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Informationen zum Autor William F. Egan, PhD, is Lecturer in Electrical Engineering at Santa Clara University, California, and formerly a principal engineer at TRW ESD and a senior technologist at GTE Government Systems. He received his PhD in electrical engineering from Stanford University. Klappentext Broad-based and hands-on, Phase-Lock Basics, Second Edition is both easy to understand and easy to customize. The text can be used as a theoretical introduction for graduate students or, when used with MATLAB simulation software, the book becomes a virtual laboratory for working professionals who want to improve their understanding of the design process and apply it to the demands of specific situations. This second edition features a large body of new statistical data obtained from simulations and uses available experimental data for confirmation of the simulation results. Zusammenfassung Broad-based and hands-on, Phase-Lock Basics, Second Edition is both easy to understand and easy to customize. Inhaltsverzeichnis Preface. Symbols List and Glossary. Getting Files from The Wiley Ftp Internet Site. PART 1. PHASE LOCK WITHOUT NOISE. 1. INTRODUCTION. 1.1 What is a phase-locked loop (PLL)?. 1.2 Why use a phase-locked loop?. 1.3 Scope of This Book. 1.4 Basic Loop. 1.5 Phase Definitions. 1.6 Phase Detector. 1.7 Combined Gain. 1.8 Operating Range. 1.9 Units and the Laplace Variable s. 2. THE BASIC LOOP. 2.1 Steady-State Conditions. 2.2 Classical Analysis. 2.3 Mathematical Block Diagram. 2.4 Bode Plot. 2.5 Note on Phase Reversals. 2.6 Summary of Transient Responses of the First Order Loop. 3. LOOP COMPONENTS. 3.1 Phase Detector. 3.2 Voltage Controlled Oscillator (VCO). 3.3 Loop Filter. 3.3.3.2 Unintended Poles. 3.4 Filter Reference Voltage. 3.5 Note On the Form of the Filter Equation. 3.6 Capacitors in Loop Filters. 3.7 Higher-Order Filters. 4. LOOP RESPONSE . 4.1 Loop Order and Type. 4.2 Closed-Loop Equations. 4.3 Open-Loop Equations--Lag-Lead Filter. 4.4 Loop with a Lag Filter. 4.5 Loop With an Integrator-and-Lead Filter. 4.6 Summary of Equations. 5. LOOP STABILITY . 5.1 Observing the Open-Loop Response. 5.2 Methods of Stability Analysis and Measures of Stability. 5.3 Stability of Various PLL Configurations. 5.4 Computing Open-Loop Gain and Phase. 5.5 Phase Margin versus Damping Factor. 6. TRANSIENT RESPONSE. 6.1 Step Response. 6.2 Envelope of the Long-Term Step Response. 6.3 Response to Ramp Input. 6.4 Response to Parabolic Input. 6.5 Other Responses. 6.6 Note on Units for Graphs. 6.7 Equivalent Circuit. 6.8 General Long-Term (Steady-State) Response Characteristics. 6.9 Open-Loop Equations in Terms of Closed-Loop Parameters. 6.10 More Complex Loops and State Space Analysis. 6.11 An Approximate Solution Using State-Space Variables. 6.12 Effect of an Added Pole. 7. MODULATION RESPONSE. 7.1 Phase and Frequency Modulation. 7.2 Modulation Responses. 7.3 Responses in a First-Order Loop. 7.4 Transfer Functions in a Second-Order Loop. 7.5 Transient Responses Between Various Points. 7.6 Magnitude and Phase of the Transfer Functions. 7.7 Related Responses. 7.8 Modulation and Demodulation in the Second-Order Loop. 7.9 Measurement of Loop Parameters for a = 0 or 1 from Modulation Responses. 7.10 Effect of an Added Pole. 8. ACQUISITION. 8.1 Overview. 8.2 Acquisition and Lock In a First-Order Loop. 8.3 Acquisition Formulas For Second-Order Loops With Sine Phase ...
