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Research Center for RF & Photonic Information Processing

College of Information Science and Electronic Engineering at Zhejiang University

Research Highlights

Research topic: Multiplexed Millimeter Wave Communication with Dual Orbital Angular Momentum (OAM) Mode Antennas


Communications using the orbital angular momentum (OAM) of radio waves have attracted much attention in recent years. In this paper, a novel millimeter-wave dual OAM mode antenna is cleverly designed, using which a 60GHz wireless communication link with two separate OAM channels is experimentally demonstrated. The main body of the dual OAM antenna is a traveling-wave ring resonator using two feeding ports fed by a 90° hybrid coupler. A parabolic reflector is used to focus the beams… Read more

Research topic: The Capacity Gain of Orbital Angular Momentum Based Multiple-Input-Multiple-Output System


In this work, we compare the technique of using uniform linear array consist of circular traveling-wave OAM antennas for multiplexing with the conventional multiple-in-multiple-out (MIMO) communication method, and numerical results show that the OAM based MIMO system can increase channel capacity while communication distance is long enough.Our results reveal that OAM waves are complementary with MIMO method. OAM waves multiplexing is suitable for long-distance line-of- sight (LoS) communications or communications in open area where the multi-path effect is weak and can be used in massive MIMO systems as well. Read more

Latest News

  • 2016.10.06: Another POSTDEADLINE paper on ‘260Gbit/s Photonic-Wireless Link in the THz Band’is accepted to present at the IEEE Photonics Conference (IPC), which is held in Hawaii, USA. This work is collaborated among NETLAB and KTH in Sweden, DTU in Denmark, Tianjin University and Zhejiang University in China. Up to now, we have successfully demonstrated the record datarates of 60Gbit/s, 160Gbit/s and 260Gbit/s in the 300-500GHz band.
  • 2016.09.30: Dr. Yu gave an invited talk ‘Exploring THz frequency bands for high speed wireless communications’ at the 41st International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz) conference held in Copenhagen, Denmark. In the talk, he reviewed the state-of-the-art work about high speed millimeter-wave/THz communication.
  • 2016.07.05: One paper entitled ‘THz Photonics-Wireless Transmission of 160Gbit/s Bitrate’ is accepted as a POSTDEADLINE paper at the 21st Opto Electronics and Communications Conference/International Conference on Photonics in Switching 2016 (OECC/PS 2016), which is held this year in July 2016, Niigata, Japan. This work is conducted by Dr. Yu from the RPIP, in close collaboration with Technical University of Denmark and Tianjin University.
  • 2016.05.21: Prof. Xianmin ZHANG, Associate Prof. Shilie ZHENG and 2 Ph.D. students attended the IEEE International Microwave Symposium (IMS). The 2016 IEEE International Microwave Symposium (IMS2016) to be held in San Francisco, California, 22-27 May 2016. IMS2016, organized by the IEEE Microwave Theory and Technique Society (MTT-S), is the premier conference for attendees to learn about the latest information in the RF and microwave industry.

Faculty

Xianmin ZHANG, Professor

Professor Xianmin Zhang received his BS and PhD degrees in physical electronics and optoelectronics from Zhejiang University, Hangzhou, China, in 1987 and 1992, respectively.

He was appointed as an associate professor of information and electronic engineering at Zhejiang University in 1994 and full professor in 1999. He was a Research Fellow with the University of Tokyo, Tokyo, Japan, and Hokkaido University, Sapporo, Japan, from November 1996 to September 1997, and October 1997 to September 1998, respectively. In 2007, he spent two months with the Research Laboratory of Electronics, Massachusetts Institute of Technology, Cambridge, MA, USA, as a Visiting Research Fellow. He is currently the Chair of the Department of Information Science & Electronic Engineering, Zhejiang University. His research interests include microwave photonics, optic fiber, and optic communication.

Research areas: Microwave photonics, Radio over fiber

Contact Phone: +86 571 87952373

E-mail: zhangxm@zju.edu.cn

Dongxiao YANG, Professor

Dongxiao Yang received the B.S., M.S., and Ph.D. degrees in physical electronics and optoelectronics from Zhejiang University, Hangzhou, China, in 1983, 1986 and 1994, respectively. In August 1986, he joined the Department of Information Science and Electronic Engineering, Zhejiang University, and was promoted to an associate professor and a professor in 1996 and 2001, respectively.

Prof. Yang is Associate Chair of Department of Information Science and Electronic Engineering, Zhejiang University. He is vice director of the Chinese Institute of Electronics on Vacuum Electronics Society, and is a member of Electronic Science and Technology Steering Committee for Chinese Higher Education. From August 1990 to October 1993, Mr. Yang was a jointly trained PhD student, the Institute of High Frequency Technique at Aachen Technical University (Institut fuer Hoch Frequenz Technik der RWTH Aachen), Aachen, Germany.

From December 1994 to July 1997, Dr. Yang was a postdoctoral fellow in Electronics and Communication at Zhejiang University. From March 1999 to February 2000, from August 2000 to July 2001, and from October 2002 to January 2003, Dr. Yang joined the Institute of Textiles and Clothing at the Hong Kong Polytechnic University as a research scientist.

Prof. Yang is the author of over 70 scientific journal and conference articles, United States Patent 7027699 titled Optical Fiber and Optical Fiber Sensors issued April 11, 2006, and four books (“Fundamentals of Photonics”, “Basic Physics of Information Electronics”, “Physics for Contemporary Information Electronics” and “Smart Fibres, Fabrics and Clothing”) which were published by Zhejiang University Press (Hangzhou, China), Woodhead Publishing Limited (Cambridge, England) and CRC Press (New York, USA). His research interests include terahertz science and technology, fiber optic sensing, and fiber optic communication. Currently, Prof. Yang is a principal investigator of on-going national project which are supported by National Science Foundation of China (NSFC).

Research areas: Terahertz Technology, Fiber Optic Communication and Sensing Technology

E-mail: yangdx@zju.edu.cn

Xiaofeng JIN, Professor

Prof. Xiaofeng Jin was born in September 1968 in Zhejiang, China. He received the Ph.D. degree in Optical Instrumentation from Zhejiang University in 1996, the Master of Engineering degree in Underwater Acousto-electronics Engineering from China Ship Building Institute in 1993, and a B.S. in Optical Engineering from Huazhong University of Science and Technology in 1990. He was appointed as an associate professor with the Department of Information & Electronic Engineering of Zhejiang University in 1999 and promoted as a full professor in 2006.

Research areas: Millimeter wave/microwave photonics, Photonic circuits and smart sensing systems

E-mail: jinxf00@zju.edu.cn

Hao CHI, Professor

His research interests are optical communication and network, microwave photonics, photonic signal processing etc.

Research areas: Optical communication and network, Microwave photonics, Photonic signal processing

Contact Phone: +86 571 87953871
E-mail: chihao@zju.edu.cn

Shilie ZHENG, Professor

Shilie Zheng received her B.S. and M.S. degrees in materials science from Zhejiang University, China, in 1995 and 1998 and received her PhD degree in physical electronics and optoelectronics from the same University in 2003. In 1998, she joined the faculty of Information Science & Electronic Engineering, Zhejiang University, where she was appointed as an associated professor in 2005. She worked as a research associate in Tohuku University from December, 2005 to April, 2006.

Dr. Zheng is the author or co-author of over 30 peer-reviewed scientific papers. Currently her research interests include human area network communication, radio over fiber links, FBG based devices and fiber optical communication systems.

Research areas: Microwave photonics, Human area network communication, Optical communication and optical devices

E-mail: zhengsl@zju.edu.cn

Xianbin YU,Research Professor

Xianbin Yu is a research professor in the College of Information Science and Electronic Engineering at Zhejiang University. He received  his Ph.D degree in 2005 from Zhejiang University in China. From 2005 to 2007, he was a postdoctoral research fellow in Tsinghua University, China. Since 2007 until 2016, he was employed at DTU Fotonik of the Technical University of Denmark in Denmark, where he became an assistant professor in 2009 and was promoted to be a Senior Researcher in 2013. His research interests are in the areas of ultrafast millimeter-wave/THz photonic information processing, ultrahigh frequency photonic wireless communication systems and emerging new applications of millimeter-wave/THz technology, etc.

He has given 20+ invited talks in prestigious international conferences within the area of communications, and has (co-)authored 2 book chapters and 150+ peer-reviewed international journal and conference papers. He held a Marie Curie Fellowship within the 7th European Community Framework Program.

Research areas: Ultrafast RF photonic signal processing, Millimeter-wave/THz photonic wireless communications, Photonics-enabled millimeter-wave/THz imaging

E-mail: xyu@zju.edu.cn

Postdocs

Shi Jia

Shi Jia

Postdoc

 

Dr. Shi Jia

Dr. Jia is currently working as a postdoc at Zhejiang University. He obtained B.E. degree and MEng. Degree in Electrical and Information Engineering, both from Tianjin University, China, and received the Ph.D. degree in Information and Communication Engineering in Ministry of Education Key Laboratory of Opto-electronic Information Technology from Tianjin University in 2016. His Ph.D. research was investigating key microwave photonics techniques in low phase noise microwave generator and broadband THz wireless communications, with a focus on optoelectronic oscillator (OEO) and ultrahigh-speed THz wireless communications. During September 2015 and August 2016, Dr. Jia worked as a guest Ph.D. researcher at DTU Fotonik, where he achieved a series of breakthrough in developing ultrahigh speed THz wireless transmission in the THz band above 300 GHz.

Current Graduate Students

—— Ph.D. Students ——

Changqiao LIU

Ph.D. (2013 – present)

Bachelor: Zhejiang University
Supervisor: Xiaofeng JIN
E-mail: 11331022@zju.edu.cn

Gelin CHEN

Ph.D. (2013 – present)

Bachelor: Xidian University
Supervisor: Shilie ZHENG
E-mail: chenyiling@zju.edu.cn

Zhijing ZHU

Ph.D. (2013 – present)

Bachelor: Zhejiang University
Supervisor: Hao CHI
E-mail: zzj1030@qq.com

Kang XIAO

Ph.D. (2014 – present)

Bachelor: Tianjin Polytechnic University
Supervisor: Xiaofeng JIN
E-mail: kangxiao_xk@163.com

Jiayu ZHENG

Ph.D. (2014 – present)

Bachelor: Dalian Maritime University
Supervisor: Xianmin ZHANG
E-mail: zhengjiayu@zju.edu.cn

Wei WANG

Ph.D. (2014 – present)

Bachelor: Zhejiang University of Technology
Supervisor: Dongxiao YANG
E-mail: 11431025@zju.edu.cn

Hongxia HE

Ph.D. (2016 – present)

Bachelor: Zhejiang University of Technology
Supervisor: Hao CHI
E-mail: hehongxia@zju.edu.cn

—— Master Students ——

Hangkai ZHANG

Master (2015 – present)

Bachelor: Zhejiang University
Supervisor: Xianbin YU
E-mail: zhanghk@zju.edu.cn

Yang ZHANG

Master (2015 – present)

Bachelor: Qingdao University
Supervisor: Xiaofeng JIN
E-mail: 244357836@qq.com

Zhenlei SHAO

Master (2015 – present)

Bachelor: Zhejiang University
Supervisor: Xianmin ZHANG
E-mail: 21531024@zju.edu.cn

Xiangyue ZHANG

Master (2015 – present)

Bachelor: Xidian University
Supervisor: Xianmin ZHANG
E-mail: 21531025@zju.edu.cn

Ruofan DONG

Master (2015 – present)

Bachelor: Huazhong University of Science and Technology
Supervisor: Shilie ZHENG
E-mail: dongruofan@zju.edu.cn

Chentao HOU

Master (2015 – present)

Bachelor: University of Electronic Science and Technology of China
Supervisor: Hao CHI
E-mail: 498571283@qq.com

Zhenhai QIAN

Master (2015 – present)

Bachelor: Zhejiang University of Technology
Supervisor: Dongxiao YANGg
E-mail: 21531020@zju.edu.cn

Shiwei WANG

Master (2016 – present)

Bachelor: Harbin Institute of Technology at Weihai
Supervisor: Xianbin YU
E-mail: wswcsbs@qq.com

Kexin LIU

Master (2016 – present)

Bachelor: Sun Yat-sen University
Supervisor: Xianbin YU
E-mail: liukx3@mail2.sysu.edu.cn

Zhiwei CHENG

Master (2016 – present)

Bachelor: Shanghai University
Supervisor: Xiaofeng JIN
E-mail: ahhssxczw@163.com

Jun’ao JIN

Master (2016 – present)

Bachelor: Zhejiang University
Supervisor: Xianmin ZHANG
E-mail: 3120101965@zju.edu.cn

Alumni

Boyu XU, PhD (2011-2016)

Yanhong ZHU, PhD (2012-2017)

Chen XU, PhD (2011-2016)

Yu PAN, PhD (2012-2017)

Yuan MEI, PhD (2011-2016)

Yuxiao XU, PhD (2012-2017)

Yanru LI, MSc (2013-2016)

Rongrong FU, MSc (2014-2017)

Weite ZHANG, MSc (2014-2017)

Yinlong ZHAO, MSc (2014-2017)

Yiping HU, MSc (2013-2016)

Yuzhou ZHANG, MSc (2014-2017)

Xinyi CHEN, MSc (2014-2017)

ChuanJiang MA, MSc (2014-2017)

Zhuofan ZHANG, MSc (2014-2017)

Mingyang LI, MSc(2014-2017)

Research Projects

 

  1. Remote photo-acoustic key technologies for shallow-sea topographic survey, supported by the National Science and Technology Support Program, 2012.01-2015.12, Project leader: Prof. Xiaofeng Jin
  2. Key technology of low phase-noise millimeter wave opto-electronic oscillators, supported by the National Natural Science Foundation, 2014.01.01-2017.12.03, Project leader: Prof. Xiaofeng Jin
  3. Multiband tunable microwave photonic signal processing with high precision, supported by the National Basic Research Program of China (973 Program), Project leader: Prof. Xiaofeng Jin
  4. Propagation and communication systems employing radio frequency orbital angular momentum wave, supported by the National Program on Key Basic Research Project of China (973 Program), 2014-2018, Project leader: Prof. Xianmin Zhang
  5. Integrated passive devices for orbital angular momentum communication systems, supported by the National Program on Key Basic Research Project of China (973 Program), 2014-2018, Project leader: Asso. Prof. Shilie Zheng
  6. Receiver scheme of vortex electromagnetic waves, Supported by the National High-tech R&D Program of China (863 Program), 2015-2016, Project leader: Asso. Prof. Shilie Zheng
  7. Plain spiral orbital angular momentum wave and its applications, supported by the National Natural Science Foundation, 2016.01-2019.12, Project leader: Asso. Prof. Shilie Zheng
  8. Photonics-assisted technologies for receiving vortex millimeter wave, supported by the National Natural Science Foundation, 2014.01-2017.12, Project leader: Prof. Xianmin Zhang
  9. Novel coaxial fiber radio frequency antennas, supported by the National Natural Science Foundation, 2012.01-2015.12, Project leader: Asso. Prof. Shilie Zheng
  10. All-optical generation of widely tunable microwave/millimeter wave based on dual-band microchip laser, supported by the National Natural Science Foundation, 2011.01-2013.12, Project leader: Prof. Xianmin Zhang
  11. Project supported by the Natural Science Foundation of Zhejiang Province for Distinguished Young Scholar, 2010.01-2012.12, Project leader: Prof. Xianmin Zhang
  12. Intra-body communication based on electro-optic reception technology, supported by the National Natural Science Foundation, 2009.01-2011.12, Project leader: Asso. Shilie Zheng
  13. Several key technologies for photonic compressive sensing, supported by the National Natural Science Foundation, 2016.01 – 2019.12,Project leader: Prof. Hao Chi
  14. Theoretical and experimental analysis on photonics radio frequency spectrum, supported by the National Natural Science Foundation, 2012.01- 2015.12, Project leader: Prof. Hao Chi
  15. Several key issues on microwave photonic signal processing, Program for New Century Excellent Talents in University of Ministry of Education of China, 2011.01 – 2013.12, Project leader: Prof. Hao Chi
  16. Photonic generation of broadband microwave/ mimllimeter-wave, supported by the National Natural Science Foundation, 2009.01-2011.12, Project leader: Prof. Hao Chi

Publications

 

—— 2016 ——

  1. Y. Xu, T. Jin, H. Chi, S. Zheng, X. Jin, and X. Zhang, Time-Frequency Uncertainty in the Photonic A/D Converters Based on Spectral Encoding, IEEE Photonics Technology Letters, Vol. 28, No. 8, pp. 841-844, April 2016.

—— 2015 ——

  1. Y. Mei, T. Jin, H. Chi, S. Zheng, X. Jin, and X. Zhang, Characterization of the photonic generation of phase-coded RF signals based on pulse shaping and frequency-to-time mapping, Applied Optics, Vol. 54, No.13, pp. 3956-3962, May 2015.
  2. Z. Zhu, H. Chi, S. Zheng, T. Jin, X. Jin, and X. Zhang, Analysis of compressive sensing with optical mixing using a spatial light modulator, Applied Optics, Vol. 54, No. 8, pp. 1894-1899, March 2015.
  3. Xiannan Hui, Shilie Zheng, Yiling Chen, Yiping Hu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Multiplexed millimeter wave communication with dual orbital angular momentum (OAM) mode antennas, Scientific Reports, Vol. 5, 10148, May 19, 2015.
  4. Shilie Zheng, Xiaonan Hui, Jiangbo Zhu, Hao Chi, Xiaofeng Jin, Siyuan Yu, and Xianmin Zhang, Orbital angular momentum mode-demultiplexing scheme with partial angular receiving aperture, Optics Express, Vol. 23, No. 9, May 4, 2015, pp. 12251-12257.
  5. Yi Wang, Xiaofeng Jin, Yanhong Zhu, Xianmin Zhang, Shilie Zheng, Hao Chi, A wideband tunable optoelectronic oscillator based on a spectral-subtraction-induced MPF, IEEE Photonics Technology Letters, Vol. 27, No. 9, May 1, 2015, pp. 947-950.
  6. Yuan Mei, Tao Jin, Hao Chi, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang, Characterization of the photonic generation of phase-coded RF signals based on pulse shaping and frequency-to-time mapping, Applied Optics, Vol. 54, No. 13, May 1, 2015, pp. 3956-3962.
  7. Xiaonan Hui, Shilie Zheng, Yiping Hu, Chen Xu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Ultralow reflectivity spiral phase plate for generation of millimeter-wave OAM beam, IEEE Antennas and Wireless Propagation Letters, Vol. 14, April 2015, pp. 966-969.
  8. Shilie Zheng, Xiaonan Hui, Xiaofeng Jin, and Hao Chi, and Xianmin Zhang, Transmission characteristics of a twisted radio wave based on circular traveling-wave antenna, IEEE Transactions on Antennas and Propagation, Vol. 63, No. 4, April 2015, pp. 1530-1536.
  9. Zhijing Zhu, Hao Chi, Shilie Zheng, Tao Jin, Xiaofeng Jin, and Xianmin Zhang, Analysis of compressive sensing with optical mixing using spatial light modulator, Applied Optics, Vol. 54, No. 8, March 10, 2015, pp. 1894-1899.
  10. Ying Chen, Xianbin Yu, Hao Chi, Shilie Zheng, Xianmin Zhang, Xiaofeng Jin, and Michael Galili, Compressive sensing with a microwave photonic filter, Optics Communications, Vol. 338, 2015, pp.428–432.

—— Before 2015 ——

  1. Y. Chen, X. Yu. H. Chi, X. Jin, X. Zhang, S. Zheng, and M. Galili, Compressive sensing in a photonic link with optical integration, Optics Letters, Vol.39, No.8, pp. 2222-2224, April 2014.
  2. Y. Chen, H. Chi, T. Jin, S. Zheng, X. Jin, and X. Zhang, Sub-Nyquist Sampled Analog-to-Digital Conversion Based on Photonic Time Stretch and Compressive Sensing With Optical Random Mixing, Journal of Lightwave Technology, Vol.31, No.21, pp.3395-3401, Nov. 2013.
  3. Hao Chi, Ying Chen, Yuan Mei, Xiaofeng Jin, Shilie Zheng, and Xianmin Zhang, Microwave spectrum sensing based on photonic time stretch and compressive sampling, Optics Letters, Vol. 38, No. 2, pp.136-138, Jan. 2013.
  4. Hao Chi, Yuan Mei, Ying Chen, Donghui Wang, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang, Microwave spectral analysis based on photonic compressive sampling with random demodulation, Optics Letters, Vol. 37, No. 22, pp.4636-4638, Nov. 2012.
  5. Ying Chen, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Differentially- Encoded Photonic Analog-to-Digital Conversion based on Phase Modulation and Interferometric Demodulation, IEEE Photonics Technology Letters, Vol.23, No.24, pp. 1890-1892, Dec. 2011.
  6. Yun Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Photonic approach for microwave spectral analysis based on Fourier cosine transform, Optics Letters, vol. 36, no.19, pp.3897-3899, Oct. 2011.
  7. H. Chi, Z. Li, X. Zhang, S. Zheng, X. Jin, and J. P. Yao, Proposal for photonic quantization with differential encoding using a phase modulator and delay-line interferometers, Optics Letters, vol.36, no.9, pp.1629-1631, May 2011.
  8. Shuna Yang, Chao Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin and Jianping Yao, Photonic analog-to-digital converter using Mach-Zehnder modulators having identical half-wave voltages with improved bit resolution, Applied Optics, Vol.48, No.22, pp.4458-4467, Aug. 2009.
  9. H. Chi, X. Zou and J. P. Yao, Analytical models for phase-modulation-based microwave photonic systems with phase modulation to intensity modulation conversion using a dispersive device, IEEE/OSA Journal of Lightwave Technology, Vol.27, No.5, pp.511-521, March 2009.
  10. Hao Chi, Jianping Yao, Frequency quadrupling and upconversion in a radio over fiber link, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.15, pp.2706-2711, Aug. 2008.
  11. H. Chi, X. Zou and J. P. Yao, An approach to the measurement of microwave frequency based on optical power monitoring, IEEE Photonics Technology Letters, Vol.20, No.17, pp.1249-1251, July 2008.
  12. H. Chi and J. P. Yao, Chirped RF pulse generation based on optical spectral shaping and wavelength-to-time mapping using a nonlinearly chirped fiber Bragg grating, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.10, pp.1282-1287, May 2008.
  13. H. Chi and J. P. Yao, Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator, IEEE Microwave and Wireless Components Letters, Vol.18, No.5, pp.371-373, May 2008.
  14. H. Chi and J. P. Yao, Power distribution of phase-modulated microwave signals in a dispersive fiber-optic link, IEEE Photonics Technology Letters, Vol.20, No.4, pp.315-317, Feb. 2008.
  15. H. Chi and J. P. Yao, A photonic analog-to-digital conversion scheme using Mach-Zehnder modulators with identical half-wave voltages, Optics Express, Vol.16, No.2, pp.567-574, Jan. 2008.
  16. H. Chi and J. P. Yao, Waveform distortions due to second-order dispersion and dispersion mismatches in a temporal pulse shaping system, IEEE/OSA Journal of Lightwave Technology, vol. 25, no.11, pp.3528-3535, November 2007.
  17. H. Chi and J. P. Yao, All-fiber chirped microwave pulse generation based on spectral shaping and wavelength-to-time conversion, IEEE Transactions on Microwave Theory and Techniques, vol. 55, no. 9, pp. 1958-1963, September 2007.
  18. H. Chi and J. P. Yao, An approach to photonic generation of high-frequency phase-coded RF pulses, IEEE Photonics Technology Letters, vol. 19, no. 10, pp. 768-770, May 2007.
  19. H. Chi, F. Zeng, and J. P. Yao, Photonic generation of microwave signals based on pulse shaping, IEEE Photonics Technology Letters, vol. 19, no. 9, pp. 668-670, May 2007.
  20. H. Chi and J. P. Yao, Symmetrical waveform generation based on temporal pulse shaping using an amplitude-only modulator, Electronics Letters, vol. 43, no. 7, pp. 415-417, March 2007.

 

—— 2015 ——

  1. X. Yu*, R. Asif, M. Piels, D. Zibar, Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, 60Gbit/s 400GHz wireless transmission, Photonics in Switching 2015, Postdeadline paper PDP1, Florence, Italy, 2015 September 22-25.
  2. Yu*, M. Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, Towards ultrahigh speed impulse radio THz wireless communications, 2015 International Conference on transparent optical networks (ICTON 2015), Invited talk, Budapest, Hungary, 2015 July 5-9.
  3. Yu*, Borja Vidal, M. Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, Experimental characterization of extremely broadband THz impulse radio systems, Paper W1E4, 40th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THZ 2015), Hong Kong, 2015 August 25-28.
  4. Yu*, L. K. Oxenløwe, TWIST: THz wireless information systems and technologies, 16th edition of the International Symposium on RFMEMS and RF-MICROSYSTEMS (MEMSWAVE 2015), Invited talk, Barcelona, Spain, 2015 June 29-July 1st.
  5. Yu*, M. Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, Ultrafast THz impulse radio communications, 4th Annual World Congress of Advanced Materials-2015 (WCAM2015), Invited talk, Chongqing, China, 2015 May 27-29.
  6. Yu*, X. Zhang, Fundamental analysis of extremely fast photonic THz wireless communication systems, IEEE 8th International Conference on Advanced Infocomm Technology (ICAIT 2015), Invited talk, Hangzhou, China, 2015 October 25-27.

Be a RPIPer — For Master and Ph.D. students

The research of RPIP center in the College of Information Science and Electronic Engineering at Zhejiang University covers a wide range of topics from basic scientific exploration into radio frequency (RF) lightwave interaction through engineering novel functional devices, to fundamental development of signal processing technologies, communication technologies and applicable engineering technologies, in a broad radio frequency (RF) spectrum of microwave, millimeter-wave and THz regions.

You are welcome to join us and continue your learning career with us, as either a Master student or a Ph.D. student. We provide an open environment, well-equipped lab facilities and well-defined projects for you depending your interest and background. We will also provide support to your future career development.

High Calibre Talents

 

The RPIP center at the College of Information Science and Electronic Engineering, Zhejiang University invites highly talented applications for assistant professorship, associate professorship, full professorship and Chair professorship positions.

Applications should include a curriculum vitae, recent publications, and reference letters from at least three people who can comment on the applicant’s professional qualification.

Some attractive programs are available to support your career at Zhejiang University, please see the links which suits for you (unfortunately only Chinese version).

Postdoctoral Research Fellows in RF photonics enabling technologies

 

This is an opportunity to join the RPIP center, College of Information Science and Electronic Engineering at Zhejiang University. The group emphasizes the interdisciplinary research in the field of RF Photonics, including RF-photonics communication systems and enabling technologies, ultrafast millimeter-wave/THz devices and industrial applications of RF photonics technologies. We are seeking several postdocs exploring new techniques/new devices for developing advanced application-oriented systems.

You will be responsible for:

  • developing one research topic related to RF photonics
  • preparing and present scientific results in papers and conferences
  • co-supervising undergraduate and graduate research students
  • assisting in recruitment of research students
  • assisting towards attracting new funding

You must have:

  • a PhD in Electrical Engineering, Opto-electronics, Physics, or a related discipline
  • published peer-reviewed research articles
  • experience in experimental optics and electronics
  • good communication skills

Remuneration package:

  • Accommodation can be rented from Zhejiang University.
  • Salary and appointment terms are consistent with the current rules at Zhejiang University. Level of salary will be commensurate with experience and qualifications.
  • The position is full-time fixed term for two years subject to the completion of a satisfactory probation period for new appointees.

Application:

Applications must be submitted as one pdf file containing all materials. The file includes:

  • Your CV
  • 3 selective publications
  • Recommendation letters

Visiting scholars

 

The RPIP center at Zhejiang University welcomes visiting scholars, fellow, associates and doctoral students from other institutions for both short and longer periods of research within or across the cores areas covered by the center. The RPIP center offers a dynamic research environment and provides a number of services and facilities for visitors.

You are welcome to contact us via email juny@zju.edu.cn, for any practical issues related to your application if you are interested in.

About RPIP

 

The Research Center for RF & Photonic Information Processing (RPIP) in the College of Information Science and Electronic Engineering at Zhejiang University was established in 2015, with research focuses on RF photonics technologies, THz science & technologies and their applications.

In the field of RF photonics technologies, we started our research on microwave-millimeter wave photonics since 2000. By combining photonics technologies and microwave engineering, as well as wireless communications, we have developed several key enabling technologies in this area, in particular, in terms of photonic microwave receiver, fiber-based microwave photonic time delay array, and photonic generation & processing of microwave/millimeter-wave, etc. In the past years, we have been involved in several national key research projects in China, for instance, National Program on Key Basic Research Project of China (973 Program), National High-tech R&D Program of China (863 Program), National Natural Science Foundation of China, with emphasizes on developing photonic phased array antenna for radar, photonic enabled microwave receiver, microwave/millimeter-wave signal processing based on Brillion scattering, broadband radio-over-fiber systems, photonic measurement of microwave/millimeter-wave frequency, photonic analogue-to-digital conversion. Several key achievements have been practically employed to solve engineering problems.

In the field of THz Science and technologies, we have expertise on developing functional THz devices, such as THz filter, THz modulator, THz polarizer and THz waveguide. We are currently driving research lines on high speed THz wireless communication and THz imaging.

Organization

 

Director of RPIP: Hao CHI, Professor

Associate directors of RPIP: Shilie ZHENG, Professor and Xianbin YU, Research Professor

6 senior staffs in the Research Center for RF & Photonic Information Processing (RPIP): 5 full professors and 1 tenue-track research professor. The RPIP’s research covers a broad spectrum in the field of RF and photonic information processing, from fundamental devices to subsystems and systems. Dr. Xianbin Yu have been working on high speed photonic wireless access technologies & THz wireless communications and have contributed many significant achievements in these areas. Dr. Xianbin Yu joined the RPIP since 2016. In the past 5 years, more than 30 Master students, 10 Ph.D. students and 100 undergraduates have been trained in the relevant topics of RPIP. Feel free to directly contact anyone on the staff list for additional information.

 

How to get to us

Hangzhou Railway Station: it takes around 30 minutes to get to Yuquan Campus from the Hangzhou Railway Station by taxi (or take No. 21 line bus from the Hangzhou Railway Station and get off at the stop of YUQUAN Campus of Zhejiang University).

Hangzhou East Railway Station: it takes around 40 minutes to get to Yuquan Campus from the Hangzhou East Railway Station by taxi (or take No. 28 line bus from the Hangzhou East Railway Station and get off at the stop of YUQUAN Campus of Zhejiang University).

From the Hangzhou Xiaoshan Airport/Shanghai Hongqiao Airport/Shanghai Pudong Airport, please take a shuttle bus/long reach shuttle bus/long-reach shuttle bus and get off at the stop of Wulinmen (ticket prices: 20CNY, 110CNY, 110CNY), and then take a taxi to get to the YUQUAN campus of Zhejiang University (alternatively, take No. 21 or No.21 line bus from the Hangzhou East Railway Station and get off at the stop of YUQUAN Campus of Zhejiang University.

Schedule of long reach shuttle bus between Shanghai Pudong airport and Hangzhou Wulinmen in Hangzhou.
From Shanghai Pudong airport to Hangzhou Wulinmen: 10:30 12:00 13:30 15:30 17:30 19:00
From Hangzhou Wulinmen to Shanghai Pudong airport: 7:00 8:30 10:30 12:30 14:30 16:00
Ticket booking: 0086-571-8799-0788

Contact Us

If you are interested in our research work, you are welcome to contact us via email, or leave a message through the form on the right.Address:
4th Floor, Administrative Building
College of Information Science and Electronics Engineering
Yuquan Campus, Zhejing University
Hangzhou 31007
China

Email: juny@zju.edu.cn

13 + 13 =

实验室设备

研究中心共享10米х8米х6米微波暗室,可进行1GHz-60GHz射频天线与毫米波传输系统的精确测试。

微波、毫米波电子测量设备

具有从厘米波到8mm、5mm各波段的测试波导、射频信号发生器、扫频源、频谱分析仪、矢量网络分析仪、毫米波混频设备以及高速时域信号测试设备:如:Agilent E8267C矢量信号源(250kHz-20GHz)、Agilent E8267D矢量信号发生器(250kHz-44GHz)、Agilent E8257D低相位噪声模拟信号发生器(50MHHz-67GHz)、Agilent E4407B频谱分析仪(9kHz-26.5GHz)、Agilent 8563EC频谱仪(DC-26.5GHz)、Agilent N9020A频谱仪(DC-26.5GHz)、Agilent 11974A毫米波混频(26.5-40GHz)、Agilent 11974V毫米波混频(50-75GHz)、Agilent 8722ES矢量网络分析仪(50MHz-40GHz)、R/S公司ZVA67矢量网络分析仪(50MHz-67GHz)、 Agilent N9068A相位噪声分析模块(配在Agilent N9020A设备上,DC-26.5GHz)、Agilent N9069A噪声系数分析模块(配在Agilent N9020A设备上,DC-26.5GHz)、R/S 公司Zvab-k30噪声系数分析模块(配在R/S的ZVA67设备上,50MHz-67GHz)、R/S公司相位噪声分析仪FSUP50(10MHz-50GHz)。

光波、光通信方面设备

JDSU模拟电光调制器(20GHz)、EO Space模拟电光调制器(20GHz、40GHz)、EO Space电光相位调制器(20GHz)、Avanex模拟电光调制器(20GHz、40GHz)、Fujitsu双极性电光调制器(10GHz)、Discovery Semiconductor光电探测器(20GHz、40GHz)、U2T高速光电探测器(50GHz、60 GHz及70GHz等)、Agilent 86141B光谱分析仪、Agilent 86140B光谱分析仪、Advantest 8381光谱分析仪、Agilent 8164+81940可调激光测试系统、Agilent 8164+81689A可调激光测试系统、EXFO FLS-2600可调谐激光器和ASE宽带光源、Calmar飞秒光纤激光器、PulseCheck自相关仪、ILX lightwave LDC-3724B 半导体激光器电源、IPG光纤放大器、Tuilaser准分子激光器及特种光纤光栅制备系统、光纤熔融拉锥系统、Agilent 83480A+83482通信分析仪(30GHz光口、40GHz电口)、Tektronix TDS7104宽带示波器等。

研究生招聘

射频与光子信息处理研究中心主要从事光子射频信号处理技术、新型高速射频通信技术、太赫兹科学与技术等方面的研究。本中心在这些领域的若干研究方向(如光子射频信号传输和滤波、光子辅助模数转换、光电振荡器、光学真延时相控阵天线、微波光子信息感知、太赫兹通信和器件等)有着多年的研究积累,取得多项优秀研究成果。

本研究中心非常欢迎有团队合作意识、具有相关专业背景的硕士攻读博士学位,欢迎相关专业的本科生来本中心攻读硕士或直博。

本研究中心将竭全力为学生的职业和个人发展提供支持。

高层次人才

 

本研究中心非常欢迎国际国内高层次人才加入,进一步推动相关方向的科研水平和促进学科的建设与发展。浙江大学支持高层次人才以多种形式加入,相关人才计划的学术条件,具体任职条件和待遇标准请参见信息与电子工程学院相关介绍。

博士后招聘

 

浙江大学信电学院电子科学与技术学科结合光子学技术、射频技术(微波、毫米波和太赫兹波)和通信技术,将开展针对下一代超高速无线接入通信系统的相关技术研究-超高频光子射频通信系统关键技术。因研究工作需要,现拟招博士后若干名。

 

一、主要研究方向

  • 毫米波/太赫兹波的超快光子学处理
  • 高速毫米波/太赫兹通信
  • 超快光电集成器件
  • 太赫兹光谱技术

二、招聘要求和职责

  1. 应具有电子工程/通信工程/光电子/物理等相关专业的博士学位。
  2. 有较强的科学研究能力和发展潜力,工作仔细负责,有团队合作精神。
  3. 具有较强的英文沟通和阅读能力。
  4. 协助指导本科生和研究生。

三、博士后待遇

  1. 学校提供优惠价格租赁教师公寓。
  2. 工资和福利待遇参照浙江大学有关规定。
  3. 课题组根据应聘者的实际能力和工作业绩发放额外奖金。
  4. 提供良好的实验条件。
  5. 提供高水平国际学术会议交流和学习的机会。

四、申请材料

  1. 详细个人简历。
  2. 代表性论文全文。
  3. 同行专家推荐信。

、联系方式

该招聘长期有效,应聘者请将申请材料以附件形式发送到 juny@zju.edu.cn,并请注明“博士后应聘”。

国内访问学者

 

本研究中心接受和欢迎有兴趣的国内访问学者来浙江大学参加不同形式的合作科研工作。

1. 短期交流访问和合作实验研究。

2. 访学期限1学年的,一般为每年的9月份入学,访学期间一般应全脱产进修,根据选定的研究课题按计划完成预定任务。国内访问学者参与所在课题组活动,访问工作结束,经考核合格者,发给国家教育部统一印制的《国内访问学者证书》或《高等学校青年骨干教师国内访问学者证书》。

余显斌科研方向

1. 超快射频光子信号处理

基于光子拍频实验产生的350GHz信号

工业界太赫兹偶极子天线

2. 超高速毫米波/太赫兹无线通信系统

光子射频信号处理是微波/毫米波/太赫兹光子学的一个重要研究方向。光子技术不但具有并行处理的能力,而且可以克服电子采样“瓶颈”和电路交换速度等限制。射频光子学研究不但涵盖了已有的很多微波技术,如远端天线、光控相位阵列等,而且还开辟了一些新的微波研究领域,如大延迟线、频谱分析、频率变换、光控微波设备、高频振荡器以及模数转换等等。特别是,随着高速、宽带光源、高速调制器和超宽带探测器等光电子器件性能的不断提高,以及纳米超快光集成器件性能的不断发展,射频光子信号处理技术已经有能力覆盖从低频微波到超高太赫兹波段。从射频光子信号处理技术在通信系统中的应用来看,下一代高速无线通信系统的通信速率无疑将大大提高,载波频率自然进入毫米波和太赫兹波领域,这就要求射频信号处理能力必须进入‘超快’的下一阶段。要实现对毫米波和太赫兹波的超快信号控制、分析和处理,光子学有着更为重要和不可替代的作用。

高速光子无线通信网络应用场景

无线速率需求趋势

16-QAM通信实验星座图

高速毫米波/太赫兹技术通信技术近些年是国际上的一个研究热点。目前的无线通信技术受到有限频率资源以及带宽的限制,无法支撑超高速(>>100Gbps)的通信速率来满足将来超大数据流量的需求,所以超高速无线通信只能在毫米波以及太赫兹波段实现。以往分析表明,要携带Tbps的通信信息,频率带宽要求在200GHz以上,这显然只有太赫兹频段才能满足这个超大带宽的要求。理论上,太赫兹波段(0.3-10THz)可以携带超过Tbps的更高通信速率,然而300GHz以上频率太赫兹通信技术整体而言仍处于起步阶段,国际标准协会也成立了太赫兹通信标准化小组,拟对太赫兹高速通信的国际标准作出规范。在高速太赫兹通信领域及时产生的一些重要成果也将对该标准的产生将具有很重要的建议作用。

3. 光子毫米波/太赫兹雷达

毫米波/太赫兹雷达系统概念

毫米波/太赫兹电磁波介于微波和红外线之间,具有宽谱特性,所以它们是很好的宽带信息载体。另一方面太赫兹与红外线相比它具有极高的方向性及较强的沙尘云雾穿透能力,所以它同时在军事和国防等其它领域也有很好的应用。

在读研究生

—— 博士研究生 ——

俆伯禺

2011届博士

本科:重庆大学
导师:金晓峰
邮箱: 173906654@qq.com

徐晨

2011届博士

本科:浙江大学
导师:章献民
邮箱: peterxuchen@zju.edu.cn

每媛

2011届博士

本科:浙江大学
导师:池灏
邮箱: meiyuan@zju.edu.cn

祝艳宏

2012届博士

本科:中国石油大学(华东)
导师:金晓峰
邮箱: zhuyh89@126.com

潘毓

2012届博士

本科:中国地质大学(武汉)
导师:章献民
邮箱: yupan@zju.edu.cn

徐宇啸

2012届博士

本科:浙江大学
导师:池灏
邮箱: xuyuxiao@zju.edu.cn

刘长桥

2013届博士

本科:浙江大学
导师:金晓峰
邮箱: 11331022@zju.edu.cn

陈弋凌

2013届博士

本科:西安电子科技大学
导师:郑史烈
邮箱: chenyiling@zju.edu.cn

朱之京

2013届博士

本科:浙江大学
导师:池灏
邮箱: zzj1030@qq.com

肖康

2014届博士

本科:天津工业大学
导师:金晓峰
邮箱: kangxiao_xk@163.com

郑佳瑜

2014届博士

本科:大连海事大学
导师:章献民
邮箱: zhengjiayu@zju.edu.cn

汪伟

2014届博士

本科:浙江工业大学
导师:杨冬晓
邮箱: 11431025@zju.edu.cn

何红霞

2016届博士

本科:浙江工业大学
导师:池灏
邮箱: hehongxia@zju.edu.cn

期待你的加入

—— 硕士研究生 ——

马川江

2014届硕士

本科:浙江大学
导师:金晓峰
邮箱: cj_ma@zju.edu.cn

傅蓉蓉

2014届硕士

本科:武汉大学
导师:金晓峰
邮箱: rrfu@zju.edu.cn

张宇舟

2014届硕士

本科:浙江大学
导师:金晓峰
邮箱: alickzhang1991@126.com

张倬钒

2014届硕士

本科:上海交通大学
导师:章献民
邮箱: zhangzhuofan@zju.edu.cn

张维特

2014届硕士

本科:浙江工业大学
导师:章献民
邮箱: wertherzhang@zju.edu.cn

陈昕熠

2014届硕士

本科:浙江工业大学
导师:郑史烈
邮箱: chenxinyi@zju.edu.cn

李明洋

2014届硕士

本科:杭州电子科技大学
导师:池灏
邮箱: limingyang2012@zju.edu.cn

赵银龙

2014届硕士

本科:重庆邮电大学
导师:杨冬晓
邮箱: 746232596@qq.com

章航垲

2015届硕士

本科:浙江大学
导师:余显斌
邮箱: zhanghk@zju.edu.cn

张杨

2015届硕士

本科:青岛大学
导师:金晓峰
邮箱: 244357836@qq.com

邵振雷

2015届硕士

本科:浙江大学
导师:章献民
邮箱: 21531024@zju.edu.cn

张向月

2015届硕士

本科:西安电子科技大学
导师:章献民
邮箱: 21531025@zju.edu.cn

董若凡

2015届硕士

本科:华中科技大学
导师:郑史烈
邮箱: dongruofan@zju.edu.cn

侯晨涛

2015届硕士

本科:电子科技大学
导师:池灏
邮箱: 498571283@qq.com

钱振海

2015届硕士

本科:浙江工业大学
导师:杨冬晓
邮箱: 21531020@zju.edu.cn

王世伟

2016届硕士

本科:哈尔滨工业大学(威海)
导师:余显斌
邮箱: wswcsbs@qq.com

刘可心

2016届硕士

本科:中山大学
导师:余显斌
邮箱: liukx3@mail2.sysu.edu.cn

程志威

2016届硕士

本科:上海大学
导师:金晓峰
邮箱: ahhssxczw@163.com

金俊傲

2016届硕士

本科:浙江大学
导师:章献民
邮箱: 3120101965@zju.edu.cn

期待你的加入

毕业研究生

李艳茹

2013届硕士

本科:浙江工商大学
导师:章献民
邮箱: lyr@zju.edu.cn

胡一平

2013届硕士

本科:浙江大学
导师:郑史烈
邮箱: huyp@zju.edu.cn

科研项目

 

  1. 国家自然科学基金,光子学压缩感知若干关键技术研究,2016.01 – 2019.12,负责人:池灏
  2. 国家自然科学基金,光子学射频频谱分析技术理论与实验研究, 2012.01- 2015.12,负责人:池灏
  3. 教育部新世纪优秀人才支持计划,微波光子信号处理若干关键问题研究, 2011.01 – 2013.12,负责人:池灏
  4. 国家自然科学基金,宽带微波/毫米波信号的光子学发生,2009.01- 2011.12 ,负责人:池灏
  5. 国家科技支撑课题,远程光声浅海地形测量关键技术,2012.01-2015.12,负责人:金晓峰
  6. 国家自然科学基金项目,低相位噪声毫米波光电振荡器关键技术的研究,2014.01.01-2017.12.03,负责人:金晓峰
  7. 国家重点基础研究发展计划(973)课题,多波段可调谐高精细度微波光子信号处理研究,“面向宽带泛在接入的微波光子器件与集成系统研究基础研究”子课题,负责人:金晓峰
  8. 国家重点基础研究发展计划(973)课题,“射频OAM传播规律与通信系统研究”,2014-2018,负责人:章献民
  9. 国家重点基础研究发展计划(973)课题,“无源集成OAM通信器件研究”,2014-2018, 子课题负责人:郑史烈
  10. 国家863计划,“涡旋电磁场接收方法研究”,2015-2016,负责人:郑史烈
  11. 国家863计划,“射频OAM调制和复用的新机理研究”,2015-2016,负责人:郑史烈
  12. 国防科技创新特区项目,“基于平面螺旋的结构电磁波及应用”,2017.12-2018.10,负责人:章献民
  13. 国家自然科学基金,“平面螺旋轨道角动量电磁波及其应用研究”,2016.01-2019.12,负责人:郑史烈
  14. 国家自然科学基金,“光子辅助涡旋毫米波接收技术研究”,2014.01-2017.12,负责人:章献民
  15. 国家自然科学基金,“新颖同轴结构光纤射频天线研究”,2012.01-2015.12,负责人:郑史烈
  16. 国家自然科学基金,“基于双频微片激光器的宽带可调谐微波/毫米波全光产生”,2011.01-2013.12,负责人:章献民
  17. 浙江省自然科学基金杰出青年团队项目,2010.01-2012.12,章献民
  18. 国家自然科学基金,“基于电光接收技术的人体通信研究”,2009.01-2011.12,负责人:郑史烈
  19. 国家863计划,2015-2016,负责人:杨冬晓
  20. 国家自然科学基金,“灵活栅格大容量光子太赫兹通信关键技术研究 ”,2018.01-2021.12,负责人:余显斌

论文发表

—— 2017——

  1. Shilie Zheng, Ruofan Dong, Zhuofan Zhang, Xianbin Yu, Xiaofeng Jin, Hao Chi, Zhi Ning Chen, and Xianmin Zhang. Non-Line-of-Sight Channel Performance of Plane Spiral Orbital Angular Momentum MIMO Systems[J]. IEEE Access, 2017, 5: 25377-25384.
  2. Yu Pan, Guoping Lin, Souleymane Diallo, Xianmin Zhang, and Yanne K. Chembo. Design of X-cut and Z-cut lithium niobate whispering-gallery-mode disk-resonators with high quality factors[J]. IEEE Photonics Journal, 2017, 9(4): 1-8.
  3. Zhuofan Zhang, Shilie Zheng, Weite Zhang, Xiaofeng Jin, Hao Chi, and Xianmin Zhang. Experimental Demonstration of the Capacity Gain of Plane Spiral OAM-Based MIMO System[J]. IEEE Microwave and Wireless Components Letters, 2017, 27(8): 757-759.
  4. Yiling Chen, Shilie Zheng, Xiaofeng Jin, Hao Chi, and Xianmin Zhang. Single-frequency computational imaging using OAM-carrying electromagnetic wave[J]. Journal of Applied Physics, 2017, 121(18): 184506.
  5. Zhaoyang Zhang, Yuqing Yuan, Ji Cang, Huayang Wu, and Xianmin Zhang. An Orbital Angular Momentum-Based In-Band Full-Duplex Communication System and Its Mode Selection[J]. IEEE Communications Letters, 2017, 21(5): 1183-1186.
  6. Yu Pan, Shilie Zheng, Yanru Li, Jiayu Zheng, Xiaofeng Jin, Hao Chi, and Xianmin Zhang. Generation of orbital angular momentum radio waves based on dielectric resonator antenna[J]. IEEE Antennas and Wireless Propagation Letters, 2017, 16: 385-388.
  7. Weite Zhang, Shilie Zheng, Xiaonan Hui, Yiling Chen, Xiaofeng Jin, Hao Chi, and Xianmin Zhang. Four-OAM-mode antenna with traveling-wave ring-slot structure[J]. IEEE Antennas and Wireless Propagation Letters, 2017, 16: 194-197.
  8. Zhuofan Zhang, Shilie Zheng, Xiaofeng Jin, Hao Chi, and Xianmin Zhang. Generation of plane spiral OAM waves using traveling-wave circular slot antenna[J]. IEEE Antennas and Wireless Propagation Letters, 2017, 16: 8-11.
  9. Weite Zhang, Shilie Zheng, Xiaonan Hui, Ruofan Dong, Xiaofeng Jin, Hao Chi, and Xianmin Zhang. Mode division multiplexing communication using microwave orbital angular momentum: an experimental study[J]. IEEE Transactions on Wireless Communications, 2017, 16(2): 1308-1318.
  10. Changqiao Liu, Xiaofeng Jin, Boyu Xu, Xiangdong Jin, Xianmin Zhang, Shilie Zheng, and Hao Chi. Impact of 3rd-order dispersion on photonic time-stretch system[J]. Optics Communications, 2017, 402: 206-210.
  11. Xiaofeng Jin, Yanhong Zhu, Jiaojiao Guo, Xiangdong Jin, Xianbin Yu, Shilie Zheng, Hao Chi, and Xianmin Zhang. Highly sensitive demodulation of a vibration-induced phase shift based on a low-noise OEO[J]. Optics letters, 2017, 42(20): 4052-4054.
  12. Boyu Xu, Changqiao Liu, Xiaofeng Jin, Xiangdong Jin, Xianbin Yu, Hao Chi, Shilie Zheng, and Xianmin Zhang. Frequency-dependent noise figure analysis of continuous photonic time-stretch system[J]. Applied optics, 2017, 56(29): 8246-8251.
  13. Rongrong Fu, Xiaofeng Jin, Yanhong Zhu, Xiangdong Jin, Xianbin Yu, Shilie Zheng, Hao Chi, and Xianmin Zhang. Frequency stability optimization of an OEO using phase-locked-loop and self-injection-locking[J]. Optics Communications, 2017, 386: 27-30.
  14. Kang Xiao, Xiaofeng Jin, Xiangdong Jin, Xianbin Yu, Xianmin Zhang, Hao Chi, and Shilie Zheng. A Two-Dimensional LiNbO3 Photonic E-Field Sensor Using Inclined Dipole Antennas[J]. IEEE Antennas and Wireless Propagation Letters, 2017, 16: 2203-2206.
  15. Yuxiao Xu, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang. On the undesired frequency chirping in photonic time-stretch systems[J]. Optics Communications, 2017, 405: 192-196.
  16. Zhijing Zhu, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang. Single-pixel imaging based on compressive sensing with spectral-domain optical mixing[J]. Optics Communications, 2017, 402: 119-122.
  17. Shuna Yang, Miao Hu, Hao Chi, and Qiliang Li. Photonic digital-to-analog conversion based on wavelength multiplexing[J]. Optics Communications, 2017, 401: 1-5.
  18. Zhijing Zhu, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang. All-positive-coefficient microwave photonic filter with rectangular response[J]. Optics letters, 2017, 42(15): 3012-3015.
  19. Guochuan Tong, Tao Jin, Hao Chi, Xiang Zhu, Tianhao Lai, and Xidong Wu. A Novel Optoelectronic Oscillator Based on Brillouin-Induced Slow Light Effect[J]. IEEE Photonics Technology Letters, 2017, 29(16): 1375-1378.
  20. Yuxiao Xu, Tao Jin, Hao Chi, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang. Photonic Generation of Dual-Chirp Waveforms With Improved Time-Bandwidth Product[J]. IEEE Photonics Technology Letters, 2017, 29(15): 1253-1256.
  21. Yuan Mei, Yuxiao Xu, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang. Spurious-Free Dynamic Range of the Photonic Time-Stretch System[J]. IEEE Photonics Technology Letters, 2017, 29(10): 794-797.
  22. Hangkai Zhang, Shiwei Wang, Shi Jia, Xianbin Yu, Xiaofeng Jin, Shilie Zheng, Hao Chi, and Xianmin Zhang. Experimental generation of linearly chirped 350 GHz band pulses with a bandwidth beyond 60 GHz[J]. Optics letters, 2017, 42(24): 5242-5245.
  23. Shi Jia, Xianbin Yu, Hao Hu, Jinlong Yu, Toshio Morioka, Peter U. Jepsen, Leif K. Oxenløwe. 120 Gb/s multi-channel THz wireless transmission and THz receiver performance analysis[J]. IEEE Photonics Technology Letters, 2017, 29(3): 310-313.

—— 2016 ——

  1. Zhuofan Zhang, Shilie Zheng, Yiling Chen, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, The capacity gain of orbital angular momentum based multiple-input-multiple-output system, Scientific Reports, Vol. 6, 25418, May 5, 2016.
  2. Yanhong Zhu, Xiaofeng Jin, Xiangdong Jin, Xianbin Yu, Shilie Zheng, Hao Chi, and Xianmin Zhang, A novel scheme of microwave generation based on heterodyne phase locking of an OEO, IEEE Photonics Technology Letters, Vol. 28, Nov. 2016, No.22, pp.2637-2640.
  3. Shilie Zheng, Weite Zhang, Zhuofan Zhang, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Generation and propagation characteristics of electromagnetic vortices in radio frequency, Photonics Research, Vol. 4, No. 5, October 2016, pp. B9-B13, Invited paper.
  4. Chen Xu, Shilie Zheng, Weite Zhang, Yiling Chen, Hao Chi, Xiaofeng Jin, and Xianmin Zhang, Free-space radio communication employing orbital angular momentum multiplexing, IEEE Microwave and wireless Components Letters, Vol. 26, No. 9, September 2016, pp. 738-740.
  5. Feng Zhou, Xiaofeng Jin, Ran Hao, Xianmin Zhang, Hao Chi, and Shilie Zheng, A graphene-based all-fiber electro-absorption modulator, Journal of Optics, Vol. 45, No. 4, 2016, pp.337-342.
  6. Yanhong Zhu, Xiaofeng Jin, Xianmin Zhang, Hao Chi, and Shilie Zheng, A Temperature Sensor Based on a Brillouin Optoelectronic Oscillator, Microwave and Optical Technology Letters, Vol. 58, No. 8, August 2016, pp.1952-1955.
  7. Yiping Hu, Shilie Zheng, Zhuofan Zhang, Hao Chi, Xiaofeng Jin, and Xianmin Zhang, Simulation of orbital angular momentum radio communication systems on new receiving scheme, IET Microwaves, Antennas & Propagation, Vol. 10, No. 10, 2016, pp.1043-1047.
  8. Weite Zhang, Shilie Zheng, Yiling Chen, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Orbital angular momentum based communications with partial arc sampling receiving, IEEE Communications Letters, Vol. 20, No. 7, July 2016, pp. 1381-1384.
  9. Yiling Chen, Shilie Zheng, Hao Chi, Xiaofeng Jin, Xianmin Zhang, Half-mode substrate integrated waveguide antenna for multiple orbital angular momentum modes, Electronics Letters, Vol. 52, No. 9, 28th April 2016, pp. 684-685.
  10. Yiling Chen, Shilie Zheng, Yue Li, Xiaonan Hui, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, A flat-lensed spiral phase plate based on phase-shifting surface for generation of millimeter-wave OAM beam, IEEE Antennas and Wireless Propagation Letters, vol. 15, 2016, pp.1156-1158.
  11. Xiaonan Hui, Shilie Zheng, Weite Zhang, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Local topological charge analysis of electromagnetic vortex beam based on empirical mode decomposition, Optics Express, Vol. 24, No. 5, Mar. 2016, pp. 5423-5430.
  12. X. Yu, S. Jia, H. Hu, M. Galili, T. Morioka, X. Zhang, P. U. Jepsen, and L. K. Oxenløwe, 160 Gbps photonics wireless transmission in the 300-500 GHz band, APL Photonics, Vol. 1, No. 8, 2016, pp. 081301.
  13. S. Jia, X. Yu, H. Hu, J. Yu, P. Guan, F. D. Ros, M. Galili, T. Morioka, L. K. Oxenløwe, THz photonic wireless links with 16-QAM modulation in the 375-450 GHz band, Optics Express, vol. 24, no. 21, 2016, pp. 23777-23783.
  14. X. Yu, R. Asif, M. Piels, D. Zibar, M. Galili, T. Morioka, X. Zhang, P. U. Jepsen, and L. K. Oxenløwe, 400GHz wireless transmission of 60 Gb/s Nyquist-QPSK signals using UTC-PD and Heterodyne mixer, IEEE Transactions on Terahertz Science and Technology, Vol. 6, No. 6, 2016, pp. 765 – 770.
  15. S. Jia, X. Yu, H. Hu, J. Yu, T. Morioka, P. U. Jepsen, L. K. Oxenløwe, THz wireless transmission systems based on photonic generation of highly pure beat-notes, IEEE Photonics Journal, Vol. 8, No. 5, 2016, pp. 1-8.
  16. X. Liu, D. X. Yang. Design of terahertz beam splitter based on surface plasmon resonance transition. Chinese Physics B, Vol. 25, No. 4, 2016, 047301.
  17. S. Yang, N. Stol, H. Chi, and Q. Li, Optimized design of delay-line buffers with an input-feedback mechanism for asynchronous optical packet switching networks, Applied Optics, Vol.55, No.31, 2016, pp.8705-8712.
  18. G. Tong, T. Jin, H. Chi, J. Zheng, X. Zhu, T. Lai, X. Wu, and Z. Shi, Reducing the noise floor in optoelectronic oscillator by optimizing the operation of modulator, Optical Engineering, Vol.55, No.10, Oct. 2016, pp.100504.
  19. Y. Mei, B. Xu, H. Chi, T. Jin, S. Zheng, X. Jin, and X. Zhang, Harmonics analysis of the photonic time stretch system, Applied Optics, Vol.55, No.26, Sept. 2016, pp.7222-7228.
  20. Y. Xu, T. Jin, H. Chi, S. Zheng, X. Jin, and X. Zhang, Time-Frequency Uncertainty in the Photonic A/D Converters Based on Spectral Encoding, IEEE Photonics Technology Letters, Vol. 28, April 2016, No. 8, pp. 841-844.
  21. Z. Zhu, H. Chi, T. Jin, S. Zheng, X. Jin, and X. Zhang, Photonic compressive sensing for analog-to-information conversion with a delay-line based microwave photonic filter, Optics Communications, Vol.371, July 2016, pp.83-88.
  22. Y. Chen, Y. Ding, Z. Zhu, H. Chi, S. Zheng, X. Zhang, X. Jin. M. Galili, and X. Yu, Photonic compressive sensing with a micro-ring-resonator-based microwave photonic filter, Optics Communications, Vol.373, Aug. 2016, pp.65-69.

—— 2015 ——

  1. Y. Mei, T. Jin, H. Chi, S. Zheng, X. Jin, and X. Zhang, Characterization of the photonic generation of phase-coded RF signals based on pulse shaping and frequency-to-time mapping, Applied Optics, Vol. 54, No.13, pp. 3956-3962, May 2015.
  2. Z. Zhu, H. Chi, S. Zheng, T. Jin, X. Jin, and X. Zhang, Analysis of compressive sensing with optical mixing using a spatial light modulator, Applied Optics, Vol. 54, No. 8, pp. 1894-1899, March 2015.
  3. Xiannan Hui, Shilie Zheng, Yiling Chen, Yiping Hu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Multiplexed millimeter wave communication with dual orbital angular momentum (OAM) mode antennas, Scientific Reports, Vol. 5, 10148, May 19, 2015.
  4. Shilie Zheng, Xiaonan Hui, Jiangbo Zhu, Hao Chi, Xiaofeng Jin, Siyuan Yu, and Xianmin Zhang, Orbital angular momentum mode-demultiplexing scheme with partial angular receiving aperture, Optics Express, Vol. 23, No. 9, May 4, 2015, pp. 12251-12257.
  5. Yi Wang, Xiaofeng Jin, Yanhong Zhu, Xianmin Zhang, Shilie Zheng, Hao Chi, A wideband tunable optoelectronic oscillator based on a spectral-subtraction-induced MPF, IEEE Photonics Technology Letters, Vol. 27, No. 9, May 1, 2015, pp. 947-950.
  6. Yuan Mei, Tao Jin, Hao Chi, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang, Characterization of the photonic generation of phase-coded RF signals based on pulse shaping and frequency-to-time mapping, Applied Optics, Vol. 54, No. 13, May 1, 2015, pp. 3956-3962.
  7. Xiaonan Hui, Shilie Zheng, Yiping Hu, Chen Xu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Ultralow reflectivity spiral phase plate for generation of millimeter-wave OAM beam, IEEE Antennas and Wireless Propagation Letters, Vol. 14, April 2015, pp. 966-969.
  8. Shilie Zheng, Xiaonan Hui, Xiaofeng Jin, and Hao Chi, and Xianmin Zhang, Transmission characteristics of a twisted radio wave based on circular traveling-wave antenna, IEEE Transactions on Antennas and Propagation, Vol. 63, No. 4, April 2015, pp. 1530-1536.
  9. Zhijing Zhu, Hao Chi, Shilie Zheng, Tao Jin, Xiaofeng Jin, and Xianmin Zhang, Analysis of compressive sensing with optical mixing using spatial light modulator, Applied Optics, Vol. 54, No. 8, March 10, 2015, pp. 1894-1899.
  10. Ying Chen, Xianbin Yu, Hao Chi, Shilie Zheng, Xianmin Zhang, Xiaofeng Jin, and Michael Galili, Compressive sensing with a microwave photonic filter, Optics Communications, Vol. 338, 2015, pp.428–432.

—— 2014及以前 ——

  1. Y. Chen, X. Yu. H. Chi, X. Jin, X. Zhang, S. Zheng, and M. Galili, Compressive sensing in a photonic link with optical integration, Optics Letters, Vol.39, No.8, pp. 2222-2224, April 2014.
  2. Y. Chen, H. Chi, T. Jin, S. Zheng, X. Jin, and X. Zhang, Sub-Nyquist Sampled Analog-to-Digital Conversion Based on Photonic Time Stretch and Compressive Sensing With Optical Random Mixing, Journal of Lightwave Technology, Vol.31, No.21, pp.3395-3401, Nov. 2013.
  3. Hao Chi, Ying Chen, Yuan Mei, Xiaofeng Jin, Shilie Zheng, and Xianmin Zhang, Microwave spectrum sensing based on photonic time stretch and compressive sampling, Optics Letters, Vol. 38, No. 2, pp.136-138, Jan. 2013.
  4. Hao Chi, Yuan Mei, Ying Chen, Donghui Wang, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang, Microwave spectral analysis based on photonic compressive sampling with random demodulation, Optics Letters, Vol. 37, No. 22, pp.4636-4638, Nov. 2012.
  5. Ying Chen, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Differentially- Encoded Photonic Analog-to-Digital Conversion based on Phase Modulation and Interferometric Demodulation, IEEE Photonics Technology Letters, Vol.23, No.24, pp. 1890-1892, Dec. 2011.
  6. Yun Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Photonic approach for microwave spectral analysis based on Fourier cosine transform, Optics Letters, vol. 36, no.19, pp.3897-3899, Oct. 2011.
  7. H. Chi, Z. Li, X. Zhang, S. Zheng, X. Jin, and J. P. Yao, Proposal for photonic quantization with differential encoding using a phase modulator and delay-line interferometers, Optics Letters, vol.36, no.9, pp.1629-1631, May 2011.
  8. Shuna Yang, Chao Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin and Jianping Yao, Photonic analog-to-digital converter using Mach-Zehnder modulators having identical half-wave voltages with improved bit resolution, Applied Optics, Vol.48, No.22, pp.4458-4467, Aug. 2009.
  9. H. Chi, X. Zou and J. P. Yao, Analytical models for phase-modulation-based microwave photonic systems with phase modulation to intensity modulation conversion using a dispersive device, IEEE/OSA Journal of Lightwave Technology, Vol.27, No.5, pp.511-521, March 2009.
  10. Hao Chi, Jianping Yao, Frequency quadrupling and upconversion in a radio over fiber link, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.15, pp.2706-2711, Aug. 2008.
  11. H. Chi, X. Zou and J. P. Yao, An approach to the measurement of microwave frequency based on optical power monitoring, IEEE Photonics Technology Letters, Vol.20, No.17, pp.1249-1251, July 2008.
  12. H. Chi and J. P. Yao, Chirped RF pulse generation based on optical spectral shaping and wavelength-to-time mapping using a nonlinearly chirped fiber Bragg grating, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.10, pp.1282-1287, May 2008.
  13. H. Chi and J. P. Yao, Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator, IEEE Microwave and Wireless Components Letters, Vol.18, No.5, pp.371-373, May 2008.
  14. H. Chi and J. P. Yao, Power distribution of phase-modulated microwave signals in a dispersive fiber-optic link, IEEE Photonics Technology Letters, Vol.20, No.4, pp.315-317, Feb. 2008.
  15. H. Chi and J. P. Yao, A photonic analog-to-digital conversion scheme using Mach-Zehnder modulators with identical half-wave voltages, Optics Express, Vol.16, No.2, pp.567-574, Jan. 2008.
  16. H. Chi and J. P. Yao, Waveform distortions due to second-order dispersion and dispersion mismatches in a temporal pulse shaping system, IEEE/OSA Journal of Lightwave Technology, vol. 25, no.11, pp.3528-3535, November 2007.
  17. H. Chi and J. P. Yao, All-fiber chirped microwave pulse generation based on spectral shaping and wavelength-to-time conversion, IEEE Transactions on Microwave Theory and Techniques, vol. 55, no. 9, pp. 1958-1963, September 2007.
  18. H. Chi and J. P. Yao, An approach to photonic generation of high-frequency phase-coded RF pulses, IEEE Photonics Technology Letters, vol. 19, no. 10, pp. 768-770, May 2007.
  19. H. Chi, F. Zeng, and J. P. Yao, Photonic generation of microwave signals based on pulse shaping, IEEE Photonics Technology Letters, vol. 19, no. 9, pp. 668-670, May 2007.
  20. H. Chi and J. P. Yao, Symmetrical waveform generation based on temporal pulse shaping using an amplitude-only modulator, Electronics Letters, vol. 43, no. 7, pp. 415-417, March 2007.

 

—— 2017 ——

  1. Xianmin Zhang and Shilie Zheng. Grouping plane spiral electromagnetic waves for structured RF beams. The 6th Asia-Pacific Conference on Antennas and Propagation (APCAP), Oct. 16-19, 2017, Xi’an, China. Invited paper
  2. Shilie Zheng and Xianmin Zhang. Capacity analysis of plane spiral orbital angular momentum based multi-input-multi-output (PSOAM-MIMO) system. The Asia-Pacific Microwave Conference on Electromagnetic Compatibility (APEMC), Oct. 16-19, 2017, Xi’an, China. Invited paper
  3. Jiayu Zheng, Shilie Zheng, Zhenlei Shao, and Xianmin Zhang. Rotational Doppler effect based on the radio orbital angular momentum wave. The Asia-Pacific Microwave Conference, Nov. 13-16, 2017, Kuala Lumpur, Malaysia.
  4. Xiangyue Zhang, Jiayu Zheng, Shilie Zheng, Xianbin Yu, Hao Chi, Xiaofeng Jin, and Xianmin Zhang. Generating the orbital angular momentum of wideband frequency signals using helical antenna. The 6th Asia-Pacific Conference on Antennas and Propagation (APCAP), Oct. 16-19, 2017, Xi’an, China.
  5. Ruofan Dong, Yiling Chen, Shilie Zheng, Xianbin Yu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang. Generation of plane spiral orbital angular momentum microwave with ring dielectric resonator antenna. The 6th Asia-Pacific Conference on Antennas and Propagation (APCAP), Oct. 16-19, 2017, Xi’an, China.
  6. Yu Pan, Shilie Zheng, Yanne Chembo, and Xianmin Zhang. Lithium Niobate Whispering Gallery mode disk resonator with high Q factor. The 22nd Opto-Electronics and Communications Conference (OECC) and The 5th Photonics Global Conference (PGC), Jul. 31 – Aug. 4, 2017, Singapore, P4-146.
  7. Changqiao Liu, Boyu Xu, Xiaoqing Shen, Cong Bo, Xiaofeng Jin, Hao Chi, Shilie Zheng, Xianbin Yu, and Xianmin Zhang. Impact of finite extinction ratio of modulator on photonic time-stretch system. International Topical Meeting on Microwave Photonics (MWP),Oct. 23-26, 2017, Beijing, China.
  8. Zhijing Zhu, Hongxia He, Hao Chi, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang. Design of the microwave photonic filter with rectangular response. The 16th International Conference on Optical Communications and Networks (ICOCN), Aug. 7-10, 2017, Wuzhen, China.
  9. Xiaodan Pang, Shi Jia, Oskars Ozolins, Xianbin Yu, Hao Hu, Leonardo Marcon, Pengyu Guan, Francesco Da Ros, Sergei Popov, Gunnar Jacobsen, Michael Galili, Toshio Morioka, Darko Zibar, and Leif K. Oxenløwe. Single channel 106 Gbit/s 16QAM wireless transmission in the 0.4 THz band. The 42nd Optical Fiber Communication Conference & Exposition (OFC), Mar. 19-23, 2017, Los Angeles, America. Top scored
  10. Xianbin Yu, Shi Jia, Xiaodan Pang, Toshio Morioka, and Leif K. Oxenløwe. Beyond 100Gbit/s wireless connectivity enabled by THz Photonics. 2017 International Conference on Transparent Optical Networks (ICTON), Jul. 1-6, 2017, Girona, Spain. Invited talk
  11. Xianbin Yu, Kexin Liu, Shiwei Wang, Shi Jia, Shilie Zheng, and Xianmin Zhang. THz photonics for future smart wireless. Asia Communications and Photonics Conference (ACP), Nov. 10-13, 2017, Guangzhou, China. Invited talk
  12. Hangkai Zhang, Shi Jia, Xianbin Yu, Xiaofeng Jin, Shilie Zheng, Hao Chi, and Xianmin Zhang. Photonic generation of linear frequency modulated terahertz pulses in the 350GHz band with beyond 40GHz bandwidth. Microwave Photonics (MWP), Oct. 23-26, 2017, Beijing, China.

—— 2016 ——

  1. Zhuofan Zhang, Shilie Zheng, Jiayu Zheng, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Plane spiral orbital angular momentum wave and its applications, IEEE International Microwave Symposium (IMS), San Francisco, USA, May 22-27, 2016.
  2. Weite Zhang, Shilie Zheng, Yiping Hu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Multi-OMA-mode microwave communication with the partial arc sampling receiving scheme, IEEE International Microwave Symposium (IMS), San Francisco, USA, May 22-27, 2016.
  3. Yanhong Zhu, Xiaofeng Jin, Xianmin Zhang, Shilie Zheng and Hao Chi, A temperature insensitive load sensor based on a dual loop optoelectronic oscillator, CLEO: Applications and Technology, June 5-11 2016, San Jose California, USA.
  4. Shilie Zheng, Xianmin Zhang, Generation and propagation characteristics of OAM radio waves, 2016 Asia-Pacific International Symposium on Electromagnetic Compatibility, Shenzhen, China, May 17-22, 2016, Invited paper.
  5. Xianmin Zhang, Plane spiral RF waves for communication and detection, ACP workshop on OAM, Wuhan, China, Nov. 2, 2016, Invited talk.
  6. X. Yu, S. Jia, H. Hu, P. Guan, M. Galili, T. Morioka, P. U. Jepsen, and L. K. Oxenløwe, THz photonic wireless transmission of 160 Gbps bitrate, 2016 21th OptoElectronics and Communications Conference (OECC 2016), Postdeadline paper, Niigata, Japan, July 3-7, 2016.
  7. X. Pang, S. Jia, O. Ozolins, X. Yu*, H. Hu, L. Marcon, P. Guan, F. Da Ros, S. Popov, G. Jacobsen, M. Galili, T. Morioka, D. Zibar, L. K. Oxenløwe*, 260Gbps Photonic-Wireless Link in the THz Band, 2016 IEEE Photonics Conference (IPC 2016), Postdeadline paper, Hawaii, USA, October 2-6, 2016.
  8. X. Yu, H. Zhang, S. Jia, T. Morioka, X. Zhang,P. U. Jepsen, L. K. Oxenløwe, Exploring THz band for high speed wireless communications, 41th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2016), Copenhagen, September 26-30, 2016, Invited talk.
  9. S. Jia, X. Yu, H. Hu, J. Yu, T. Morioka, P. U. Jepsen, L. K. Oxenløwe, Experimental analysis of THz communication receiver performance, 41th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2016), Copenhagen, September 26-30, 2016.
  10. S. Jia, X. Yu, H. Hu, J. Yu, T. Morioka, P. U. Jepsen, L. K. Oxenløwe, 80 Gbps 16-QAM multicarrier THz wireless communication link in the 400 GHz band, 2016 42th European Conference and Exhibition on Optical Communication (ECOC 2016), Dusseldorf, Germany, September 19-21, 2016.
  11. X. Yu, K. Liu, H. Zhang, T. Morioka, X. Zhang,P. U. Jepsen, L. K. Oxenløwe, Optical coherent receiver enables THz wireless bridge, The 8th International Symposium on Ultrafast Phenomena and Terahertz Waves (ISUPTW 2016), Chongqing, China, October 2016.
  12. Y. Mei, Y. Xu, H. Chi, T. Jin, S. Zheng, X. Jin, and X. Zhang, “Nonlinearity analysisof photonic time stretch system” ,The 25th Wireless and Optical CommunicationConference, Chengdu, China, 2016.
  13. M. Li, L. Zhang, Y. Wu, and H. Chi, Comprehensive assessment of optical network in power grid, The 15th International Conference on Optical Communications and Networks (ICOCN 2016), Hangzhou, China, 2016.

—— 2015 ——

  1. X. Yu*, R. Asif, M. Piels, D. Zibar, Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, 60Gbit/s 400GHz wireless transmission, Photonics in Switching 2015, Postdeadline paper PDP1, Florence, Italy, 2015 September 22-25.
  2. Yu*, M. Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, Towards ultrahigh speed impulse radio THz wireless communications, 2015 International Conference on transparent optical networks (ICTON 2015), Invited talk, Budapest, Hungary, 2015 July 5-9.
  3. Yu*, Borja Vidal, M. Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, Experimental characterization of extremely broadband THz impulse radio systems, Paper W1E4, 40th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THZ 2015), Hong Kong, 2015 August 25-28.
  4. Yu*, L. K. Oxenløwe, TWIST: THz wireless information systems and technologies, 16th edition of the International Symposium on RFMEMS and RF-MICROSYSTEMS (MEMSWAVE 2015), Invited talk, Barcelona, Spain, 2015 June 29-July 1st.
  5. Yu*, M. Galili, T. Morioka, P. Uhd Jepsen, L. K. Oxenløwe, Ultrafast THz impulse radio communications, 4th Annual World Congress of Advanced Materials-2015 (WCAM2015), Invited talk, Chongqing, China, 2015 May 27-29.
  6. Yu*, X. Zhang, Fundamental analysis of extremely fast photonic THz wireless communication systems, IEEE 8th International Conference on Advanced Infocomm Technology (ICAIT 2015), Invited talk, Hangzhou, China, 2015 October 25-27.

 

专利

 

  1. 每媛、池灏、郑史烈、章献民、金晓峰,一种基于窄带双峰相移光纤光栅的光电振荡器及其方法,ZL201210456227.8,授权日:2014.10.29
  2. 陈莹、池灏、章献民、金晓峰、郑史烈,一种基于压缩采样与时域展宽技术的微波光子测频装置及其方法,专利号:ZL201210455785.2,授权日:2015.01.14
  3. 池 灏、金晓峰、章献民,一种基于受激布里渊散射的微波光子混频方法及装置,专利号:200610050401.3,授权日:2009.09.02
  4. 池 灏、金晓峰、章献民,一种可调谐微波光子滤波器,专利号:200610050400.9,授权日:2009.09.02
  5. 区坚海,金晓峰,章献民,郑史烈,池灏,郑鑫,基于π/2相位调制的干涉型光传感器的正交解调装置,专利号:ZL2011101826195,申请日:2011.07.01,授权公告日:2014.08.20
  6. 陈滢,池灏,章献民,金晓峰,郑史烈,基于压缩采样与时域展宽技术的微波光子测频装置及其方法,专利号:ZL201210455785.2,申请日:2012.11.14,授权公告日:2011.01.14
  7. 每媛,池灏,章献民,郑史烈,金晓峰,一种基于窄带双峰相移光纤光栅的光电振荡器及其方法,专利号:ZL201210456227.8,申请日:2012.11.14,授权公告日:2014.10.29
  8. 彭小东,金晓峰,徐文,李建龙,一种水下声源方位估计方法,国家发明专利,已于2012年9月申请,2014年5月17日授权,专利号:201210392742.4
  9. 施学良,郑史烈,章献民,金晓峰,池灏, 新型同轴结构光纤射频天线, 专利号:ZL201110089783.1,申请日:2011.04.11,授权公告日:2013.09.04
  10. 卢春燕,王翌,金晓峰,章献民,池灏,郑史烈,基于微波光子信号正交锁定的测距方法与装置,专利号:ZL201210170032.7,申请日:2012.05.29,授权公告日:2013.12.04
  11. 杨波,金晓峰,章献民,池灏,郑史烈, 一种基于激光波长调节的频率宽带可调光电振荡器, 专利号:ZL201110282894.4,申请日:2011.09.22,授权公告日:2013.03.13
  12. 施学良,章献民,郑史烈,金晓峰,池灏,基于受激布里渊散射的倾斜光栅传感器,专利号: ZL201110449958.5,申请日:12.29,授权公告日:2013.07.24
  13. 王震宇,章献民,郑史烈,池灏,金晓峰, 基于VCSEL内调制的ROF链路收发装置, 专利号:ZL201010572969.8,申请日:2010.11.30,授权公告日:2013.06.05
  14. 杨波,金晓峰,章献民,池灏,郑史烈, 一种基于光纤环形谐振腔的毫米波发生装置及其方法, 专利号:ZL201010206508.9,申请日:2010.6.22,授权公告日:2013.01.02
  15. 兰宝林,章献民,郑史烈,池灏,金晓峰, 基于偏振检测模块的高速光纤通信中偏振态控制系统,专利号:ZL201010598297.8, 申请日:2010.12.21,授权公告日:2012.07.04
  16. 徐恺,金晓峰,区坚海,章献民,郑史烈,池灏,外差式相位干涉型光纤传感器的正交解调装置,专利号:ZL201010039599.1, 申请日:2010.01.08,授权公告日:2011.12.21
  17. 王翌,金晓峰,章献民,郑史烈,池灏,邹英寅,一种兼有衰减调节功能的微型光纤可调延迟线,专利号:ZL201010040084.3, 申请日:2010.01.19,授权公告日:2011.11.16
  18. 冀军,王翌,金晓峰,章献民,郑史烈,池灏,一种偏振无关的微型光纤可调延迟线,专利号:ZL200910157015.8, 申请日:2009.12.31,授权公告日:2011.07.20
  19. 金晓峰,章飞,冀军,王翌,章献民,邹英寅,池灏,郑史烈,隔离度和中心波长高速可调的光梳状滤波器,专利号:ZL200910100074.1, 授权公告日:2011.02.09
  20. 谢银芳,王健,杨冬晓,一种适用于容阻性负载宽频带的高压简易脉冲发生装置,专利号:ZL201410017003.6,授权公告日:2016.04
  21. 祝艳宏,金晓峰,章献民,郑史烈,池灏,吕武略,基于光电振荡器的振动信息获取方法,专利号:ZL201410151576.8,授权公告日:2016.09
  22. 祝艳宏,金晓峰,金韬,邓圆,控制指向性的水下激光声源及其控制方法,专利号:ZL201410177819.5,授权公告日:2017.01.04
  23. 周锋,金晓峰,章献民,郑史烈,池灏,全光纤结构的电场敏感元件及电场传感装置,专利号:ZL201410519443.1,授权公告日:2017.03.15
  24. 瞿柯林,马川江,金晓峰,章献民,郑史烈,池灏,一种基于激光声源探测水下目标方位及尺寸的测量系统及其测量方法,专利号:ZL201510180547.9,授权公告日:2017.04.12
  25. 吕武略,金晓峰,章献民,郑史烈,池灏,一种干涉型传感器臂长差的测量装置,专利号:ZL201410603812.5,授权公告日:2017.04.12
  26. 每媛,池灏,金韬,郑史烈,章献民,金晓峰,自锁定式光电振荡器及其方法,专利号:ZL201410328872.0,授权公告日:2017.02.22
  27. 回晓楠,郑史烈,章献民,金晓峰,池灏,能产生轨道角动量波束的极低反射率旋转相位板设计方法,专利号:ZL201410539014.0,授权公告日:2017.01.25
  28. 徐晨,郑史烈,章献民,金晓峰,池灏,能产生并传输射频轨道角动量的光学链路,专利号:ZL201410850243.4,授权公告日:2017.02.22
  29. 郑史烈,章献民,金晓峰,池灏,一种用于轨道角动量模式解复用的部分接收方法,专利号:ZL201410850504.2,授权公告日:2017.04.26
  30. 郑史烈,章献民,池灏,金晓峰,Travelling wave loop antenna based on metal ring cavity for generating radio frequency OAM,专利号:US9705200B2,授权公告日:2017.07.11
  31. 郑史烈,陈弋凌,章献民,金晓峰,池灏,一种用于射频轨道角动量模式解复用的取样接收方法,专利号:ZL201410844679.2,授权公告日:2017.10.13
  32. 陈弋凌,李越,回晓楠,郑史烈,章献民,一种基于相移表面的轨道角动量平面螺旋相位板,专利号:201510654873.9,授权公告日:2017.10.20

科研方向

微波光子新型传感与探测技术

研究方向描述

本研究方向主要开展基于微波光子的新型传感与探测技术研究,目标主要针对未知或掩藏目标的传感与探测新方法与新技术的研究,如:空间电磁探测、地下目标探测、掩埋生命探测、水下目标探测等。

负责人:金晓峰教授

太赫兹波功能器件的研究

研究方向描述

太赫兹波功能器件在各类太赫兹波系统中有着不可替代的作用和广泛应用,例如,卫星、飞机等飞行器之间的远距离太赫兹通信系统,短距离太赫兹保密通信系统,太赫兹波雷达系统,太赫兹波成像系统,太赫兹波传感系统等。本研究方向在基于金属表面等离子激子、周期性结构的太赫兹滤波、调制、偏振、波导等功能器件研究,以及基于石墨烯、介质、半导体的太赫兹滤波、调制、波导等功能器件研究等方面,有研究基础。

负责人:杨冬晓教授

射频轨道角动量通信技术研究

研究方向描述描述

移动互联网的普及使得无线通信系统的大容量要求和电磁波频谱资源受限这一矛盾日益凸显。另外微波SAR、多光谱/高光谱遥感卫星的高分辨率化发展亦使得高分卫星通信的数据量海量增加。电磁波的频谱资源非常有限,且基于电磁波的常规参数(频谱、相位、振幅等维度)以扩大信息容量已经得到较为充分的开发和利用。针对无线通信容量不断增长这一重大需求,该方向研究基于轨道角动量(OAM)这一新的物理参数维度的射频OAM波束的调制、复用及解复用等机理,从原理和器件两个层面上寻求其可充分利用的新技术,以期大幅提高无线通信系统频率效率和容量,对于民用或军用通信系统都具有非常重要的意义。

光子毫米波/太赫兹雷达

毫米波/太赫兹雷达系统概念


科研方向描述

毫米波/太赫兹电磁波介于微波和红外线之间,具有宽谱特性,所以它们是很好的宽带信息载体。另一方面太赫兹与红外线相比它具有极高的方向性及较强的沙尘云雾穿透能力,所以它同时在军事和国防等其它领域也有很好的应用。

负责人:余显斌特聘研究员

师资队伍

章献民,教授

1987年毕业于浙江大学电子物理技术专业,199212月获物理电子学与光电子学博士学位。1996年至1998年,先后在日本东京大学和北海道大学作访问研究。2007年在美国麻省理工学院电子学研究实验室作访问研究。199912月晋升为教授,20011月被评为博士生导师。

现为中国电子学会微波分会委员,浙江省电子学会副理事长,浙江省通信学会副理事长。2005年入选教育部新世纪优秀人才支持计划,2006年入选浙江省新世纪151人才工程重点资助培养人员。现任浙江大学信息与电子工程学院院长。

工作研究领域:射频信号处理、微波光子学

电话:0571-87952373
电子信箱:zhangxm@zju.edu.cn

杨冬晓,教授

973项目专家组专家,中国电子学会太赫兹分会委员会委员,中国电子教育学会高等教育分会第六届学术委员会副主任,我国首个学生“反哺”教师的浙江大学信电系平安基金理事会理事长;曾任中国电子学会真空电子学分会第八届委员会副主任委员、第九届委员会副主任委员,2006年-2010年教育部电子科学与技术专业分教指委委员。

目前主要的研究在太赫兹(1 THz = 1000 GHz)科学与技术领域,科研工作包括太赫兹波功能器件的研究;作为项目负责人,完成国家自然科学基金5项(含一年期、交流项目各1项)、国家863项目8项;与他人合作,发表国内外学术期刊论文70余篇、发表国际会议论文20余篇、出版教材3本、出版国际学术专著1本、授权美国发明专利1项、获国家级教学成果二等奖1项、获浙江省高等教育教学成果一等奖1项。

工作研究领域:太赫兹科学与技术、光纤传感与通信

电子信箱:yangdx@zju.edu.cn

金晓峰,教授

1990年本科毕业于华中科技大学光电子系,1993年硕士毕业于中国舰船研究院水声电子专业,1996年博士毕业于浙江大学测试计量技术及仪器专业。2000-2004年期间,曾在美国高科技公司开展研究与开发工作;在光电子技术、电磁场与微波技术、测试计量技术与仪器、水声工程等多个学科与领域具有相关的研究经验。

目前主要从事的研究项目主要包括:科技部973课题、国家科技支撑课题、国家自然科学基金以及其他纵向与企事业联合攻关项目等。

工作研究领域:光通信技术、微波/毫米波技术、微波光子技术、新型传感与探测技术

电子信箱:jinxf00@zju.edu.cn

池灏,教授

信息与电子工程学院电子工程系教授、博士生导师
主要研究兴趣包括光纤通信和光网络、微波光子学、光纤电子学、光子信号处理等。

工作研究领域:光网络与光通信、微波光子学、光子信号处理、光纤电子学

电话:0571-87953871
电子信箱: chihao@zju.edu.cn

郑史烈,教授

1995年毕业于浙江大学,主修材料学,辅修英语。1998年3月获浙江大学材料科学与工程工学硕士学位。1998年4月起任教于浙江大学信息与电子工程系。2003年6月获浙江大学电子科学与技术工学博士学位。2005年11月至2006年3月在日本东北大学智能系从事博士后研究。

迄今在国内外专业期刊发表论文70余篇,其中被SCI收录的论文60余篇。负责或参加多项国家自然科学基金及省自然科学基金项目

工作研究领域:射频信号处理、微波光子学、光网络与光通信器件

电子信箱:zhengsl@zju.edu.cn

余显斌,特聘研究员

2005年于毕业于浙江大学并获得博士学位,2005-2007年在清华大学从事博士后研究工作,2007-2016年在丹麦技术大学工作,先后任职博士后、助理教授和长聘高级研究员,其中2009-2011年为欧盟玛丽居里研究员。主要开展超快毫米波/太赫兹光子处理技术、超高频光子无线通信和太赫兹应用技术等方面技术的研究。

曾主持执行欧盟项目2项,丹麦基金项目3项,并参与欧盟多个项目的研究。截止目前,余博士已著书2章节,发表超过150篇高水平技术论文。指导和合作的学生论文3次获得国际会议优秀论文奖。他多次应邀作国际会议受邀报告,主持过多个国际会议分会。

工作研究领域:超快毫米波/太赫兹光子处理技术、超高频光子无线通信、太赫兹应用技术

电子邮箱:xyu@zju.edu.cn

博士后

贾石

贾石

博士

 

Nazar Muhammad Idrees

Nazar Muhammad Idrees

博士

 

在读研究生

—— 博士研究生 ——

刘长桥

2013级博士

本科:浙江大学
导师:金晓峰

朱之京

2013级博士

本科:浙江大学
导师:池灏

陈弋凌

2013级博士

本科:西安电子科技大学
导师:郑史烈

郑佳瑜

2014级博士

本科:大连海事大学
导师:章献民

汪伟

2014级博士

本科:浙江工业大学
导师:杨冬晓

肖康

2014级博士

本科:天津工业大学
导师:金晓峰

冀军

2016级博士

本科:浙江大学
导师:章献民

何红霞

2016级博士

本科:浙江工业大学
导师:池灏

徐思渊

2017级博士

本科:浙江大学
导师:章献民

易重银

2017级博士

本科:浙江工业大学
导师:池灏

熊孝文

2017级博士

本科:南京邮电大学
导师:郑史烈

王世伟

2017级博士

本科:哈尔滨工业大学(威海)
导师:余显斌

Muhammad Saqlain

2017级博士

本科:University of Engineering & Technology Peshawar, Pakistan
导师:余显斌

—— 硕士研究生 ——

邵振雷

2015级硕士

本科:浙江大学
导师:章献民

张杨

2015级硕士

本科:青岛大学
导师:金晓峰

侯晨涛

2015级硕士

本科:电子科技大学
导师:池灏

金俊傲

2016级硕士

本科:浙江大学
导师:章献民

华琳

2016级硕士

本科:南京邮电大学
导师:章献民

徐川善

2016级硕士

本科:浙江大学
导师:杨冬晓

程志威

2016级硕士

本科:上海大学
导师:金晓峰

郭姣姣

2016级硕士

本科:南京邮电大学
导师:金晓峰

张程慧

2016级硕士

本科:厦门大学
导师:金晓峰

邢俊娜

2016级硕士

本科:西安电子科技大学
导师:池灏

马青

2016级硕士

本科:浙江大学
导师:郑史烈

刘可心

2016级硕士

本科:中山大学
导师:余显斌

周佳良

2017级硕士

本科:北京航空航天大学
导师:章献民

王畅

2017级硕士

本科:中国计量大学
导师:杨冬晓

秦东林

2017级硕士

本科:杭州电子科技大学
导师:金晓峰

杜一杰

2017级硕士

本科:南京工业大学
导师:金晓峰

蒋诗情

2017级硕士

本科:杭州电子科技大学
导师:池灏

王欣悦

2017级硕士

本科:浙江大学
导师:郑史烈

李伟

2017级硕士

本科:浙江大学
导师:余显斌

高翔

2017级硕士

本科:浙江理工大学
导师:余显斌

曹晓晓

2017级硕士

本科:安徽大学
导师:余显斌

毕业研究生

徐晨,2011级博士,导师:章献民

每媛,2011级博士,导师:池灏

徐宇啸,2012级博士,导师:池灏

胡一平,2013级硕士,导师:郑史烈

马川江,2014级硕士,导师:金晓峰

张宇舟,2014级硕士,导师:金晓峰

张维特,2014级硕士,导师:章献民

李明洋,2014级硕士,导师:池灏

章航垲,2015级硕士,导师:余显斌

钱振海,2015级硕士,导师:杨冬晓

徐伯禺,2011级博士,导师:金晓峰

祝艳宏,2012级博士,导师:金晓峰

潘毓,2012级博士,导师:章献民

李艳茹,2013级硕士,导师:章献民

傅蓉蓉,2014级硕士,导师:金晓峰

张倬钒,2014级硕士,导师:章献民

陈昕熠,2014级硕士,导师:郑史烈

赵银龙,2014级硕士,导师:杨冬晓

张向月,2015级硕士,导师:章献民

董若凡,2015级硕士,导师:郑史烈

中心概况

 

        浙江大学信息与电子工程学院射频与光子信息处理研究中心成立于2015年,主要依托一级学科“电子科学与技术”所属的“物理电子学”二级学科,是电子科学与技术一级学科博士点和博士后流动站的组成部分。本研究中心主要开展射频光子技术、太赫兹技术及其应用的研究。

        在射频光子信号处理领域,本研究中心将光子学技术与微波技术、无线通信技术相结合,在国内较早开展了微波毫米波光子学领域的研究。涉及光子微波接收、光控微波光纤延迟线阵列、微波毫米波光子信号产生与处理等方面,形成了自己的学科特色和优势。开展的主要研究工作包括:相控阵雷达天线的光子馈电技术研究、光子微波接收技术研究、基于布里渊散射的光子微波/毫米波信号处理研究、宽带radio over fiber链路研究、微波毫米波频率的光子测量、基于光子学的宽带微波/毫米波信号发生、光子模数转换等,并先后承担了国家973项目课题、863项目课题、国家自然科学基金以及若干军工方面的项目工作。在光载射频通信、光控真时延雷达、微波信号产生、微波光子高灵敏度传感技术方面积累了丰富的研究经验,本团队研发的若干成果得到了若干应用单位的使用,并得到高度评价。

        在太赫兹技术领域,本研究中心在太赫兹滤波、调制、偏振、波导等功能器件等方面,也有非常厚实的研究基础,并正大力推进高速太赫兹无线通信,太赫兹感知信号处理和成像等相关技术的研究。

人员结构

 

中心主任:池灏教授

副主任:郑史烈教授、余显斌特聘研究员

本研究中心有教师6名,其中教授5名,特聘研究员1名。余显斌特聘研究员多年来在丹麦科技大学从事高速接入通信技术和太赫兹通信方面的科研工作,取得丰硕成果,于2015年加入浙江大学信息与电子工程学院射频与光子信息处理中心。 近五年来,本研究中心培养的硕士生超过30名,博士生超过10名,本科生超过100名。

 

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联系我们

如果您对我们的研究感兴趣,欢迎加入我们或开展合作研究。可在右边栏留言或发邮件给我们。地址: 浙江省杭州市 · 浙江大学信息与电子工程学院玉泉校区行政办公楼4楼邮编: 310027邮箱: juny@zju.edu.cn

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浙江大学信息与电子工程学院

射频与光子信息处理研究中心


欢迎您!

研究亮点

研究课题:Ultrafast Photonics Wireless Communicaiton in the THz Band


Superior to photonic millimeter-wave systems, terahertz (THz) band (300 GHz-10 THz) provides a much larger bandwidth and thus promises an extremely high capacity. However, the capacity potential of THz wireless systems has by no means been achieved yet. Here, we have successfully demonstrated 60Gbit/s, 160Gbit/s and 260Gbit/s photonics wireless transmission by using a single THz emitter in the 300-500 GHz band, in close collaboration with DTU, KTH and Tianjin University… 阅读更多

研究课题:基于轨道角动量的MIMO(多入多出)系统的容量增益


在本研究中,我们比较了基于轨道角动量MIMO系统和传统MIMO系统在直射信道信道下的系统容量增益。我们发现在传输距离足够远时OAM-MIMO系统有更大的容量增益。这说明OAM波束能够和现有的MIMO技术很好地融合,并且适用于远距离通信、荒凉地区(多径效应不明显)通信和大规模MIMO系统等多种情况。

阅读更多

研究课题:Multiplexed Millimeter Wave Communication with Dual Orbital Angular Momentum (OAM) Mode Antennas


Communications using the orbital angular momentum (OAM) of radio waves have attracted much attention in recent years. In this paper, a novel millimeter-wave dual OAM mode antenna is cleverly designed, using which a 60GHz wireless communication link with two separate OAM channels is experimentally demonstrated. The main body of the dual OAM antenna is a traveling-wave ring resonator using two feeding ports fed by a 90° hybrid coupler. A parabolic reflector is used to focus the beams… 阅读更多

中心新闻

  • 2018年9月:射频与光子信息处理研究中心硕士生刘可心关于‘Enhanced Accessibility of 350GHz 100Gbit/s 16-QAM Photonic Wireless Communication Links’的研究工作荣获11th UK-Europe-China Workshop on Millimetre Waves and Terahertz Technologies (UCMMT 2018)最佳学生论文奖。热烈祝贺!
  • 2018年5月-9月:余显斌研究员受邀分别参加了OECC 2018 (韩国济州岛),CIOP 2018 (中国北京), ICAIT 2018 (瑞典斯德哥尔摩),APCOPT 2018 (中国西安)和UCMMT 2018(中国杭州)多个国际会议,并作特邀报告,介绍了课题组在光子辅助太赫兹超高速通信方面取得的最新研究进展,展望了该研究领域的应用前景、发展趋势和技术挑战。
  • 2017年11月10-13日:余显斌研究员受邀参加Asia Communications and Photonics Conference (ACP 2017)国际会议并作邀请报告,综述了太赫兹的研究现状、太赫兹光子学在发展超高速太赫兹通信技术的应用等。ACP 2017于11月10-13日在中国广州举行。
  • 2017年7月2-6日:余显斌研究员受邀参加19th International Conference on Transparent Optical Networks (ICTON 2017)国际会议,并作邀请报告‘Beyond 100Gbit/s wireless connectivity enabled by THz Photonics’,介绍了课题组最近在超高速光子太赫兹通信技术方面取得的成果。ICTON 2017于7月2-6日在西班牙Girona举行。
  • 2017年5月8-10日:由章献民教授担任TPC Chair的2017年全国微波毫米波会议(NCMMW2017)暨2017年微波毫米波科技成果及产品展(MWIE2017)在杭州市浙江会议中心(之江饭店)成功举行。 大会邀请了40位微波毫米波领域国内外知名专家作特邀报告,近700专家和代表参加了学术交流。另外,近30家微波毫米波领域单位参加了本届微波展览。
  • 2017年5月8日:西班牙瓦伦西亚理工大学副教授Borja Vidal于5月6日-12日在射频与光子信息处理研究中心交流访问,并作精彩Tutorial报告‘Microwave and Terahertz Photonics’。报告综述了光子学在微波/毫米波信号馈送、产生以及处理等方面的一些关键技术,并重点介绍了非线性光学效应和光子集成在提高相关信号处理性能方面的应用,以及太赫兹光子技术在宽谱探测方面的研究进展。
  • 2017年4月24日:美国Virginia Diodes公司创始人兼CEO Thomas W. Crowe博士来访并作精彩报告‘Submillimeter-wave Instrumentation,报告主要介绍了基于肖特基二极管的太赫兹器件及其在无线电天文学、等离子体诊断和安检成像领域的应用。Thomas Crowe博士于1986-1997年任教于弗吉尼亚大学,于1996年成立了VDI公司并担任CEO至今。他的研究领域包括:太赫兹集成半导体器件技术、太赫兹化学和生物传感的技术、太赫兹目标特性技术。
  • 2017年3月20日:余显斌博士和瑞典NETLAB/KTH、丹麦技术大学DTU以及天津大学合作完成的106Gbit/s超高速400GHz通信传输研究成果在2017年光通信国际会议OFC(The Optical Networking and Communication Conference)获得‘TOP SCORED’论文。X. Pang, S. Jia, O. Ozolins, X. Yu, H. Hu, L. Marcon, P. Guan, F. D. Ros, S. Popov, G. Jacobsen, M. Galili, T. Morioka, D. Zibar, L. K. Oxenloewe, Single Channel 106Gbit/s 16QAM Wireless Transmmission in the 0.4 THz band.
  • 2016年10月31日:余显斌博士发表在APL Photonics上关于超高速太赫兹无线通信的研究成果,最近被Nature Photonics列为研究亮点(Research Highlights)。该项研究工作实验演示了300-500GHz频段单天线160Gbit/s的无线传输,首次成功展示了太赫兹频段在支撑>100Gbit/s超高速无线通信的潜力。X. Yu, S. Jia, H. Hu, M. Galili, T. Morioka, P. U. Jepsen, L. K. Oxenloewe, 160Gbit/s photonics wireless transmission in the 300-500 GHz band, APL PHOTONICS 1, 081301 (2016).
  • 2016年10月24日: 热烈祝贺射频与光子信息处理研究中心3名研究生获得奖学金。张倬钒,2014级硕士,荣获浙江大学最高奖学金荣誉——竺可桢奖学金。陈弋凌,2013级博士,荣获研究生国家奖学金。张维特,2014级硕士,荣获研究生国家奖学金。3名同学在研究生期间都参与了国家973、863和国家自然基金等重大科研项目的研究,在射频轨道角动量的多项关键技术取得突破和进展。再次祝贺!
  • 2016年10月6日:余显斌研究员与瑞典NETLAB、丹麦技术大学DTU、瑞典皇家工学院KTH以及天津大学的联合研究成果‘260Gbit/s Photonic-Wireless Link in the THz Band’被接收为光电领域国际会议IPC的POSTDEADLINE paper!该项研究工作成功实现了在300-500GHz频段的260Gbit/s超高速率无线传输,进一步更新了之前在该频段保持的60Gbit/s、160Gbit/s速率记录。IPC国际会议是是在光子学领域的重要国际会议之一,是IEEE光电子学会的旗舰年度峰会。IPC 2016于2016年10月2-6日在美国夏威夷举行。
  • 2016年9月30日:余显斌研究员参加2016 IRMMW-THz国际会议,并作邀请报告‘Exploring THz frequency bands for high speed wireless communications’,介绍了他在高速太赫兹通信技术方面取得的成果,并对最近国际上高速太赫兹毫米波太赫兹波通信技术的研究现状进行了回顾和分析。IRMMW-THz是太赫兹技术研究的专题国际会议,2016年为第41届,在丹麦哥本哈根举行。余显斌研究员还主持了一个IRMMW-THz分会场。
  • 2016年7月5日:余显斌研究员与丹麦技术大学、天津大学的联合研究成果‘THz Photonics-Wireless Transmission of 160 Gbit/s Bitrate’被接收为光电领域国际会议OECC的POSTDEADLINE paper!该项研究工作成功实现了在300GHz-500GHz频段的160Gbit/s记录性高速率无线传输。OECC国际会议是光电子、光纤传输系统和网络方面的顶级会议之一,OECC 2016于2016年7月3-7日在日本Niigata举行。丹麦技术大学的Dr. Pengyu Guan将宣讲该POSTDEADLINE paper。
  • 2016年5月21日:章献民教授、郑史烈副教授和2名博士生参加国际会议 – The IEEE International Microwave Symposium (IMS)。IMS国际会议是由IEEE MTT协会组织的、关于射频和微波技术最新进展的顶级会议。2016年IMS国际会议于5月22-27日在美国加州旧金山举行。

Welcome to


Research Center for RF & Photonic Information Processing

College of Information Science and Electronic Engineering at Zhejiang University

Research Highlights

Research topic: Multiplexed Millimeter Wave Communication with Dual Orbital Angular Momentum (OAM) Mode Antennas


Communications using the orbital angular momentum (OAM) of radio waves have attracted much attention in recent years. In this paper, a novel millimeter-wave dual OAM mode antenna is cleverly designed, using which a 60GHz wireless communication link with two separate OAM channels is experimentally demonstrated. The main body of the dual OAM antenna is a traveling-wave ring resonator using two feeding ports fed by a 90° hybrid coupler. A parabolic reflector is used to focus the beams… Read more

Research topic: The Capacity Gain of Orbital Angular Momentum Based Multiple-Input-Multiple-Output System


In this work, we compare the technique of using uniform linear array consist of circular traveling-wave OAM antennas for multiplexing with the conventional multiple-in-multiple-out (MIMO) communication method, and numerical results show that the OAM based MIMO system can increase channel capacity while communication distance is long enough.Our results reveal that OAM waves are complementary with MIMO method. OAM waves multiplexing is suitable for long-distance line-of- sight (LoS) communications or communications in open area where the multi-path effect is weak and can be used in massive MIMO systems as well. Read more

Latest News

  • 2016.10.06: Another POSTDEADLINE paper on ‘260Gbit/s Photonic-Wireless Link in the THz Band’is accepted to present at the IEEE Photonics Conference (IPC), which is held in Hawaii, USA. This work is collaborated among NETLAB and KTH in Sweden, DTU in Denmark, Tianjin University and Zhejiang University in China. Up to now, we have successfully demonstrated the record datarates of 60Gbit/s, 160Gbit/s and 260Gbit/s in the 300-500GHz band.
  • 2016.09.30: Dr. Yu gave an invited talk ‘Exploring THz frequency bands for high speed wireless communications’ at the 41st International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz) conference held in Copenhagen, Denmark. In the talk, he reviewed the state-of-the-art work about high speed millimeter-wave/THz communication.
  • 2016.07.05: One paper entitled ‘THz Photonics-Wireless Transmission of 160Gbit/s Bitrate’ is accepted as a POSTDEADLINE paper at the 21st Opto Electronics and Communications Conference/International Conference on Photonics in Switching 2016 (OECC/PS 2016), which is held this year in July 2016, Niigata, Japan. This work is conducted by Dr. Yu from the RPIP, in close collaboration with Technical University of Denmark and Tianjin University.
  • 2016.05.21: Prof. Xianmin ZHANG, Associate Prof. Shilie ZHENG and 2 Ph.D. students attended the IEEE International Microwave Symposium (IMS). The 2016 IEEE International Microwave Symposium (IMS2016) to be held in San Francisco, California, 22-27 May 2016. IMS2016, organized by the IEEE Microwave Theory and Technique Society (MTT-S), is the premier conference for attendees to learn about the latest information in the RF and microwave industry.