Feedback, Nonlinear, and Distributed Circuits (3rd Ed.) The Circuits and Filters Handbook, 3rd Edition Series
Coordonnateur : Chen Wai-Kai
Upon its initial publication, the Handbook of Circuits and Filters broke new ground. It quickly became the resource for comprehensive coverage of issues and practical information that can be put to immediate use. Not content to rest on his laurels, editor Wai-kai Chen divided the second edition into volumes, making the information easily accessible and digestible. In the third edition, these volumes have been revised, updated, and expanded so that they continue to provide solid coverage of standard practices and enlightened perspectives on new and emerging techniques.
Feedback, Nonlinear, and Distributed Circuits draws together international contributors who discuss feedback amplifier theory and then move on to explore feedback amplifier configurations. They develop Bode?s feedback theory as an example of general feedback theory. The coverage then moves on to the importance of complementing numerical analysis with qualitative analysis to get a global picture of a circuit?s performance. After reviewing a wide range of approximation techniques and circuit design styles for discreet and monolithic circuits, the book presents a comprehensive description of the use of piecewise-linear methods in modeling, analysis, and structural properties of nonlinear circuits highlighting the advantages. It describes the circuit modeling in the frequency domain of uniform MTL based on the Telegrapher?s equations and covers frequency and time domain experimental characterization techniques for uniform and nonuniform multiconductor structures.
This volume will undoubtedly take its place as the engineer's first choice in looking for solutions to problems encountered in the analysis and behavior predictions of circuits and filters.
Feedback Circuits. Feedback Amplifier Theory. Feedback Amplifier Configurations. General Feedback Theory. Network Functions and Feedback. Measurement of Return Difference. Multiple-Loop Feedback Amplifiers. Nonlinear Circuits. Qualitative Analysis. Synthesis and Design of Nonlinear Circuits. Representation, Approximation, and Identification. Transformation and Equivalence. Piecewise-Linear Circuits and Piecewise-Linear Analysis. Simulation. Cellular Neural Networks and Cellular Wave Computers. Bifurcation and Chaos. Distributed Circuits. Transmission Lines. Multiconductor Transmission Lines. Time and Frequency Domain Responses. Distributed RC Networks. Synthesis of Distributed Circuits. Index.
Date de parution : 06-2017
17.8x25.4 cm
Date de parution : 06-2009
Ouvrage de 454 p.
17.8x25.4 cm
Thèmes de Feedback, Nonlinear, and Distributed Circuits :
Mots-clés :
MOS Transistor; feedback amplifier; Open Loop Voltage Gain; Synthesis and Design of Nonlinear Circuits; Equivalent Circuit; Synthesis of Distributed Circuits; Driving Point Impedance; Transmission Lines; Piecewise-Linear Analysis; Voltage Gain; Leon O; Chua; Transfer Impedance; Koryu Ishii Thomas; Return Difference; John Choma; Circuit Equations; Martin Hasler; Open Loop Amplifier; Angel Rodríguez-Vuez; Nonlinear Resistor; Manuel Delgado-Restituto; Nonlinear Circuit; Jose L; Huertas; Input Port; F; Vidal; Open Loop Gain; Guanrong Chen; IEEE Trans; Wolfgang Mathis; Chua’s Circuit; Joos Vandewalle; Feedback Network; Lieven Vandenberghe; Shunt Admittance; Lindberg Erik; Feedback Factor; Pole Splitting; Zndy os; Feedback; Rekeczky Csaba; Output Resistance; Michael Peter Kennedy; Common Emitter Transistor; Vandenberghe Lieven; Loop Gain; Thomas Koryu Ishii; Closed Loop Gain; De Zutter Daniël; Martens Luc; Luc Martens; Daniël De Zutter; Vladimír Székely; piecewise-linear methods; distributed circuits; feedback amplifier theory; Bode's feedback theory; nonlinear circuits