第三届国际无线会议(IWS 2015)技术议程预告

2015-03-17 来源:微波射频网 字号:
周三会议:

WE1A: 低功耗RF收发器(2015年4月1日,星期三)

Room: Song 1
RF Techniques and Wireless Power
Chair: Thomas Ussmueller, University of Innsbruck
Co-Chair: Elvis Mak , U. of Macau
Abstract: The first three papers of this session cover advanced techniques for wireless devices and systems, including compact I/Q imbalance calibration, accurate modeling of RF LDMOSFET, and a wideband inductorless low-noise amplifier. The next two papers present advanced techniques and modeling skills for efficient on-chip wireless power transmission.

WE-1-A-1: A Compact I/Q Imbalance Calibration Technique for Power-Aware Fully-Integrated Receiver without On-Chip Baseband Processor
0820-0840
M. Huang1,2, X. Liang1, J. Guo1,2, D. Chen1,2, 1Sun Yat-sen University, Guangzhou, China, 2SYSU-CMU Shunde International Joint Research Institute, Foshan, China
(117)

WE-1-A-2: An Accurate Parameter Extraction Method for RF LDMOSFET Small-Signal Model
0840-0900
W. N. Song, J. Fu, Y. D. Wang, W. Zhou, W. Zhang, J. Cui, Y. Zhao, G. Q. Li, Z. H. Liu, Institute of Microelectronics, Tsinghua University, Beijing, China
(160)

WE-1-A-3: A 0.1-6 GHz industorless differential common gate LNA
0900-0920
C. Chen, R. Zhang, Z. Li, S. Diao, F. Lin, University of Science and Technology of China, Hefei, China
(170)

WE-1-A-4: Efficient On-Chip Wireless Power Transmission
0920-0940
S. Raju, M. Chan, P. Yue, Hong Kong University of Science and Technology, Hong Kong, Hong Kong
(341)

WE-1-A-5: Modeling of On-Chip Wireless Power Transmission System
0940-1000
S. Raju, . Prawoto, M. Chan, P. Yue, Hong Kong University of Science and Technology, Hong Kong, Hong Kong
(342)

WE1B: 混合信号/ ADC(2015年4月1日,星期三)

Room: Song 3
Signal processing and Power Amplifier
Chair: Franklin Bien, UNIST
Co-Chair: Sai-Weng Sin (Terry), U. of Macau
Abstract: This session includes five papers presented the advances in the signal processing, data conversion, and power amplification.

WE-1-B-1: 14.4-GS/s, 5-bit, 50mW Time-Interleaved ADC with Distributed Track-and-Hold and Sampling Instant Synchronization for ADC-Based SerDes
0820-0840
T. Jiang1, P. Y. Chiang2, 1Qualcomm Inc, Raleigh, United States, 2Fudan University, Shanghai, China
(214)

WE-1-B-2: Phase mismatch study and correction of a parallel FBD sigma delta ADC for SDR receiver
0840-0900
R. Lahouli1,2, M. Ben-Romdhane1, C. Rebai1, D. Dallet2, 1GRESCOM Research Laboratory , Ariana, Tunisia, 2IMS Research Laboratory, Bordeaux, France
(245)

WE-1-B-3: Adaptive Nulling Array Antenna Using a New Variable Step Size LMS-type Algorithm
0900-0920
M. Li, X. Xi, Z. Song, J. Liu, Y. Huang, Xi’an University of Technology, Xi'an, China
(324)

WE-1-B-4: A Design Method for Concurrent Tri-Band Doherty Power Amplifier
0920-0940
F. Costanzo, R. Giofrè, L. Piazzon, M. Deepak Nair, University of Roma Tor Vergata, Roma, Italy
(340)

WE1C: 天线(2015年4月1日,星期三)

Room: Yuan 1/2
Antenna and Measurements for Cellular Systems
Chair: Xiuyin Zhang, South China University of Technology
Co-Chair: Hang Wong, City University
Abstract: The multiple-input-multiple-output (MIMO) antenna is used for mobile phones and the broadband base station antenna array is designed for different frequency band applications, such as: 2G, 3G and 4G bands.

WE-1-C-1: Design of Planar Wideband MIMO Antenna for Mobile Phones
0820-0840
W. Li, Z. Tu, Q. Chu, South China University of Technology, Guangzhou, China
(156)

WE-1-C-2: Measurement-based performance evaluation of a tri-polarized MIMO antenna in a reverberation chamber
0840-0900
D. Piao, P. Chen, L. Yang, Y. Mao, Communication University of China, Beijing, China
(186)

WE-1-C-3: Broadband Stacked F-Probe Patch Antenna and Its Array for Base Station
0900-0920
Y. Jin1, Z. Du2, 1Microwave and Antenna Institute, Beijing, China, 2Microwave and Antenna Institute, Beijing, China
(198)

WE-1-C-4: A Planar Antenna for GPS/WLAN/UWB Applications
0920-0940
Y. Wu, Y. Long, Sun Yat-sen University, Guangzhou, China
(229)

WE-1-C-5: Fractal MA and for in-band RCS Reduction of Array Antennas
0940-1000
S. Li, X. Cao, J. Gao, Y. Zhao, Z. Zhang, Information and Navigation College, Xi’an, China
(233)

WE1D: 毫米波系统(2015年4月1日,星期三)

Room: Yuan 3/4
Millimeter-Wave Circuits & Systems
Chair: Liang Wu, HKUST
Co-Chair: Terry Lai, City University
Abstract: Millimeter-Wave frequencies enable many applications such as short-range, high-data-rate communications. The implementation of both the circuits and systems is very challenging. Papers in this session present some critical building blocks and systems at mm-wave frequencies.

WE-1-D-1: A 340 GHz MMIC 4 Sub-harmonic Mixer Using Silicon-based Schottky Barrier Diodes
0820-0840
C. Liu1,2, Q. Li1, Y. Xiong2, 1University of Electronic Science and Technology of China , Chengdu, China, 2CAEP, China, Chengdu, China
(119)

WE-1-D-2: A D-band Chip-to-Waveguide-Horn (CWH) Antenna with 18.9 dBi Gain Using CMOS Technology
0840-0900
X. Deng1,2, Y. Li2, W. Wu1, Y. Xiong2, 1 Nanjing University of Science and Technology, Nanjing, China, 2CAEP, China, Chengdu, China
(123)

WE-1-D-3: Novel Wideband Orthomode Transducer for 70-95GHz
0900-0920
P. N. Choubey, W. Hong, State Key Laboratory of MMW, Nanjing, China
(253)

WE-1-D-4: Design of a Wide Band and Fundamental Wave Mixer Based on the Novel Broadband Balun
0920-0940
Z. Li1,2, S. Zhang1,2, J. Sun1,2, J. Liu1,2, 1Science and Technology on Electronic Test & Measurement Laboratory , Qingdao, China, 241st Institute of China Electronic Technology Group Corporation, Qingdao, China
(255)

WE-1-D-5: Low Cost W-band Sub-harmonic Mixer Using Quasi-MMIC Technology
0940-1000
Z. Xu, Y. Cui, J. Xu, J. Guo, C. Qian, Southeast University, Nanjing, China
(314)

WE1E: 功率放大器(2015年4月1日,星期三)

Room: Tang 2/3
Wideband Power Amplifiers
Chair: Rui Ma, Mitsubishi Electric
Co-Chair: Nathalie Deltimple, IMS Bordeaux
Abstract: Advanced wideband and efficient fully analog or digital power amplifiers in GaN and CMOS technologies are presented. In addition, DPD technique for linearizing wideband PAs is also reported.

WE-1-E-1: A Fully Analog Two-way Sequential GaN Power Amplifier with 40% Fractional Bandwidth
0820-0840
J. Shao1,2, R. Ma1, K. Teo1, S. Shinjo3, K. Yamanaka3, 1Mitsubishi Electric Research Labs, Cambridge, United States, 2University of North Texas, Denton, United States, 3Mitsubishi Electric Corporation, Kamakura, Japan
(203)

WE-1-E-2: A Ultra-Wideband CMOS PA with Dummy Filling for Reliability
0840-0900
Y. Chang, Y. Ye, C. Domier, Q. J. Gu, University of California, Davis, Davis, United States
(204)

WE-1-E-3: A 3.5-9.5 GHz Compact Digital Power Amplifier with 39.3% Peak PAE in 40nm CMOS Technology
0900-0920
H. J. Qian1, J. O. Liang2, X. Luo1, 1Delft University of Technology, Delft, Netherlands, 2Huawei Technologies Co., Ltd., Shenzhen, China
(208)

WE-1-E-4: Robust and Fast Iterative Algorithm based on Levenberg-Marquardt and Spectral Extrapolation for Wideband Digital Predistortion of RF Power Amplifiers
0920-0940
H. Wang1,2, F. Liu1,2, W. Tao1,2, 1University of Science and Technology of China, Hefei, China, 2Chinese Academy of Sciences, Hefei, China
(240)

WE-1-E-5: Investigation of the Attenuation Characteristics of Radio Signal in Ruins
0940-1000
S. Zhou, K. Liao, J. He, E. Li, Zhejiang University, Hangzhou, China
(174)

WE2A: 低功耗RF收发器(2015年4月1日,星期三)

Room: Song 1
Low-Power Wireless Circuits
Chair: Thomas Ussmueller, University of Innsbruck
Co-Chair: Elvis Mak , U. of Macau
Abstract: The focus of this session is low-power RF circuit design. Different circuit concepts for wireless applications will be presented. The topics in this session include an inductorless wideband (DC to 1.2GHz) low-noise amplifier, a tri-band Wilkinson power divider with high harmonic suppression, a wideband (18 to 21GHz) sub-harmonic receiver front-end, an IR-UWB transmitter for medical imaging, and finally a 5GHz switched power splitter.

WE-2-A-1: A Double Active gm-Boosted-Based Inductorless Differential Wideband Low-Noise Amplifier
1100-1120
R. Zhang, C. Chen, Z. Li, Z. Fu, S. Diao, F. Lin, University of Science and Technology of China, Hefei, China
(169)

WE-2-A-2: A Fully Integrated CMOS IF Module for C-band RF Transceiver
1120-1140
K. Zhang1,3, Z. Li1,3, Z. Wang1,3, G. Yang1,3, T. Sun1,3, 1Southeast University, Nanjing, China, 2Ministry of Education of China, Nanjing, China, 3Southeast University, Wuxu, China
(176)

WE-2-A-3: Design of Wideband Sub-Harmonic Receiver Front-End Using 0.18-um BiCMOS Technology
1140-1200
P. Wang1, T. Wu1, M. Chou1, M. Chen1, Y. Chang1,2, D. Chang2, S. S. Hsu1, 1National Tsing Hua University, Hsinchu, Taiwan, 2National Applied Research Laboratories, Hsinchu, Taiwan
(300)

WE-2-A-4: A Versatile Pulse Rate and Low Power CMOS IR UWB Transmitter for medical Imaging
1200-1220
P. K. Saha, M. N. Karim, Bangladesh University of Engineering and Technology (BUET), Dhaka, Bangladesh
(304)

WE-2-A-5: Design of 5GHz Switched Power Splitter on Organic Flexible Substrate
1220-1240
B. Ravelo1, B. Mirkhaydarov2, G. P. Rigas2,3, M. Shkunov2, S. Swaisaenyakorn4, P. R. Young4, 1Irseem, St Etienne du Rouvray, France, 2Advanced Technology Institute, Guildford, United Kingdom, 3National Physical Laboratory (NPL) , Teddington, United Kingdom, 4School of Engineering and Digital Arts, Canterbury, United Kingdom
(307)

WE2B: 过滤器和输电线路(2015年4月1日,星期三)

Room: Song 3
Passive Structures
Chair: Xiuyin Zhang, South China University of Technology
Co-Chair: Patrick Chiang, Oregon State
Abstract: This session presents passive structures including power dividers, couplers, and filters covering over 1 GHz to 6 GHz. Technologies to be discussed include bulk acoustic resonators (BAR), hairpin resonators, slot resonators, stepped impedance resonators (SIR), and tuning methods.

WE-2-B-1: A Design of Luneberg Lens Using Symmetry Metamaterial Unit Cell
1100-1120
Y. Shi, J. Wang, L. Li, C. Liang, Xidian University, Xi'an, China
(237)

WE-2-B-2: Design and Analysis of a Terahertz Bandpass Filter
1120-1140
J. Zhuang, W. Hong, Z. Hao, State Key Laboratory of Millimeter Waves, Nanjing, China
(266)

WE-2-B-3: Empirical Equation for Carrier Power Dependence of Passive Intermodulation Product
1140-1200
M. Ye1, Y. He1, H. Zhu2, 1Xi'an Jiaotong University, Xi'an, China, 2BXT RF Technologies, Fuzhou, China
(270)

WE-2-B-4: A New Shunt-stub-based Meander Artificial Transmission Line in Miniaturized Microwave Passive Components
1200-1220
Y. Cao, X. Tang, L. Wang, T. Yan, University of Electronic Science and Technology of China, Chengdu, China
(289)

WE-2-B-5: Compact Third-Order Dual-Band Bandpass Filters Using Short-Circuited Stubs Loaded λ4 Resonator
1220-1240
Z. Zhang, Q. Chu, L. Qiu, South China University of Technology, Guangzhou, China
(210)

WE2C: 天线(2015年4月1日,星期三)

Room:Yuan 1/2
Antenna Radiation Properties
Chair: Corbett Rowell, Nazarbayev University
Co-Chair: Ken Mays, Sonnet Software
Abstract: This session covers a range of different antenna and feeding technologies for antenna arrays, unidirectional antennas, and circularly polarized antennas for applications in measurement, array miniaturization, UWB, and WLAN.

WE-2-C-1: Strongly coupled array elements decoupled by Eigen-mode analysis and its affection on radiate property
1100-1120
X. Zhuang1, . Feng1, D. WU1,2, 1State Labs on Information Science and Technology, Beijing, China, 2Chongqing Communication Institute, Chongqing, China
(258)

WE-2-C-2: A Differential-Fed Unidirectional Antenna for Ultra-Wideband Applications
1120-1140
M. Li, K. Luk, City University of Hong Kong, Hong Kong SAR, China
(267)

WE-2-C-3: CPW-fed Wideband Circularly-Polarized Antenna
1140-1200
X. Ren1,1, R. Lian1, H. Zhang1, Y. Yin1, S. Gao2, 1Xidian University, Xi'an, China, 2University of Kent, Canterbury, United Kingdom
(275)

WE-2-C-4: A Broad Band #-Shaped 4-Element Tapered Slot Antenna Array for Measurement Applications
1200-1220
P. Fei1,3, X. Wen1,3, P. Zhang1,3, Y. Jiao4, 1The Second Academy of China Aerospace Science & Industry Corporation (CASIC), Beijing, China, 2Science and Technology on Metrology and Calibration Laboratory, Beijing, China, 3Beijing Institute of Radio Metrology and Measurement, Beijing, China, 4Xidian University, Xi'an, China
(306)

WE-2-C-5: Graph Drawing Based WLAN Indoor Mapping and Localization Using Signal Correlation via Edge Detection
1220-1240
M. Zhou1, Q. Zhang1, Z. Tian1, K. Xu2, F. Qiu1, Q. Wu1, 1Chongqing University of Posts and Telecommunications, Chongqing, China, 2Ericsson, San Jose, United States
(134)

WE2D: 过滤器和输电线路(2015年4月1日,星期三)

Room: Yuan 3/4
Wireless Circuits & Components
Chair: Lu Yan, U. of Macau
Co-Chair: Jianping Guo, Sun Yat-sen University
Abstract: Wireless circuits and components including magnetically coupled resonator, quadrature signal generator and band-pass filters will be discussed in this session. Techniques for impedance matching and integration will be presented.

WE-2-D-1: On-board Detection of SCR System Insufficient and Improper Reductant by Magnetically Coupled Resonators
1100-1120
C. Wang, X. Yuan, J. Zhang, State Key Laboratory of Automobile Dynamic Simulation, Changchun, China
(178)

WE-2-D-2: A 400MHz to 4GHz Image-reject Up Convert Mixer Integrated a Broadband Quadrature Signal Generator
1120-1140
Y. Peng1,1, L. Zhang1,1, Y. Shen2,2, J. Fu2,2, Y. Wang2,2, 1Institute of Microelectronics of Chinese Academy of Sciences, Beijing, China, 2Institute of Microelectronics, Tsinghua University, Beijing, Beijng, China
(246) 

WE-2-D-3: Substrate Integrated Waveguide Dual-Band Bandpass Filter with Complementary Modified Split-Ring Resonators
1140-1200
T. Yan, X. Tang, University of Electronic Science and Technology of China, Chengdu, China
(264)

WE-2-D-4: Miniaturized Differential Bandpass Filter with Improved Common-mode Suppression for Healthcare Facilities
1200-1220
H. Wang, F. Jiang, W. Li, Y. Yang, The 28th Research Institure of China Electronics Technology Group Corporation, Nanjing, China
(318)

WE2E: 功率放大器(2015年4月1日,星期三)

Room: Tang 2/3
Broadband and multi-band PAs
Chair: Nathalie Deltimple, IMS Bordeaux
Co-Chair: Rui Ma, Mitsubishi Electric
Abstract: This session presents linearity and efficiency issues for broadband and multi-band PAs. Modeling and Crest Factor Reduction will also discussed.

WE-2-E-1: Effects of Windowing Based Crest Factor Reduction Technique on Digitally Predistorted PAs for Multicarrier WCDMA
1100-1120
D. Maroor Vikraman1, R. Giofre1, L. Piazzon1, P. Colantonio1, F. M. Ghannouchi2, 1University of Rome, Tor Vergata, Rome, Italy, 2iRadio Lab, University of Calgary, Calgary, Canada
(161)

WE-2-E-2: A Complexity-Reduced Band-Limited Memory Polynomial Behavioral Model for Wideband Power Amplifier
1120-1140
Q. Zhang1,1, Y. Liu1,2, J. Zhou1,1, W. Chen1,3, 1China Academy of Engineering Physics, Mianyang, China, 2University of California, San Diego, United States, 3Tsinghua University, Beijing, China
(185)

WE-2-E-3: Broadband Power Amplifier Linearity Enhancement Under Carrier Aggregated Stimulus Using An Auxiliary Impedance Branch
1140-1200
Y. Hu1, H. Sarbishaei2, S. Boumaiza1, 1University of Waterloo, Waterloo, Canada, 2Skyworks, Ottawa, Canada
(252)

WE-2-E-4: A Nonlinear Filter-based Model for Concurrent Dual-Band Power Amplifiers
1200-1220
C. Wang, X. Zhu, State Key Laboratory of Millimeter Waves, Nanjing, China
(277)

WE-2-E-5: A Broadband High Efficiency Class-F Power Amplifier Design Using GaAs HEMT
1220-1240
J. Lan, J. Zhou, Z. Yu, B. Yang, Southeast University, Nanjing, China
(313)

WE3A: 频率合成器/振荡器(2015年4月1日,星期三)

Room: Song 1
Frequency Synthesis
Chair: Kevin Jun Yin, U. of Macau
Co-Chair: Shawn Hsu, National Tsing Hua University
Abstract: Frequency synthesis techniques are critical for almost all wireless transceivers. This session includes papers on various key building blocks for frequency synthesis including a low-phase-noise CMOS VCO, a CMOS DCO with improved frequency resolution, a frequency tripler MMIC achieving high harmonic rejection ratio, a balanced reflection type HMIC vector modulator as well as a high date-rate PLL-based two-point FM modulator.

WE-3-A-1: A Balanced Reflection Type HMIC Vector Modulator over 34-36GHz Based on Cold State pHEMTs
1340-1400
D. Sun, Y. Fan, J. Xu, S. Jiang, Southeast University, Nanjing, China
(114)

WE-3-A-2: Ultra-Low Phase-Noise VCO for Microwave/MM-Wave Point-to-Point Backhaul Communication
1400-1420
L. Jin1, X. Luo2, 1Huawei Technologies Co., Ltd., Shenzhen, China, 2Delft University of Technology, Delft, Netherlands
(207)

WE-3-A-3: A W Band Balanced Tripler MMIC With Excellent Harmonic Suppression and Low Conversion Loss
1420-1440
K. Han1, T. Liu1, H. He2, J. Zhang1, 1Shanghai Institute of Micro-system and Information Technology, Shanghai, China, 2East China Normal University, Shanghai, China
(234)

WE-3-A-4: A 10 Mb/s Hybrid Two-Point Modulator with Front-End Phase Selection and Dual-Path DCO Modulation
1440-1500
X. Li1, S. Lv1, X. Liu1, N. Xu1, W. Rhee1, W. Jia2, Z. Wang1, 1Tsinghua University, Beijing, China, 2Research Institute of Tsinghua University in Shenzhen, Shenzhen, China
(259)

WE-3-A-5: A High-Resolution Tail-Capacitor Based Tuning Scheme for LC-DCO
1500-1520
Z. Wang, L. He, L. Yang, F. Lin, University of Science and Technology of China, Hefei, China
(327)

WE3B: 过滤器和输电线路(2015年4月1日,星期三)

Room: Song 3
Multiple Band Passive Elements
Chair: Morgan Chen, Huawei
Co-Chair: Xiuyin Zhang, South China University of Technology
Abstract: This session will present passive elements implementing resonant structures that cover multiple bands from below 2 GHz to past 10 GHz to control power across frequencies. Designs to be presented include wide-band filters, a dual-band power divider, and a multiple channel diplexer.

WE-3-B-1: Wideband Bandpass Filter Using Open Stub Loaded Square Ring
1340-1400
C. Tang, X. Lin, Y. Fan, K. Song, D. Li, University of Electronic Science and Technology of China, Chengdu, China
(120)

WE-3-B-2: A New Dual-Band Wilkinson Power Divider
1400-1420
C. Tang, X. Lin, Y. Fan, K. Song, D. Li, University of Electronic Science and Technology of China, Chengdu, China
(121)

WE-3-B-3: Design of Quad-Channel Diplexer Using Short Stub Loaded Resonator
1420-1440
D. Luo, F. Chen, J. Qiu, Q. Chu, South China University of Technology, Guangzhou, China
(159)

WE-3-B-4: A Novel UWB Bandpass Filter Based on Quadruple-mode Resonator
1440-1500
D. Li, Y. Zhang, C. Tang, K. Song, Y. Fan, University of Electronic Science and Technology of China(UESTC), Chengdu, China
(128)

WE-3-B-5: Millimeter-Wave 4:1 Transformer-based Balun Design for CMOS RF IC’s
1500-1520
L. Jing1, A. Li1, D. Luo1, C. R. Rowell2, C. P. Yue1, 1Hong Kong University of Science and Technology, Hong Kong, Hong Kong, 2Nazarbayev University, Astana, Kazakhstan
(124)

WE3C: 雷达系统(2015年4月1日,星期三)

Room: Yuan 1/2
Radar Systems and Signal Processing
Chair: Dr. Randolf Ebelt, FAU
Co-Chair: Corbett Rowell, Nazarbayev University
Abstract: The session starts with a discussion of a complete multichannel L Band Radar. We will continue with a method to improve accuracy of RCS calculations, a novel MIMO algorithm for target localization and a combination of ODFM based radar sensing and communication. The session ends with a low complexity particle filtering method for primary user tracking.

WE-3-C-1: Solutions of Broadband RCS Using the Characteristic Basis Function Method
1340-1400
M. Zhang1, Q. Zheng1, Y. Sun1, Z. Wang2,2, G. Wang1, C. Li1, 1Anhui University, Hefei, China, 2Anhui University of Science and Technology, Huainan, China
(239)

WE-3-C-2: Polarized Modulation Scheme for Mobile Satellite MIMO Broadcasting
1400-1420
B. Zuo1, K. Zhao1, W. Li1, N. Zhang1,2, 1Nanjing University, Nanjing, China, 2Harbin Institute of Technology, Harbin, China
(279)

WE-3-C-3: 4-D Parameter Estimation in Bistatic MIMO Radar for Near-Field Target Localization
1420-1440
E. Zhou, H. Jiang, H. Qi, Jilin University, Changchun, China
(297)

WE-3-C-4: Delay and Doppler Shift Estimation for OFDM-Based Radar-Radio (RadCom) System
1440-1500
J. Gu, J. Moghaddasi, K. Wu, Polytechnique of Montreal, Montreal, Canada
(333)

WE3D: IC电源管理(2015年4月1日,星期三)

Room: Yuan 3/4
Wireless Sensing & Energy Harvesting
Chair: Jianping Guo , Sun Yat-sen University
Co-Chair: Lu Yan, U. of Macau
Abstract: Wireless power transfer and visible light communication for wireless sensing & energy harvesting will be discussed in this session. Analyses and designs on the coil and low power rectification circuit for wireless power transfer, and link budget analysis for visible light communication systems will be presented.

WE-3-D-1: A Study of Three-Coil Magnetically Coupled Resonators for Wireless Power Transfer
1340-1400
J. Zhang, X. Yuan, C. Wang, Jilin Univ., Changchun, China
(162)

WE-3-D-2: Analyses and Experiments of Field-circuit Coupling Equations for Wireless Power Transfer Using Solenoidal Coils
1400-1420
X. Song1,2, G. Liu1, Y. Li1, C. Zhang1, X. Xu3, 1Institute of Electrical Engineering, Chinese Academy of Sciences, Beijing, China, 2University of Chinese Academy of Sciences, Beijing, China, 3Institute of Microelectronics, Chinese Academy of Sciences, Beijing, China
(262)

WE-3-D-3: A Double-sided Rectenna Design for RF Energy Harvesting
1420-1440
J. Zhang, Z. Wu, C. Liu, B. Zhang, B. Zhang, Wuhan University of Technology, Wuhan, China
(311)

WE-3-D-4: Link Budget Analysis for Visible Light Communication Systems
1440-1500
B. Hussain, F. Che, C. P. Yue, L. Wu, The Hong Kong University of Science and Technology, Hong Kong, Hong Kong
(332)

WE-3-D-5: Reactive Nonlinearity for Low Power Rectification
1500-1520
S. Hemour, K. Wu, Poly-Grames Research Center, Montreal, Canada
(338)

WE3E: 功率放大器(2015年4月1日,星期三)

Room:Tang 2/3
Wireless Circuits & Components
Chair: Lu Yan, U. of Macau
Co-Chair: Jianping Guo, Sun Yat-sen University
Abstract: Wireless circuits and components including magnetically coupled resonator, power amplifier, quadrature signal generator and band-pass filters will be discussed in this session. Techniques for impedance matching and integration will be presented.

WE-3-E-1: 8GSps 6bit DAC in 0.18um SiGe Technology
1340-1400
W. Li1, L. Zhou2, D. Xue1, D. Wu2, F. Jiang1, J. Wu2, Q. Yang1, S. Yu1, 1Wuhan Research Institute of Post & Telecommunication, Wuhan, China, 2Institute of Microelectronics of Chinese Academy of Sciences, Beijing, China
(256)

WE-3-E-2: A High Efficiency, 40dBm, 728-768 MHz MMIC Doherty Power Amplifier using Low-Voltage GaAs HBT Technology for LTE and Active Antenna System Applications
1400-1420
A. Aktug, A. Degirmenci, S. Sayginer, Aselsan Inc., Ankara, Turkey
(265)

WE-3-E-3: A 2 to 92 GHz Distributed Amplifier Using 70-nm InP HEMTs
1420-1440
Y. Li1,2, W. Goh1, Y. Xiong2, 1Nanyang Technologial University, Singapore, Singapore, 2CAEP, China, Chengdu, China
(179)

WE-3-E-4: A 3-to-7GHz wideband LNA with IIP3 of -2dBm and 0.5dB in-band gain ripple
1440-1500
H. Cruz, S. Lee, C. Luo, National Cheng Kung University, Tainan, Taiwan
(331)

(注:以上演讲人和议题为拟定安排,最终日程安排以会议当天实际议程为准。)

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