Designing Dynamic Circuit Response Vol - 2

Chapter 1: Transient and Frequency Response Reactive Circuit Elements First-Order Time-Domain Transient Response Complex Poles and the Complex Frequency Domain Second-Order Time Domain Response: RLC Circuit Forced Response and Transfer Functions in the s-Domain The Laplace Transform Time-Domain Response to a Unit Step Function Circuit Characterization in the Time Domain The s-Plane Frequency Response of Transfer Functions Graphical Representation of Frequency Response Loci of Quadratic Poles Optimization of Time-Domain and Frequency-Domain Response Reactance Chart Transfer Functions of Passive Circuits Closure Chapter 2: Dynamic Response Compensation Passive Compensation: Voltage Divider Op-Amp Transfer Functions from Reactance Charts Feedback Circuit Response Representation Feedback Circuit Stability Compensation Techniques Compensator Design: Compensating with Zeros in H Compensator Design: Reducing Static Loop Gain Compensator Design: Pole Separation and Parameter Variation Two-Pole Compensation Output Load Isolation Complex Pole Compensation Compensation by the Direct (Truxal's) Method Power Supply Bypassing Chapter 3: High-Frequency Impedance Transformations Active Device Behavior above Bandwidth BJT High-Frequency Model Impedance Transformations in the High-Frequency Region Reactance Chart Representation of ?-Gyrated Circuits Reactance Chart Stability Criteria for Resonances Emitter-Follower Reactance-Plot Stability Analysis Emitter-Follower High-Frequency Equivalent Circuit Emitter-Follower High-Frequency Compensation Emitter-Follower Resonance Analysis from the Base Circuit Emitter-Follower Compensation with a Base Series RC BJT Amplifier with Base Inductance The Effect of rb' on Stability Field-Effect Transistor High-Frequency Analysis Output Impedance of a Feedback Amplifier Closure References Index