Description
This authoritative book gives you new perspective on the RF and analog hardware and systems design aspects of software defined radio. It delves into the architecture of transmitters and receivers that make software-defined radio a reality. Covering both the practical aspects and underpinnings of these architectures, the book details all key RF and analog baseband components and sub-systems, from the converters that interface with DSPs and ASICs through to the duplexer feeding the antenna. It enables you to select the right technique for any application by providing alternatives for implementing the main system components. The book places emphasis on broadband and multi-band techniques, including broadband quadrature techniques, methods of dealing with the diplexer issue in transceivers, high-dynamic range and general coverage receiver techniques, and linearization applied to LNAs, receiver front-ends, transmitters and PAs. This practical resource looks at the cost factors of using particular techniques to ensure that you are creating communications devices that can compete successfully in the marketplace. Moreover, the book includes a survey of current technology that guides you in identifying future trends, so that current designs can be adapted to ever-changing technology and market demands.
Table Of Contents
IntroductionWhat is Software Defined Radio. The Requirements for Software-Defined Radio. The Benefits of Multi-Standard Terminals. Operational Requirements. Business Models for Software-Defined Radio. New Base Station and Network Architectures. Smart Antenna Systems. Projects and Sources of Information for Software-Defined Radio. Organization of the Text. References. ; Basic Architecture of a Software-Defined RadioIdeal Software-Defined Radio Architecture. Required Hardware Specifications. Digital Aspects of a Software Radio. Current Technology Limitations. Impact of Superconducting Technologies on Software Defined Radio. References.; Flexible RF Receiver ArchitecturesIntroduction. Receiver Architecture Options. Implementation of a Digital Receiver. Multi-Band and General Coverage Systems. The Problem of the Duplexer. Achieving Image Reduction. Dynamic Range Enhancement. Influence of Phase-Noise on EVM for a Linear Transceiver. Relationship between EVM, PCDE, and Rho. References; Flexible Transmitters and PASIntroduction. Differences in PA Requirements and for Base-Stations and Handsets. Basic Upconversion Architectures. Broadband Quadrate Techniques. Linearization Applied to Software Radio Transmitters. Power Amplifier Linearization Techniques. Transmitter Linearization Techniques. RF Synthesis Techniques. Power Efficiency. References. ;
Author
-
Peter B. Kenington
Peter Kenington is director of advanced technology at Andrew Corporation. A fellow of the IEE and a senior member of the IEEE, he earned both a B.E. in electrical and electronics engineering and a Ph.D. in communications engineering from the University of Bristol, United Kingdom. Dr. Kenington is also the author of High Linearity RF Amplifier Design (Artech House, 2000).