Radio Frequency Integrated Circuit Design - Webs

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Impedance Matching without the need to generate a list of S parameters. However, it is worthwhile to be familiar with these design techniques, since they can give insight into circuit design, which can be of much more value than simply knowing the location of the ‘‘simulate’’ button. References [1] Krauss, H. L., C. W. Bostian, and F. H. Raab, Solid State Radio Engineering, New York: John Wiley & Sons, 1980. [2] Smith, J. R., Modern Communication Circuits, 2nd ed., New York: McGraw-Hill, 1998. [3] Irwin, J. D., Basic Engineering Circuit Analysis, New York: Macmillan Publishing Company, 1993. [4] Sadiku, M. N. O., Elements of Electromagnetics, 2nd ed., Fort Worth, TX: Sanders College Publishing, 1994. [5] Razavi, B., ‘‘A Study of Phase Noise in CMOS Oscillators,’’ IEEE J. Solid-State Circuits, Vol. 31, March 1996, pp. 331–343. [6] Pozar, D. M., Microwave Engineering, 2nd ed., New York: John Wiley & Sons, 1998. 93
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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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Page 64 and 65: 3 A Brief Review of Technology 3.1
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Page 68 and 69: 3.4 Small-Signal Model A Brief Revi
Page 70 and 71: 3.6 High-Frequency Effects A Brief
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Page 74 and 75: A Brief Review of Technology Soluti
Page 76 and 77: A Brief Review of Technology 3.8 Ba
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Page 80 and 81: A Brief Review of Technology 3.16,
Page 82 and 83: A Brief Review of Technology The tr
Page 84 and 85: 4 Impedance Matching 4.1 Introducti
Page 86 and 87: Impedance Matching Z 2 = Z in + j
Page 88 and 89: Figure 4.5 A Smith chart. Impedance
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Page 92 and 93: Impedance Matching Figure 4.9 Which
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Page 102 and 103: Impedance Matching Thus, in the fir
Page 104 and 105: Impedance Matching The exact resist
Page 106 and 107: Impedance Matching 4.10 Quality Fac
Page 108 and 109: Impedance Matching Example 4.7 Matc
Page 110 and 111: Impedance Matching line to change w
Page 112 and 113: Impedance Matching S22 = b 2 a2 | a
Page 116 and 117: 5 The Use and Design of Passive Cir
Page 118 and 119: The Use and Design of Passive Circu
Page 162 and 163: 6 LNA Design 6.1 Introduction and B
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LNA Design Figure 6.3 C� is repla
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f T = LNA Design 1 2�(C� + C�
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LNA Design Figure 6.5 Small-signal
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LNA Design output impedance. Thus,
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LNA Design At low frequencies, this
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LNA Design The gain of either ampli
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A v = v o vi = LNA Design R L R F
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LNA Design Z� A v = (−g m R L )
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LNA Design Figure 6.14 Sample plots
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LNA Design i 2 on_tot = i 2 n Z 2
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Bopt = LNA Design − v T (�C�
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LNA Design 165 inductor is increase
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LNA Design Figure 6.18 Minimum nois
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LNA Design Finally, the noise figur
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LNA Design 6.3.6 Noise in the Commo
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LNA Design Extracting only the smal
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LNA Design In the special case wher
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LNA Design Figure 6.26 Plot of fund
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LNA Design Results are shown in Tab
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LNA Design where VA is the Early vo
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LNA Design Figure 6.31 Illustration
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LNA Design 6.33(a) [5]. With the us
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LNA Design Figure 6.35 Redrawn tran
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LNA Design With any of these mirror
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R E = re� v IP3 2vT� 2/3 LNA De
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LNA Design Figure 6.38 Simulated vo
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LNA Design [5] Ray, B., et al., ‘
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7 Mixers 7.1 Introduction The purpo
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Mixers Figure 7.2 Transconductance
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Mixers Figure 7.4 Double-balanced m
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Mixers so that for half the cycle Q
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Mixers 7.5(b). If the capacitance o
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Mixers Figure 7.8 Downconversion fr
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Mixers Figure 7.9 Mixer noise shown
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Figure 7.11 Mixer with switching. v
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Mixers Figure 7.13 Mixer for noise
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7.8 Linearity Mixers Mixers have bo
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Mixers Figure 7.16 Mixer with nonli
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Mixers Figure 7.20 Sidebands in upc
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Mixers Figure 7.24 RC networks to p
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Polyphase Filters Mixers A multista
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Mixers V2 = 1 2 cos [(� LO −
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Mixers Figure 7.28 Plot of image re
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Figure 7.30 The Moore mixer. Figure
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Mixers Figure 7.33 Mixer with folde
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Mixers 233 will move dc output volt
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Mixers Figure 7.34 Mixer with folde
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Mixers These two noise sources are
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Mixers make this one a second-order
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Mixers Table 7.5 Image Rejection fo
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Mixers Figure 7.37 Single-balanced
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8 Voltage-Controlled Oscillators 8.
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8.3 The LC Resonator Voltage-Contro
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Voltage-Controlled Oscillators Figu
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Voltage-Controlled Oscillators osci
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Voltage-Controlled Oscillators tion
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Voltage-Controlled Oscillators This
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Voltage-Controlled Oscillators C pa
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neg = Voltage-Controlled Oscillator
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Figure 8.20 Circuit for oscillator
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Voltage-Controlled Oscillators Q. I
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Voltage-Controlled Oscillators osci
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Voltage-Controlled Oscillators V ta
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Figure 8.34 Phase noise versus freq
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Voltage-Controlled Oscillators wher
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Voltage-Controlled Oscillators nois
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Voltage-Controlled Oscillators swin
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Voltage-Controlled Oscillators We w
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304 Radio Frequency Integrated Circ
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9 High-Frequency Filter Circuits 9.
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9.3 Integrated RF Filters High-Freq
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High-Frequency Filter Circuits Figu
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as High-Frequency Filter Circuits 3
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High-Frequency Filter Circuits 9.4
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High-Frequency Filter Circuits If t
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High-Frequency Filter Circuits wher
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High-Frequency Filter Circuits can
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High-Frequency Filter Circuits LNA.
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High-Frequency Filter Circuits a ca
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High-Frequency Filter Circuits and
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High-Frequency Filter Circuits insi
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High-Frequency Filter Circuits [2]
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