05789nam 2200745Ia 450 991013976540332120230721022503.01-282-23756-X97866122375600-470-74654-80-470-74655-6(CKB)1000000000789868(EBL)454303(OCoLC)609843787(SSID)ssj0000361072(PQKBManifestationID)11305311(PQKBTitleCode)TC0000361072(PQKBWorkID)10350963(PQKB)11131289(MiAaPQ)EBC454303(Au-PeEL)EBL454303(CaPaEBR)ebr10317784(CaONFJC)MIL223756(OCoLC)648760905(EXLCZ)99100000000078986820090422d2009 uy 0engurcn|||||||||txtccrHigh efficiency RF and microwave solid state power amplifiers[electronic resource] /Paolo Colantonio, Franco Giannini, Ernesto LimitiChichester, UK J. Wiley20091 online resource (520 p.)Wiley series in microwave and optical engineeringDescription based upon print version of record.0-470-51300-4 Includes bibliographical references and index.High Efficiency RF and Microwave Solid State Power Amplifiers; Contents; Preface; About the Authors; Acknowledgments; 1 Power Amplifier Fundamentals; 1.1 Introduction; 1.2 Definition of Power Amplifier Parameters; 1.3 Distortion Parameters; 1.3.1 Harmonic Distortion; 1.3.2 AM-AM/AM-PM; 1.3.3 Two-tone Intermodulation; 1.3.4 Intercept Point IPn; 1.3.5 Carrier to Intermodulation Ratio; 1.3.6 Spurious Free Dynamic Range; 1.3.7 Adjacent Channel Power Ratio; 1.3.8 Noise and Co-Channel Power Ratio (NPR and CCPR); 1.3.9 Multi-tone Intermodulation Ratio; 1.3.10 Error Vector Magnitude1.4 Power Match Condition 1.5 Class of Operation; 1.6 Overview of Semiconductors for PAs; 1.7 Devices for PA; 1.7.1 Requirements for Power Devices; 1.7.2 BJT; 1.7.3 HBT; 1.7.4 FET; 1.7.5 MOSFET; 1.7.6 LDMOS; 1.7.7 MESFET; 1.7.8 HEMT; 1.7.9 General Remarks; 1.8 Appendix: Demonstration of Useful Relationships; 1.9 References; 2 Power Amplifier Design; 2.1 Introduction; 2.2 Design Flow; 2.3 Simplified Approaches; 2.4 The Tuned Load Amplifier; 2.5 Sample Design of a Tuned Load PA; 2.6 References; 3 Nonlinear Analysis for Power Amplifiers; 3.1 Introduction; 3.2 Linear vs. Nonlinear Circuits3.3 Time Domain Integration 3.3.1 Iterative Algorithm (Newton-Raphson and Fixed-point); 3.4 Example; 3.4.1 Forward Euler Solution; 3.4.2 Backward Euler Solution; 3.4.3 Steady-state Analysis and Shooting Method; 3.4.4 Example; 3.5 Solution by Series Expansion; 3.6 The Volterra Series; 3.6.1 Response to a Single-tone Excitation; 3.6.2 Response to a Two-tone Excitation; 3.6.3 The Probing Method; 3.6.4 Example; 3.6.5 Cascade of Systems; 3.7 The Fourier Series; 3.8 The Harmonic Balance; 3.8.1 Example; 3.8.2 Multi-tone HB Analysis; 3.9 Envelope Analysis; 3.10 Spectral Balance3.11 Large Signal Stability Issue 3.12 References; 4 Load Pull; 4.1 Introduction; 4.2 Passive Source/Load Pull Measurement Systems; 4.3 Active Source/Load Pull Measurement Systems; 4.3.1 Two-signal Path Technique; 4.3.2 Active Loop Technique; 4.4 Measurement Test-sets; 4.4.1 Scalar Systems; 4.4.2 VNA Based Systems; 4.4.3 Six-port Reflectometer Based Systems; 4.5 Advanced Load Pull Measurements; 4.5.1 Intermodulation Measurements; 4.5.2 Time-domain Waveform Load Pull; 4.5.3 Pulsed Load Pull; 4.6 Source/Load Pull Characterization; 4.7 Determination of Optimum Load Condition4.7.1 Example of Simplified Load Pull Contour 4.7.2 Design of an Amplifier Stage using Simplified Load Pull Contours; 4.8 Appendix: Construction of Simplified Load Pull Contours through Linear Simulations; 4.9 References; 5 High Efficiency PA Design Theory; 5.1 Introduction; 5.2 Power Balance in a PA; 5.3 Ideal Approaches; 5.3.1 Tuned Load; 5.3.2 Class F or Inverse Class F (Class F-1); 5.3.3 Class E or General Switched-mode; 5.4 High Frequency Harmonic Tuning Approaches; 5.4.1 Mathematical Statements; 5.5 High Frequency Third Harmonic Tuned (Class F); 5.6 High Frequency Second Harmonic Tuned5.7 High Frequency Second and Third Harmonic TunedDo you want to know how to design high efficiency RF and microwave solid state power amplifiers? Read this book to learn the main concepts that are fundamental for optimum amplifier design. Practical design techniques are set out, stating the pros and cons for each method presented in this text. In addition to novel theoretical discussion and workable guidelines, you will find helpful running examples and case studies that demonstrate the key issues involved in power amplifier (PA) design flow. Highlights include:Clarification of topics which are often misunderstood and misused,Wiley series in microwave and optical engineering.Power amplifiersAmplifiers, Radio frequencyMicrowave amplifiersSolid state electronicsPower amplifiers.Amplifiers, Radio frequency.Microwave amplifiers.Solid state electronics.621.381325Colantonio Paolo985766Giannini Franco1944-7505Limiti Ernesto985767MiAaPQMiAaPQMiAaPQBOOK9910139765403321High efficiency RF and microwave solid state power amplifiers2253110UNINA