| Preface | p. xi |
| Network Characterization | p. 1 |
| Network Representations | p. 1 |
| Z-Parameter Representation | p. 2 |
| Y-Parameter Representation | p. 4 |
| H-Parameter Representation | p. 5 |
| G-Parameter Representation | p. 6 |
| ABCD-Parameter Representation | p. 7 |
| Parameter Conversions | p. 8 |
| Network Connections | p. 11 |
| The Cascade Connection | p. 11 |
| The Parallel Connection | p. 13 |
| The Series Connection | p. 14 |
| The Series-Parallel Connection | p. 17 |
| The Parallel-Series Connection | p. 19 |
| S-Parameters | p. 21 |
| S-Parameter Conversions | p. 25 |
| Generalized S-Parameters | p. 30 |
| Signal Flow Graphs | p. 35 |
| The S-Parameter Cascade Connection | p. 40 |
| S-Parameter Parallel and Series Connections [18] | p. 43 |
| Indefinite S-Parameters | p. 47 |
| N-Port Networks With N-Terminals | p. 54 |
| References | p. 59 |
| Network Analysis | p. 61 |
| Circuit Elements | p. 62 |
| Series and Shunt Impedance | p. 62 |
| Transmission Lines | p. 67 |
| The Ideal Transformer | p. 71 |
| Voltage and Current Sources | p. 73 |
| Network Analysis | p. 75 |
| S-Parameter Analysis Using the Connection Matrix | p. 78 |
| S-Parameter Analysis Using Explicit Expressions | p. 81 |
| Nodal Analysis | p. 85 |
| Network Characterization | p. 99 |
| Active and Passive Networks | p. 100 |
| Stability | p. 103 |
| Conjugately Matched Two-Ports | p. 115 |
| Transducer Power Gain | p. 118 |
| Maximum Available Gain | p. 121 |
| Available Power Gain | p. 122 |
| Operating Power Gain | p. 123 |
| Constant Gain Contours | p. 124 |
| Mismatch Loss | p. 129 |
| Voltage Gain | p. 135 |
| Noise Figure | p. 136 |
| Power Amplifiers | p. 143 |
| Active Device Conversions | p. 143 |
| References | p. 146 |
| Mapping and Optimization | p. 149 |
| Mapping | p. 149 |
| Mapping Theory and the Bilinear Transform | p. 150 |
| The Smith Chart | p. 157 |
| Impedance Matching Using the Smith Chart | p. 163 |
| Source and Load Mappings | p. 171 |
| Multiport Mappings | p. 178 |
| Mapping Applications | p. 187 |
| Feedback Amplifier Mapping | p. 187 |
| Active Isolator | p. 191 |
| Reflection Amplifier | p. 192 |
| Optimization | p. 209 |
| Error Functions | p. 214 |
| Optimization Specifications | p. 222 |
| Direct Search Optimization Methods | p. 232 |
| Indirect Search Optimization Methods | p. 238 |
| Optimization Strategy | p. 247 |
| References | p. 248 |
| Modern Network Synthesis | p. 251 |
| Introduction To Network Synthesis | p. 251 |
| Element Extraction | p. 256 |
| The Approximation Problem | p. 259 |
| Low-Pass Filter Synthesis | p. 262 |
| The Butterworth or Maximally Flat Low-Pass Filter | p. 262 |
| The Chebyshev or Equal-Ripple Low-Pass Filter | p. 267 |
| The Inverse Chebyshev Low-Pass Filter | p. 272 |
| The Elliptic Low-Pass Filter | p. 279 |
| Phase Approximation | p. 280 |
| Frequency And Impedance Scaling | p. 285 |
| Bandpass Filter Synthesis | p. 288 |
| Low-Pass to Bandpass Transformation | p. 288 |
| Bandpass Approximation | p. 293 |
| High-Pass Filter Synthesis | p. 299 |
| Bandstop Filter Synthesis | p. 300 |
| Termination Adjustment | p. 304 |
| Network Transformations | p. 305 |
| Transformer Networks | p. 312 |
| Singly Terminated Networks | p. 317 |
| Conclusion | p. 324 |
| References | p. 324 |
| Distributed Network Synthesis | p. 327 |
| Distributed Equivalence | p. 330 |
| The Transmission Line Element | p. 334 |
| The Double-Length TLE | p. 340 |
| Distributed Network Transformations | p. 343 |
| Distributed Approximations | p. 361 |
| Cascaded Transmission Line Networks | p. 362 |
| Networks With TLEs and Low-Pass Stubs | p. 367 |
| Networks With TLEs and High-Pass Stubs | p. 375 |
| Bandpass and Bandstop Approximations | p. 381 |
| Impedance-Transforming Networks | p. 390 |
| High-Pass Elements | p. 392 |
| Low-Pass Elements | p. 394 |
| Transmission Line Elements | p. 398 |
| Conclusion | p. 401 |
| References | p. 402 |
| Impedance Matching and Modeling | p. 405 |
| Synthesis Of Impedance-Matching Networks | p. 406 |
| Lumped-Element GBW Limitations | p. 413 |
| Ideal GBW Limitations | p. 417 |
| Distributed-Element GBW Limitations | p. 420 |
| Load Modeling | p. 423 |
| Distributed Models | p. 426 |
| Complex Load Models | p. 435 |
| Negative-Image Models | p. 440 |
| Doubly Terminated Matching Networks | p. 456 |
| Sloped Approximations | p. 472 |
| The Real Frequency Matching Technique | p. 477 |
| Impedance From Resistance or Reactance Functions | p. 478 |
| Computing Reactance From Discrete Resistance Functions | p. 484 |
| Impedance-Matching Using Resistance Functions | p. 488 |
| Summary | p. 494 |
| References | p. 495 |
| Practical Applications | p. 499 |
| Directional Couplers | p. 501 |
| Balanced Amplifiers | p. 509 |
| A 4.0- to 8.0-Ghz Balanced Amplifier | p. 516 |
| Microstrip Design | p. 521 |
| Microstrip Couplers | p. 521 |
| Microstrip Discontinuities | p. 522 |
| A Microstrip Balanced Amplifier | p. 526 |
| Mmic Design | p. 542 |
| Feedback Amplifiers | p. 543 |
| Resistive Compensated Amplifiers | p. 551 |
| Mmic Resistive Compensated Amplfier | p. 554 |
| Summary | p. 562 |
| References | p. 324 |
| Index | p. 567 |
| Table of Contents provided by Syndetics. All Rights Reserved. |
