GAL, CPLD

Covers PAL, GAL, CPLD, and the transition to FPGAs using HDLs.

Programmable Logic Circuits, FPGA

Explores logic circuit classification, FPGA design methodology, implementation, and Altera Cyclone IV architecture.

Digital Logic Circuits: Memory Fundamentals

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

Digital Circuits: Logic Basics

Introduces digital circuits, covering binary systems, logic operators, Boolean algebra, memory elements, and practical examples like BCD decoders and shift registers.

Multiplexers: Design and Functionality

Covers the design and operation of 2-to-1 and 1-to-2 multiplexers, including transistor count and truth table analysis.

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.

VLSI Basics: Design and Technology

Covers VLSI design basics, including scaling, technology, MOSFET operation, and logic circuit implementation.

Programmable Logic Devices: PAL, GAL, CPLD

Covers PAL, GAL, CPLD, and the evolution to FPGAs, explaining their architecture and advantages.

Finite State Machines: Design and Analysis Techniques

Provides an overview of finite state machines, covering their design, analysis, and practical applications in digital systems.

Digital Design: Lowerbounds and Recommendations

Covers abstraction levels, EPFL design flow, lowerbounds, and layout recommendations.