Radio Frequency Integrated Circuit Design - Webs

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The Use and Design of Passive Circuit Elements in IC Technologies as shown in Figure 5.42. This results in low inductance (a few tenths of a nanohenry) and very little extra capacitance. One disadvantage is that the pads must be further apart; however, the patterning of the PCB is still very fine, requiring a specialized process. Once flipped and attached, it is also not possible to probe the chip. When using chip-on-board packaging, the chip is mounted directly on the board and bond wires run directly to the board, eliminating the package, as shown in Figure 5.43. The PCB may be recessed so the top of the chip is level with the board. This may require a special surface on the PCB (gold, for example) to allow bonding to the PCB. Packaging has an important role in the removal of heat from the circuit, which is especially important for power amplifiers. Thermal conduction can be through contact. For example, the die may touch the metal backing. Thermal conduction can also be through metal connections to bond pads, wires to package, or directly to PCB for chip-on-board. In the case of the flip-chip, thermal conduction is through solder bumps to the printed circuit board. Figure 5.42 Flip-chip packaging. Figure 5.43 Chip-on-board packaging. References [1] Abrie, P. L. D., RF and Microwave Amplifiers and Oscillators, Norwood, MA: Artech House, 2000. [2] Barke, E., ‘‘Line-to-Ground Capacitance Calculations for VLSI: A Comparison,’’ IEEE Trans. on Computer-Aided-Design, Vol. 7, Feb. 1988, pp. 195–298. 139
140 Radio Frequency Integrated Circuit Design [3] Verghese, N. K., T. J. Schmerbeck, and D. J. Allstot, Simulation Techniques and Solutions for Mixed-Signal Coupling in Integrated Circuits, Norwell, MA: Kluwer, 1995. [4] Long, J. R., ‘‘A Narrowband Radio Receiver Front-End for Portable Communications Applications,’’ Ph.D. dissertation, Carleton University, 1996. [5] Mohan, S. S., et al., ‘‘Simple Accurate Expressions for Planar Spiral Inductances,’’ IEEE J. Solid-State Circuits, Vol. 34, Oct. 1999, pp. 1419–1424. [6] Razavi, B., Design of Analog CMOS Integrated Circuits, New York: McGraw-Hill, 2000, Chapters 17 and 18. [7] Danesh, M., et al., ‘‘A Q-Factor Enhancement Technique for MMIC Inductors,’’ Proc. RFIC Symposium, 1998, pp. 183–186. [8] Cheung, D. T. S., J. R. Long, and R. A. Hadaway, ‘‘Monolithic Transformers for Silicon RFIC Design,’’ Proc. BCTM, Sept. 1998, pp. 105–108. [9] Long, J. R., and M. A. Copeland, ‘‘The Modeling, Characterization, and Design of Monolithic Inductors for Silicon RF IC’s,’’ IEEE J. Solid-State Circuits, Vol. 32, March 1997, pp. 357–369. [10] Edelstein, D. C., and J. N. Burghartz, ‘‘Spiral and Solenoidal Inductor Structures on Silicon Using Cu-Damascene Interconnects,’’ Proc. IITC, 1998, pp. 18–20. [11] Hisamoto, D., et al., ‘‘Suspended SOI Structure for Advanced 0.1-�m CMOS RF Devices,’’ IEEE Trans. on Electron Devices, Vol. 45, May 1998, pp. 1039–1046. [12] Yue, C. P., and S. S. Wong, ‘‘On-Chip Spiral Inductors with Patterned Ground Shields for Si-Based RF IC’s,’’ IEEE J. Solid-State Circuits, Vol. 33, May 1998, pp. 743–752. [13] Craninckx, J., and M. S. J. Steyaert, ‘‘A 1.8-GHz Low-Phase-Noise CMOS VCO Using Optimized Hollow Spiral Inductors,’’ IEEE J. Solid-State Circuits, Vol. 32, May 1997, pp. 736–744. [14] Niknejad, A. M., and R. G. Meyer, ‘‘Analysis, Design, and Optimization of Spiral Inductors and Transformers for Si RF IC’s,’’ IEEE J. Solid-State Circuits, Vol. 33, Oct. 1998, pp. 1470–1481. [15] Rogers, J. W. M., J. A. Macedo, and C. Plett, ‘‘A Completely Integrated Receiver Front- End with Monolithic Image Reject Filter and VCO,’’ IEEE RFIC Symposium, June 2000, pp. 143–146. [16] Rogers, J. W. M., et al., ‘‘Post-Processed Cu Inductors with Application to a Completely Integrated 2-GHz VCO,’’ IEEE Trans. on Electron Devices, Vol. 48, June 2001, pp. 1284–1287. [17] Zolfaghari, A., A. Chan, and B. Razavi, ‘‘Stacked Inductors and Transformers in CMOS Technology,’’ IEEE J. Solid-State Circuits, Vol. 36, April 2001, pp. 620–628. [18] Niknejad, A. M., J. L. Tham, and R. G. Meyer, ‘‘Fully-Integrated Low Phase Noise Bipolar Differential VCOs at 2.9 and 4.4 GHz,’’ Proc. European Solid-State Circuits Conference, 1999, pp. 198–201. [19] van Wijnen, P. J., ‘‘On the Characterization and Optimization of High-Speed Silicon Bipolar Transistors,’’ Beaverton, OR: Cascade Microtech, 1995.
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Radio Frequency Integrated Circuit
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Radio Frequency Integrated Circuit
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Contents Foreword xv Acknowledgment
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Contents 3.8 Base Shot Noise Discus
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Contents 5.25 Packaging 135 5.25.1
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Contents 7.12 General Design Commen
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Contents 9.5 Some Simple Image Reje
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Foreword I enjoyed reading this boo
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Foreword estimates of parasitic cap
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xx Radio Frequency Integrated Circu
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2 Radio Frequency Integrated Circui
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2 Issues in RFIC Design, Noise, Lin
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Issues in RFIC Design, Noise, Linea
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The input noise is Issues in RFIC D
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2.5 Filtering Issues Issues in RFIC
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3 A Brief Review of Technology 3.1
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A Brief Review of Technology IC = I
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3.4 Small-Signal Model A Brief Revi
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3.6 High-Frequency Effects A Brief
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A Brief Review of Technology If thi
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A Brief Review of Technology Soluti
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A Brief Review of Technology 3.8 Ba
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A Brief Review of Technology • Pi
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A Brief Review of Technology 3.16,
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A Brief Review of Technology The tr
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4 Impedance Matching 4.1 Introducti
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Impedance Matching Z 2 = Z in + j
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Figure 4.5 A Smith chart. Impedance
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4.3 Impedance Matching Impedance Ma
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Impedance Matching Figure 4.9 Which
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Impedance Matching Figure 4.11 Lowp
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Impedance Matching section, convers
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Impedance Matching Much as in the p
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Impedance Matching Note that dots i
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Impedance Matching Thus, in the fir
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Impedance Matching The exact resist
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Impedance Matching 4.10 Quality Fac
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Impedance Matching Example 4.7 Matc
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190 Radio Frequency Integrated Circ
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Voltage-Controlled Oscillators back
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I C_AVE = 1 Voltage-Controlled Osci
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Voltage-Controlled Oscillators Loop
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Voltage-Controlled Oscillators freq
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Voltage-Controlled Oscillators Figu
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Voltage-Controlled Oscillators from
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Voltage-Controlled Oscillators [10]
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10 Power Amplifiers 10.1 Introducti
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Power Amplifiers where G is the pow
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Power Amplifiers Figure 10.4 Optima
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Power Amplifiers Figure 10.8 Power
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Power Amplifiers Figure 10.9 Curren
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Power Amplifiers The efficiency is
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Power Amplifiers sinusoid), this pe
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Power Amplifiers Note that this agr
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Power Amplifiers stabilization. The
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Power Amplifiers Solution The first
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Power Amplifiers Figure 10.22 Class
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Figure 10.24 Class E waveforms. Pow
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Power Amplifiers B = 0.1836 0.81Q R
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Power Amplifiers Figure 10.25 Initi
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Power Amplifiers added to the funda
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Power Amplifiers 10.8.1 Variation o
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Example 10.4 Class F Power Amplifie
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Figure 10.36 Class H amplifier. Pow
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Power Amplifiers ered quite good. O
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Power Amplifiers Figure 10.39 Time-
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Figure 10.42 High-Q matching circui
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Figure 10.44 Multiple transistors.
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Power Amplifiers Figure 10.48 Combi
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Power Amplifiers have very narrow b
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Power Amplifiers Figure 10.53 Feedf
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Power Amplifiers in class A (input
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About the Authors John Rogers recei
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Index 1-dB compression point, 30-32
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Index Damped resonator, 247-48 Emit
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Index Local oscillator, 5 Mixing co
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Index Quadrature phase shift keying
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