00792nam 2200217 i 450099100437123780753620250307112458.0250307t20212022it e b 001 0dita 9788846762849Bibl. Dip.le Aggr. Studi Umanistici - Sez. FilosofiaitaUn dialogo su Olympe de Gouges :donne, schiavitù, cittadinanza /a cura di Thomas Casadei e Lorenzo MilazzoPisa :ETS,2021232 p. ;19 cm.Rifrazioni. Dialoghi sui classici ;3GiusnaturalismoRaccolte di saggiDiritti umaniConcezione [di] Gouges, Olympe : deCasadei, ThomasMilazzo, Lorenzo991004371237807536Dialogo su Olympe de Gouges4325380UNISALENTO03637nam 2200589Ia 450 991100701700332120200520144314.01-61353-061-71-61344-418-4(CKB)3190000000024596(EBL)1192412(SSID)ssj0000943661(PQKBManifestationID)11580609(PQKBTitleCode)TC0000943661(PQKBWorkID)10982246(PQKB)11098214(MiAaPQ)EBC1192412(EXLCZ)99319000000002459620090722d2010 uy 0engur|n|---|||||txtccrDesigning dynamic circuit response /D. FeuchtRaleigh, NC SciTech Pub.c20101 online resource (292 p.)Analog circuit design series ;v. 2Description based upon print version of record.1-891121-83-9 Includes bibliographical references and index.Contents; 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 ResponseReactance Chart Transfer Functions of Passive CircuitsClosure; 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 BypassingChapter 3. High-Frequency Impedance TransformationsActive Device Behavior above Bandwidth; BJT High-Frequency Model; Impedance Transformations in the High-Frequency Region; Reactance Chart Representation of b-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 InductanceThis second volume, Designing Dynamic Circuit Response builds upon the first volume Designing Amplifier Circuits by extending coverage to include reactances and their time- and frequency-related behavioral consequences.Analog circuit design series ;v.2Frequency response (Dynamics)Transients (Dynamics)Electronic circuit designFrequency response (Dynamics)Transients (Dynamics)Electronic circuit design.621.3815/35ZN 5400rvkFeucht Dennis1825084MiAaPQMiAaPQMiAaPQBOOK9911007017003321Designing dynamic circuit response4392548UNINA