Book contents
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 High-frequency and high-data-rate communication systems
- 3 High-frequency linear noisy network analysis
- 4 High-frequency devices
- 5 Circuit analysis techniques for high-frequency integrated circuits
- 6 Tuned power amplifier design
- 7 Low-noise tuned amplifier design
- 8 Broadband low-noise and transimpedance amplifiers
- 9 Mixers, switches, modulators, and other control circuits
- 10 Design of voltage-controlled oscillators
- 11 High-speed digital logic
- 12 High-speed digital output drivers with waveshape control
- 13 SoC examples
- Appendix 1 Trigonometric identities
- Appendix 2 Baseband binary data formats and analysis
- Appendix 3 Linear matrix transformations
- Appendix 4 Fourier series
- Appendix 5 Exact noise analysis for a cascode amplifier with inductive degeneration
- Appendix 6 Noise analysis of the common-emitter amplifier with transformer feedback
- Appendix 7 Common-source amplifier with shunt–series transformer feedback
- Appendix 8 HiCUM level 0 model for a SiGe HBT
- Appendix 9 Technology parameters
- Appendix 10 Analytical study of oscillator phase noise
- Appendix 11 Physical constants
- Appendix 12 Letter frequency bands
- Index
- References
1 - Introduction
Published online by Cambridge University Press: 05 March 2013
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 High-frequency and high-data-rate communication systems
- 3 High-frequency linear noisy network analysis
- 4 High-frequency devices
- 5 Circuit analysis techniques for high-frequency integrated circuits
- 6 Tuned power amplifier design
- 7 Low-noise tuned amplifier design
- 8 Broadband low-noise and transimpedance amplifiers
- 9 Mixers, switches, modulators, and other control circuits
- 10 Design of voltage-controlled oscillators
- 11 High-speed digital logic
- 12 High-speed digital output drivers with waveshape control
- 13 SoC examples
- Appendix 1 Trigonometric identities
- Appendix 2 Baseband binary data formats and analysis
- Appendix 3 Linear matrix transformations
- Appendix 4 Fourier series
- Appendix 5 Exact noise analysis for a cascode amplifier with inductive degeneration
- Appendix 6 Noise analysis of the common-emitter amplifier with transformer feedback
- Appendix 7 Common-source amplifier with shunt–series transformer feedback
- Appendix 8 HiCUM level 0 model for a SiGe HBT
- Appendix 9 Technology parameters
- Appendix 10 Analytical study of oscillator phase noise
- Appendix 11 Physical constants
- Appendix 12 Letter frequency bands
- Index
- References
Summary
High-frequency circuits in wireless, fiber-optic, and imaging systems
The term radio frequency integrated circuits or, in short, RFICs, describes circuits operating in the 300MHz to 3GHz range. In the 1990s, RFICs became closely associated with the cellular phone industry. In contrast, microwave (3–30GHz) and mm-wave (30–300GHz) monolithic integrated circuits, or MMICs, first introduced in the 1970s, have largely been associated with GaAs and III-V technologies and a broader spectrum of commercial and military applications. Today, Si, SiGe, and III-V integrated circuits coexist in commercial products throughout these frequency ranges, each with its own niche market.
In this book, the general term high-frequency integrated circuits, HF ICs, is employed to include RFICs, MMICs, as well as high-speed digital and 300+ GHz electronic monolithic integrated circuits. These high-frequency circuits and systems cover the frequency range from 1GHz to 1THz and find their application in:
wireless,
backplane,
optical fiber, and
other wired communications,
which have become mainstream in the last 20 years. Other, more recent, applications and systems such as:
road safety and automotive radar,
security,
industrial sensors,
remote sensing and radiometers, and
radioastronomy
also benefit from the IC concepts and design methodologies developed here. These circuits can be loosely classified in:
tuned narrowband,
wideband, and
broadband.
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- Chapter
- Information
- High-Frequency Integrated Circuits , pp. 1 - 13Publisher: Cambridge University PressPrint publication year: 2013