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Radio Frequency Integrated Circuits and Systems [Hardback]

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  • Formāts: Hardback, 488 pages, height x width x depth: 253x196x26 mm, weight: 1195 g, Worked examples or Exercises; 6 Tables, black and white; 83 Halftones, unspecified; 459 Line drawings, unspecified
  • Izdošanas datums: 16-Apr-2015
  • Izdevniecība: Cambridge University Press
  • ISBN-10: 0521190797
  • ISBN-13: 9780521190794
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  • Cena: 79,41 €
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Radio Frequency Integrated Circuits and SystemsPalielināt
  • Formāts: Hardback, 488 pages, height x width x depth: 253x196x26 mm, weight: 1195 g, Worked examples or Exercises; 6 Tables, black and white; 83 Halftones, unspecified; 459 Line drawings, unspecified
  • Izdošanas datums: 16-Apr-2015
  • Izdevniecība: Cambridge University Press
  • ISBN-10: 0521190797
  • ISBN-13: 9780521190794
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9780521190794.html
Keywords:
Focusing on the core topics of radio frequency integrated circuits (RFICs) and system design, this textbook provides the in-depth coverage and detailed mathematical analyses needed to gain a thorough understanding of the subject. Throughout, theory is linked to practice with real-world application examples; practical design guidance is also offered, covering the pros and cons of various topologies, and preparing students for future work in industry. Written for graduate courses on RFICs, this uniquely intuitive and practical book will also be of value to practising RFIC and system designers. Key topics covered include RF components, signals and systems, two-ports, noise, distortion, low-noise amplifiers, mixers, oscillators, power amplifiers, and transceiver architectures. Lecture slides and a solutions manual for instructors are provided online to complete the course package.

This book provides in-depth coverage of the core topics together with cutting-edge developments and practical applications to prepare students for radio frequency (RF) design in industry. Detailed mathematical analyses are included, and theory is linked to practice through real-world application examples. Lecture slides and a solutions manual for instructors are provided online.

Recenzijas

'[ This book] should be of high interest to practicing engineers and students alike.' Asad Abidi, University of California, Los Angeles '[ An] excellent textbook for students keenly interested to learn how to design IC transceivers. [ Contains] lots of focused and relevant fundamental background from a viewpoint of the well-known industrial researcher. The book is also good as a convenient refresher for seasoned IC designers.' Bogdan Staszewski, Delft University of Technology 'Although this is not the first book on RF circuits, it is the most up to date one that I know. For instance, it includes recent circuit insights to make CMOS radio receivers more interference robust. I especially like the intuition that Hooman Darabi develops and the depth of coverage without becoming overly mathematical.' Eric Klumperink, University of Twente

Papildus informācija

Provides in-depth coverage of the core topics, cutting-edge developments and practical applications to prepare students for radio frequency (RF) design in industry.
Preface xi
1 RF components 1(37)
1.1 Electric fields and capacitance
2(2)
1.2 Magnetic fields and inductance
4(4)
1.3 Time-varying fields and Maxwell's equations
8(2)
1.4 Circuit representation of capacitors and inductors
10(1)
1.5 Distributed and lumped circuits
11(3)
1.6 Energy and power
14(2)
1.7 LC and RLC circuits
16(5)
1.8 Integrated capacitors
21(4)
1.9 Integrated inductors
25(9)
1.10 Problems
34(3)
1.11 References
37(1)
2 RF signals and systems 38(49)
2.1 Fourier transform and Fourier series
39(2)
2.2 Impulses and impulse response
41(4)
2.3 Passive filters
45(6)
2.4 Active filters
51(4)
2.5 Hilbert transform and quadrature filters
55(5)
2.6 Stochastic processes
60(9)
2.7 Analog linear modulation
69(6)
2.8 Analog non-linear modulation
75(4)
2.9 Modern radio modulation scheme
79(2)
2.10 Problems
81(4)
2.11 References
85(2)
3 RF two-ports 87(31)
3.1 Introduction to two-ports
87(1)
3.2 Available power
88(2)
3.3 Impedance transformation
90(8)
3.4 Transmission lines
98(4)
3.5 The Smith chart
102(4)
3.6 S-parameters
106(5)
3.7 Low-loss transmission lines
111(2)
3.8 Differential two-ports
113(1)
3.9 Problems
114(3)
3.10 References
117(1)
4 Noise 118(40)
4.1 Types of noise
119(16)
4.2 Two-port equivalent noise
135(3)
4.3 Noise figure
138(2)
4.4 Minimum NF
140(6)
4.5 Noise figure of a cascade of stages
146(1)
4.6 Phase noise
147(1)
4.7 Sensitivity
148(4)
4.8 Noise figure measurements
152(2)
4.9 Problems
154(3)
4.10 References
157(1)
5 Distortion 158(45)
5.1 Blockers in wireless systems
159(3)
5.2 Full-duplex systems and coexistence
162(1)
5.3 Small signal non-linearity
163(14)
5.4 Large signal non-linearity
177(2)
5.5 Reciprocal mixing
179(3)
5.6 Harmonic mixing
182(2)
5.7 Transmitter concerns
184(17)
5.8 Problems
201(1)
5.9 References
202(1)
6 Low-noise amplifiers 203(35)
6.1 Matching requirements
204(4)
6.2 RF tuned amplifiers
208(8)
6.3 Shunt feedback LNAs
216(4)
6.4 Series feedback LNAs
220(3)
6.5 Feedforward LNAs
223(3)
6.6 LNA practical concerns
226(5)
6.7 LNA power-noise optimization
231(4)
6.8 Problems
235(2)
6.9 References
237(1)
7 RF mixers 238(64)
7.1 Mixer fundamentals
238(2)
7.2 Evolution of mixers
240(3)
7.3 Active mixers
243(15)
7.4 Passive current-mode mixers
258(21)
7.5 Passive voltage-mode mixers
279(2)
7.6 Transmitter mixers
281(6)
7.7 Harmonic folding in transmitter mixers
287(2)
7.8 LNA/mixer case study
289(8)
7.9 Problems
297(3)
7.10 References
300(2)
8 Oscillators 302(77)
8.1 The linear LC oscillator
303(5)
8.2 The non-linear LC oscillator
308(4)
8.3 Phase noise analysis of the non-linear LC oscillator
312(18)
8.4 LC oscillator topologies
330(9)
8.5 Q-degradation
339(2)
8.6 Frequency modulation effects
341(5)
8.7 More LC oscillator topologies
346(4)
8.8 Ring oscillators
350(10)
8.9 Quadrature oscillators
360(5)
8.10 Crystal oscillators
365(5)
8.11 Phase-locked loops
370(4)
8.12 Problems
374(3)
8.13 References
377(2)
9 Power amplifiers 379(32)
9.1 General considerations
379(2)
9.2 Class A PAs
381(3)
9.3 Class B PAs
384(3)
9.4 Class C PAs
387(2)
9.5 Class D PAs
389(2)
9.6 Class E PAs
391(3)
9.7 Class F PAs
394(1)
9.8 PA linearization techniques
395(12)
9.9 Problems
407(2)
9.10 References
409(2)
10 Transceiver architectures 411(59)
10.1 General considerations
412(1)
10.2 Receiver architectures
413(13)
10.3 Blocker-tolerant receivers
426(5)
10.4 Receiver filtering and ADC design
431(3)
10.5 Receiver gain control
434(1)
10.6 Transmitter architectures
435(14)
10.7 Transceiver practical design concerns
449(16)
10.8 Problems
465(3)
10.9 References
468(2)
Index 470
Hooman Darabi is a Senior Technical Director and Fellow of Broadcom Corporation, California, and an Adjunct Professor at the University of California, Los Angeles. He is an IEEE Solid State Circuits Society distinguished lecturer and his research interests include analog and RF IC design for wireless communications.