Microelectronic Circuit Design: A Comprehensive Guide for Students and Professionals
Microelectronic Circuit Design is a textbook by Richard C. Jaeger and Travis N. Blalock that covers the fundamentals and applications of analog and digital circuits. The book is divided into four parts: Part I introduces the basic concepts of electronic devices and circuits; Part II focuses on analog circuit design, including amplifiers, filters, oscillators, and power supplies; Part III covers digital circuit design, such as logic gates, flip-flops, counters, registers, and memory; and Part IV explores integrated circuit design, fabrication, and testing.
The book is designed for undergraduate and graduate students who want to learn the principles and techniques of modern electronic circuit design. It is also suitable for professionals who need to refresh or update their knowledge of microelectronics. The book features numerous examples, exercises, problems, and case studies that illustrate the practical aspects of circuit design. The book also provides online resources, such as simulation tools, lecture slides, and solutions manual.
Microelectronic Circuit Design is a comprehensive and accessible guide that helps students and professionals master the art and science of microelectronics. It is one of the most popular and widely used textbooks in the field of microelectronic circuit design[^2^].Some of the topics covered in Microelectronic Circuit Design are:
Electronic devices and models: This topic introduces the basic concepts and characteristics of semiconductor devices, such as diodes, transistors, and integrated circuits. It also explains how to model these devices using equivalent circuits and mathematical equations.
Single-stage and multistage amplifiers: This topic covers the design and analysis of various types of amplifiers, such as common-emitter, common-base, common-collector, differential, operational, and feedback amplifiers. It also discusses the performance parameters and limitations of amplifiers, such as gain, bandwidth, noise, distortion, and stability.
Analog filters and signal processing: This topic covers the design and analysis of various types of analog filters, such as low-pass, high-pass, band-pass, band-stop, and all-pass filters. It also discusses the applications of analog filters in signal processing, such as modulation, demodulation, sampling, reconstruction, and frequency conversion.
Oscillators and waveform generators: This topic covers the design and analysis of various types of oscillators and waveform generators, such as sinusoidal, relaxation, multivibrator, sawtooth, triangle, square, and pulse generators. It also discusses the principles and techniques of frequency stabilization and synchronization.
Power supplies and regulators: This topic covers the design and analysis of various types of power supplies and regulators, such as rectifiers, filters, voltage multipliers, linear regulators, switching regulators, and battery chargers. It also discusses the issues and challenges of power supply design, such as efficiency, ripple, load regulation, line regulation, protection circuits.
Logic gates and Boolean algebra: This topic introduces the basic concepts and operations of Boolean algebra and logic gates. It also explains how to simplify and optimize logic expressions using Karnaugh maps and Quine-McCluskey method.
Combinational logic circuits: This topic covers the design and analysis of various types of combinational logic circuits, such as adders, subtractors, comparators, multiplexers, demultiplexers, encoders, decoders. It also discusses the performance parameters and limitations of combinational logic circuits such as propagation delay,