04677nam 2200649Ia 450 991045735120332120200520144314.01-281-05762-297866110576260-08-055064-9(CKB)1000000000349851(EBL)311398(OCoLC)476098327(SSID)ssj0000254594(PQKBManifestationID)11939378(PQKBTitleCode)TC0000254594(PQKBWorkID)10208632(PQKB)11074260(MiAaPQ)EBC311398(Au-PeEL)EBL311398(CaPaEBR)ebr10190197(CaONFJC)MIL105762(OCoLC)162593827(EXLCZ)99100000000034985120070521d2007 uy 0engur|n|---|||||txtccrSwitchmode RF power amplifiers[electronic resource] /Andrei Grebennikov and Nathan O. SokalBurlington, MA ;Amsterdam Elsevier/Newnesc20071 online resource (443 p.)Communications engineering series Switchmode RF power amplifiersDescription based upon print version of record.0-7506-7962-X Includes bibliographical references and index.Front Cover; Switchmode RF Power Amplifiers; Copyright Page; Table of Contents; About Andrei Grebennikov; About Nathan O. Sokal; Preface; Acknowledgments; Chapter 1: Power-Amplifier Design Principles; 1.1 Spectral-Domain Analysis; 1.2 Basic Classes of Operation: A, AB, B, and C; 1.4 High-Frequency Conduction Angle; 1.5 Nonlinear Effect of Collector Capacitance; 1.6 Push-Pull Power Amplifiers; References; Chapter 2: Class-D Power Amplifiers; 2.1 Switched-Mode Power Amplifiers with Resistive Load; 2.2 Complementary Voltage-Switching Configuration2.3 Transformer-Coupled Voltage-Switching Configuration2.4 Symmetrical Current-Switching Configuration; 2.5 Transformer-Coupled Current-Switching Configuration; 2.6 Voltage-Switching Configuration with Reactive Load; Chapter 3: Class-F Power Amplifiers; 3.1 Biharmonic Operation Mode; 3.6 Load Networks with Lumped Elements; Chapter 4: Inverse Class F; 4.1 Biharmonic Operation Mode; 4.4 Load Networks with Lumped Elements; References; Chapter 5: Class E with Shunt Capacitance; 5.1 Effect of Detuned Resonant Circuit; 5.2 Load Network with Shunt Capacitor and Series Filter5.3 Matching with Standard Load5.8 Load Network with Transmission Lines; 5.9 Practical RF and Microwave Class-E Power Amplifiers and Applications; References; Chapter 6: Class E with Finite dc-Feed Inductance; 6.1 Class E with One Capacitor and One Inductor; 6.2 Generalized Class-E Load Network with Finite dc-Feed Inductance; 6.7 Load Network with Transmission Lines; 6.9 Power Gain; Chapter 7: Class E with Quarter-wave Transmission Line; 7.1 Load Network with Parallel Quarter-wave Line; 7.2 Optimum Load Network Parameters; 7.4 Matching Circuit with Lumped Elements; ReferencesChapter 8: Alternative and Mixed-Mode High-Efficiency Power Amplifiers8.2 Class-E/F Power Amplifiers; 8.4 Inverse Class-E Power Amplifiers; Chapter 9: Computer-Aided Design of Switched-Mode Power Amplifiers; 9.1 HB-PLUS Program for Half-Bridge and Full-Bridge Direct-Coupled Voltage-Switching Class-D and Class-DE Circuits; 9.4 HB-PLUS CAD Examples for Class D and Class DE; 9.5 HEPA-PLUS CAD Example for Class E; 9.7 ADS Circuit Simulator and Its Applicability to Switched-Mode Class E; IndexA majority of people now have a digital mobile device whether it be a cell phone, laptop, or blackberry. Now that we have the mobility we want it to be more versatile and dependable; RF power amplifiers accomplish just that. These amplifiers take a small input and make it stronger and larger creating a wider area of use with a more robust signal.Switching mode RF amplifiers have been theoretically possible for decades, but were largely impractical because they distort analog signals until they are unrecognizable. However, distortion is not an issue with digital signals-like those usedPower amplifiersMicrowave amplifiersElectronic books.Power amplifiers.Microwave amplifiers.621.381535Grebennikov Andrei1956-725307Sokal Nathan O989606MiAaPQMiAaPQMiAaPQBOOK9910457351203321Switchmode RF power amplifiers2263444UNINA