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Solid-State Microwave High-Power Amplifiers.
This practical resource offers expert guidance on the most critical aspects of microwave power amplifier design. This comprehensive book provides descriptions of all the major active devices, discusses large signal characterization, explains all the key circuit design procedures. Moreover you gain k...
| Clasificación: | Libro Electrónico |
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| Autor principal: | |
| Otros Autores: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Norwood :
Artech House,
2009.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Solid-State Microwave High-Power Amplifiers; Contents; Preface; Chapter 1 Introduction; 1.1 Scope of This Book; 1.1.1 Future Developments; References; Chapter 2 High-Power Amplifiers; 2.1 Applications and Specifications; 2.2 Active Devices; References; Chapter 3 Physics of Active Devices; 3.1 Introduction; 3.2 Basic Concepts of Solid-State Physics; 3.3 Charge Transport in Semiconductors; 3.4 Junctions and Barriers; 3.5 FETs and MESFETs; 3.6 Heterojunction Transistors; References; Chapter 4 Device Characterization and Modeling; 4.1 Introduction; 4.2 Small-Signal Characterization and Models.
- 4.2.1 MESFET and HEMT Small-Signal Model4.2.2 HBT Small-Signal Model; 4.3 Large-Signal Characterization; 4.3.1 Load Pull; 4.3.2 Large-Signal Parameters: AM/AM and AM/PM; 4.3.3 S-Parameters Versus Bias; 4.4 Large-Signal Models; 4.4.1 MESFET and HEMT Large-Signal Model; 4.4.2 HBT Large-Signal Model; References; Chapter 5 Phase Noise; 5.1 Introduction; 5.2 Noise in Semiconductors; 5.3 Noise in Active Devices; 5.4 Phase Noise; 5.5 Phase Noise in Amplifiers; References; Chapter 6 Technologies for Microwave Power Amplifiers; 6.1 Introduction; 6.2 Waveguide Components.
- 6.3 Microwave Integrated Circuits (MICs)6.3.1 Microwave Printed Circuits; 6.3.2 Hybrid Circuits; 6.3.3 Miniature Hybrid or Semimonolithic Ceramic Circuits; 6.3.4 Monolithic Circuits; References; Chapter 7 Power Combiners and Dividers; 7.1 Introduction; 7.2 Balanced Stages and Quadrature Couplers; 7.2.1 Interdigitated Couplers; 7.2.2 Branch-Line Couplers; 7.2.3 Wilkinson Couplers, In-Phase and Quadrature; 7.2.4 Comparison of Three Types of Microstrip Quadrature Couplers; 7.3 180° Couplers; 7.4 Lumped-Element l/4 Transformers; 7.5 Radial Combiners; 7.5.1 Microstrip Lines.
- 7.5.2 Radial Waveguides7.5.3 Conical Waveguides; 7.6 Coupler Arrays; References; Chapter 8 General Power-Amplifier Design; 8.1 Introduction; 8.2 Load-Pull Design; 8.3 Broadband Matching Networks; 8.4 Bode and Fano-Theoretical Limitations on Matching; 8.5 Bandwidth vs. Power; 8.6 Load-Line Design; 8.7 Large-Signal Simulation Design: Harmonic Balance; 8.8 Potential Instabilities; 8.8.1 Low-Level Oscillations: Rollet's k Factor; 8.8.2 Internal Oscillations; 8.8.3 Parametric Oscillations; 8.8.4 Bias Oscillations; References; Chapter 9 High-Efficiency Amplifiers; 9.1 Introduction.
- 9.2 Class A: Output Power and Efficiency Versus Load Line9.3 Class AB: Peak Voltage Versus Conduction Angle and Load Line; 9.4 Overdriven Amplifiers; 9.4.l Class B: Optimal Efficiency and Class F; 9.4.2 Class B: Optimal Power; 9.4.3 Class A: Optimal Loading; 9.4.4 Class A: Optimal Power and Efficiency; 9.5 Class E; 9.6 Real Devices and Circuits; References; Chapter 10 Linear Power Amplifiers; 10.1 Introduction; 10.2 Linearity; 10.2.1 Amplitude Distortion: Two-Tone IMD; 10.2.2 Real IMD Curves; 10.2.3 Phase Distortion: Two-Tone IMD; 10.2.4 Composite Amplitude and Phase Distortion.