Active Network AnalysisActive Network Analysis gives a comprehensive treatment of the fundamentals of the theory of active networks and its applications to feedback amplifiers. The guiding light throughout has been to extract the essence of the theory and to discuss those topics that are of fundamental importance and that will transcend the advent of new devices and design tools. The book provides under one cover a unified, comprehensive, and up-to-date coverage of these recent developments and their practical engineering applications. In selecting the level of presentation, considerable attention has been given to the fact that many readers may be encountering some of these topics for the first time. Thus basic introductory material has been included. The work is illustrated by a large number of carefully chosen and well-prepared examples. |
Contents
1 | |
CHAPTER TWO | 61 |
CHAPTER THREE | 126 |
CHAPTER FOUR | 185 |
CHAPTER FIVE | 253 |
CHAPTER SIX | 323 |
CHAPTER SEVEN | 393 |
CHAPTER EIGHT | 465 |
CHAPTER NINE | 553 |
APPENDIX I | 624 |
APPENDIX II | 628 |
APPENDIX III | 630 |
632 | |
634 | |
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Common terms and phrases
absolutely stable active network admittance matrix amplifier of Fig Assume capacitor Chen Circuit Theory closed RHS cofactors column common-emitter compute condition Consider controlled current source controlled source controlling parameter corresponding current gain current source cutset defined denotes determinant difference and null difference with respect digraph directed graph edges equations equivalent network Example feedback amplifier feedback network Figure formula given hermitian hybrid matrix immittance indefinite-admittance matrix inductor linear loop lossless reciprocal matrix with respect natural frequencies network of Fig node null return difference Nyquist plot obtained open-circuited p-vector passive poles power gain Prob real-frequency axis reference value resistor resulting return difference matrix return ratio root locus sensitivity function short-circuit shown in Fig signal stability Substituting terminals Theorem time-invariant transfer function transfer impedance transistor two-port network unilateral variables vector voltage gain voltage source voltage-controlled current source w-port y-parameters yields zero