Software defined radio enabling technologies
Software defined radio (SDR) is one of the most important topics of research, and indeed development, in the area of mobile and personal communications. SDR is viewed as an enabler of global roaming and as a unique platform for the rapid introduction of new services into existing live networks. It t...
| Otros Autores: | |
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| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
New York :
J. Wiley
c2002.
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| Edición: | 1st edition |
| Colección: | Wiley series in software radio.
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| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009627935306719 |
Tabla de Contenidos:
- Software Defined Radio; Contents; List of Contributors; Foreword - by Dr Joseph Mitola III; Abbreviations; Biographies; Introduction; Part I: Perspective; 1 Software Based Radio; 1.1 A Multi-Dimensional Model Sets the Stage; 1.2 What is Software Based Radio; 1.2.1 Software Defined Radio and Software Radio; 1.2.2 Adaptive Intelligent Software Radio and Other Definitions; 1.2.3 Functionality, Capability and SBR Evolution; 1.3 Architectural Perspectives for a Software Based Radio; 1.3.1 The Radio Implementer plane; 1.3.2 The Network Operator plane; 1.4 Software Radio Concepts
- 1.5 Adoption Timeframes for Software Based Radio1.6 Realization of Software Based Radio Requires New Technology; 1.7 Power/Performance/Price Limitations of Handsets Dictates Inflexible Networks; 1.8 Regulatory Concepts Facilitate SBR Introduction; 1.9 Conclusions; Acknowledgements; References; Part II: Front End Technology; 2 Radio Frequency Translation for Software Defined Radio; 2.1 Requirements and Specifications; 2.1.1 Transmitter Specifications; 2.1.2 Receiver Specifications; 2.1.3 Operating Frequency Bands; 2.2 Receiver Design Considerations; 2.2.1 Basic Considerations
- 2.2.2 Receiver Architectures2.2.3 Dynamic Range Issues and Calculation; 2.2.4 Adjacent Channel Power Ratio (ACPR) and Noise Power Ratio (NPR); 2.2.5 Receiver Signal Budget; 2.2.6 Image Rejection; 2.2.7 Filter Functions within the Receiver; 2.3 Transmitter Design Considerations; 2.3.1 Filtering Analogies between Receiver and Transmitter; 2.3.2 Transmitter Architectures; 2.3.3 Transmitter Efficiency and Linearity; 2.4 Candidate Architectures for SDR; 2.4.1 Zero IF Receivers; 2.4.2 Quadrature Local Oscillator; 2.4.3 Variable Preselect Filters; 2.4.4 Low IF Receivers; 2.5 Conclusions
- AcknowledgementsReferences; Appendix; 3 Radio Frequency Front End Implementations for Multimode SDRs; 3.1 Evolution of Radio Systems; 3.2 Evolution of RF Front Ends - Superheterodyne Architecture; 3.3 The AN2/6 Product Family - Dual Band, Six Mode; 3.3.1 The AN2/6 Architecture; 3.3.2 Lessons Learned From the AN2/6; 3.4 Alternative RF Front End Architectures; 3.4.1 Direct Conversion RF Front Ends; 3.4.2 Pure Digital RF Front Ends; 3.4.3 Analog Digital Combination Solutions; 3.4.4 Directions for a Completely Successful SDR RF Front End; 3.5 Conclusion; Acknowledgements; References
- 4 Data Conversion in Software Defined Radios4.1 The Importance of Data Converters in Software Defined Radios; 4.1.1 ADCs for SDR Base Stations; 4.1.2 ADCs for SDR Handsets; 4.1.3 DACs for SDR Applications; 4.2 Converter Architectures; 4.2.1 Flash Converters; 4.2.2 Multistage Converters; 4.2.3 Sigma-Delta Converters; 4.2.4 Digital-to-Analog Converters; 4.3 Converter Performance Impact on SDR; 4.3.1 Noise Sources - Impact on SDR Sensitivity; 4.3.2 SNR of Data Converter; 4.3.3 Spurious Impact on Performance; 4.3.4 Digital-to-Analog Converter Specification; 4.4 Conclusions and Future Trends
- References
