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Nonlinear RF Circuits and Nonlinear Vector Network Analyzers
  • Language: en
  • Pages: 300

Nonlinear RF Circuits and Nonlinear Vector Network Analyzers

With increasingly low-cost and power-efficient RF electronics demanded by today's wireless communication systems, it is essential to keep up to speed with new developments. This book presents key advances in the field that you need to know about and emerging patterns in large-signal measurement techniques, modeling and nonlinear circuit design theory supported by practical examples. Topics covered include: • Novel large-signal measurement techniques that have become available with the introduction of nonlinear vector network analyzers (NVNA), such as the LSNA, PNA-X and SWAP • Direct extraction of device models from large-signal RF dynamic loadlines • Characterization of memory effects (self-heating, traps) with pulsed RF measurements • Interactive design of power-efficient amplifiers (PA) and oscillators using ultra-fast multi-harmonic active load-pull • Volterra and poly-harmonic distortion (X-parameters) behavioral modeling • Oscillator phase noise theory • Balancing, modeling and poly-harmonic linearization of broadband RFIC modulators • Development of a frequency selective predistorter to linearize PAs

High-Speed Heterostructure Devices
  • Language: en
  • Pages: 726

High-Speed Heterostructure Devices

Fuelled by rapid growth in communications technology, silicon heterostructures and related high-speed semiconductors are spearheading the drive toward smaller, faster and lower power devices. High-Speed Heterostructure Devices is a textbook on modern high-speed semiconductor devices intended for both graduate students and practising engineers. This book is concerned with the underlying physics of heterostructures as well as some of the most recent techniques for modeling and simulating these devices. Emphasis is placed on heterostructure devices of the immediate future such as the MODFET, HBT and RTD. The principles of operation of other devices such as the Bloch Oscillator, RITD, Gunn diode, quantum cascade laser and SOI and LD MOSFETs are also introduced. Initially developed for a graduate course taught at Ohio State University, the book comes with a complete set of homework problems and a web link to MATLAB programs supporting the lecture material.

LCP for Microwave Packages and Modules
  • Language: en
  • Pages: 269

LCP for Microwave Packages and Modules

A comprehensive overview of electrical design using Liquid Crystal Polymer (LCP) at package, component and system levels, providing a detailed look at everything you need to know to get up-to-speed on the subject, including successful design details, techniques and potential pitfalls.

Modern RF and Microwave Measurement Techniques
  • Language: en
  • Pages: 475

Modern RF and Microwave Measurement Techniques

A comprehensive, hands-on review of the most up-to-date techniques in RF and microwave measurement, including practical advice on deployment challenges.

X-Parameters
  • Language: en
  • Pages: 237

X-Parameters

The definitive guide to X-parameters, written by the original inventors and developers of this powerful new paradigm, and containing real-world case studies, definitions, detailed derivations and exercises with solutions. An essential reference for researchers, engineers, scientists and students looking to remain on the cutting-edge of nonlinear RF and microwave engineering.

mm-Wave Silicon Power Amplifiers and Transmitters
  • Language: en
  • Pages: 471

mm-Wave Silicon Power Amplifiers and Transmitters

Build high-performance, spectrally clean, energy-efficient mm-wave power amplifiers and transmitters with this cutting-edge guide to designing, modeling, analysing, implementing and testing new mm-wave systems. Suitable for students, researchers and practicing engineers, this self-contained guide provides in-depth coverage of state-of-the-art semiconductor devices and technologies, linear and nonlinear power amplifier technologies, efficient power combining systems, circuit concepts, system architectures and system-on-a-chip realizations. The world's foremost experts from industry and academia cover all aspects of the design process, from device technologies to system architectures. Accompanied by numerous case studies highlighting practical design techniques, tradeoffs and pitfalls, this is a superb resource for those working with high-frequency systems.

High-Frequency Integrated Circuits
  • Language: en
  • Pages: 921

High-Frequency Integrated Circuits

A transistor-level, design-intensive overview of high speed and high frequency monolithic integrated circuits for wireless and broadband systems from 2 GHz to 200 GHz, this comprehensive text covers high-speed, RF, mm-wave and optical fiber circuits using nanoscale CMOS, SiGe BiCMOS and III-V technologies. Step-by-step design methodologies, end-of-chapter problems and practical simulation and design projects are provided, making this an ideal resource for senior undergraduate and graduate courses in circuit design. With an emphasis on device-circuit topology interaction and optimization, it gives circuit designers and students alike an in-depth understanding of device structures and process limitations affecting circuit performance.

Microwave and RF Vacuum Electronic Power Sources
  • Language: en
  • Pages: 843

Microwave and RF Vacuum Electronic Power Sources

Get up-to-speed on the theory, principles and design of vacuum electron devices.

Microwave and Wireless Measurement Techniques
  • Language: en
  • Pages: 235

Microwave and Wireless Measurement Techniques

Provides practical information on microwave and wireless metrology, from typical metrology parameters to building your own measurement benches.

Dynamic Power Supply Transmitters
  • Language: en
  • Pages: 495

Dynamic Power Supply Transmitters

"Power is dissipated (lost) when this current flows through any resistance, which includes the amplifier's transistor. This dissipated power is the product of the current in the load times the voltage difference between the supply voltage to the amplifier and the output signal voltage. When the voltage supplied to the amplifier is a constant value, and by far the most common design practice, the situation in Fig. 1-2a results. Power dissipation in the amplifier is maximum when the output signal voltage is 1/2 of the supply voltage. When the output signal voltage is higher, even though the current value is larger the voltage drop is less and the power dissipation is lower. Similarly, when the output signal voltage is small, even though the voltage drop is now large the current in the load is smaller and again the power dissipation is lower"--