Beijing Time: GMT+8 ICICN Conference Program.pdf · Session T5: High Power Laser Source,...

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Organized by Co-Organized by CO-Sponsored by

ICICN

Conference Program

IEEE The 8 th International Conference

on Information, Communication and Networks

Beijing Time: GMT+8

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P.3 Welcome Address

P.4 Conference Committees

P.6 Guideline for Online Conference

P.7 Schedule at a Glance

P.8 Plenary & Keynote Speakers Details

Plenary Speaker I: Prof. Chao Lu

Keynote Speaker I: Prof. Xizheng Ke

Plenary Speaker II: Prof. Alexey Kavokin

Plenary Speaker III: Prof. Kenneth Grattan FREng

Plenary Speaker IV: Prof. David Payne

P.15 Schedule in Details from August 22nd to August 25th

August 22nd: Test

August 23rd: Keynote, Plenary and Invited Speeches

August 24th: Invited Speeches

August 25th: Oral Sessions

P.26 Invited Speeches in Details

P.56 Oral Presentation Abstract

P.73 Listeners

Table of Contents

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Dear distinguished delegates,

We are pleased to welcome you to 2020 IEEE The 8th International Conference on Information,

Communication and Networks (ICICN 2020), which will be held online on August 22-25, 2020 due to

COVID-19.

ICICN is organized by Shaanxi Normal University, China, co-organized by Xi`an University of Posts &

Telecommunications, China, Northwestern Polytechnical University, China, Supported by Nanyang

Technological University, Singapore, Macau University of Science and Technology, China, Xi`an Jiaotong

University, China, Xi'an University of Technology, China, Huazhong University of Science and Technology,

China, Liaocheng University, China, and Scienece and Engineering Institute, USA, etc.

After several rounds of review procedure, the program committee accepted those papers to be published

by IEEE in ICICN 2020 conference proceedings. We wish to express our sincere appreciation to all the

individulas who have contributed to ICICN 2020 in various ways. Special thanks are extended to our

colleagues in the program committee for their thorough review of all the submissions, which is vital to the

success of the conference, and also to the members in the organizing committee and the volunteers who

had delicated their time and efforts in planning, promoting, organizing and helping the conference.

This conference program is highlighted by four Plenary Speakers: Prof. Chao Lu, The Hong Kong Polytechnic

University, Hong Kong; Prof. Alexey Kavokin, Westlake University, China; Prof. Kenneth Grattan FREng, The

Royal Academy of Engineering, The UK National Academy of Engineering, City University London, UK; Prof.

David Payne, University of Southampton, UK; and one Keynote Speaker: Prof. Xizheng Ke, Xi'an University

of Technology, China.

One best presentation will be selected from each session, evaluated from: originality; applicability;

technical Merit; qualities of PPT; English. The best one will be announced at the end of each Session, and

we will e-mail you after conference.

Yours sincerely,

Conference Organizing Committees

Welcome Address

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Organizing Committee

Honorary Chairs

Xun Hou, Xi'an Jiaotong University, China (Academician, Chinese Academy of Sciences)

Hongxing Xu, Wuhan University, China (Academician, Chinese Academy of Sciences)

Xuelong Li, Northwestern Polytechnical University, China (IEAS Academician)

General Chairs

Perry Ping Shum, Nanyang Technology University, Singapore (OSA Fellow, SPIE Fellow)

Jianlin Zhao, Northwestern Polytechnical University, China

Hairong Zheng, Shaanxi Normal University. China

General Co-chair

Xiaohui Li, Shaanxi Normal University, China

Techical Program Committee Chairs

Qijie Wang, Nanyang Technology University, Singapore

Xizheng Ke, Xi'an University of Technology, China

Wenhui Fan, Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, China

Jiamin Gong, Xi'an University of Posts and Telecommunications, China

Jianqing Li, Macau University of Sience and Technology, China

Nan-Kuang Chen, Liaocheng University, China

Xiaoqiang Lu, Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, China

Local Chairs

Pengfei Liang, Shaanxi Normal University, China

Dong Mao, Northwestern Polytechnical University, China

Lei Zhang, Xi'an Jiaotong University, China

TPC Members

Howard Lee, Baylor University and Texas A&M, USA

Qizhen Sun, Huazhong University of Science and Technology, China

Jianzhong Hao ,Institute for Infocomm Research, Singapore

Bandar M. Alshammari, Aljouf University, Saudi Arabia

Zhicai Shi, Shanghai University of Engineering Science, China

Wen-Jyi Hwang, National Taiwan Normal University, Taiwan

Svetlana Vasileva-Boyadzhieva, International College - Dobrich, Bulgaria

Tatsuya Yamazaki, Niigata University, Japan

Ali Marzoughi, The University of New South Wales, Australia

Nitikarn Nimsuk, Thammasat University, Thailand

Abu Bakar Ibrahim, Universiti Pendidikan Sultan Idris, Malaysia

Tushar Jaware, R.C.Patel Institute of Technology, India

Aashish A. Bardeka, Sipna College of Engineering & Technology, India

Paulo Batista, University of Évora, Portugal

Wen Qi, Donghua University, China

Conference Committees

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Jain-Shing Liu, Providence University, Taiwan

Yanping Zhang, Gonzaga University, USA

Dong Huang, Chinese Academy of Sciences, China

Abhishek Kumar, Rajasthan Technical University, India

Chiunhsiun Lin, National Taipei University, Taiwan

Shaobo Du, Guizhou University of Commerce, China

Yanwen Wang, Xijing University, China

Sunqing Su, Jimei University, China

Retno Wigajatri Purnamaningsih, Universitas Indonesia, Indonesia

Honglin Liu, China Jiliang University, China

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Time The whole program is arranged by Beijing Time (UTC+8), please double-check your Test Time and Presentation

Time, and update withyour Local Time on your own schedule, to make sure be online on time.

TEST DAY:August 22-For test of some basic fuctions we would use during conference.

Tool Equipment Needs to Be Prepared

ZOOM (https://zoom.com.cn/) will be used for the

whole online event. On the buttom of the web page,

you can choose download the app for free and then

choose ‘JOIN A MEETING ’, then input room’s ID.

As usual you could not creat an account in China now, so you

can join in our conference as a visitor, ZOOM may ask you to

input your phone number and the passwords they sent to your

number to verify.

Please prepare a digital device with

Microphone(mandatory) and Webcam(optional), a

computer or laptop is recommended; Andmake sure

you are connected to a stable and high-quality Wi-Fi

network, or 4G or Internet if available.

How To Use Zoom: https://support.zoom.us/hc/en-us/articles/206618765-Zoom-Video-Tutorials

Presentation Tips

1 2

1 2 3

Please prepare a computer or

laptop with Microphone and

enough battery and connect to a

stable and high-quality Wi-Fi

network; If not, please pre-record

present video with 10mins and 5

mins for Q&A.

Please stay at a quiet place with

proper lighting, and without any

noise; This is a formal academic

event, please wear formal dress

and behave properly.

Presentation Time: Total 15 Mins for

every presenter, 10 Mins for

presentation, and 5 Mins for Q&A.

At first, please do a self introduction

of presenter yourself, then share

your screen, and star the

presentation.

4 5 6

One best Presentation will be

chosen from each session and

announced at the end of the

session. The conference secretary

will email you the certificates after

the conference.

For those video presentations,

you can ask the staff to help you

play or play it by yourself. But

please stay online during your

sessions

An English PPT must be prepared

and use English during the

presentation

Please enter in your session’s room

10 Mins earlier of the start of

sessions.

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Each Presentation will be recorded,

if you don’t want it, please inform

our staff ahead of time.

Guideline for Online Conference

https://zoom.com.cn/https://support.zoom.us/hc/en-us/articles/206618765-Zoom-Video-Tutorials

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Beijing Time: GMT+8

August 22nd

-Test

10:00-18:00 Test

August 23rd

-Plenary, Keynote and Invited speeches

Room A : ID: 661 4324 8539

9:00-9:05 Opening Remarks:

Prof. Hairong Zheng, Dean of Graduate School, Shaanxi Normal University, China

9:05-9:50 Plenary Speaker I:

Prof. Chao Lu, The Hong Kong Polytechnic University, Hong Kong

9:50-10:35 Keynote Speaker I:

Prof. Xizheng Ke, Xi'an University of Technology, China

10:35-11:00 Morning Break

11:00-11:45 Plenary Speaker II:

Prof. Alexey Kavokin, Westlake University, China

11:45-13:30 Lunch Break

13:30-15:30 Invited Speakers of topic: Space Communications, Navigation and Tracking

16:00-16:45 Plenary Speaker III:

Prof. Kenneth Grattan FREng, City University London, UK

16:45-17:30 Plenary Speaker IV:

Prof. David Payne, University of Southampton, UK

August 24th

-Invited Speeches

Room A : ID: 661 4324 8539 Room B : ID: 613 2916 2069

9:30-12:10 Session T1: Optical Communications and Networks Session T2: Quantum Information and Related

Quantum Technologies


13:30-15:50 Session T3: Optical Communications, Networks and

Ultrafast Photonics

Session T4: Quantum Information and Related


15:50-16:00 Afternoon Break

16:00-18:20 Session T5: High Power Laser Source, Fiber-based

Devices and Applications

Session T6: Quantum Information and Related


August 25th

-Oral Sessions

Room A : ID: 661 4324 8539 Room B : ID: 613 2916 2069

10:00-11:30 Session 1: Data and Information Engineering Session 2: Intelligent Calculation and Application


Room A : ID: 661 4324 8539 Room B : ID: 613 2916 2069 Room C: ID: 697 6169 9793

14:00-15:30 Session 3: Communication

Principle and Technology

Session 4: Wireless

Communication

Session 5: Space

Communications, Navigation

and Tracking


16:00-17:45 Session 6: Wireless Network

Session 7: Micro/nano-photonic

Device and All Optical Signal

Processing

Session 8: Information

Communication and

Management

Ps: Any questions, please contact our Wechat: 18108245450 or e-mail: icicn@ [email protected], we are always online.

Schedule at a Glance

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Biography Abstract

Prof. Chao LU obtained his BEng in Electronic Engineering

from Tsinghua University, China in 1985, and his MSc and PhD

from University of Manchester in 1987 and 1990 respectively.

He joined the School of Electrical and Electronic Engineering,

Nanyang Technological University(NTU), Singapore in 1991

and has been there as a Lecturer, Senior Lecturer and

Associate Professor until 2006. From June 2002 to December

2005, he was seconded to the Institute for Infocomm

Research, Agency for Science, Technology and Research

(A*STAR), Singapore, as Program Director and Department

Manager leading a research group in the area of optical

communication and fibre devices. He joined Department of

Electronic and Information Engineering, The Hong Kong

Polytechnic University as Professor in 2006 and is Chair

Professor of Fibre Optics there now. Over the years, he has

published more than 300 papers in major international

journals and has given a number of invited talks in major

international conferences. He has been organizer or technical

program committee member of many international

conferences. His current research interests are in the area of

high capacity transmission techniques for long haul and short

reach systems and distributed optical sensing systems. In

addition to academic research work, he has had many

industrial collaborative research projects and has a number of

awarded patents. He is fellow of the Optical Society(OSA).

Optical communication technologies have been developed

rapidly in the past 20 years. How to further increase the

capacity and efficiency of future high capacity optical

networks is the challenge facing our research community

now. In the talk, I will review the current development in

the area and discuss the possible future development in

devices, system and networks technologies.

Plenary Speaker I

Prof. Chao Lu

The Hong Kong Polytechnic University,

Hong Kong

Title: Optical Communication Systems:

Current Status and Future Perspectives

Room A ID: 661 4324 8539

Test Time: 17:00-17:10, August 22nd

Speech Time: 9:05-09:50, August 23rd

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Biography Abstract

Xizheng Ke, Ph.D., Second-level Professor, head of information

and communication system discipline of Xi'an University of

Technology, deputy director of Shaanxi Provincial Key

Laboratory of Intelligent Cooperative Network Military-civilian

Joint Construction. Famous Teaching Teacher of Shaanxi

Province, Fellow of Chinese Institute of Electronics, Director of

Chinese Optical Engineering Society, Standing Director of

Shaanxi Optical Society. He received his bachelor's degree from

Shaanxi Institute of Technology in 1983 and his Ph.D. degree

from University of Chinese Academy of Sciences in 1996. From

1997 to 2002, he did post-doctoral research in Xidian University

and the Second Artillery Engineering Institute. He is an editorial

board member of "Journal of Electronics", "Infrared and Laser

Engineering", "Journal of Electronic Measurement and

Instruments", "Laser Technology", "Applied Optics", "Journal of

Xi'an University of Technology", Editorial Board Member of

Journal of Time and Frequency, Editorial Board Member of

National Science and Technology Awards Review Expert of

"Journal of Atmospheric Science Research", Member of Subject

Review Group of Shaanxi Provincial Academic Degrees

Committee. He won the Outstanding Young Scholar Award of

the Chinese Academy of Sciences in 2000, and he was awarded

the title of "Excellent Science and Technology Commissioner of

Guangdong Province of the Ministry of Education of the

Ministry of Science and Technology" in 2009. Also, he won the

title of “Leader of Green Yang Jinfeng” in Yangzhou City in

2015, the China Industry-University-Research Innovation Award

in 2018, the second prize of China Industry-University-Research

Innovation Achievement in 2019 and the title of "Excellent

Scientific and Technological Worker of Chinese Institute of

Electronics" in 2020. Since 2001, he has won 16 provincial and

ministerial science and technology awards, including 1

first-class prize and 5 second-class prizes. He has obtained

more than 20 national authorized invention patents, published

9 monographs in Science Press, and more than 400 academic

papers in domestic and foreign journals with citation H index

26 and G index 42. Till now, more than 30 doctoral students

have been cultivated under his direction.

Compared with the direct detection technology, the

coherent detection technology of free space optical

communication has a detection sensitivity of about 20

dB gain, which is more suitable for long-distance laser

communication. A free space optical communication

field experiment based on heterodyne detection is built in

the near ground 100 km link from erlangjian to Quanji

Township, Qinghai Lake. The experimental results show

that the PTZ motor at the transmitting end adopts the

rectangular scanning mode, and the infrared camera at

the receiving end can capture the beam and realize the

beam alignment step by step; the adaptive optical system

based on the combination of fast steering mirror and

deformable mirror can complete the wavefront

correction, and the effect of simultaneous correction of

fast steering mirror and deformable mirror is better than

that of single correction of fast steering mirror or

deformable mirror; multi antenna emission junction

compared with the single antenna transmission structure,

the structure can effectively improve the average value

of the coupling optical power of the receiver, and the

variance of the coupling power of the multi antenna

transmission in the receiver is smaller than that of the

single antenna transmission, which shows that the multi

antenna transmission technology can effectively suppress

the light intensity flicker.

Keynote Speaker I

Prof. Xizheng Ke

Xi'an University of Technology, China

Title: Experimental study on 100km free

space coherent optical communication

Room A ID: 661 4324 8539



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Biography Abstract

Professor Alexey Kavokin has received his PhD in Physics

from the Ioffe Institute of Russian Academy of Sciences in

1993. In 1998 he has become a Professor of the Blaise

Pascal University, Clermont-Ferrand, France. In 2005 he has

joined the University of Southampton, United Kingdom, as a

Chair of Nanophysics and Photonics. In 2018 he has moved

to China where he now works as a Chair Professor and

Director of the International Center for Polaritonics at the

Westlake university, Hangzhou. The track record of Prof.

Kavokin includes over 400 publications mostly devoted to

the physics of strongly coupled light-matter systems. He

authored the monographs “Cavity polaritons” (Elsevier,

2003) and “Microcavities” (Oxford University Press, 2007,

2013). His awards include the Marie Curie Chair of

Excellence in Rome (2006), the Megagrant of the

Government of Russian Federation (2011) and the

Established Career Fellowship of the EPSRC (United

Kingdom, 2013). Main research achievements include the

theory of Polariton lasing, the predictions of Optical Spin

Hall and Spin Meissner effect and the series of works

toward observation of the Light Induced Superconductivity.

Superconducting flux qubits are based on a superposition of

clock-wise and anti-clockwise currents formed by millions

of Cooper pairs. In order to excite the system in a

superposition state, the half-quantum flux of magnetic field

is passed through the superconducting circuit containing one

or several Josephson junctions. The system is forced to

generate a circular current to either reduce the magnetic flux

to zero or to build it up to a full-quantum flux. Circular

currents of exciton-polaritons mimic the superconducting

flux qubits being composed by a large number of bosonic

quasiparticles that compose a single quantum state of a

many-body condensate. The essential difference comes from

the fact that polaritons are electrically neutral, and the

magnetic field would not have a significant effect on a

polariton current. We note however, that the phase of a

polariton condensate must change by an integer number of

2π, when going around the ring. If one introduces a π-phase

delay line in the ring, the system is obliged to propagate a

clockwise or anticlockwise circular current to reduce the

total phase gained over one round-trip to zero or to build it

up to 2π. We show that such a π-delay line can be provided

by a dark-soliton embedded into a ring condensate and

pinned to a potential well created by the C-shape

non-resonant pump-spot. The physics of resulting split-ring

polariton condensates is essentially similar to the physics of

flux qubits. In particular, they exhibit pronounced Bloch

oscillations passing periodically through clockwise and

anticlockwise current states as Figure 1 shows. We argue

that qubits based on split-ring polariton condensates may be

characterized by a high figure of merit that makes them a

valuable alternative to superconducting qubits.

Room A ID: 661 4324 8539



Plenary Speaker II

Prof. Alexey Kavokin

Westlake University, China

Title: Qubits based on Split-Ring

Condensates of Exciton Polaritons

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Figure 1. The considered shape of a non-resonant pump spot

(a), the oscillations of the topological charge of the resulting

split-ring polariton condensate (b), snap-shots of the

absolute value of the many-body wave-function of the

polariton condensate (left panels), its phase (middle panels)

and phase for the fixed radius (right panels) at different

stages of the time evolution ((c) m=0.3, (d) m=0, (e)

m=-0.3)).

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Biography Abstract

Professor Grattan graduated in Physics from Queen's University

Belfast with a BSc (First Class Honours) in 1974, followed by a

PhD in Laser Physics. His doctoral research involved the use of

laser-probe techniques for measurements on potential new

laser systems.

Following Queen's, in 1978 he became a Research Fellow at

Imperial College of Science and Technology, sponsored by the

Rutherford Laboratory to work on advanced photolytic drivers

for novel laser systems. This involved detailed measurements

of the characteristics and properties of novel laser species and

a range of materials involved in systems calibration.

In 1983 he joined City University London as a "new blood"

Lecturer in Physics, being appointed Professor of Measurement

and Instrumentation in 1991 and Head of the Department of

Electrical, Electronic and Information Engineering. From 2001

to 2008 he was the Associate and then Deputy Dean of the

School of Engineering and from 2008 to 2012 the first Conjoint

Dean of the School of Engineering & Mathematical Sciences

and the School of Informatics. In 2013 he was appointed the

Inaugural Dean of the City Graduate School. He was appointed

George Daniels Professor of Scientific Instrumentation in 2013

and to a Royal Academy of Engineering Research Chair in 2014.

His research interests have expanded to include the

development and use of fibre optic and optical systems in the

measurement of a range of physical and chemical parameters.

The work has been sponsored by a number of organizations

including EPSRC, the EU, private industry and charitable

sources, and he holds several patents for instrumentation

systems for monitoring in industry using optical techniques. He

obtained the degree of Doctor of Science (DSc) from City

University in 1992 for his sensor work. Professor Grattan is

extensively involved with the work of the professional bodies

having been Chairman of the Science, Education and

Technology of the Institution of Electrical Engineers (now IET),

the Applied Optics Division of the Institute of Physics and he

was President of the Institute of Measurement and Control

during the year 2000. He has served on the Councils of all three

of these Professional Bodies. He was awarded the Callendar

Medal of the Institute of Measurement and Control in 1992,

and twice the Honeywell Prize for work published in the

Optical Fibre Sensors have been developed extensively

now over some four decades – created to address a range

of challenging industrial applications where conventional

sensors often are badly conditioned for important

monitoring needs. Systems are required to enhance

safety, to allow assets to be used for longer, to schedule

repair and maintenance better and to create a more cost

effectively and improve the working environment for us

all. As an example, the demands of electric and

autonomous transport, be it on land, sea or air, as well as

energy generation and distribution and robotics make

enormous demands for better sensor systems.

This talk will review the essential background to and

history of optical fibre sensors and then look at how a

range of optical fibre-based techniques can be applied to

problems such as those highlighted and offer alternative,

and better solutions to those from current technologies be

they electronic, hydraulic, electrochemical, and analogue

or digital – revealing solutions which have the potential

readily to be adopted by industry. The work will

review a number of ‘case studies’, where working in

collaboration with industry and researchers across the

world, new and practical solutions to key problems have

been found and implemented in-the-field, not just as

laboratory demonstrations.

Plenary Speaker III

Prof. Kenneth Grattan FREng

City University London, UK

Title: Optical fiber sensors: better

solutions for Challenging Industrial

Measurement Problems?

Room A ID: 661 4324 8539



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Institute's journal as well as the Sir Harold Hartley Medal in

2012 for distinction in the field of instrumentation and control.

He was awarded the Applied Optics Divisional Prize in 2010 for

his work on optical sensing and the honorary degree of Doctor

of the University of the University of Oradea in 2014.

He was elected President of the International Measurement

Confederation (IMEKO) in 2014, serving from 2015 to 2018. He

was elected to the Royal Academy of Engineering, the UK

National Academy of Engineering, in 2008.

Professor Grattan has been Deputy Editor of the Journal

Measurement Science and Technology for several years and

currently serves on the Editorial Board of several major

journals in his field in the USA and Europe. In January 2001 he

was appointed Editor of the IMEKO Journal "Measurement"

and also serves on their General Council. He is the author and

co-author of over seven hundred refereed publications in major

international journals and at conferences and is the co-editor

(with Professor B T Meggitt) of a five volume topical series on

Optical Fiber Sensor Technology. His work is highly cited by his

peers nationally and internationally. He is a Visiting Professor at

several major Universities in China, with strong links to Harbin

Engineering University and the Shandong Academy of Sciences.

Professor Grattan has been a Member of the University

Executive Committee (ExCo) since 2008 and chairs two of its

sub-Committees, the University Sustainability Committee and

the Business Continuity Management Committee. He has

served on Senate for over 20 years, as well as many of its

sub-Committees.

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Biography Abstract

Prof. Sir David Neil Payne CBE FRS FREng is Director of the

Optoelectronics Research Centre at the University of

Southampton UK. His work has had a great impact on

telecommunications and laser technology over the last forty

years. The vast transmission capacity of today’s internet

results directly from the erbium-doped fibre amplifier

(EDFA) invented by David and his team in the 1980s. His

pioneering work in fibre fabrication in the 70s resulted in

almost all of the special fibres in use today including fibre

lasers. With US funding, he led the team that broke the

kilowatt barrier for fibre laser output to international

acclaim and now holds many other fibre laser performance

records. He has published over 650 Conference and Journal

papers. As an entrepreneur David’s activities have led to a

cluster of 11 photonics spin-out companies in and around

Southampton. He founded SPI Lasers PLC, which was

acquired by the Trumpf Corporation of Germany. He is an

Emeritus Chairman of the Marconi Society and a foreign

member of the Russian Academy of Sciences, the Indian

National Science Academy and the Indian Academy of

Engineering. David is a fellow of the Royal Society and the

Royal Academy of Engineering.

The internet is perhaps the most important and

life-changing invention of the 20th century. It required the

invention of a new global communication medium capable

of carrying vast quantities of information across

trans-oceanic distances, reliably, cheaply and efficiently.

Unpredictably, this turned out to be optical fibres made

from the two most common elements of the earth’s crust,

silicon and oxygen (silica).

As the internet traffic grows by some estimates at

40%/annum there is constant pressure to find more fibre

capacity, although at $8/km the option remains to simply

install more fibre, rather than find better fibres. However,

in many applications where duct volume, single fibre

capacity, reduced transit time or better phase stability is

critical, there will be a role for novel advanced designs such

as hollow-core or multi-core fibres. Transit time and

stability is becoming increasingly important for global

timing, time-stamping for financial trading, 5G wireless

(where the density of masts is determined by the delay

between them) and autonomous vehicles.

With the huge increase in data traffic comes a headache in

how to store the information for the requisite period of

time that is often mandated by banks and government – up

to several hundred years. A new storage medium based

once again on silica appears a leading contender to replace

today’s tape units. The technique, known as 5D storage

because of the way each bit can be written and read,

provides both high storage density and the extraordinary

lifetime estimated at 1020 years.

The parallel field of high-power fibre lasers also relies on

silica fibre. This field has seen a revolution in industrial laser

processing and the market has grown to several $B/annum.

Because of its robust, monolithic nature and its efficiency,

the fibre laser is finding favour in defence applications as

well. With its extraordinary combination of low expansion

coefficient and high optical damage, silica is the

unassailable material of choice for this hugely important

industrial market.

Plenary Speaker IV

Prof. David Payne

University of Southampton, UK

Title: Silica and Silicon: The ultimate photonic

materials

Room A ID: 661 4324 8539



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Day 1: Test Day

10:00-11:30 Invited Speakers Test

Room A ID: 661 4324 8539 Invites Speaker: Session T1-T2

Ning Jiang, Lixia Xi, Xianfeng Tang, Hui Yang, Chen Chen, Jiangbing Du, Feng Tian, Jing Zhang, Peng Xue, Xiaojun Jia, Lijian Zhang, Zhangqi Yin, Yong Zhang, Pei Zhang

Room B ID: 613 2916 2069 Invites Speaker: Session T3-T4

Changyuan Yu, Zhensen Gao, Lin Huang and Xueming Liu, Chun-Nien Liu, Zaidao Wen, Kan Wu, Weiqing Gao, Xiulai Xu, Chunhua Dong, Jin Liu, Qing Zhang, Chaoyuan Jin, Yongheng Huo

14:00-15:00 Invited Speaker & Oral Presenters Test

Room A ID: 661 4324 8539

Invites Speaker: Session T5-T6

Bo Guo, Jian Wu, Dapeng Zhou, Jiangming Xu, Weili Zhang, Baoquan Jin, Fuxing Gu, Qiongyi He, Jietai Jing, Qiang Zhou, Zhaoyang Zhang, Ruifang Dong, Kun Huang

Room B ID: 613 2916 2069 Oral Session: 1-2 N098, N123, N140, 126, N146, N3002-A, N3003-A, N120, N121, N107, N009, N135

15:30-16:30 Oral Presenters Test

Room A ID: 661 4324 8539 Oral Session: 3-4 N006, N102, N122, N138, N095, N139, N145, N096, N097, N104, N116, N3001

Room B ID: 613 2916 2069 Oral Session: 5-6

N134, N108, N141, N136, N110, N111 N129, N105, N119, N127, N143, N117, FP2-8003

ROOM C ID:697 6169 9793 Oral Session: 7-8 N124, N128, N133, N144, N137, N131, FP2-8010, FP2-8007, FP2-8008, FP2-8009, FP2-8011, FP1-004, FP1-006, FP1-008

17:00-18:00 Keynote, Plenary & Invited Speakers Test

Room A ID: 661 4324 8539

17:00-17:10 Plenary Speaker I: Prof. Chao Lu

17:10-17:20 Keynote Speaker I: Prof. Xizheng Ke

17:20-17:30 Plenary Speaker II: Prof. Alexey Kavokin

17:30-17:40 Plenary Speaker IV: Prof. Kenneth Grattan FREng

17:40-17:50 Plenary Speaker V: Prof. David Payne

Room B ID: 613 2916 2069 Invited Speaker of topic: Space Communications, Navigation and Tracking Qinghua Tian, Yi Lei, Huiqin Wang, Li Zhao, Yi Wang, Jiahao Huo

Schedule

August 22nd, 2020

Beijing Time: GMT +8

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Day 2: Keynote, Plenary and Invited Speeches

Room A: 661 4324 8539 Chair: Prof. Xiaohui Li, Shaanxi Normal University, China 9:00-9:05 Opening Remarks Prof. Hairong Zheng, Dean of Graduate School, Shaanxi Normal University, China

9:05-9:50 Plenary Speaker I Prof. Chao Lu, The Hong Kong Polytechnic University, Hong Kong Title: Optical Communication Systems: Current Status and Future Perspectives

9:50-10:35 Keynote Speaker I Prof. Xizheng Ke, Xi'an University of Technology, China Title: Experimental study on 100km free space coherent optical communication

10:35-11:00 Morning Break

Chair: Prof. Feng Li, Xi’an Jiaotong University, China 11:00-11:45 Plenary Speaker II Prof. Alexey Kavokin, Westlake University, China Title: Qubits Based on Split-Ring Condensates of Exciton Polaritons


Invited Speakers of topic: Space Communications, Navigation and Tracking

Chair: Prof. Tianshu Wang, Changchun University of Science and Technology, China


13:30-13:50 Qinghua Tian, Beijing University of Posts and Telecommunications, China An overview of Machine Learning-aided Applications for free space optical communication

13:50-14:10 Yi Lei, Hefei University of Technology, China Improved Decoding of Staircase Codes via Soft-aided Bit-Marking Algorithm

14:10-14:30 Huiqin Wang, Lanzhou University of Technology, China Asymmetrically Clipped Optical OFDM with Index Modulation for Turbulent Channels

14:30-14:50 Li Zhao, Xi’an Technological University, China The layout of VLC light source for both lighting and communication reliability

14:50-15:10 Yi Wang, China Jiliang University, China Average Bit Error Rate Analysis of Multi-hop Free Space Optical Spatial Modulation System over Malaga Fading Channels

15:10-15:30 Jiahao Huo, University of Science & Technology Beijing, China Theoretical Analysis of PD Thermal Noise for PDM-IM Signals by using Different SVRs


Chair: Prof. Nan-Kuang Chen, Liaocheng University, China 16:00-16:45 Plenary Speaker III Prof. Kenneth Grattan FREng, City University London, UK Title: Optical fiber sensors: better solutions for Challenging Industrial Measurement Problems?

16:45-17:30 Plenary Speaker IV Prof. David Payne, University of Southampton, UK Title: Silica and Silicon: The ultimate photonic materials

Schedule

August 23rd, 2020 Beijing Time: GMT +8

17

Day 3: Invited Speeches

Morning: 9:30-12:10

Session T1: Optical Communications and Networks Chair: Prof. Jianping Li, Guangdong University of Technology, China

Room A: ID: 661 4324 8539

9:30-9:50

Ning Jiang, University of Electronic Science and Technology of China, China

Secure WDM Optical Communication Based on Private Chaotic Spectral Phase Encryption

9:50-10:10

Lixia Xi, Beijing University of Posts and Telecommunications, China

An Overview on Fiber-Optic transmission system based Nonlinear Frequency Division Multiplexing

10:10-10:30 Chen Chen, Chongqing University, China

MIMO Visible Light Communication: A User-Centric Perspective

10:30-10:50 Hui Yang, Beijing University of Posts and Telecommunications, China

Edge Intelligent-oriented Optical Network and Control

10:50-11:10

Jiangbing Du, Shanghai Jiao Tong University, China

Machine learning aided inverse design of optical fiber link for improved mode-division-multiplexing

11:10-11:30

Xianfeng Tang, Beijing University of Posts and Telecommunications, China

Physical Layer Encryption of CO-OFDM System Based on Cellular Automata and DNA Encoding

11:30-11:50 Feng Tian, Beijing University of Posts and Telecommunications, China

A 3-Dimensional Adaptive Hierarchical QAM Scheme for Elastic Optical Network

11:50-12:10 Jing Zhang, University of Electronic Science and Technology of China, China

The Cascaded Neural Network for MFI and OSNR monitoring

Session T2: Quantum Information and Related Quantum Technologies Chair: Prof. Yin Cai, Xi’an Jiaotong University, China

Room B: ID: 613 2916 2069

9:30-10:00 Keynote Speaker

Peng Xue, Beijing Computational Science Research Center, China

Parity-time-symmetric quantum walks

10:00-10:30 Keynote Speaker

Xiaojun Jia, Shanxi University, China

Continuous Variable quantum teleportation through fiber-channel

10:30-10:50 Lijian Zhang, Nanjing University, China

High-dimensional quantum states: generation and characterization

10:50-11:10 Zhangqi Yin, Beijing Institute of Technology, China

Quantum Information processing with levitated nanodiamonds

11:10-11:30 Yong Zhang, Nanjing University, China

Nonlinear multiplexing holography in nonlinear photonic crystal

11:30-11:50 Pei Zhang, Xi'an Jiaotong University, China

Mode sorter with astigmatic Gouy phase


Schedule

August 24th, 2020


18


Afternoon: 13:30-15:50

Session T3: Optical Communications, Networks and Ultrafast Photonics Chair: Prof. Tianye Huang, China University of Geosciences, China

Room A: ID: 661 4324 8539

13:30-13:50 Changyuan Yu, The Hong Kong Polytechnic University, Hongkong Indoor Visible Light Communication Systems with Dimming Control

13:50-14:10 Zhensen Gao, Guangdong University of Technology, China Chaotic optical communication: recent progresses and challenges

14:10-14:30 Lin Huang, Zhejiang University, China Xueming Liu, Nanjing University of Aeronautics and Astronautics, China Real time characterization of buildup dynamics of solitons in ultrafast fiber lasers

14:30-14:50 Chun-Nien Liu, National Chung Hsing University, Taiwan Simulation and Package of Si-Photonics Transceiver Module for High Speed Data Center and Cloud Network

14:50-15:10 Zaidao Wen, Northwestern Polytechnical University, China Intelligent synthetic aperture radar target perception and recognition: from automatic to autonomous

15:10-15:30 Kan Wu, Shanghai Jiaotong University, China Integrated beam steering devices and lidar

15:30-15:50 Weiqing Gao, Hefei University of Technology, China Passively mode-locked fiber laser at 1.95 µm waveband using saturable absorber based on SnSe nanoparticles

Session T4: Quantum Information and Related Quantum Technologies Chair: Prof. Feng Li, Xi’an Jiaotong University, China

Room B: ID: 613 2916 2069

13:30-14:00 Keynote

Speaker

Xiulai Xu, Institute of Physics, CAS, China

Purcell effect and lasing from quantum dots in a topological photonic crystal nanocavity

14:00-14:20 Chunhua Dong, University of Science and Technology of China, China Non-reciprocity in a multi-mode optomechanical microresonator

14:20-14:40 Jin Liu, Sun Yat-sen University, China High-Q bound States in the continuum based on all dielectric metasurfaces

14:40-15:00 Qing Zhang, Peking University, China Exciton Polariton and Micro/nano-Lasing of Lead-Halide Perovskite Semiconductors

15:00-15:20 Chaoyuan Jin, Zhejiang University, China In-situ Laser Interference for Nano-material Growth and Microcavity Photonic Devices

15:20-15:40 Yongheng Huo, University of Science and Technology of China High-performance Single & Entangled Photon Sources using MBE Grown III/V Semiconductor Quantum Dots


Schedule

August 24th, 2020


19


Afternoon: 16:00-18:20

Session T5: High Power Laser Source, Fiber-based Devices and Applications Chair: Prof. Zinan Wang, University of Electronic Science and Technology of China, China

Room A: ID: 661 4324 8539

16:00-16:20 Bo Guo, Harbin Engineering University, China

Advances in 2D materials-based multi-wavelength ultrafast photonics

16:20-16:40 Jian Wu, National University of Defense Technology, China

Yb-doped fiber laser with Black phosphorus: versatility in spatial/temporal domain

16:40-17:00

Dapeng Zhou, Dalian University of Technology, China

Computational Brillouin Optical Time-Domain Analysis via Compressed Sensing and Ghost Imaging

17:00-17:20

Jiangming Xu, National University of Defense Technology, China

Novel pump source enabled performance exploration of high power random fiber laser

17:20-17:40 Weili Zhang, University of Electronic Science and Technology of China, China

Control and imaging application of fiber random lasers

17:40-18:00 Baoquan Jin, Taiyuan University of Technology, China

Parallel Signal Processing for Distributed Optical Fiber Sensors

18:00-18:20 Fuxing Gu, University of Shanghai for Science and Technology, China

Semiconductor monolayers on optical micro/nanofibers for low threshold lasing

Session T6: Quantum Information and Related Quantum Technologies Chair: Prof. Yin Cai, Xi’an Jiaotong University, China

Room B: ID: 613 2916 2069

16:00-16:20

Qiongyi He, Peking University, China

Versatile Multipartite Einstein-Podolsky-Rosen Steering via a Quantum Frequency Comb

16:20-16:40 Jietai Jing, East China Normal University, China

Quantum Light Source based on Atomic Ensemble

16:40-17:00 Qiang Zhou, University of Electronic Science and Technology of China, China

Towards a High-Performance Teleportation System for Quantum Internet

17:00-17:20

Zhaoyang Zhang, Xi'an Jiaotong University, China

Coherent control on novel dynamic behaviors of light in electromagnetically induced photonic lattices

17:20-17:40

Ruifang Dong, National Time Service Center, CAS, China

Nonlocal dispersion cancellation characterization of frequency entanglement and its application in nonlocality test

17:40-18:00 Kun Huang, East China Normal University, China Mid-infrared photon-number-resolving detection based on frequency upconversion

Schedule

August 24th, 2020


20

Day 4: Oral Sessions

Room A ID: 661 4324 8539 Session 1: Data and Information Engineering Chair: Prof. Bao Ge, Shaanxi Normal University, China

10:00-10:15 N098

Research on Computer Aided Detection and Segmentation of Pulmonary Nodules Based

on Deep Learning and Generative Adversarial Networks

Ziming Wang, Jingxiang Sun, Siyi Yang and Yuzhuo Cheng Northeastern University, China

10:15-10:30 N123

Sparse Support Vector Machine for Network Behavior Anomaly Detection

Mengxue Deng, Xinrong Wu, Peilun Feng and Weijun Zeng

Army Engineering University of PLA, China

10:30-10:45 N140

Oil Field Crude Oil Production Level Prediction Method Based on AHP-PSO-BP

Hongtao Hu, Yingzi Pu and Xin Guan

Xi’an Shiyou University, China

10:45-11:00 N126

Cooperative Cache Placement Algorithm for Arbitrary Topology in ICN Based on Particle

Swarm Optimization

Siyang Shan, Chunyan Feng and Tiankui Zhang

Beijing University of Posts and Telecommunications, China

11:00-11:15 N146

Research on Information Security of Large Enterprises

Jia Liu

SDIC Intelligence Co.,Ltd., China

11:15-11:30 N3002-A

Real-time Alert Project Based on Express Delivery Big Data

Qien Li

Chengdu Cisiondata Co., Ltd, China

Room B ID: 613 2916 2069 Session 2: Intelligent Calculation and Application Chair: Prof. Xiaoping Lu, Macau University of Science and Technology, Macau

10:00-10:15 N3003-A

Multiple object tracking based on convolutional neural networks

Chi Zhicheng, Li Dongshen and Liu Han

Chang'an University, China

10:15-10:30 N120

Patent management evaluation of tobacco enterprises based on Grey Relational Analysis

and Efficacy Coefficient Method

Xiaojuan Wang and Hong Zhang

China Tobacco Guizhou Industrial CO.,LTD, China

Schedule

August 25th, 2020


21

10:30-10:45 N121

Research on risk assessment technology of power monitoring system based on machine

learning

Bo Li, Ye Liang, Hao Wang, Zhengwei Jiang and Xueqi Jin

Beijing Kedong Electric Power Control System Co., Ltd., China

10:45-11:00 N107

Giant enhancement of forward stimulated Brillouin scattering in surface plasmon

polaritons waveguide

Yuan Xie, Tianye Huang and Perry Shum Ping

China University of Geosciences (Wuhan), China

11:00-11:15 N009

A Service Composition Optimization Model Based on Petri Nets and Service Contracts

Zhou Fang, Chao Ma, Jiaxing Qu, Xue Song and Chi Zhang

Heilongjiang Province Cyberspace Research Center, China

11:15-11:30 N135

Micro-grid oriented active demand response optimization scheme

Anqin Luo, Jianan Yuan, Chao Huo and Yue Liu

Beijing SmartChip Microelectronics Technology Company Limited, China


Room A ID: 661 4324 8539 Session 3: Communication Principle and Technology Chair: Prof. Liang Wang, Shaanxi Normal University, China

14:00-14:15 N006

Antenna Selection for Non-Orthogonal Multiple Access with Space Time Block Codes

Guowei Lei and Sunqing Su

Jimei University, China

14:15-14:30 N102

An Adaptive Power Allocation and Coding Scheme for Improving Achievable Rate of the

Gaussian Interference Channel

Zhonglong Wang, Liyuan Zhang and Meng Ma

Peking University, China

14:30-14:45 N122

Resource Allocation in OFDMA Networks with Deep Reinforcement Learning

Jiaxin Liu, Xiao Ma, Weijia Han and Liang Wang

Shaanxi Normal University, China

14:45-15:00 N095

Uplink Cooperative NOMA Scheme with Higher Spectral Efficiency

Yunxiao Sun, Yan Li, Xiang Wang, Yajuan Guo and Daohua Zhu

State Grid Jiangsu Electric Power Co., Ltd. Electric Power Research Institute, China

15:00-15:15 N138

Robust Resource Division Multiplexing in Highly Time-varying Channels

Weijia Han, Xiao Ma, Chen Li and Di Tang

Shaanxi Normal University, China

15:15-15:30 N139

A New Refined Lyapunov Functional for Time-varying Delayed Systems

Can Zhao, Daixi Liao, Xinzhi Liu, Qishui Zhong, Shouming Zhong and Kaibo Shi

University of Electronic Science and Technology of China, China

22

Room B ID: 613 2916 2069 Session 4: Wireless Communication Chair: Prof. Junhui Zhao, East China Jiaotong University, China (IET Fellow)

14:00-14:15 N145

Optical Access network for a SMART Niamey

Djibo Boubacar Issoufou, Ahmed Kora, Djibo Boubacar Issoufou and Samuel Ouya

Laboratoire e-Inov DSTN ESMT/ESP/UCAD, Ecole Sup. Multinationale Télécom, Senegal

14:15-14:30 N096

WLAN Fingerprint Localization with Stable Access Point Selection and Deep LSTM

Xinyu Shi, Jing Guo and Zesong Fei

Beijing Institute of Technology, China

14:30-14:45 N104

Distributed mmWave Massive MIMO: a Performance Comparison with a Centralized

Architecture for Various Degrees of Hybridization

Yu Zhao, Ignas G.Niemegeers and Sonia Heemstra De Groot

Eindhoven University of Technology Eindhoven, The Netherlands

14:45-15:00 N097

Artificial Noise Projection Matrix Optimization Method for Secure Multi-cast Wireless

Communication

Jianbang Gao, Zhaohui Yuan and Bin Qiu

Northwestern Polytechnical University, China

15:00-15:15 N116

New Pilot Signal Design on Compressive Sensing Based Random Access for Machine Type

Communication

Ma Jing, Erzhong Xue and Dong Xueli

Xidian University, China

15:15-15:30 N3001

Effect of Synchronization Deviation on The Performance of PSWFs Non-sinusoidal

Communication System

Chuan-Hui Liu, Da-Wei Yang, Fa-Ping Lu and Jia-Fang Kang

Naval Aviation University, China

Room C ID: 697 6169 9793 Session 5: Space Communications, Navigation and Tracking Chair: Assoc.Prof. Chunfeng Wang, China Academy of Space Technology, China Prof. Mingjun Wang, Xi'an University of Technology, China

14:00-14:15 N134

Aerial Image Stitching via Transformation Space Filtering

Hao Wang, Zhengyan Ding and Zhiguo Yan

Third Research Institute of Ministry of Public Security, China

14:15-14:30 N108

A Bayesian Probabilistic AOA Localization Algorithm

Zhenyu Zhang, Shaoli Kang and Xiang Zhang

Beihang University, China

14:30-14:45 N141

Improved DV-Hop Based on Dynamic Parameters Differential Evolution Localization

Algorithm

Qiang Li, Xia Huang, Yuhang Xu and Dan Zhao

Lanzhou Jiaotong University, China

14:45-15:00 N110

Detecting Malicious TLS Network Traffic Based on Communication Channel Features

Rongfeng Zheng, Jiayong Liu, Kai Li, Shan Liao and Liang Liu

Sichuan University, China

23

15:00-15:15 N136

Allocation of available link resources based on the number of aircraft in different airspaces

Dongli Wang, Qilu Sun, Yequn Wang, Xiaohongyi Han and Hui Zhong

Air Force Engineering University, China

15:15-15:30 N111

Research on routing control with delay constraint based on contact plan for integrated

satellite-terrestrial network

Hao Zhang and Chunfeng Wang

China Academy of Space Technology, China


Room A ID: 661 4324 8539 Session 6: Wireless Network Chair: Prof. Qinglin Zhao, Macau University of Science and Technology, China

16:00-16:15 N129

Triple-Handshake-Based Semi-Blind Beamforming in mmWave Massive MIMO

Ziyao Hong, Ting Li and Fei Li

Nanjing University of Post & Telecommunication, China

16:15-16:30 N105

A Secure routing scheme based on probability prediction for wireless sensor networks

Di Tang, You Yu, Jian Gu, Yuanyuan Yang, Weijia Han and Xiao Ma

The Third Research Institute of the Ministry of Public Security, China

16:30-16:45 N119

Research and Implement of Just-In-Time Dual Buffer-Queues in LoRaWAN Gateways

Jia Wang and Pan-Guo Fan

Northwestern Polytechnical University, China

16:45-17:00 N127

Modeling and Performance Analysis of LTE Coexisting with Wi-Fi

Zichao Qin, Aijing Li and Hai Wang

The Army Engineering University of PLA, China

17:00-17:15 N143

EE-TAR: Energy Efficient and Thermal Aware Routing Protocol for Software Defined

Wireless Body Area Networks

Adeel Ahmed, Xingfu Wang, Ammar Hawbani, Muhammad Umar Farooq, Taiyaba Qureshi

and Shamsher Ullah

University of Science and Technology of China, China

17:15-17:30 N117

A Knowledge Reasoning Algorithm Based on Network Structure and Representation

Learning

Jinkui Yao and Yulong Zhao

Jiangnan Institute of Computing Technology, China

17:30-17:45 FP2-8003

A method of real-time service quality evaluation based on customer behavior

Yinchao Cheng, Qifang Xie and Zichun Zhang

China Mobile Research Institute, Department of User and Market Research, China

Room B ID: 613 2916 2069 Session 7: Micro/nano-photonic Device and All Optical Signal Processing Chair: Prof. Zhanqiang Hui, Xi'an University of Posts and Telecommunications, China

16:00-16:15 N124

Study on Non-coherent Detection of DP-QPSK Signal Based on Delay-Line-Interferometer

Huiwen Yin and Zhiping Huang

National University of Defense Technology, China

24

16:15-16:30 N128

Ring Resonator Structure for An Add-drop Filter Application

Muhammad Raditya Gumelar and Retno Wigajatri Purnamaningsih

Universitas Indonesia, Indonesia

16:30-16:45 N133

DOA estimation for nested array from reusing redundant virtual array elements viewpoint

Chenghong Zhan, Guoping Hu, Zixin Zhang, Yule Zhang and Shijie Yue

Air Force Engineering University, Xi’an, China

16:45-17:00 N144

Research on Anti-jamming Algorithm of BDS Signal in WiFi6 Environment

Qiliang Chen, Jiahong Liang, Fan Zhang and Bo Bi

Beijing Microelectronics Technology Institute, China

17:00-17:15 N137

A Low-complexity Hybrid Iterative Signal Detection Algorithm for Large-scale MIMO

Dan Zhao, Dong Shen, Xiaofang Cao and Xia Huang

Lanzhou Jiaotong University, China

17:15-17:30 N131

A feature-based automatic LED part locating method and the inspection of welding quality

of LED chips

Zili Chen and Honglin Liu

China Jiliang University, China

17:30-17:45 FP2-8010

Traffic modelling for IoT networks: A survey

Yufei Li and Wanqing Tu

The University of Auckland, Auckland, New Zealand

Room C ID: 697 6169 9793 Session 8: Information Communication and Management Chair: Dr.Pranav Nerurkar, NMIMS University, India

16:00-16:15 FP2-8007

A machine learning approach for predicting antibody properties

Oche A Egaji, Seamus Ballard-smith, Ikram Asghar and Mark Griffiths

University of South Wales, Pontypridd, United Kingdom

16:15-16:30 FP2-8008

Detecting illicit entities in Bitcoin using supervised learning of ensemble decision trees

Pranav Nerurkar, Yann Busnel, Romaric Ludinard, Fabien Autrel, Kunjal Shah, Madhav

Chandane, Sunil Bhirud and Dhiren Patel

NMIMS University Mumbai, Maharashtra

16:30-16:45 FP2-8009

A smart transportation management system for managing travel events

Ikram Asghar, James Cosgrove, William Warren, Oche Alexander Egaji, Mark Griffiths, and

Shelly Barratt

University of South Wales, Pontypridd, United Kingdom

16:45-17:00 FP2-8011

Designing IT service management at Indonesia Internet Domain Names Registry

Association’s helpdesk function

Evelyn Sevina Hermita, Yudho Giri Sucahyo and Arfive Gandhi

Universitas Indonesia, Depok, Indonesia

17:00-17:15 FP1-004

Constructing a learning style model in an adaptive learning system

GAO Huzi and YIN Guocai

North China Institute of Aerospace Engineering, China

25

17:15-17:30 FP1-006

The space of human interaction as the basis for modeling multilingualism and minimizing

the studied languages

Bulatbayeva Kulzhanat Nurymzhanovna and Duisekova Kulyash Kerimbekovna

L.N.Gumilyov Eurasian National University, Kazakhstan

17:30-17:45 FP1-008

Tablet computer truly help students to master mathematical knowledge?

Xintong Yang

Northeastern University at Qinhuangdao, China

26

Invited Speeches in Details

August 23rd GMT+8

Invited Speakers of topic: Space Communications, Navigation and Tracking Room A ID: 661 4324 8539

Chair: Prof. Tianshu Wang, Changchun University of Science and Technology, China


13:30-13:50

Qinghua Tian, Beijing University of Posts and Telecommunications, China

Title: An overview of Machine Learning-aided Applications for free space optical communication

Biography:

Qinghua Tian received the PhD degree in electromagnetic field and microwave technology from Beijing University of

Posts and Telecommunication (BUPT), Beijing, China, in 2013. She is currently the associate professor at BUPT and the

member of the State Key Laboratory of Information Photonics and Optical Communications and key member of Beijing Key

Laboratory of Space-ground Interconnection and Convergence in BUPT. Her current research interests focus on deep

learning and optical communication and satellite communication. She has authored and co-authored more than 50

international journals and peer-reviewed conference papers.

Abstract:

Compared with radio frequency wireless communication, Free Space Optical (FSO) communication has a larger capacity

and greater flexibility and can satisfy the increasing demand for data capacity improvement. FSO communication can

quickly establish communication links in harsh environments. It is a promising communication method to satisfy the

increasing needs of the intelligent and digitalization of modern information technology. However, atmospheric turbulence

affects the performance of space optical communication, which is the main factor of the decline of communication

performance. A large number of studies have been carried out to reduce the impact of atmospheric turbulence and

improve transmission performance. However, there are still some difficulties in solving some problems with traditional

methods. Fortunately, the emergence of Artificial intelligence (AI), especially Machine Learning (ML), has given many good

ways to solve these problems. In this report, the applications for the combination between ML and FSO communication

are reviewed and some of the challenges in these applications are discussed.

References

[1] Rabinovich W S, Moore C I, Mahon R, et al. Free-space optical communications research and demonstrations at the US

Naval Research Laboratory[J]. Applied Optics, 2015, 54(31): F189-F200.

[2] Irwan R, Lane R G. Analysis of optimal centroid estimation applied to Shack–Hartmann sensing[J]. Applied optics, 1999,

38(32): 6737-6743.

[3] Barrett T K, Sandler D G. Artificial neural network for the determination of Hubble Space Telescope aberration from

stellar images[J]. Applied optics, 1993, 32(10): 1720-1727.

[4] Paine S W, Fienup J R. Machine learning for improved image-based wavefront sensing[J]. Optics letters, 2018, 43(6):

1235-1238.

[5] Gonsalves R A. Phase retrieval and diversity in adaptive optics[J]. Optical Engineering, 1982, 21(5): 215829.

[6] Paxman R G, Schulz T J, Fienup J R. Joint estimation of object and aberrations by using phase diversity[J]. JOSA A, 1992,

9(7): 1072-1085.

[7] Brady G R, Guizar-Sicairos M, Fienup J R. Optical wavefront measurement using phase retrieval with transverse

translation diversity[J]. Optics express, 2009, 17(2): 624-639.

[8] Tian Q, Lu C, Liu B, et al. DNN-based aberration correction in a wavefront sensorless adaptive optics system[J]. Optics

27

express, 2019, 27(8): 10765-10776.

[9] Nishizaki Y, Valdivia M, Horisaki R, et al. Deep learning wavefront sensing[J]. Optics express, 2019, 27(1): 240-251.

[10] Guo H, Xu Y, Li Q, et al. Improved Machine Learning Approach for Wavefront Sensing[J]. Sensors, 2019, 19(16): 3533.

[11] Chen M, Jin X, Xu Z. Investigation of Convolution Neural Network-Based Wavefront Correction for FSO

Systems[C]//2019 11th International Conference on Wireless Communications and Signal Processing (WCSP). IEEE, 2019:

1-6.

[12] Khalighi M A, Schwartz N, Aitamer N, et al. Fading reduction by aperture averaging and spatial diversity in optical

wireless systems[J]. IEEE/OSA Journal of Optical Communications and Networking, 2009, 1(6): 580-593.

[13] Guo H, Korablinova N, Ren Q, et al. Wavefront reconstruction with artificial neural networks[J]. Optics express, 2006,

14(14): 6456-6462.

[14] Hu K, Xu Z X, Yang W, et al. Build the structure of WFSless AO system through deep reinforcement learning[J]. IEEE

Photonics Technology Letters, 2018, 30(23): 2033-2036.

[15] Tian Q, Li Z, Hu K, et al. Turbo-coded 16-ary OAM shift keying FSO communication system combining the CNN-based

adaptive demodulator[J]. Optics express, 2018, 26(21): 27849-27864.

[16] Li Z, Tian Q, Zhang Q, et al. An improvement on the CNN-based OAM Demodulator via Conditional Generative

Adversarial Networks [C]. ICOCN, 2019.

*17+ S. R. Park, L. Cattell, J. M. Nichols, A. Watnik, T. Doster, and G. K. Rohde, “De-multiplexing vortex modes in optical

communications using transport-based pattern recognition,” Opt. Express 26(4), 4004–4022 (2018).

13:50-14:10

Yi Lei, Hefei University of Technology, China

Title: Improved Decoding of Staircase Codes via Soft-aided Bit-Marking Algorithm

Biography:

Yi Lei was born in Chongqing, China. She received the B.E. degree in electronic information and technology program from

Beijing Forestry University (BJFU), Beijing, China, in 2013, and the Ph.D. degree in electronic science and technology from

Beijing University of Posts and Telecommunications (BUPT), Beijing, China, in 2019. Funded by the China Scholarship

Council (CSC), she held a visiting Ph.D. position at Signal Processing Systems (SPS) Group, Department of Electrical

Engineering, Eindhoven University of Technology (TU/e), Eindhoven, The Netherlands, from 2017 to 2018. Since August

2018, she has been a Guest Researcher with TU/e. Since March 2019, she has also been a Lecture with the Hefei University

of Technology. Her current research interests include optical communication systems, fiber-wireless integration, MIMO,

channel coding, and signal processing.

Abstract:

Staircase code (SCC) is a popular family of hard-decision forward error correction codes that gives large coding gain. In this

talk, we will review our recent works on SCCs, in particular the proposed soft-aided bit-marking (SABM) algorithm. SABM is

based on the idea of marking highly reliable bits and highly unreliable bits by partially using soft information from the

channel. These marked bits are used to improve the decoding of SCCs by reducing the effect of miscorrections and

extending the error-correcting capability of the component codes. For SCCs with 2-error-correcting capability BCH

component codes, SABM enables additional gains of up to 0.3 dB when compared to standard decoding for SCCs. This has

been experimentally demonstrated as well in an optical communication systems. The main feature of SABM is its low

complexity as it only requires to slightly modify the decoding structure of standard SCCs and store very small part of the

soft bits. The extension of SABM (with minor modifications) to product codes is also investigated.

References

*1+ Y. Lei, B. Chen, G. Liga, X. Deng, Z. Cao, J. Li, K. Xu, A. Alvarado, “Improved Decoding of Staircase Codes: The Soft-aided

Bit-marking (SABM) Algorithm,” IEEE Transactions on Communications, vol. 67, no. 12, pp. 8220-8232, 2019.

*2+ Y. Lei, A. Alvarado, B. Chen, X. Deng, Z. Cao, J. Li, K. Xu, “Decoding staircase codes with marked bits,” International

Symposium on Turbo Codes & Iterative Information Processing (ISTC), Hong Kong, China, 2018.

[3] Y. Lei, B. Chen, A. Alvarado, “Improved BER performance of hard-decision staircase code via geometric shaping,”

28

Symposium on Information Theory and Signal Processing in The Benelux (SITB), Twente, The Netherlands, 2018.

[4] B. Chen, Y. Lei, S. van der Heide, J. van Weerdenburg, A. Alvarado, C. Okonkwo, “First Experimental Verification of

Improved Decoding of Staircase Codes using Marked Bits,” Optical Fiber Communications Conference (OFC), 2019.

*5+ A. Alvarado, Y. Lei, D. S. Millar, “Achievable Information Rate Losses for High Order Modulation and Hard-Decision

Forward Error Correction,” 44th European Conference On Optical Communication(ECOC), Roma, Italy, 2018.

*6+ B. Chen, Y. Lei, D. Lavery, C. Okonkwo, A. Alvarado, “Rate-Adaptive Coded Modulation with Geometrically-shaped

Constellations,” Asia Communications and Photonics Conference (ACP), Hangzhou, China, 2018.

[7] A. Alvarado, G. Liga, Y. Lei, B. Chen, A. Balatsoukas-Stimming, “Improving HD-FEC Decoding via Bit Marking,”

Opto-Electronics and Communications Conference (OECC) and International Conference on Photonics in Switching and

Computing (PSC), Fukuoka, Japan, July 2019.

14:10-14:30

Huiqin Wang, Lanzhou University of Technology, China

Title: Asymmetrically Clipped Optical OFDM with Index Modulation for Turbulent Channels

Biography:

Wang Huiqin is currently professor and doctoral supervisor at Lanzhou University of technology. She is a senior member of

the Chinese Optical Society and Gansu Institute of Electronics. She is also the director of the provincial excellent course on

Communication Principles. She received her bachelor's degree from Lanzhou Jiaotong University in 1996 and the PhD

degree from Xi'an University of Technology in 2011. Presided over/participated in the completion of more than 20

projects, including national Natural Science Foundation of China, Army 863 project, provincial and ministerial level

scientific research project. She is the recipient of 7 science and technology awards, include 1 third level provincial award, 5

first level departmental awards and 1 second level departmental award. In recent years, she has obtained 5 invention

patent authorization, 6 utility model patents authorization and 6 software copyrights. She has published over 60 academic

papers in Optics and Laser Technology, Optical Engineering, China Science and other well-known academic journals. She

published a textbook named "Computer Communication Technology".

Abstract:

Asymmetrically Clipped Optical OFDM (ACO-OFDM) has the disadvantages of high peak-to average power ratio (PAPR) and

low energy efficiency (EE) that has been limited its application in wireless optical communications (WOCs). In this paper,

we present a novel ACO-OFDM method called Asymmetrically Clipped Optical OFDM with Index Modulation

(ACO-OFDM-IM) for WOCs. ACO-OFDM-IM adds space dimension to convey more extra information by employing the

subcarrier-index. By applying such way, the spectral efficiency (SE) and EE can be improved. In addition, the asymptotic

average bit error probability (ABEP) under turbulent channel of the proposal is derived. The results show that

ACO-OFDM-IM has better performance than ACO-OFDM. For example, the (8,2) ACO-OFDM-IM scheme can achieve

approximately 2dB SNR gain than ACO-OFDM with the same SE and BER. Moreover, the data rates can be significantly

enhanced compared with ACO-OFDM.

References

[1] Z. Ghassemlooy and W. O. Popoola. Terrestrial free space optical communication. Mobile and Wireless Commun.:

Network Layer and Circuit Level Design. Rijeka, Croatia: Intech, 2010, pp. 355–391.

[2] Majumdar, Arun k. and Jennifer C. Ricklin, ends. Free-space Laser communications principles and advances[M].

Springer Science & Business Media 2010, (2): 5-6

[3] YIN Hang，LIU Zhi. Performance Analysis of Atmospheric Laser Communication System Based on OFDM Under Weak

Turbulence Environment. Journal of Changchun University of Science and Technolog.Vol.38 No.3 Jun.2015

[4] Ranjha B and Kavehrad M.Hybrid asymmetrically clipped OFDM-based IM/DD optical wiress system[J]. Journal of

Optical Communications and Networking 2014;6(4),pp:387-396.

*5+ Ertuğrul Başar, Ümit Aygölü, Erdal Panay ırcı,Fellow, Orthogonal Frequency Division MultiplexingWith Index

Modulation[J].IEEE Transactions on signal processing, 2013, 61 (22): 5536-5549.

[6] Basar E, Panayirci E. Optical OFDM with index modulation for visible light communications. In: Proc.IEEE Int. Works hop

29

son Opt. Wirel. Commun. ; Sep. 2015;Istanbul,Turkey. pp. 11–15.

[7] Basar E , Panayirci E , Uysal M , et al. Generalized LED index modulation optical OFDM for MIMO visible light

communications systems[C]. International Conference on Communications. IEEE .2016,pp:1-5.

[8] Mao T, Jiang R, and Bai R. Optical dual-mode index modulation aided OFDM for visible light communications. Optics

Communications. 2017;,391:37–41.

[9] Qi Wang, Tianqi Mao and Zhao cheng Wang, Index Modulation-Aided OFDM for Visible Light Communications, 2017.

[10] Hany S. Hussein. Optical polar based MIMO-OFDM with fully generalised index-spatial LED modulation. IET

Communications. 14(2) 2020, pp:282-289

[11] Yusuf Acar, Todor Cooklev. High performance OFDM with index modulation. Physical Communication(32) 2019,

192-199

*12+ Shuping Dang, Basem Shihada. Toward Spectral and Energy Efficient 5G Networks Using Relayed OFDM with Index

Modulation. Arp, 2019. IEEE

[13] Ruofan Luo, Hongwei Chen. PAPR reduction of the power efficient asymmetrically clipped-OFDM[C].14th International

Conference on Optical Communications and Networks (ICOCN), 2015: 1-3.

[14] JUN LI, YUYANG PENG. Enhanced Index Modulated OFDM Spread Spectrum. IEEE Access. 11.16. 2018.

14:30-14:50

Li Zhao, Xi’an Technological University, China

Title: The layout of VLC light source for both lighting and communication reliability

Biography:

Professor Li Zhao graduated from Xi'an University of technology in 2009 with a doctor's degree. In the same year, she

joined Xi'an technology University to teach. The main research directions are: optical channel characteristics, channel

coding, modulation technology, signal processing in free space optical communication system; light source layout,

modulation technology, indoor positioning in visible light communication system. As the project leader, she has

undertaken more than 10 scientific research projects in the field of optical communication. As a main participant, she has

participated in many scientific research projects. She has obtained 2 national invention patents, 1 national utility model

patent and 2 software registration rights. She has published more than 30 papers in the field of optical communication;

relevant research achievements have won a number of Shaanxi Provincial science and technology awards.

Abstract:

In the visible light communication (VLC) system, the light emitting diode(LED) has a double function of illumination and

communication. In order to take the illumination uniformity and the communication reliability into consideration, this

paper takes the 4m*4m*3m room size as the model and uses the illumination compensation technology in the common

indoor light source layout model to optimize the layout. It is concluded a kind of light source composed of five LED arrays

layout mode. Under this kind of layout, the power consumption of the system can be reduced, at the same time the

uniformity of illumination can be improved. In order to balance the reliability of VLC system, we used indoor illumination

standard deviation and average BER of receiving plane in communication system to build a system optimization model

function f(L,i).When the function (L,i) reaches the minimum value, it can ensure the requirement of the receiving plane

illumination and the BER of communication. Finally, the simulation results show that the function f(L,i) takes the minimum

value when L=0.4m and i=0.01m.At the same time, the standard deviation of the system illumination is 20.1 and power

consumption is 146W and the BER is 5.07x10-7.The results show that the system can take the uniformity of indoor

illumination distribution and the reliability of communication into account, which provides an optimization method for the

layout of indoor VLC.

14:50-15:10

Yi Wang, China Jiliang University, China

Title: Average Bit Error Rate Analysis of Multi-hop Free Space Optical Spatial Modulation System over Malaga Fading

Channels

30

Biography:

Yi Wang received her PhD from Harbin Engineering University, Harbin, China. Currently, she is a professor at China JiLiang

University. Her research interests include free-space optical communication, laser beam propagation in atmospheric

turbulence, and optical coherent detection.

Abstract:

Free-space optical (FSO) communication has attracted a growing attention for a large number of applications with its

appealing advantages. These advantages include higher data rates, high security, cost-effectiveness, broadband access and

license-free spectrum. However, atmospheric turbulence caused by random fluctuations in the atmosphere, pointing

errors caused by beam vibration between the transmitter and receiver, and path loss due to absorption and scattering of

particles will significantly impair the performance and availability of FSO system. As an effective method to overcome

these disadvantages, relay transmission has received more and more attention recently. Among them, serial relaying (i.e.,

multi-hop transmission) can expand the coverage of limited power transmitters, improve system reliability, and has a wide

range of application prospects. In addition, spatial modulation (SM) has been proposed as a novel and promising multiple

input multiple output (MIMO) technique for FSO communication systems. Compared with traditional MIMO technology,

this technology has the advantages of avoiding inter-channel interference, eliminating the needs of inter-antenna

synchronization, and provides a robust system against channel estimation errors. Space shift keying (SSK) is a special case

of SM modulation. It only uses the antenna index as a means of transmitting information. Compared with SM modulation,

it is easier to implement. In this paper, we analysis the performance of free space optical spatial modulation system using

decode and forward (DF) relaying under Malaga (M) aggregate channel. We evaluate the probability density function of

the sum of the squares of the difference between the two channel coefficients under the M-channel model to develop an

analytical expression for the average bit error rate (ABER) of the system under consideration. On the basis of theoretical

derivation, the influence of the pointing error, the number of relay nodes, and atmospheric turbulence (from weak to

strong) on ABER are analyzed through simulation. It is found that the ABER of the FSO system remains almost unchanged

under moderate to strong atmospheric turbulence. In addition, it is found that compared with the other two turbulence

regimes, the performance of the considered system in the weak turbulence state is poor. Moreover, as the number of relay

nodes and the pointing error increase, the ABER of the system deteriorates. It is also observed that the performance of the

FSO system degrades with an increasing number of optical sources. Therefore, a trade-off between spectral efficiency and

ABER performance can be observed. The research and analysis of the performance of the serial DF relaying FSO SM system

can provide a good theoretical basis for future engineering implementation.

15:10-15:30

Jiahao Huo, University of Science & Technology Beijing, China

Title: Theoretical Analysis of PD Thermal Noise for PDM-IM Signals by using Different SVRs

Biography:

JIAHAO HUO was born in Hebei, China,1989. He received the M.S. degree from the Changchun University of Science and

Technology, in June 2014, the Ph.D. degree from the University of Science and Technology Beijing, in 2019. He joined the

Photonics Research Center, The Hong Kong Polytechnic University, in June 2016, as a Research Assistant. He is currently a

Lecturer with the University of Science and Technology Beijing. His research interests include high-capacity IM/DD systems

for optical interconnect, optical access networks, and digital signal processing techniques for advanced modulation

formats.

Abstract:

Driven by the growing traffic demand in inter- and intra-data center connections, polarization division multiplexing

intensity modulation with direct detection (PDM-IM-DD) using a Stokes vector receiver (SVR) has been proposed. However,

for different SVR architectures, the corresponding demultiplexing matrix is required to recover the Stokes vectors from the

detected signals, which combined with an arbitrary state of polarization (SOP), will change the effect of noise dynamically

and significantly influence the system performance. In this paper, theoretical PD thermal noise models using four SVRs are

developed and the simulation of 224 Gbit/s PDM-PAM4-DD transmission is analyzed.

31

August 24th GMT+8

Session T1: Optical Communications and Networks Room A ID: 661 4324 8539

Chair: Prof. Jianping Li, Guangdong University of Technology

9:30-9:50

Ning Jiang, University of Electronic Science and Technology of China, China

Title: Secure WDM Optical Communication Based on Private Chaotic Spectral Phase Encryption

Biography:

Prof. Ning Jiang received the B.S. degree in the University of Electronic Science and Technology of China (UESTC) in 2005

and the Ph.D. degree in the Southwest Jiaotong University in 2012. He is currently working at the School of Information

and Communication Engineering, University of Electronic Science and Technology of China. He has published 77 authored

or coauthored SCI research papers including two highly-cited papers and 28 top-journal papers (H-index 18). His current

research works focus on the all-optical secure communications and optical access networks.

He is a senior member of IEEE society, a member of Chinese Association for Cryptologic Research, a member of Chinese

Optical Society and a member of the Optical Society of America (OSA). He also serves as a review editor of Optical

Communications and Networks and Non-Conventional Communications and Networks, as well as a reviewer for several

top-level journals, including Photonics Research, Optics Express, Optics Letters, Journal of Lightwave Technology, IEEE

Photonics Technology Letters, IEEE Journal of Selected Topics in Quantum Electronics, IEEE Communication Letters, Applied

Optics, IEEE Photonics Journal, Chinese Physics B, and Chinese Optics Letters.

Abstract:

As the ongoing demand for communication capacity, the information security of communication systems has attracted

more and more attention. In this work, we propose and demonstrate a novel physical layer encryption scheme for

wavelength division multiplexing (WDM) systems based on private chaotic spectral phase encryption. In the proposed

scheme, a pair of chaotic signals for spectral phase encryption are privately generated by two local semiconductor lasers

subject to a common random-phase-constant-amplitude injection. We experimentally demonstrate the secure

transmissions of four 12.5 Gb/s WDM channels over 50-km single-mode fiber (SMF) to confirm the feasibility of the

proposed scheme, and systematically investigate the encryption and decryption performances by numerical simulations.

The results indicate that the WDM signal is well encrypted as a noise-like signal at the transmitter end. All channels are

deeply overlapped and indistinguishable, as such the eavesdropper cannot directly implement channel isolation by a

demultiplexer. At the receiver end, the WDM signal can be correctly

recovered after chaotic spectral phase decryption, with a BER lower than 10-5. The proposed encryption scheme is

compatible with the existing WDM optical communication systems, and does not require replacing the hardware such as

the light source, amplifiers, transmitters and receivers. Besides, our scheme needs only one pair of encryption and

decryption devices for all the WDM channels, it is suitable for solving the security challenges in resource-limited optical

fiber links.

9:50-10:10

Lixia Xi, Beijing University of Posts and Telecommunications, China

Title: An Overview on Fiber-Optic transmission system based Nonlinear Frequency Division Multiplexing

Biography:

Lixia Xi received her BS and MS degrees in physics from Hebei Normal University and Beijing Normal University in 1994 and

1997, respectively. She received her PhD in physical electronics from Beijing University of Posts and Telecommunication in

2005. She is currently a professor in State Key Laboratory of Information Photonics and Optical Communications, Beijing

University of Posts and Telecommunications. Her research interest main focus on high-speed optical communication

systems.

32

Abstract:

Kerr nonlinearity has been considered as a major factor limiting the transmission capacity in high speed and long-haul

optical fiber communications. To address this issue, a novel nonlinear transmission scheme called nonlinear frequency

division multiplexing (NFDM) has been proposed, which has natural immunity to Kerr nonlinearity impairment [2-6]. In this

transmission scheme, information is encoded in the nonlinear spectra by nonlinear Fourier transform (NFT) (also called the

inverse scattering transform). These nonlinear spectra propagate independently with nonlinear Schrödinger equation,

which means there is no crosstalk among the nonlinear spectral components. Hence, the NFDM system possesses inherent

robustness to fiber nonlinearity. In this talk, I will give an overview on the progress of NFDM research in recent years. The

principle and the main techniques of the NFDM systems will be introduced. Our works on the nonlinear-frequency-packing

technique and frequency offset estimation for NFDM system will be given. The challenges of NFDM transmissions in

practical implementation conditions will be analyzed and the outlook will be provided.

10:10-10:30

Chen Chen, Chongqing University, China

Title: MIMO Visible Light Communication: A User-Centric Perspective

Biography:

Dr. Chen Chen received the B.S. and M.Eng. degrees from the University of Electronic Science and Technology of China,

Chengdu, China, in 2010 and 2013, respectively, and the Ph.D. degree from Nanyang Technological University, Singapore, in

2017. He is currently an Assistant Professor with the School of Microelectronics and Communication Engineering,

Chongqing University, China. His research interests include visible light communications, LiFi, visible light positioning,

optical access networks, and digital signal processing.

Abstract:

Multiple-input multiple-output (MIMO) is a promising technology to efficiently improve the achievable rate of

light-emitting diodes (LEDs) enabled visible light communication (VLC) systems. For conventional MIMO techniques such as

spatial diversity (SD) and spatial multiplexing (SMP), the working mode of each LED transmitter is independent of users’

spatial positions. In this talk, we discuss three user-centric MIMO techniques, including SD/SMP switching, adaptive SMP

and SD-aided adaptive SMP, for achievable rate improvement of indoor MIMO-VLC systems, by exploiting users’ spatial

positions as a new degree of diversity. Our results show that the achievable rate of a 4×4 MIMO-VLC system in a typical

indoor environment can be significantly improved by applying the user-centric MIMO techniques compared with the

conventional ones. Moreover, we also show that user-centric MIMO techniques outperform conventional ones under the

condition of only slightly increased computational complexity with limited feedback information.

10:30-10:50

Hui Yang, Beijing University of Posts and Telecommunications, China

Title: Edge Intelligent-oriented Optical Network and Control

Abstract:

This talk presents a novel edge Intelligent-oriented optical network and control with artificial intelligence algorithm, which

can enhance the performances of edge optical networking and control plane.

10:50-11:10

Jiangbing Du, Shanghai Jiao Tong University, China

Title: Machine learning aided inverse design of optical fiber link for improved mode-division-multiplexing

Biography: Dr. Jiangbing DU received B.S. (02-05) and M.S. (05-08) degrees respectively from College of Physics and

Institute of Modern Optics, Nankai University, Tianjin, China. He obtained his PhD degree (08-11) in Electronic Engineering

from The Chinese University of Hong Kong. He was with Huawei technologies from 2011 to 2012. He joined Shanghai Jiao

33

Tong University since 2012. Dr. DU is a senior member of IEEE and OSA. He is the author or coauthor of over 150 journal

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