The Design of CMOS Radio-Frequency Integrated CircuitsCambridge University Press, 22 dic 2003 This book, first published in 2004, is an expanded and thoroughly revised edition of Tom Lee's acclaimed guide to the design of gigahertz RF integrated circuits. A new chapter on the principles of wireless systems provides a bridge between system and circuit issues. The chapters on low-noise amplifiers, oscillators and phase noise have been significantly expanded. The chapter on architectures now contains several examples of complete chip designs, including a GPS receiver and a wireless LAN transceiver, that bring together the theoretical and practical elements involved in producing a prototype chip. Every section has been revised and updated with findings in the field and the book is packed with physical insights and design tips, and includes a historical overview that sets the whole field in context. With hundreds of circuit diagrams and homework problems this is an ideal textbook for students taking courses on RF design and a valuable reference for practising engineers. |
Dall'interno del libro
Risultati 1-5 di 89
Pagina
... Simply obtaining sufficient gain over some acceptable bandwidth is frequently insufficient. In many wireless applications, the received signal amplitude is in the microvolt range. The need to amplify such minute signals as noiselessly ...
... Simply obtaining sufficient gain over some acceptable bandwidth is frequently insufficient. In many wireless applications, the received signal amplitude is in the microvolt range. The need to amplify such minute signals as noiselessly ...
Pagina 2
... simply too small to enclose several wavelengths of anything lower in frequency. Because Hertz's sensor was another spark gap (integral with a loop resonator), the received signal had to be large enough to induce a visible spark ...
... simply too small to enclose several wavelengths of anything lower in frequency. Because Hertz's sensor was another spark gap (integral with a loop resonator), the received signal had to be large enough to induce a visible spark ...
Pagina 10
... (simply reforming the Wollaston wire into the shape of a spade) after visiting Fessenden's laboratory, and even had the audacity to claim a prize for its invention. In this case, however, justice did prevail, and Fessenden won an ...
... (simply reforming the Wollaston wire into the shape of a spade) after visiting Fessenden's laboratory, and even had the audacity to claim a prize for its invention. In this case, however, justice did prevail, and Fessenden won an ...
Pagina 13
... simply from one tube. Additionally, the nonlinearity of the tube demodulated the signal. Furthermore, overcoupling the output to the input turned the thing into a wonderfully compact RF oscillator. In a 1914 paper entitled "Operating ...
... simply from one tube. Additionally, the nonlinearity of the tube demodulated the signal. Furthermore, overcoupling the output to the input turned the thing into a wonderfully compact RF oscillator. In a 1914 paper entitled "Operating ...
Pagina 28
... simply p.. so that /z represents the open- circuit amplification factor. Additionally, note that the transconductance and plate resistance are only weak functions (cube roots) of operating point. For this reason, vacuum tubes generate ...
... simply p.. so that /z represents the open- circuit amplification factor. Additionally, note that the transconductance and plate resistance are only weak functions (cube roots) of operating point. For this reason, vacuum tubes generate ...
Sommario
| 1 | |
| 40 | |
PASSIVE RLC NETWORKS | 87 |
CHARACTERISTICS OF PASSIVE 1C COMPONENTS | 114 |
A REVIEW OF MOS DEVICE PHYSICS | 167 |
DISTRIBUTED SYSTEMS | 202 |
THE SMITH CHART AND SPARAMETERS | 221 |
A Short Note on Units | 227 |
Gain and Phase Margin as Stability Measures | 451 |
RootLocus Techniques | 453 |
Summary of Stability Criteria | 459 |
Errors in Feedback Systems | 462 |
Frequency and TimeDomain Characteristics of First and SecondOrder Systems | 466 |
Useful Rules of Thumb | 469 |
RootLocus Examples and Compensation | 470 |
Summary of RootLocus Techniques | 477 |
Why 50 or 75 W | 229 |
Problem Set | 231 |
BANDWIDTH ESTIMATION TECHNIQUES | 233 |
The Method of OpenCircuit Time Constants | 234 |
The Method of ShortCircuit Time Constants | 254 |
Further Reading | 259 |
Summary | 265 |
Problem Set | 266 |
HIGHFREQUENCY AMPLIFIER DESIGN | 270 |
Zeros as Bandwidth Enhancers | 271 |
The ShuntSeries Amplifier | 282 |
Bandwidth Enhancement with fT Doublers | 288 |
Tuned Amplifiers | 290 |
Neutralization and Unilateralization | 294 |
Cascaded Amplifiers | 297 |
AMPM Conversion | 306 |
Summary | 307 |
Problem Set | 308 |
VOLTAGE REFERENCES AND BIASING | 314 |
Diodes and Bipolar Transistors in CMOS Technology | 316 |
SupplyIndependent Bias Circuits | 317 |
Bandgap Voltage Reference | 318 |
Constantgm Bias | 325 |
Summary | 328 |
NOISE | 334 |
Shot Noise | 342 |
Flicker Noise | 344 |
Popcorn Noise | 347 |
Classical TwoPort Noise Theory | 348 |
Examples of Noise Calculations | 352 |
A Handy Rule of Thumb | 355 |
Typical Noise Performance | 356 |
Noise Models | 357 |
Problem Set | 358 |
LNA DESIGN | 364 |
Derivation of Intrinsic MOSFET TwoPort Noise Parameters | 365 |
Power Match versus Noise Match | 373 |
PowerConstrained Noise Optimization | 380 |
Design Examples | 384 |
Linearity and LargeSignal Performance | 390 |
SpuriousFree Dynamic Range | 397 |
Summary | 399 |
Problem Set | 400 |
MIXERS | 404 |
Mixer Fundamentals | 405 |
Nonlinear Systems as Linear Mixers | 411 |
MultiplierBased Mixers | 416 |
Subsampling Mixers | 433 |
DiodeRing Mixers | 434 |
Problem Set | 437 |
FEEDBACK SYSTEMS | 441 |
A Puzzle | 446 |
Stability of Feedback Systems | 450 |
Compensation through Gain Reduction | 478 |
Lag Compensation | 481 |
Lead Compensation | 484 |
Slow Rolloff Compensation | 486 |
Summary of Compensation | 487 |
Problem Set | 488 |
RF POWER AMPLIFIERS | 493 |
ClassAAB B and C Power Amplifiers | 494 |
Class D Amplifiers | 503 |
Class E Amplifiers | 505 |
Class F Amplifiers | 507 |
Modulation of Power Amplifiers | 512 |
Summary of PA Characteristics | 540 |
RF PA Design Examples | 541 |
Additional Design Considerations | 547 |
Design Summary | 555 |
PHASELOCKED LOOPS | 560 |
Linearized PLL Models | 566 |
Some Noise Properties of PLLs | 571 |
Phase Detectors | 574 |
Sequential Phase Detectors | 579 |
Loop Filters and Charge Pumps | 588 |
PLL Design Examples | 596 |
Summary | 604 |
OSCILLATORS AND SYNTHESIZERS | 610 |
Describing Functions | 611 |
Resonators | 631 |
A Catalog of Tuned Oscillators | 635 |
Negative Resistance Oscillators | 641 |
Frequency Synthesis | 645 |
Summary | 654 |
Problem Set | 655 |
PHASE NOISE | 659 |
General Considerations | 661 |
Phase Noise | 664 |
The Roles of Linearity and Time Variation in Phase Noise | 667 |
Circuit Examples | 678 |
Amplitude Response | 687 |
Summary | 689 |
Problem Set | 690 |
ARCHITECTURES | 694 |
Dynamic Range | 695 |
Subsampling | 713 |
Transmitter Architectures | 714 |
Oscillator Stability | 715 |
Chip Design Examples | 716 |
Summary | 762 |
RF CIRCUITS THROUGH THE AGES | 764 |
The AllAmerican 5Tube Superhet | 768 |
The Regency TR1 Transistor Radio | 771 |
ThreeTransistor Toy CB WalkieTalkie | 773 |
Index 111 | 777 |
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