IEEE MTT-V053-I03A (2005-03)

010 - 01406269......Page 1
020 - 10.1109@TMTT.2005.845850......Page 3
030 - 10.1109@TMTT.2004.842512......Page 4
I. I NTRODUCTION......Page 7
A. Mode Spectrum of NRD-Guide and $H$ -Guide......Page 8
B. Spectral Dyadic Green's Function and Volume-Integral Equation......Page 9
C. Current Discretization and System Matrix Structure......Page 10
D. Analytical Evaluation in Space-Domain Integrations and ${ m}=......Page 12
A. NRD-Guide Open Ends......Page 13
Fig. 5. Frequency characteristics of the phase of ${ S} _{11}$ f......Page 14
C. NRD-Guide Resonators......Page 15
Fig.€11. Resonant frequency characteristics of an inhomogeneous......Page 16
IV. C ONCLUSION......Page 17
C. D. Nallo, F. Frezza, and A. Galli, Full-wave modal analysis o......Page 19
I. I NTRODUCTION......Page 21
Fig.€1. (a) Schematic of the popular source inductor feedback am......Page 22
B. Design Procedure of the Source-Inductor-Feedback LNA......Page 24
Fig.€4. Calculated $K_c$ versus $ R/P$ characteristics of modern......Page 25
Fig.€6. Flowchart of the design procedures for finding optimized......Page 26
Fig.€9. Detailed process flows of silicon substrate thinning.......Page 27
Fig.€11. (a) Measured and simulated quality factors versus frequ......Page 28
Fig. 13. Measured transducer gain ( ${ S}_{21}$ ) versus frequen......Page 29
D ERIVATION OF THE NF FOR AN FET W ITH G ATE AND S OURCE I NDUCT......Page 30
D. Melendy, P. Francis, C. Pichler, K. Hwang, G. Srinivasan, and......Page 31
Fig.€1. Generic schematic of optimum single-ended dual-fed distr......Page 33
II. E FFECT OF FET I NPUT AND O UTPUT C APACITANCE ON THE SE DFD......Page 34
IV. A MPLIFIER D ESIGN......Page 35
Fig. 5. Embedded simulated ${s}$ -parameters of the 50- $\Omega$......Page 36
Fig.€9. Measured load power versus frequency.......Page 37
M. R. Moazzam and C. S. Aitchison, High gain microwave amplifier......Page 38
C. Cammacho-Penalosa and C. S. Aitchison, Modeling frequency dep......Page 39
I. I NTRODUCTION......Page 40
II. W EIGHTED T WO -D IMENSIONAL (2-D) FDTD F ORMULATION......Page 41
Fig.€2. Numerical dispersion of the AOM optimized at 10 CPW and......Page 42
Fig.€4. Numerical dispersion of the DOM optimized at 10 CPW and......Page 43
A. Optimal Parameter......Page 44
D. Relative RMS Error Comparison......Page 45
F. Three-Dimensional (3-D) Case......Page 46
G. CM Techniques......Page 47
Fig.€10. Numerical dispersion of the HAM-FW method, HAM-S method......Page 48
G. Sun and C. W. Trueman, Quantification of the truncation error......Page 49
II. C ROSS -C OUPLED $E$ -P LANE F ILTERS......Page 51
Fig. 3. Coupling coefficient values versus: (a) iris width $({l}......Page 52
TABLE I D ATA FOR $Ka$ -B AND C ROSS -C OUPLED F OLDED $E$ -P LA......Page 53
C. Four-Resonator Cross-Coupled Filter With Asymmetric Response......Page 54
Fig.€12. Calculated (dashed line) and measured (solid line) resp......Page 55
Fig.€15. (a) Response of a direct-coupled $E$ -plane filter with......Page 56
IV. M ILLIMETER -W AVE D IPLEXER......Page 57
A. E. Williams, A four-cavity elliptic waveguide filter, IEEE Tr......Page 58
Y. Rong, H. Yao, K. A. Zaki, and T. Dolan, Millimeter-wave $Ka$......Page 59
Fig.€1. Schematic diagram of the classical Doherty amplifier.......Page 60
A. Principle of Operation......Page 61
B. Efficiency Calculation......Page 62
Fig.€5. Fundamental current as a function of conduction angle $(......Page 63
Fig.€9. Comparison of PAE measurement results of the three-stage......Page 64
Fig. 13. Bias voltage adjustment of peak amplifier #2 with incre......Page 65
Y. Yang, J. Yi, Y. Y. Woo, and B. Kim, Optimum design for linear......Page 66
S. C. Cripps, RF Power Amplifiers for Wireless Communications .......Page 67
Fig.€2. Dual-mode ring resonator topology using shunt-capacitanc......Page 69
B. Odd-Mode Analysis......Page 70
III. F ILTER A NALYSIS......Page 71
IV. D ISCUSSIONS ON V ARIOUS T YPES OF D UAL -M ODE R INGS......Page 72
TABLE II D ESIGN P ARAMETERS FOR R INGS A AND B......Page 73
Fig.€12. (a) Frequency response of varactor-tuned filter at vari......Page 74
M. Makimoto and M. Sagawa, Varactor tuned bandpass filters using......Page 75
A. Radial Electric-Current Loop in Free Space......Page 76
III. E LECTRIC -F IELD C OMPONENTS D UE TO A D ISK OF R ADIAL C......Page 77
IV. N UMERICAL S OLUTION OF A T OP -L OADED C OAXIAL T RANSITION......Page 78
Fig.€4. Input impedance as a function of frequency for a coaxial......Page 79
VI. C ONCLUSIONS......Page 80
M. Sierra-Pérez, M. Vera, A. G. Pino, and M. Sierra-Castañer, An......Page 81
II. L INEARIZATION P RINCIPLE......Page 82
A. Amplifier Modeling......Page 83
IV. G ENERAL C RITERIA FOR D IMENSIONING THE L INEARIZER......Page 84
V. E VALUATION OF D ISTORTION F ROM THE LD AND B UFFER......Page 85
VI. E XPERIMENTAL V ALIDATION......Page 86
F. H. Raab, P. Asbeck, S. Cripps, P. B. Kenington, Z. B. Popovic......Page 87
C. G. Rey, Adaptive polar work-function predistortion, IEEE Tran......Page 88
II. C-C OLPITTS O SCILLATOR T OPOLOGY AND O NE -P ORT A NALYSIS......Page 89
Fig. 3. $\vert G_{r} (\omega_{n})/G_{m0}\vert$ over $\omega_{n}$......Page 90
III. P HASE N OISE IN THE P ROPOSED C-C OLPITTS O SCILLATOR......Page 91
Fig. 9. Measurement results. (a) $L_{\rm tank} = 10$ nH, $C_{g}......Page 93
TABLE III M EASUREMENT R ESULTS OF THE P ROPOSED C-C OLPITTS VCO......Page 94
P. Kinget, A fully integrated 2.7 V 0.35 $\mu$ m CMOS VCO for 5......Page 95
II. D ESIGN S TRATEGY......Page 96
Fig.€1. Single-mode equivalent circuits for the principal polari......Page 97
III. R ESULTS......Page 98
Fig.€7. Phase difference between the transmission coefficients f......Page 99
IV. C ONCLUSION......Page 100
R. Tascone, R. Orta, M. Baralis, A. Olivieri, and O. Peverini, C......Page 101
A. CMRC Filter......Page 103
B. T-Shaped Patches......Page 104
B. ACMRC BPF......Page 105
C. CPW-Fed BPF......Page 106
Q. Xue, K. M. Shum, and C. H. Chan, Low conversion loss fourth-s......Page 107
1) Low-Frequency Noise Sources Near DC:......Page 109
2) Noise Sources and Noisy Output Signal [ 4 ]: Any physical cir......Page 110
IV. N UMERICAL S IMULATION OF A B IPOLAR T RANSISTOR O SCILLATOR......Page 111
V. C ONCLUSION......Page 112
Phase-Noise Calculation......Page 113
J. C. Nallatamby, M. Prigent, M. Camiade, and J. Obregon, Phase......Page 114
A. Identification of PCB Discontinuities in the Wavelet Domain......Page 115
Fig.€1. Discretization of the PCB in the wavelet domain.......Page 116
B. Adopted Full-Wave Model......Page 117
D. Inclusion of the Two-Port Equivalent Into a Quasi-TEM TL Mode......Page 118
Fig.€3. Right-angle-bend geometry in a microstrip line.......Page 119
A. Validation of the Identification Process for a Right-Angle-Be......Page 120
B. Inclusion of the Discontinuity Model Into a Quasi-TEM Model......Page 121
C. Validation of the Methodology Through Comparison With Measure......Page 122
Fig.€12. Time-domain waveforms of the: (a) transmitted power wav......Page 123
E. Choice of the Basis......Page 124
P. Kok and D. De Zutter, Capacitance of a circular symmetric mod......Page 125
J. R. Phillips, L. Daniel, and L. M. Silveira, Guaranteed passiv......Page 126
II. D IRECT P ARAMETER E XTRACTION......Page 127
A. Emitter, Base, and Collector Resistances......Page 128
C. Base Emitter and Base Collector Capacitances......Page 129
Fig. 6. Measured (triangles) and calculated (dashed line) ${ C}_......Page 130
D. Transport Factor......Page 131
III. H IGH -F REQUENCY N OISE M ODELING......Page 132
Fig.€13. Measured and simulated: (a) minimum noise figure, (b) m......Page 133
Fig.€15. Simplified layout of the transistor and equivalent circ......Page 134
Fig.€17. Noise figure versus temperature plot for a constant bas......Page 135
J. M. O'Callaghan and J. P. Mondal, A vector approach for noise......Page 136
Fig.€2. Block diagram of the dual-loop OEO.......Page 137
Fig.€4. Experimental data for the oscillator output taken from a......Page 138
B. Phase-Noise Measurement......Page 139
D. B. Sullivan, D. W. Allan, D. A. Howe, and F. L. Walls, Eds.,......Page 140
W. F. Walls, Cross-correlation phase noise measurements, in Proc......Page 141
II. M EASUREMENT S ETUP......Page 142
IV. R ESULTS: A MPLITUDE AND P HASE I MBALANCE......Page 143
Fig.€7. Mode conversion dependent on phase error.......Page 144
C. R. Curry, How to calibrate through balun transformers to accu......Page 145
Fig.€1. Planar transmission-line network with deembedding arms a......Page 146
A. Application of the Lorentz Reciprocity Theorem to the Deembed......Page 147
B. Procedure for Extracting Scattering Parameters From the Ortho......Page 148
Fig.€4. Positions of two probe arms with respect to the deembedd......Page 149
III. D ISCUSSION OF P ERFORMANCE......Page 150
Fig. 6. End conductance of a $w/h = 1.79$ and $\epsilon _{r} = 2......Page 151
Fig.€9. Attenuation constant of a lossless microstrip with $\eps......Page 152
J. Martel, R. R. Boix, and M. Horno, Static analysis of microstr......Page 153
E. Drake, R. R. Boix, M. Horno, and T. K. Sarkar, Comparison amo......Page 154
II. A NALYSIS OF C OUPLED S PIRAL R ESONATORS......Page 155
Fig.€3. (a) Coupling coefficient $k$ as a function of coupling g......Page 156
TABLE€I N ORMALIZED C OUPLING M ATRIX FOR THE F OUR -P OLE F IL......Page 157
IV. E XPERIMENTAL P ERFORMANCE......Page 158
EM User's Manual, Version 8.0, Sonnet Software Inc., North Syrac......Page 159
II. LNB T ASKS......Page 160
IV. D OWN -C ONVERTER......Page 161
B. Proposed VCO......Page 162
A. Conventional Divide-by-Two Prescaler......Page 163
Fig.€12. Cross section of the technology adopted.......Page 164
VIII. E XPERIMENTAL R ESULTS......Page 165
TABLE€II IC P ERFORMANCE S UMMARY......Page 166
R. G. Meyer and A. K. Wong, Blocking and desensitization in RF a......Page 167
I. I NTRODUCTION......Page 168
III. B ROYDEN -B ASED D IRECT SM......Page 169
V. C OMPARISON B ETWEEN B ROYDEN, NISM, AND LISM......Page 170
Fig.€3. Results after applying Broyden-based direct SM optimizat......Page 171
Fig.€6. Fine model minimax objective function values at each ite......Page 172
VII. CMOS D RIVERS FOR A L ONG M ICROSTRIP L INE......Page 173
Fig.€14. Fine model minimax objective function values at each LI......Page 174
B. Razavi, Design of Analog CMOS Integrated Circuits . New York:......Page 175
II. T IME -D OMAIN M ODELING W ITH L UMPED -E LEMENT D EVICES OF......Page 177
III. N EGATIVE -F EEDBACK -B ASED F OURIER -T RANSFORM M ETHOD......Page 178
IV. H ILBERT -T RANSFORM -B ASED F OURIER -T RANSFORM M ETHOD......Page 179
A. Triangular Pulse......Page 180
B. Rectangular Pulse......Page 181
Fig.€10. Time-domain waveforms and their spectra extracted with......Page 182
VI. E RROR AND C ONVERGENCE T EST......Page 183
K. Murakami, S. Hontsu, and J. Ishii, Transient analysis of a cl......Page 184
II. T HEORY......Page 185
A. LNA/180 $^{\circ}$ -bit Design......Page 186
Fig.€6. Simulated insertion and return losses at different analo......Page 187
IV. P HYSICAL D ESIGN......Page 188
Fig. 12. Measured output return loss $(S_{22})$ from 11 to 12 GH......Page 189
VI. C ONCLUSION......Page 190
J.-S. Rieh, D. Greenberg, M. Khater, K. T. Schonenberg, S.-J. Je......Page 191
II. S INGULAR E LEMENTS......Page 192
B. Singular Vector Bases......Page 193
Fig.€2. Effects of material property and wedge angle on the sing......Page 194
A. Rectangular Slit Waveguide......Page 195
Fig.€4. Electric field of the first mode along the slit in Fig.€......Page 196
D. Microstrip Transmission Line......Page 197
A. Definition of the Interpolation Operators......Page 198
b) Proof of (13): Equation (10) implies $$ \int_{\Delta}\nabla \......Page 199
L. Vardapetyan, $hp$ -adaptive finite element method for electro......Page 200
I. I NTRODUCTION......Page 201
II. 2-D NUFFT A LGORITHM......Page 202
III. I NCORPORATING THE 2-D NUFFT I NTO THE SDA......Page 203
Fig.€4. Measured and calculated $S$ -parameters of the hairpin r......Page 204
Fig.€7. Measured and calculated $S$ -parameters of the interdigi......Page 205
W. Menzel, L. Zhu, K. Wu, and F. Bögelsack, On the design of nov......Page 206
Website......Page 208
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