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Compact Ku-band transmitter design for satellite communication applications : from system analysis to hardware implementation /
Compact Ku-band Transmitter Design for Satellite Communication Applications reviews approaches to and topologies of Ku-band transmitters. The advantages and disadvantages of these transmitters are explored along with critical design criteria necessary to enhance system performance. The design and im...
| Call Number: | Libro Electrónico |
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| Main Author: | |
| Other Authors: | |
| Format: | Electronic eBook |
| Language: | Inglés |
| Published: |
Boston :
Kluwer Academic Publishers,
©2002.
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| Subjects: | |
| Online Access: | Texto completo |
Table of Contents:
- Cover
- Table of Contents
- PREFACE
- 1. INTRODUCTION
- 2. KU-BAND TRANSMITTER ARCHITECTURE
- 2.1 DESIGN CRITERIA
- 2.2 UP-CONVERSION TOPOLOGIES
- 3. TRANSMITTER SYSTEM SIMULATION MODEL
- 3.1 INTRODUCTION
- 3.2 SYSTEM MODEL DEVELOPMENT
- 3.3 TRANSMITTER MODULE IMPLEMENTATION PROCEDURE
- 4. REVIEW OF KU-BAND MIXERS
- 4.1 MIXER DESIGN PRINCIPLES
- 4.2 MIXER PERFORMANCE PARAMETERS
- 4.3 DEVICE TECHNOLOGIES FOR KU-BAND MIXER
- 4.4 KU-BAND MIXER TOPOLOGIES
- 4.5 COMPARISON OF KU-BANDMIXER
- 4.6 CONCLUSIONS
- 5. REVIEW OF KU-B AND VCOs
- 5.1 OSCILLATOR DESIGN PRINCIPLES
- 5.2 VCO DESIGN PRINCIPLES
- 5.3 VCO PERFORMANCE PARAMETERS
- 5.4 KU-BAND VCO MMIC
- 5.5 KU-BAND GAAS MESFET VCO DESIGN
- 5.6 KU-BAND ALGAAS/GAAS HBT VCO
- 5.7 CONCLUSIONS
- 6. TRANSMITTER MMIC FOR SATELLITE COMMUNICATIONS APPLICATIONS
- 6.1 INTRODUCTION
- 6.2 TRANSMITTER MMIC DESIGN CRITERIA
- 6.3 DUAL GATE MIXER
- 6.4 VOLTAGE CONTROLLED OSCILLATOR
- 6.5 IF AMPLIFIER MMIC AND RF AMPLIFIER MMIC
- 6.6 DRIVER AMPLIFIER MMIC
- 6.7 POWER AMPLIFIER DESIGN
- 6.8 CONCLUSIONS
- 7. TRANSMITTER MODULE DESIGN
- 7.1 INTRODUCTION
- 7.2 STRIP LINE BAND PASS FILTER
- 7.3 MODULE DESIGN
- 7.4 MODULE MEASUREMENT RESULTS
- 7.5 CONCLUSION
- 8. CONCLUSION
- BIBLIOGRAPHY.