The 18th International Conference on Optical Communications and Networks (ICOCN 2019) 5-8 August 2019 Xiangming Hotel, Huangshan, Anhui, China

Table of Contents

Welcome Message ...... 2

Committees ...... 3

General Information ...... 8

Conference Hightlights ...... 10

Agenda of Sessions ...... 14

Technical Program ...... 18

Key to Authors and Presiders ...... 80

International Conference on Optical Communications and Networks (ICOCN2019) ● 5 August 2019-8 August 2019 ● Page 1 Welcome to the 18th International Conference on Optical Communications and Networks

It is a great pleasure to invite you to participate in the 18th opportunity to meet and interact with the researchers who are In addition to the technical program, there will be an International Conference on Optical Communications and leading these advances. We have over 618 presentations impressive range of exhibitions from the relevant industries, Networks (ICOCN2019) and share the latest news in scheduled, including 3 keynotes and 226 invited talks made publishers and professional organizations communications and photonics science, technology and by many of the world’s most prominent researchers from . innovations from leading universities, research laboratories academia and industry. We thank all the contributors and We have also prepared a rich social program to facilitate and companies throughout the world. ICOCN has been held authors for making ICOCN2019 a truly unique, outstanding meeting and networking with colleagues from all over the annually tracing back to 2002. It is now one of the largest global event. world. A conference welcome reception will be held in the international conferences on optical communications, evening on Monday, 5 August. On the evening of Wednesday, photonics and relevant technologies. There will be 75 regular technical sessions, and two post- 7 August, the Banquet and Awards Ceremony will be held for deadline paper sessions. Our conference highlight is the all conference registrants. Lucky-draw will be carried out for The ICOCN2019 technical conference features a full suite of Plenary Session scheduled on the morning of Tuesday, 6 those who help us select the Best Poster Award by submitting plenary, invited, and contributed talks given by international August. Three outstanding, distinguished speakers will give the ticket. academic and industrial researchers who are leaders in their presentations: Jonathan Knight from University of Bath will respective fields. This year’s conference will feature the give a talk on Making better optical fibers. Chao LU from The It is an enormous task to organize a conference and it is following topics: Optical fibers and fiber-based devices; Hong Kong Polytechnic University will also present on impossible to succeed without the dedicated efforts of many Optical transmission systems, subsystems and technologies; Application of optical transmission techniques in distributed supporters and volunteers. We are indebted to the entire Networks architectures, management and applications; optical fiber sensing systems. Finally, Rene-Jean Essiambre Technical Program Committee and the Subcommittee Chairs Optoelectronic integration and devices; Optical signal from Bell Labs will discuss Wired communication: from who have worked persistently throughout the whole year to processing & microwave photonics; Optical measurements Maxwell to optical fibers. invite speakers, solicit and review papers, organize the and imaging; Ultrafast photonics and nonlinear optics; technical sessions which results in the excellent technical Photonics for energy; Space communications, navigation & Young Scientist Awards sponsored by Light: Science & program. We also thank the staff and volunteers from Anhui tracking; Quantum photonics and applications; Applications will be given to 5 young researchers with the age Univ. and China Jiliang Univ. We also thank the IEEE Optoelectronics based on organic and nanostructured no more than 40 by the conference date who made Photonics Society for sponsoring the event. materials; Machine learning for optical communication outstanding contributions and present on our conference. In systems, networks and devices; 2D-materials based addition, 10 Best Student Paper Awards and 15 Best Poster Sincerely, photonics; Supercontinuum fiber sources; Fiber-optic Awards will be selected by the Technical committee or expert magnetic field sensors and other devices; and Random fiber panel during the conference. All these awards will be lasers. With a conference program of broad scope and of the presented during the conference banquet on the evening of highest technical quality, ICOCN2019 provides an ideal Wednesday, 7 August. venue to keep up with new research directions and an

Xinyong Dong Benli Yu Perry Ping Shum China Jiliang Univ., China Anhui Univ., China Nanyang Tech. Univ., Singapore General Chair General Chair General Chair

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Committees

Honorary Chairs Yanmei Tang, China Jiliang Univ., China Yunqi Liu, Shanghai Univ., China Xiaoyi Dong, Nankai Univ., China Yi Xu, China Jiliang Univ., China Shuqin Lou, Beijing Jiaotong Univ., China Weishang Hu, Shanghai Jiao Tong Univ., China Ping Lu, Huazhong Univ. of Sci. and Tech., China Steering Committee Xiaomin Ren, Beijing Univ of Posts and Tel., China Chengbo Mou, Shanghai Univ., China Perry Ping Shum, Nanyang Technological Univ., Singapore, Hwa-Yaw Tam, Hong Kong Polytechnic Univ., China Wei Peng, Dalian Univ. of Tech., China Chair Songlin Zhuang, Univ. of Shanghai for Sci. and Tech., China Guangming Tao, Huazhong Univ. of Sci. and Tech., China Kin-Seng Chiang, City Univ. of Hong Kong, HongKong Yingying Wang, Beijing Univ. of Tech., China General Chairs Xinyong Dong, China Jiliang Univ., China Lei Wei, Nanyang Tech. Univ., Singapore Xinyong Dong, China Jiliang Univ., China Chao Lu, Hong Kong Polytechnic Univ., Hong Kong Yiping Wang, Shenzhen Univ., China Perry Ping Shum, Nanyang Tech. Univ., Singapore Guy Omidyar, Omidyar-Inst., USA Anbang Wang, Taiyuan Univ. of Tech., China Benli Yu, Anhui Univ., China Shilong Pan, Nanjing Univ. of Aeronautics and Astronautics, Zinan Wang, Univ. of Electronic Sci. and Tech. of China, China General Co-Chairs China Athikom Roeksabutr, Mahanakorn Univ. of Tech., Thailand Yuwen Qin, Guangdong Univ. of Tech., China Qiang Wu, Northumbria Univ., UK Gangxiang Shen, Soochow Univ., China Jian-Jun He, Zhejiang Univ., China Li Xia, Huazhong Univ. of Sci. and Tech., China Chongqing Wu, Beijing Jiaotong Univ., China Zuyuan He, Shanghai Jiao Tong Univ., China Jun Yang, Harbin Engineering Univ., China Wen-De Zhong, Nanyang Technological Univ., Singapore Technical Program Committee Chairs Minghong Yang, Wuhan Univ. Tech., China Subcommittees Libo Yuan, Harbin Engineering Univ., China Daoxin Dai, Zhejiang Univ., China Yong Zhao, Northeastern Univ., China Baiou Guan, Jinan Univ., China Track 1: Optical fibers and fiber-based devices Han Zhang, Shenzhen Univ., China Zhaohui Li, Sun Yat-sen Univ., China Tuan Guo, Jinan Univ., China, Chair Wentao Zhang, Inst. of Semiconductors, CAS, China Xiangjun Xin, Beijing Univ. of Posts and Tel., China Yan'ge Liu, Nankai Univ., China, Chair Mingjiang Zhang, Taiyuan Univ. of Tech., China Xinliang Zhang, Huazhong Univ. of Sci. and Tech., China Liyang Shao, Southern Univ. of Sci. and Tech., China, Chair Pu Zhou, National Univ. of Defense Tech., China Xuping Zhang, Nanjing Univ., China Changyuan Yu, Hong Kong Polytechnic Univ., China, Chair Tao Zhu, Chongqing Univ., China Weihong Bi, Yanshan Univ., China Local Organizing Committee Guiyao Zhou, South China Normal Univ., China Chi Chiu Chan, Shenzhen Tech. Univ., China Changyu Shen, China Jiliang Univ., China, Chair Track 2: Optical transmission systems, subsystems and Nan-Kuang Chen, Liaocheng Univ., China Xuqiang Wu, Anhui Univ., China, Chair technologies Xinyu Fan, Shanghai Jiao Tong Univ., China Chunliu Zhao, China Jiliang Univ., China Jian Chen, Nanjing Univ. of Posts and Tel., China, Chair Yuan Gong, Univ. of Electronic Sci. and Tech. of China, China Weiqing Gao, HeFei Univ. of Tech., China Songnian Fu, Huazhong Univ. of Sci. and Tech., China, Chair Bo Liu, Nankai Univ., China Yaqi Tang, China Jiliang Univ., China Jian Wu, Beijing Univ. of Posts and Tel., China, Chair

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Lilin Yi, Shanghai Jiao Tong Univ., China, Chair Huaxi Gu, Xidian Univ., China Wenhua Gu, Nanjing Univ. of Sci. and Tech., China Tianwai Bo, KAIST, Korea Bingli Guo, Beijing Univ. of Posts and Tel., China Ran Hao, Zhejiang Univ., China Jiangbing Du, Shanghai Jiao Tong Univ., China Hongxiang Guo, Beijing Univ. of Posts and Tel., China Yong-Zhen Huang, Chinese Academy of Sciences, China Shanguo Huang, Beijing Univ. of Posts and Tel., China Weigang Hou, Northeastern Univ., China Yuqing Jiao, Eindhoven Univ. of Tech., Netherlands Alan Pak Tao Lau, HK Polytech. Univ., China Brigitte Jaumard, Concordia Univ., Canada Mingyu Li, Zhejiang Univ., China Borui Li, Huawei Technologies Co., Ltd., China Hoon Kim, KAIST, Korea Ting Mei, Northwestern Polytechnical Univ., China Jianqiang Li, Alibaba Group, USA Juhao Li, Peking Univ., China Xiaodong Pi, Zhejiang Univ., China Zhengxuan Li, Shanghai Univ., China Rui Lin, KTH Royal Inst. of Tech., Sweden Minhao Pu, Technical Univ. of Denmark, Denmark Yong Liu, Univ. of Electronic Sci. and Tech. of China, China Wei Lu, Univ. of Sci. and Tech. of China, China Ho Pui Aaron HO, Chinese Univ. of Hong Kong, HK Bo Liu, Nanjing Univ. of Information Sci. & Tech., China Carmen Mas Machuca, Technical Univ. of Munich, Germany Wei Shi, Laval Univ., Canada Ning Liu, Huawei Technologies Co., Ltd, China Avishek Nag, Univ. College Dublin, Ireland Yaocheng Shi, Zhejiang Univ., China Xiurong Ma, Tianjing Univ. Tech., China Kim Khoa Nguyen, École de Technologie Supérieure, Xiankai Sun, Chinese Univ. of Hong Kong, Hong Kong, China Li Pei, Beijing Jiaotong Univ., China Canada Yunxu Sun, Harbin Inst. of Tech. Shenzhen Graduate School, Periklis Petropoulos, Univ. of Southampton, UK Wenda Ni, Azure Networking, Microsoft, Canada China Ming Tang, Huazhong Univ. of Sci. and Tech., China Jelena Pesic, Nokia Bell Labs, France Junqiang Sun, Huazhong Univ. of Sci. and Tech., China Jian Wang, Huazhong Univ. of Sci. and Tech., China Houman Rastegarfar, Univ. of Arizona, USA Jianwei Wang, Peking Univ., China Liang Wang, Chinese Univ. of Hong Kong, China Jesse Simsarian, Nokia Bell Labs, USA Qijie Wang, Nanyang Technological Univ., Singapore Kun Xu, Beijing Univ. of Posts and Tel., China Elaine Wong, Univ. of Melbourne, Australia Jin Wang, Nanjing Univ. of Posts and Tel., China Fatih Yaman, NEC Laboratories, USA Lena Wosinska, KTH Royal Inst. of Tech., Sweden Qijie Wang, Nanyang Technological Univ., Singapore Lianshan Yan, Southwest Jiaotong Univ., China Wei Xu, Tsinghua Univ., China Kevin Williams, Eindhoven Univ. of Tech., Netherland Qi Yang, Huazhong Univ. of Sci. and Tech., China Yongli Zhao, Beijing Univ. of Posts and Tel., China Yang Xu, Zhejiang Univ., China Xingwen Yi, Sun Yat-sen Univ., China Min Zhu, Southeast Univ., China Lin Yang, Inst. of Semiconductors, CAS, China Yang Yue, Juniper Networks, USA Yu Yu, Huazhong Univ. of Sci. and Tech., China Track 4: Optoelectronic integration and devices Fan Zhang, Peking Univ., China Linjie Zhou, Shanghai Jiao Tong Univ., China Haoshuo Chen, Nokia, USA, Chair Zhiping Zhou, Peking Univ., China Track 3: Networks architectures, management and Liu Liu, South China Normal Univ., China, Chair applications Jianguo Liu, Inst. of Semiconductors, CAS, China, Chair Track 5: Optical signal processing & microwave photonics Jiajia Chen, KTH, Royal Inst. of Tech., Sweden, Chair Yikai Su, Shanghai Jiao Tong Univ., China, Chair Hongwei Chen, Tsinghua Univ., China, Chair Gangxiang (Steven) Shen, Soochow Univ., China, Chair Hualong Bao, Univ. of Sussex, England Jianji Dong, Huazhong Univ. of Sci. and Tech., China, Chair Jie Zhang, Beijing Univ. of Posts and Tel., China, Chair Xinlun Cai, Sun Yat-sen Univ., China Shiming Gao, Zhejiang Univ., China, Chair Zuqing Zhu, Univ. of Sci. and Tech. of China, China, Chair Po Dong, Nokia Bell Lab, USA Shilong Pan, Nanjing Univ. of Aeronautics and Astronautics, Bowen Chen, Soochow Univ., China Xuetao Gan, Northwestern Polytechnical Univ., China China, Chair

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Amol Choudhary, Indian Inst. of Tech. (IIT) Delhi, India Hao He, Shanghai Jiao Tong Univ., China Jae-Hoon Han, Korea Inst. of Sci. and Tech., Korea Peucheret Christophe, Univ. of Rennes, France Wing-Cheung Law, Hong Kong Polytechnic Univ., China Wei Ji, National Univ. of Singapore, Singapore Xinhuan Feng, Jinan Univ., China Peng Li, Zhejiang Univ., China Qian Li, Peking Univ. Shenzhen Graduate School, China Zhanghua Han, Nanjing Univ. of Sci. and Tech., China Bin Liu, National Univ. of Singapore, Singapore Xiaofeng Liu, Zhejiang Univ., China Chaoran Huang, Princeton Univ., USA Liwei Liu, Shenzhen Univ., China Xueming Liu, Zhejiang Univ., China Ming Li, Inst. of Semiconductors, CAS, China Linbo Liu, Nanyang Tech. Univ., Singapore Weiwei Liu, Nankai Univ., China Xuejin Li, Shenzhen Univ., China Tongyu Liu, Laser Inst. of Shandong Academy of Sci., China Zhichao Luo, South China Normal Univ., China Christina Lim, Univ. of Melbourne, Australia Yiqing Lu, Macquarie Univ., Australia Zhongqi Pan, Univ. of Louisiana Lafayette, USA Zhixin Liu, Univ. College London, UK Fake Lu, State Univ. of New York, USA Mark Pelusi, Univ. of Sydney, Australia Arnan Mitchell, RMIT Univ., Australia Huilian Ma, Zhejiang Univ., China Guanshi Qin, Jilin Univ., China Tigang Ning, Beijing Jiaotong Univ., China Dennis Matthews, UC Davis College of Engineering, USA Sze Y. Set, Univ. of Tokyo, Japan Li Pei, Beijing Jiaotong Univ., China Keiichi Nakagawa, Univ. of Tokyo, Japan Fengqiu Wang, Nanjing Univ., China Chester Shu, The Chinese Univ. of Hong Kong, China Tymish Y. Ohulchanskyy, Shenzhen Univ., China Jun Wang, Chinese Academy of Sciences, China Dawn Tan, Singapore Univ. of Design Tech., Singapore Yingquan Peng, China Jiliang Univ., China Xiaoyong Wang, Nanjing Univ., China Chao Wang, Univ. of Kent, England Zhuyuan Wang, Southeast Univ., China Zhi Wang, Nankai Univ., China Jian Wang, Huazhong Univ. of Sci. and Tech., China Anna Wang, Zhejiang Univ., China Kan Wu, Shanghai Jiao Tong Univ., China Lianshan Yan, Southwest Jiaotong Univ., China Peng Xi, Peking Univ., China Min Xiao, Nanjing Univ., China Lin Yang, Inst. of Semiconductors, CAS, China Xiaobo Xing, South China Normal Univ., China Peiguang Yan, Shenzhen Univ., China Xiaoke Yi, Univ. of Sydney, Australia Qing Yang, Zhejiang Univ., China Zhijun Yan, Huazhong Univ. of Sci. and Tech., China Xiaoguang Zhang, Beijing Univ. of Posts and Tel., China Yuanhong Yang, Beihang Univ., China Zuxing Zhang, Nanjing Univ. of Posts and Tel., China Xiaoping Zheng, Tsinghua Univ., China Baoli Yao, Xi'an Inst. of Optics and Precision Mechanics, Luming Zhao, Jiangsu Normal Univ., China Qunbi Zhuge, Shanghai Jiao Tong Univ., China CAS, China Quanzhong Zhao, Shanghai Inst. of Optics and Fine Weiwen Zou, Shanghai Jiao Tong Univ., China Zhen Yuan, Univ. of Macau, China Mechanics, CAS, China Haiming Zhu, Zhejiang Univ., China Track 6: Optical measurements and imaging Track 7: Ultrafast photonics and nonlinear optics Junle Qu, Shenzhen Univ., China, Chair Minglie Hu, Tianjin Univ., China, Chair Track 8: Photonics for energy Jun Qian, Zhejiang Univ., China, Chair Jianfeng Li, Univ. of Electronic Sci. and Tech. of China, Jianpu Wang, Nanjing Tech Univ., China, Chair Kebin Shi, Tsinghua Univ., China, Chair China, Chair Le Wang, China Jiliang Univ., China, Chair Wenjun Zhou, Univ. of California Davis, USA, Chair Jianrong Qiu, Zhejiang Univ., China, Chair Rong-Jun Xie, National Inst. for Materials Sci., Japan, Chair Haiwen Cai, Shanghai Inst. of Optics and Fine Mechanics, Yun-Feng Xiao, Peking Univ., China, Chair Yang Yang, Zhejiang Univ., China, Chair CAS, China Shengping Chen, National Univ. of Defense Tech., China Wallace Choy, the Univ. of Hong Kong, China Yongkang Dong, Harbin Inst. of Tech., China Xianfeng Chen, Shanghai Jiao Tong Univ., China Letian Dou, Purdue Univ., USA

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Feng Gao, Linköping Univ., Sweden Chair Shengwang Du, Hong Kong Univ. of Sci. and Tech., China David Ginger, Univ. of Washington, China Jing Xu, Zhejiang Univ., China, Chair Guoping Guo, Univ. of Sci. and Tech. of China, China C.S. Lee, City Univ. of Hong Kong, China Yanqing Lu, Nanjing Univ., China W.Steve Kolthammer, Imperial College London, UK Dehui Li, Huazhong Univ. of Sci. and Tech., China Jun Ao, Guilin Univ. of Electronic Tech., China Myungshik Kim, Imperial College London, UK Huili Li, East China Normal Univ., China Ming Chen, Beijing Research Inst. of Telemetry, China Jiaming Li, Shanghai Jiao Tong Univ., China Jiang Li, Shanghai Inst. of Ceramics, China Academy of Sci., Guijun Hu, Jilin Univ., China Tiefu Li, Tsinghua Univ., China China Xianqing Jin, Univ. of Sci. and Tech. of China Yanqing Lu, Nanjing Univ., China Xiaofeng Li, Soochow Univ., China Cong Li, China Academy of Space Tech., China Feng Mei, Shanxi Univ., China Junwei Luo, Inst. of Chemistry, CAS, China Jing Li, Commercial Aircraft Corporation of China, China Xiaolong Su, Shanxi Univ., China Zaifa Pan, Zhejiang Univ. of Tech., China Lilin Liu, Sun Yat-Sen Univ., China Lin Tian, Univ. of California Merced, USA Mingying Peng, South China Univ. of Tech., China Jianfei Liu, Hebei Univ. of Tech., China Guoyong Xiang, Univeristy of Sci. and Tech. of China, China Tzebin Song, Lawrence Berkeley National Laboratory, USA Junshan Mu, China Satellite Maritime Tracking and Control Man-Hong Yung, Southern Univ. of Sci. and Tech., China Weijie Song, Ningbo Inst. of Materials Tech. and Department, China Lijian Zhang, Najing Univ., China Engineering, Chinese Academy of Sci., China Chao Wang, China Academy of Space Tech., China Qiang Zhang, Univeristy of Sci. and Tech. of China, China Jianxin Tang, Soochow Univ., China Tianyun Wang, China Satellite Maritime Tracking and Wei Zhang, Tsinghua Univ., China Jing Wang, Sun Yat-sen Univ., China Control Department, China Special session 1: Optoelectronics based on organic and Yuansheng Wang, Fujian Inst. of Research on the Structure Ling Wu, Beijing Inst. of Telecommunication and Tracking, nanostructured materials of Matter, China China Wei Huang, Northwestern Polytechnical Univ., China, Chair Gang Wu, Zhejiang Univ., China Yan Xia, Hunan Univ., China Zugang Liu, China Jiliang Univ., China, Chair Mingmei Wu, Sun Yat-sen Univ., China Yunxia Xia, Key Laboratory of Beam Control, CAS Michele Muccini, National Research Council, Italy, Chair Jeong Weon Wu, Ewha Womans Univ., Korea Haifeng Yang, Southwest Inst. of Electronic Tech., China Pavel Brunkov, Ioffe Inst., Russia Liu Yang, Zhejiang Univ., China Haitao Yang, Space Engineering Univ., China Fred Chen, Shanghai Taoe Chemical Tech., China Jingbi You, Inst. of Semiconductors, CAS, China Yifei Yang, Jiangsu Univ. of Sci. and Tech., China Guanglu Ge, National Center for NanoSci. and Tech., China Xuegong Yu, Zhejiang Univ., China Baokang Zhao, National Univ. of Defense Tech., China Xiaojun Guo, Shanghai Jiao Tong Univ., China Haibo Zeng, Nanjing Univ. of Sci. and Tech., China Jie Zhong, Zhejiang Univ., China Yizheng Jin, Zhenjiang Univ., China Jia Zhu, Nanjing Univ., China Tianhua Zhou, Shanghai Inst. of Optics and Fine Mechanics, Rongyin Kuang, Najing Tech., China CAS Track 9: Space communications, navigation & tracking Zhen Li, Wuhan Univ./Tianjin Univ., China Weigang Zhu, Equipment Academy, China Nan Chi, Fudan Univ., China, Chair Dongge Ma, South China Univ. of Tech., China Bo Cong, China Satellite Maritime Tracking and Control Track 10: Space communications, navigation & tracking Hong Meng, Peking Univ., China Department, China, Chair Xianmin Jin, Shanghai Jiao Tong Univ., China, Chair Junbiao Peng, South China Univ. of Tech., China Tianshu Wang, Changchun Univ. of Sci. and Tech., China, Xifeng Ren, Univ. of Sci. and Tech. of China, China, Chair Nigel Pickett, Nanoco Technologies, UK

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Lei Qian, TCL, China Special session 3: 2D-materials based photonics Special session 5: Fiber-optic magnetic field sensors and Xiaowei Sun, Southern Univ. of Sci. and Tech., China Weida Hu, Shanghai Inst. of Technical Physics, CAS, China other devices Jinshan Wang, Watrp International, USA Chair Shengli Pu, Univ. of Shanghai for Sci. and Tech., China, Chair Lei Wang, Huazhong Univ. of Sci. and Tech., China Kaihui Liu, Peking Univ., China, Chair Lei Shi, Huazhong Univ. of Sci. and Tech., China, Chair Guohua Xie, Wuhan Univ., China Hongtao Lin, Zhejiang Univ., China, Chair Fei Xu, Nanjing Univ., China, Chair Rongjun Xie, Xiamen Univ., China Hua Zhang, City Univ. of Hong Kong, China John Philip, Indira Gandhi Centre for Atomic Research, India Xuyong Yang, Shanghai Univ., China Juejun Hu, Massachusetts Inst. of Tech., USA Stavros Pissadakis, Foundation for Research and Tech.- Haibo Zeng, Nanjing Univ. of Sci. and Tech., China Anlian Pan, Hunan Univ., China Hellas, Greece Haizheng Zhong, Beijing Inst. of Tech., China Han Zhang, Shenzhen Univ., China Jijun Feng, Univ. of Shanghai for Sci. and Tech., China Fushan Li, Fuzhou Univ., China Deep Jariwala, Univ. of Pennsylvania, USA Qun Han, Tianjin Univ., China Lixiang Wang, Changchun Inst. of Applied Chemistry, China Xiaomu Wang, Nanjing Univ., China Ming Deng, Chongqing Univ., China Changqi Ma, Suzhou Institue of Nano-Tech and Nano- Zhipei Sun, Aalto Univ., Finland Xianglong Zeng, Shanghai Univ., China Bionics, China Baicheng Yao, Univ. of Electronic Sci. and Tech. of China, Yinping Miao, Tianjin Univ. of Tech., China Yiqiang Zhang, Zhengzhou Univ., China China Qi Wang, Northeastern Univ., China Tao Song, Suzhou Univ., China Yaqing Bie, Sun Yat-Sen Univ., China Mahieddine Lahoubi, Badji-Mokhtar Annaba Univ., Algeria Zhengqian Luo, Xiamen Univ., China Yuejiang Song, Nanjing Univ., China Special session 2: Machine learning for optical Qiaoliang Bao, Monash Univ., Australia communication systems, networks, and devices Special session 6: Random fiber lasers Qunbi Zhuge, Shanghai Jiao Tong Univ., China, Chair Special session 4: Supercontinuum fiber source Yunjiang Rao, Univ. of Electronic Sci. and Tech. of China, Yongli Zhao, Beijing Univ. of Posts and Tel., China, Chair Shengping Chen, National Univ. of Defense Tech., China, China, Chair Yanni Ou, Nokia Bell Labs, Germany, Chair Chair Zinan Wang, Univ. of Electronic Sci. and Tech. of China, Shuangyi Yan, Univ. of Bristol, UK Peiguang Yan, Shenzhen Univ., China, Chair China, Co-Chair Zilong Ye, California State Univ., Los Angeles, USA Zhi Wang, Nankai Univ., China Pu Zhou, National Univ. of Defense Tech., China, Co-Chair Sabidur Rahman, UC Davis, USA Tingwu Ge, Beijing Univ. of Tech., China Anderson S. L. Gomes, Federal Univ. of Pernambuco, Brazil Yu Wu, Google, USA Xiaohui Gao, Xi'an Inst. of Optics and Precision Mechanics, Weili Zhang, Univ. of Electronic Sci. and Tech. of China, Jianqiang Li, Alibaba Group, USA China China Nan Hua, Tsinghua Univ., China Weijia Yang, YSL Photonics, China Jiangming Xu, National Univ. of Defense Tech., China Xiaosong Yu, Beijing Univ. of Posts and Tel., China Xiaohui Li, Shanxi Normal Univ., China Mengqiu Fan, China Academy of Engineering Physics, China Xiaoning Zhang, Univ. of Electronic Sci. and Tech. of China Limin Xiao, Fudan Univ., China Danish Rafique, ADVA, Germany

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General Information Registration Transportation Location: Lobby of Huangshan Xiangming Hotel Conference Venue: Huangshan Xiangming Hotel From Huangshan Tunxi International Airport（黄 会议地点：黄山香茗大酒店 Hours: 山屯溪国际机场） 14: 00-22: 00 Monday, 5 August By Taxi: 4.7km driving to Huangshan Xiangming Address: No. 2 Yingbin Avenue, Tunxi District, 08: 00-18: 00 Tuesday, 6 August Hotel (about RMB 10) Huangshan, China 08: 00-18: 00 Wednesday, 7 August 酒店地址：安徽省黄山市屯溪区迎宾大道 2 号 From Huangshan North Railway Station（黄山北 08: 00-13: 00 Thursday, 8 August 站） Speaker Preparation By Taxi: 16km driving to Huangshan Xiangming All oral presenters should check in at the corresponding Hotel (about RMB 40). session room at least ten minutes prior to their By Bus (High-speed Train Express route 2/高铁快线 scheduled talk to upload and check their presentation. 2 路 ): from Huangshan North Railway Station to No shows of the oral presentation will be reported Xiangming Hotel (about 55 minutes, RMB 5). to Conference management and these papers will not be published. From Huangshan Railway Station（黄山火车站） By Taxi: 4.3km driving to Huangshan Xiangming Poster Preparation Hotel (about RMB 10). Authors should prepare their poster before the poster

before the poster session starts. The poster must not From nearby cities exceed the boundaries of the poster board and A0 Accessibility 合肥 (0.9m Width * 1.2m Height) size is recommended. 1. Hefei ( ): There are 24 high-speed trains per Located in the Tunxi district of Huangshan City, the Authors are required to be standing by their poster for day travelling between Hefei South Railway Station Xiangming Hotel is a short drive away from the duration of their allocated session to answer （合肥南站）and Huangshan North Station（黄山北 站）with the shortest travelling time of 80 minutes. Huangshan Tunxi Airport, railway station and Tunxi questions and further discuss their work with attendees. Old Street, and about a one-hour drive to the No shows will be reports to Conference 2. Hangzhou (杭州): There are 29 high-speed trains famous Huang Shan scenic area. The management and these papers will not be published. per day travelling between Hangzhou East Railway interconnected buildings of the hotel complex Poster Board Size – 1m (Width) * 2m (Height) Station（杭州东站） and Huangshan North Station straddle a small lake, and the Hui Cultural Center is Location: 4 F, Huangshan Xiangming Hotel （黄山北站）with the shortest travelling time of 86 just a short walk away. Conference rooms offer Hours: minutes. Poster Session 1 15:30-16:00, 6 August projectors and simultaneous translation equipment, 3. Shanghai (上海): There are 14 high-speed trains digital recording equipment, a satellite video Poster Session 2 10:00-10:30, 7 August per day travelling between Shanghai Hongqiao conference system and more. The hotel's large Railway Station（上海虹桥站）and Huangshan North banquet hall and other function rooms are also Poster Session 3 15:30-16:00, 7 August Station（黄山北站）with the shortest travelling time available for non-business functions like weddings Poster Session 4 10:00-10:30, 8 August of 146 minutes. or private parties.

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Exhibition Lunches & Dinner Social Events

The ICOCN2019 Exhibition is open to all attendees. Three-day buffet lunches and dinner (Aug. 6-8) in Welcome reception Huangshan Xiangming Hotel are included in the Location: Public area, 4F, Huangshan Xiangming Hotel All participants are cordially invited to the Welcome registration fee for all registered delegates. And lunch Reception. It will be a great opportunity to develop a Hours: & dinner tickets are provided within the badge. broad, deep and diverse network of personal Location: Violet Hall, 3F, Huangshan Xiangming Hotel 09: 00-18: 00 Tuesday, 6 August connections with participants from all over the world. Hours: Complimentary food and beverages will be offered by 09: 00-18: 00 Wednesday, 7 August Organizing Committee of ICOCN'2019. It is free to all 12:00-13:30 Tuesday, 6 August the registered participants. 09: 00-16: 00 Thursday, 8 August Location: Violet Hall, 3F, Huangshan Xiangming Hotel 18:00-20:00 Tuesday, 6 August Time: 18: 00-21: 00, 5 August 12:00-13:30 Wednesday, 7 August Conference Banquet and Awards Ceremony 12:30-14:00 Thursday, 8 August All participants are cordially invited to the banquet. We Conference Materials will announce the winners of Young Scientist Awards, ICOCN2019 Technical Digest will be provided in a USB Best Student Paper Award and Best Poster Award. The drive and not available in print form. The ICOCN2019 winners will receive their certificates and awards at the Technical Digest material is composed of the 3-page Tea & Coffee Breaks ceremony. Participate in our Lucky Draw during the summaries of invited and accepted contributed papers. banquet, you may be one of the lucky winners! At the The Technical Digest material is included with a 15:30-16:00 Tuesday, 6 August same time, you will enjoy delicacies foods. It will be an technical conference registration and can be found in unforgettable Banquet that you will always remember your registration bag. The Digest will be available on 10:00-10:30 Wednesday, 7 August with a smile. IEEE Xplore Digital Library (http://www.ieee.org/web/publications/xplore/) after 15:30-16:00 Wednesday, 7 August The Banquet is included in the registration fee for all the conference. IEEE Xplore Digital Library is archived register delegates. The ticket is provided within the 10:00-10:30 Thursday, 8 August and indexed by INSPEC R and EI Compendex, where it badge. The student Award recipients will be invited to will be available to the international technical 16:00-16:30 Thursday, 8 August attend the Banquet and Award Ceremony for free. community. Location: Xiangming Hall, 2F, Xiangming Hotel

Time: 18: 30-21: 00, 7 August

International Conference on Optical Communications and Networks (ICOCN2019) ● 5 August 2019-8 August 2019 ● Page 9

Conference Highlights

Plenary Presentations Application of Optical Wired communication: from Time: 09:30-11:45, Tuesday, 6 August Transmission Techniques in Maxwell to optical fibers Venue: Yunhai Hall, 2F, Xiangming Hotel Distributed Optical Fibre Sensing Systems 11:00-11:45, Tuesday, 6 August ICOCN2019 will feature three plenary presentations. The presentation will be preceded 10:15-11:00, Tuesday, 6 August René-Jean Essiambre by an Opening Ceremony from 9:00-9:30. More Chao LU Bell Labs, Nokia information appear below. The Hong Kong Polytechnic Biography: Rene-Jean Essiambre Making better optical fibers University, China received his Ph.D. in Physics from Laval University, Qué Biography: Chao LU obtained his BEng in Electronic 09:30-10:15, Tuesday, 6 August bec City, Canada and pursued post-doctoral studies at Engineering from Tsinghua University, China in 1985, the Institute of Optics of the University of Rochester, Jonathan Knight and his MSc and PhD from University of Manchester in Rochester, NY. In 1997, he joined Lucent Technologies 1987 and 1990 respectively. He joined the School of University of Bath, United (which became Alcatel-Lucent and now Nokia). Dr. Kingdom Electrical and Electronic Engineering, Nanyang Technological University (NTU), Singapore as a faculty Essiambre worked on fiber lasers, optical fiber Biography: Jonathan Knight is a member in 1991 and was there until 2006. From June nonlinearity, advanced modulation formats, coherent Professor of Physics at the University of Bath in the 2002 to December 2005, he was seconded to the detection, space-division multiplexing and information United Kingdom. His research focuses on developing Institute for Infocomm Research, Agency for Science, theory applied to optical fibers. He has an extensive new forms of optical fibre, from concept through Technology and Research (A*STAR), Singapore, as knowledge of fiber-optic communication systems and fabrication and characterisation to applications. Program Director and Department Manager leading a contributed to the design of many installed commercial research group in the area of optical communication systems. He has given over 100 invited talks, including Abstract: Conventional optical fibres based on total and fibre devices. He joined the Department of the 2018 Physics Nobel Prize Lecture of Arthur Ashkin. internal reflection have enabled high-bandwidth digital Electronic and Information Engineering, The Hong He has served on or chaired several conference communications and many other applications. Kong Polytechnic University in 2006 and is Chair committees, including OFC, ECOC, CLEO and the IEEE However they are fundamentally unable to achieve Professor of Fibre Optics there now. Over the years, he Photonics Society (IPS). He was program and general some desirable performance characteristics. For has published more than 300 papers in major co-chair of CLEO Science & Innovation in 2012 and example, they cannot transmit ultraviolet and mid- international journals. His research interests are in the 2014, respectively. He is a recipient of the 2005 infrared light, or powerful short or ultrashort pulses. For area of high capacity transmission techniques for long Engineering Excellence Award from OSA, a fellow of these applications, optical fibres based on the use of a haul and short reach systems and distributed optical the IEEE and the OSA, and a Distinguished Member of hollow core surrounded by microstructured silica can sensing systems. In addition to academic research work, he has had many industrial collaborative research Technical Staff (DMTS) and Fellow at Bell Labs, Nokia. be much better. Over the last few years, a new family of projects and has a number of awarded patents. His He is also a Fellow of the Institute of Advanced Studies hollow-core fibres based on the use of anti-resonances current research interests are in the area of high of Technical University of Munich (IAS-TUM) in Munich, has emerged. We will review the basic physics and capacity transmission techniques for long haul and Germany. He is an Ambassador of TUM. He is currently demonstrated performance of these novel fibres, and short reach systems and distributed optical sensing member of the Board of Governors and V-P of the discuss their potential limitations and expected further systems. He is a fellow of the Optical Society (OSA). Membership Council at IPS. performance gains.

International Conference on Optical Communications and Networks (ICOCN2019) ● 5 August 2019-8 August 2019 ● Page 10

Young Scientist Awards 15 recipients, a certificate & a HUAWEI smartphone The Musical stage show is included in the registration for each fee for all register delegates. The ticket is provided ICOCN2019 is pleased to announce that this All the accepted and registered poster papers are within the badge. Extra ticket will be sold at the year’s Young Scientist Awards is sponsored by registration desk (RMB 120 per person). Light: Science & Applications (LSA). eligible for the Best Poster Award competition, but pre-conference shortlist will be carried out Location: Xiangming Hotel Theatre 5 recipients, a certificate & a HUAWEI ultrabook for based on the peer-review results by TPC/invited Time: 20: 00-21: 10, 6 August each reviewers. The shortlisted posters are arranged to To be eligible for the award, the candidates must present in the first poster session of the be the first & presenting author of the registered conference. Those who win the first fifteen largest Free Membership Promotion to paper and born after Aug. 5, 1979. The selection number of “Best Poster Award” vote tickets will IEEE Photonics Society will be made by the TPC or expert panel during be given the Best Poster Award. Certificates and In partnership with ICOCN, the IEEE Photonics the conference. Each awardee will receive a prizes (a HUAWEI smartphone) will be presented Society has created a half-year member certificate of award and a HUAWEI ultrabook as to the winners in the award ceremony during the promotion campaign that participants of the prize in the award ceremony during the conference banquet. conference banquet. conference can benefit from. The following promotion is only active for current IEEE members Musical stage show: Picturesque who are new to the Society or have lapsed in their Best Student Paper Awards Huizhou and Huangshan membership for over 18-months. ICOCN2019 is pleased to announce that this For a limited time, such members can join at no year’s Best Student Paper Awards is sponsored by cost and the IEEE Photonics Society will assume State Key Laboratory of Optical Fibre and Cable the member expenses for the remainder of 2019 Manufacture Technology. and until February 2020. This campaign will run 10 recipients, a certificate & a HUAWEI Pad for each from March 1, 2019 to August 15, 2019. Do not Any full-time research student, who is the first and miss out on applying! presenting author of a full paper submitted with choosing presentation type of "Oral for Best Banquet Lucky-draw Student Paper Award" will be eligible for this award competition. Ten winners will be selected Every registered non-student participant will be by the TPC or expert panel. Each awardee will given a Best Poster Award Voting Ticket at the receive a certificate of award and a HUAWEI Pad Musical stage show: Picturesque Huizhou and registration desk when they collect the as prize in the award ceremony during the Huangshan, a large-scale song and dance drama, conference materials. Those who help us select conference banquet. consist of five sessions, a variety of performance the awardee candidates by writing down the measures run through the whole performance, poster numbers on the voting ticket and put it into the ticket collecting box during the first Best Poster Awards including modern Huizhou drama, Beijing opera, flower-opera, folk medley, song and dance set poster session time will get the chance to be lucky ICOCN2019 is pleased to announce that this and so on. The whole drama is magnificent, guy. Do help us by submitting your choice for the year’s Best Poster Awards is sponsored by symphonic and captivating, which is a culture Best Poster. LUSTER LightTech Group & YSL Photonics Co., gluttonous feast that cannot resisted to watch and Ltd. enjoy.

International Conference on Optical Communications and Networks (ICOCN2019) ● 5 August 2019-8 August 2019 ● Page 11

Conference & Exhibition Map

2F

4F

3 4 5 6 7

8 9 10 11 12

Coffee Break Poster Area Booth

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 12

ICOCN 2019—Agenda of Sessions

NOTES

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 13

ICOCN 2019—Agenda of Sessions

Explanation of Session Codes

W1A.1

Day of the Week Number T = Tuesday (Presentation order

W = Wednesday within the session)

Th = Thursday

Series Number Session 1=First Series of Sessions Designation 2=Second Series of Sessions (alphabetically)

The first letter of the code designates the day of the week (T = Tuesday, W = Wednesday, Th = Thursday). The second element indicates the session series in that day (for instance, 1would denote the first parallel session in that day). The third element continues alphabetically through a series of parallel sessions. The lettering then restarts with each new series. The number on the end of the code (separated from the session code with a period) signals the position of the talk within the session (first, second, third, etc.). For example, a presentation coded W1A.1 indicates that this paper is being presented on Wednesday (W) in the first series of sessions (1), and is the first parallel session (A) in that series and the first paper (1) presented in that session.

Plenaries are noted with Plenary

Keynotes are noted with K ey note

Invited papers are noted with Invited

BSPAs are noted with ☼

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ICOCN 2019—Agenda of Sessions

Tuesday, 6 August

Exhibition Room 2 Room 3 Room 5 Room 6 Room 7 Room 8 Room 10 Room 11 Room 12 Area Agenda of Sessions

08:00-18:00 Registration, Lobby, 1F

09:00-09:30 Opening Ceremony, Yunhai Hall(云海厅), 2F

09:30-11:45 Plenary Session, Yunhai Hall(云海厅), 2F

12:00-13:30 Lunch Break, Violet Hall (紫罗兰餐厅), 3F

T2A T2B T2C T2D T2E T2F T2G T2H T2I Optical Young 2D-materials Ultrafast & Novel fibers Optical mea Microwave Organic & Quantum photonics I nonlinear & devices I surement I photonics I nano photonics I transmission I Scientist 13:30-15:30 optics I optoelectroni Award I cs I Conference Exhibition

15:30-16:00 Poster Session I & Coffee Break, 4F

T3A T3B T3C T3D T3E T3F T3G T3H T3I Optical Young Machine Ultrafast & Random Optical mea Optoelectron Organic & Quantum 16:00-18:00 networks I Scientist learning I nonlinear Fiber Lasers I surement II ics I nano photonics II Award II optics II optoelectroni cs-II

18:00-20:00 Dinner Break, Violet Hall (紫罗兰餐厅), 3F

20:00-21:10 Musical stage show, Xiangming Hotel Theatre

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ICOCN 2019—Agenda of Sessions Sessions of Agenda

Wednesday, 7 August

Exhibition Room 2 Room 3 Room 5 Room 6 Room 7 Room 8 Room 10 Room 11 Room 12 Area

08:00-18:00 Registration, Lobby, 1F

W1A W1B W1C W1D W1E W1F W1G W1H W1I Optical Optical 2D-materials Novel laser Novel fibers Optical mea Optoelectro Organic & Quantum 08:00-10:00 transmission II networks II photonics II sources & devices II surement III nics II (BSPA) nano photonics III (BSPA) (BSPA) (BSPA) optoelectron ics-III 10:00-10:30 Poster Session II & Coffee Break, 4F

W2A W2B W2C W2D W2E W2F W2G W2H W2I BSPA: Tracks 2 BSPA: Tracks Machine Ultrafast & Novel fibers Optical mea Optoelectro Organic & Quantum 10:30-12:00 & 9 3 & 5 learning II nonlinear III & devices III surement IV nics III nano photonics IV (BSPA) (BSPA) (BSPA) (BSPA) (BSPA) optoelectron ics IV Conference 12:00-13:30 Lunch Break, Violet Hall (紫罗兰餐厅 ), 3F Exhibition W3A W3B W3C W3D W3E W3F W3G W3H W3I Optical Optical 2D-materials Supercomtin Novel fibers Optical mea Optoelectro Organic & Quantum 13:30-15:30 transmission III signal photonics III uum sources & devices IV surement V nics IV nano photonics V processing I optoelectron ics V

15:30-16:00 Poster Session III & Coffee Break, 4F

W4A W4B W4C W4D W4E W4F W4G W4H W4I Optical Optical Machine Ultrafast & Random Optical mea Optoelectro Organic & Quantum 16:00-18:00 transmission IV networks III learning III nonlinear Fiber Lasers surement VI nics V nano photonics VI optics IV II optoelectron ics VI

18:30-21:00 Banquet and Awards Ceremony, Xiangming Hall (香茗厅), 2F

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ICOCN 2019—Agenda of Sessions

Thursday, 8 August Exhibition Room 2 Room 3 Room 5 Room 6 Room 7 Room 8 Room 10 Room 11 Room 12 Area Agenda of Sessions 08:00-13:00 Registration, Lobby, 1F

Th1A Th1B Th1C Th1D Th1E Th1F Th1G Th1H Th1I Optical Space com Fiber Supercomtin Novel fibers Optical mea Optoelectro Organic & Quantum 08:00-10:00 transmission munications I magnetic uum sources & devices V surement VII nics VI nano photonics VI V devices I II optoelectron ics VII

10:00-10:30 Poster Session IV & Coffee Break, 4F

Th2A Th2B Th2C Th2D Th2E Th2F Th2G Th2H Th2I Optical Space com Fiber Ultrafast & Novel fibers Optical mea Photonics for Organic & Quantum transmission munications II magnetic nonlinear & devices VI surement VIII energy I nano Conference 10:30-12:30 photonics VII VI devices II optics V optoelectron Exhibition ics VIII

12:30-14:00 Lunch Break, Violet Hall (紫罗兰餐厅 ), 3F

Th3B Th3E Th3G Th3H Post- Optical Organic & Deadline 14:00-16:00 Novel fibers Photonics for networks IV nano Paper & devices VII energy I optoelectron ics IX

16:00-16:30 Coffee Break, 4F

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ICOCN 2019—Tuesday, 6 August

14:00-22:00 Registration, Lobby (大厅 ), 1F

09:00-09:30 Opening Ceremony, Yunhai Hall (云海厅 ), 2F

09:30-11:45, Plenary Session , Yunhai Hall (云海厅 ), 2F August 6 Tuesday, Presider: Perry Ping Shum, Nanyang Technological University, Singapore

T1A.1 • 09:30 Plenary Making better optical fibers, Jonathan Knight; University of Bath, UK. Conventional optical fibres based on total internal reflection have enabled high-bandwidth digital communications and many other applications. However, they are fundamentally unable to achieve some desirable performance characteristics. For example, they cannot transmit ultraviolet and mid-infrared light, or powerful short or ultrashort pulses. For these applications, optical fibres based on the use of a hollow core surrounded by microstructured silica can be much better. Over the last few years, a new family of hollow-core fibres based on the use of anti-resonances has emerged. We will review the basic physics and demonstrated performance of these novel fibres, and discuss their potential limitations and expected further performance gains.

T1A.2 • 10:15 Plenary Application of Optical Transmission Techniques in Distributed Optical Fibre Sensing Systems, Chao Lu; The Hong Kong Polytechnic University, China. Optical communication and distributed optical sensing system are two important application areas of optical fiber. Both systems use some of the excellent properties offered by optical fiber including low loss and immunity to electromagnetic interference etc. Although they have been developed separately over many years, they share a lot of similarities in signal detection techniques. The repaid development of high capacity optical communication systems in recent years have created many new tools for signal detection and they can be explored for potential sensing applications. In the talk, application of signal detection techniques developed for optical communication systems to enhance the performance of distributed sensing system performance is described. In addition, some recent work in combining optical communication and distributed sensing system is highlighted.

T1A.3 • 11:00 Plenary Wired communication: from Maxwell to optical fibers, René-Jean Essiambre; Bell Labs, Nokia. Electrical wired communication appeared in the 19th century and enabled for the first time near-instantaneous communication over continental distances. Over the last two centuries, there has been a steady evolution from using electrical currents to using electromagnetic fields to transmit information over long distances. The discovery of low-loss optical fibers in the last few decades has enabled a dramatic increase in the rate of information transmission and, importantly, a considerable reduction in the cost of transmitted bits. The latter lead to a widespread democratization of information sharing. We will present an overview of the evolution of long-haul wired communication, from single metallic wires to optical fibers. The emphasis will be on the physical phenomena thought to have driven technological evolution and some historical events that may have played a role in the development of long-haul communication.

12:00-13:30 Lunch Break, Violet Hall (紫罗兰餐厅 ), 3F

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ICOCN 2019—Tuesday, 6 August

Room 2, Track 2 Room 3, YSA Room 5, Special 3 Room 6, Track 7

13:30-15:30 13:30-15:30 13:30-15:30 13:30-15:30 T2A • Optical transmission I T2B • Young Scientist Award I T2C • 2D-materials photonics I T2D • Ultrafast & nonlinear optics I Chao Lu Presider: Haoshuo Chen, Nokia Bell Presider: , Hong Kong Polytechnic Univ., Presider: Weida Hu, Shanghai Inst. of Presider: Chengbo Mou, Shanghai Hong Kong Labs, USA Tech. Physics, CAS, China Univ., China

T2A.1 • 13:30 Invited T2B.1 • 13:30 T2C.1 • 13:30 Invited T2D.1 • 13:30 Keynote Single-span 112-Gb/s SSB- Accurate, Robust and Fast Beam Characterization for Silicon/2D-materials Photonic Dynamics of soliton formation QAM signal transmission Fiber Beams Based on Deep Learning, Liangjin Huang1, Inte-grated Devices, Daoxin in mode-locked lasers, beyond 120 km with direct Yi An1, Jun Li1, Kun Xie1, Jinyong Leng1, Lijia Yang1 and Pu Dai1, Jiang Li1, Yanlong Yin1 and Xueming Liu1; 1Zhejiang Univ., detection using a MIMO- Zhou1; 1National Univ. of Defense Tech., China. Fiber beam Jingshu Guo1; 1Zhejiang Univ., China. Real-time spectroscopy ANN nonlinear equalizer, characterization based on deep learning, including mode China. Silicon photonics has access to ultrafast fiber lasers Yikai Su1; 1Shanghai Jiao Tong Univ., decomposition and M^2 evaluation, has been first-ever attracted much attention because of the opens new opportunities for exploring China. We present a MIMO-ANN non- demonstrated by simulation and experiment. Deep CMOS compatibility, high integrated complex soliton interaction dyna-mics. linear equalizer for processing a QAM learning enables not only high accuracy and speed but density, etc. In this paper, we present our Here, we will report the observations of Tuesday, 6 August signal in a SSB-SCD system. Transmission also high antinoise ability. recent works on silicon/2D-materials the buildup process of solitons in mode-

of a 112-Gb/s SSB 16-QAM signal over a T2B.2 • 13:45 photonic integrated devices for photo- locked lasers. single-span 120-km single mode fiber 0.5 mm resolution distributed fiber strain sensor with a detection and thermal-tuning. (SMF) and beyond is demonstrated. location-deviation compensation algorithm based on

OFDR, Mingming Luo1 and Jianfei Liu1; 1Hebei Univ. of

Tech., China. We propose and demonstrate a 0.5 mm spatial resolution fiber strain sensor with a location- deviation compensation algorithm. Experimental results reveal 50000 equivalent sensors along 25 m fiber.

T2A.2 • 14:00 Invited T2B.3 • 14:00 T2C.2 • 14:00 Invited Towards Long-Distance Fiber Amplification of surface plasmons on a staggered Two Dimensional Xene Opto- Orbital Angular Momentum doubly-corrugated metallic surfaces by electron beam, electronics, Han Zhang1; Multiplexing Communicati- Yong Qiang Liu1; 1Peking Univ., China. We propose and 1Shenzhen Univ., China. 2D ons, Jian Wang1; 1Huazhong study a novel excitation method of SSP by using electron layers of metal dichalcogeni- Univ. of Science and Tech., beam with a staggered double grating theoretically and des have attracted much atten- T2D.2 • 14:15 China. In this talk, we review fiber-based numerically. tion because of their ultrathin thickness Dynamics of asymmetric soliton explo- sions in ultrafast fiber lasers, Wenxiong orbital angular momentum communica- T2B.4 • 14:15 and potential applications in electronics Du1, Heping Li1, Junwen Li1, Zhuang tions. We report long-distance OAM mul- Reconfigurable photonic signal processor with gra- and optoelectronics. We further explore Wang1 and Yong Liu1; 1UESTC, China. tiplexing transmission (3 OAM modes, 22 dient descent algorithm, Hailong Zhou1, Yuhe Zhao1, Xu the optoelectronic properties of mono- Asymmetric soliton explosions are nume- wavelengths) through 110-km fiber with- Wang1, Dingshan Gao1, Jianji Dong1 and Xinliang Zhang1; layer MoS2 synthesized by chemical rically demonstrated in an Yb-doped out MIMO-DSP assisted by all-fiber OAM 1HUST, China. The proposed photonic signal processor is vapor deposition on sapphire substrate fiber laser. The explosion events occur (de)multiplexer and Raman amplification capable of performing various functions including multi- and contacted the Au electrode by when the pump strength is tuned to channel optical switching, optical multiple-input-multiple- lithographie method for applications in reside between stationary dissipative output descrambler and tunable optical filter. photodetectors. soliton and noise-like pulse regime.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 19

ICOCN 2019—Tuesday, 6 August

Room 7, Track 1 Room 8, Track 6 Room 10, Track 5 Room 11, Special 1 Room 12, Track 10

13:30-15:30 13:30-15:30 13:30-15:30 13:30-15:30 13:30-15:30 T2E • Novel fibers & devices I T2F • Optical measurement I T2G • Microwave photonics I T2H • Organic & nano T2I • Quantum photonics I Presider: Fei Xu, Nanjing Univ., Presider: Changyuan Yu, Hong Presider: Xiaoguang Zhang, optoelectronics I Presider: Yangjian Cai, China Beijing Univ. of Posts and Tel., Kong Polytechnic Univ., China Presider: Zugang Liu, China Shandong Normal Univ., China China Jiliang Univ., China

T2E.1 • 13:30 Invited T2F.1 • 13:30 Invited T2G.1 • 13:30 Invited T2H.1 • 13:30 Keynote T2I.1 • 13:30 Invited Optical Fiber Devices A submarine cable moni- Photonic generation of The prospective and Necessity of Reinterpre- August 6 Tuesday, Based on Hybridstructu- toring system based on reconfgurable multi-band challenges and of micro tation of Quantum Tunnel re Optical Fibers, Li Pei1; multi-parameter optical linearly frequency-modul- LED’s to be displays, Han- Effect, Xiaomin Ren1; 1Beijing Jiaotong Univ., time domain reflecto-me- ated signals, Shilong Pan1, Ping D. Shieh1,2; 1National 1Beijing Univ. of Posts and China. The optic fiber ter, Xuping Zhang1; Wenjuan Chen1 and Dan Chiao Tung Univ., China; Telecommun., China. The devices and optical fiber sensors with 1Nanjing Univ., China. Submarine Zhu1; 1Nanjing Univ. of Aeronautics 2Sun Yat-sen Univ, China. Both LCD necessity of reinterpret-tation of different hybrid cascaded structure cable monitoring system based on and Astronautics, China. A photon- and OLED are facing challenges for quantum tunnel effect is concluded have obvious advantages in flexible multi-parameter optical time domain ics-based multi-band LFM waveform high brightness, power consumption, by negating the current inter- control of polarization characteristics, reflectometer (M-OTDR) is realized, generator with reconfigurable center free form sharp, adequate lifetime pretation while new mathematical improving extinction ratio, multi- which could not only detect but even frequency, band-width and time dur- and cost-performance adequate for concepts are defined. A novel model dimensional parameter sensing and precaution damage before it actually ation is proposed and demonstrated “universal” displays. Micro LEDs are is established mathematically base suppressing cross-sensitivity, etc. happen through synchronous mea- based on two coherent optical freq- emerging for the above features. on the concept of energy level surement on attenuation and uency combs. LFM signals ranging This talk will address those issues dispersion. vibration. from L to Ka bands are generated. and prospective of micro LED’s for practical display panel applications.

T2E.2 • 14:00 Invited T2F.2 • 14:00 Invited T2G.2 • 14:00 Invited ☼T2H.2 • 14:15 T2I.2 • 14:00 Invited Proposal of Low-Noise Fading suppression in Φ- Microwave photonic Comparative Study on the Influence of Quantum state control in and High-Bandwidth OTDR with multiple chan- signal processing based Quantum Dot Display and Liquid Crystal single quantum dots and Graded Index Plastic nels, Zinan Wang1; 1Univ. on modal dispersion, Display on Human Visual Function, the coupling with photo- 1 2 3 Optical Fibers, Yasuhiro of Science and Tech. of Chao Wang1; 1Univ. of Kent, Xiangyu Qu , Shanshan Zeng , Ke Wei , nic crystal cavities, Xiulai Rongrong Wen4, Kaiwei Feng4, Jianqi Koike1 and Azusa Inoue1; China, China. In this talk, UK. Multimode wave- Xu1; 1Inst. of Physics Cai2 and Yi Chen1; 1China Jiliang Univ., 1Keio Univ., Japan. The low-noise we will theoretically describe and guides provide significant modal . China; 2China National Inst. of Chinese Academy of Sciences, China Graded Index Plastic Optical Fiber experimentally verify how the fading dispersion and hold great potential Standardization, China; 3Mianyang Inst. We report strong coupling for cavity (GI POF), which is achieved by phenomenon in phase-sensitive op- for providing chromatic dispersion of Product Quality Inspection, China; QED between different excitonic microscopic heterogeneities of the tical time-domain reflectometry will and true time delay towards various 4Beijing YangMing ZhiDao Photoelectric states in a single quantum dot and a core polymer material, has been be suppressed with an arbitrary microwave photonics applications, Sci. and Tech. Co.L-td, China. We cavity including two-photon Rabi proposed as “the capillary of light” number of independent probing such as photonic time stretch conducted a human factor experiment on splitting, and the interaction enhan- of high-bitrate data transmission in channels. systems and transverse microwave the QD display and LCD. The parameters cement between cavities and p-shell IoT environment. photonic filters. ACC, HOAs and MTF were selected as excitons will be discussed. objective physio-logical indicators. Analysis the effects of displays on human eye physiological characteristics.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 20

ICOCN 2019—Tuesday, 6 August

Room 2, Track 2 Room 3, YSA Room 5, Special 3 Room 6, Track 7

T2A.3 • 14:30 Invited T2B.5 • 14:30 T2C.3 • 14:30 Invited T2D.3 • 14:30 Invited Imperfections of Kramers- High Power Random Fiber Laser: From Demonstration to Graphene enhanced microres- Unveiling soliton booting Kronig-based optical transm- Application, Jiangming Xu1, Jun Ye1, Yang Zhang1, Jiaxin onators for high performance dynamics in ultrafast fiber ission system, Tianwai Bo1 and Song1, Long Huang1, Hanwei Zhang1 and Pu Zhou1; 1National communication and sensing, lasers, Zhichao Luo1; 1South Hoon Kim1; 1Korea Advanced Univ. of Defense Tech., China. We present a high power Baicheng Yao1, Zhongxu Cao1 China Normal Univ., China. Inst. of Science and Tech., random fiber laser (RFL) with unique temporal stability, and Ning An1; 1UESTC, China. We report our recent South Korea. We will review several spectrum and polarization features and the application We share advances in graphene based advances on the soliton build-up technical challenging of the Kramers- exploration of RFL in high power MOPA and mid-infrared micro-resonators, for enhanced physics, dynamics in ultrafast fiber lasers. These Kronig coherent receiver in metro optical laser generation. such as optomechanics, selective gain- findings will give some new insights into transmission systems. It includes the assitance, and dispersion modulation, the transient soliton dynamics as well as impractical digital upsampling, suscep- T2B.6 • 14:45 leading to controllable frequency combs, soliton formation dynamics in fiber lasers. tibility to the laser noise and effect of Effect of Gold Coating on Distributed Strain Measurement fiber lasers and biochemical sensors. fiber polarization mode dispersion. at High Temperature up to 700 ℃ by Dpp-botda, Pengbai Xu1, Yongkang Dong2 and Yuwen Qin1; 1Guangdong Univ. of

Tuesday, 6 August Tech, China; 2Harbin Inst. of Tech., China. We thoroughly investigate the effect of the gold coating of Gold-coated fiber (GCF) on strain measurement at high temperature up to 700 ℃ with differential pulse pair Brillouin optical time analysis (DPP-BOTDA).

T2A.4 • 15:00 Invited T2B.7 • 15:00 T2C.4 • 15:00 Invited T2D.4 • 15:00 Invited Multi-path Channel Estimation The effect of position of ytterbium-doped fiber on the Low dimensional metal Nonlinear pulse dynamics in in Mobile Visible Light Com- output spectrum of random fiber laser, Rui Song1, Lanjian halide perovskite photonics, spatiotemporal mode-locked munication Based on Decision Chen1, Weiqiang Yang1 and Jing Hou1; 1National Univ. of Anlian Pan1; 1Hunan Univ., multimode fiber lasers, Feedback, Yanjun Zhong1, Jian Defense Tech., China. The experimental results show that China. We demonstrated the Xiaosheng Xiao1; 1Tsinghua Chen1, Xiaodi You2 and putting ytterbium-doped fiber in the random fiber laser’s controlled growth of in-plane Univ., China. Spatiotemporal Changyuan Yu2; 1Nanjing Univ. of posts cavity is beneficial for the generation of high-order Stokes. A directional perovskite CsPbBr3 nano- mode-locked lasers, i.e., multiple trans- and telecommunications, China; 2The super-continuum with more than 500nm can be generated. wires on annealed M-plane sapphire verse and dinal modes are simultane- Hong Kong Polytechnic Univ., China. We substrates, and the guided nanowire ously locking, are general forms of mode- propose a novel outdoor mobile visible exhibit excellent photoresponse proper- locking. Several spatiotemporal selforga- light communication channel estimation ties of 4400 A/W and a very fast response nization effects, e.g. soliton molecule, method based on decision feedback. speed of 252s, such guided nanowire multipulsing, observed by our group will Simulation results show that compared arrays have great potential in the be introduced and discussed. with the conventional scheme, the integration works. proposed method can reduce the bit error rate below 10-4.

15:30-16:00 Poster Session 1 & Coffee Break, 4F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 21

ICOCN 2019—Tuesday, 6 August

Room 7, Track 1 Room 8, Track 6 Room 10, Track 5 Room 11, Special 1 Room 12, Track 10

T2E.3 • 14:30 Invited T2F.3 • 14:30 Invited T2G.3 • 14:30 Invited T2H.3 • 14:30 Invited T2I.3 • 14:30 Invited Mode manipulation bas- Acoustic weak signal de- New concept of 3-D Exciton and Polaron- Nonequilibrium dynamics ed on few-mode fiber tection technology, Ping optical circuit using pho- Induced Reversible Dipole of GaAs semiconductor devices, Zuxing Zhang1, Lu1, Wanjin Zhang1 and tonic crystal polariza- Reorientation in Amor- nano-devices visualized Su Chen1, Yang Xu1, Bing Deming Liu1; 1Huazhong tion grating, Takayuki phous Organic Semicon- by infrared superreso- Sun1 and Hongdan Wan1; Univertsity of Science and Kawashima1; 1Photonic ductor Films, Qisheng lution nanoimaging, 1 1 1 1 1 Nanjing Univ. of Posts and Tele., Tech., China. Due to the overwhelm- Lattice, Inc., Japan Zhang , Chao Deng and Taiju Zhenghua An ; Fudan Univ., China. August 6 Tuesday, China. In this paper, several kinds of ming advantages compared with Tsuboi 1; 1Zhejiang Univ., China. Heat in optoelectronic devices is few-mode fiber (FMF) based devices traditional electronic sensors, fiber- There is enough free space in important for system performance in has been designed. Then an all-FMF optic acoustic sensors have arisen amorphous organic semiconductor modern communication technology. mode-locked ring laser with carbon enormous interest in multiple disci- films for molecular rotation and re- Heat production is associated with nanotubes was demonstrated with plines. we present the recent resear- arrangement, which is contradiction hot electron dynamics. We present the generation of high purity cylin- ch achievements of our group on of the common sense view that the here real-space nanothermometric drical vector beams (CVBs). weak acoustic signal detection tech- rotation of organic molecules in imaging of hot carrier dissipation

nology. organic thin films is restricted. dynamics in GaAs nano-devices.

T2E.4 • 15:00 Invited T2F.4 • 15:00 Invited T2G.4 • 15:00 Invited T2H.4 • 15:00 Invited T2I.4 • 15:00 Invited High frequency vibration Chaos distributed fiber Narrow-linewidth photo- Organic field-effect tran- Experimental study on sensors using fiber inter- sensor, Mingjiang Zhang1, nic microwave generation sistor structures as a truly quantum coherence and fereometer with spatial Jianzhong Zhang1, Lijun based on an optically inje- multi-functional platform: it's application, Guoyong mode beating, Nan Kuang Qiao1, Tao Wang 1 and cted semiconductor laser from light-emission to cell Xiang1; 1Uni. of Sci. & Tech. Chen1, Cheng-Kai Yao1, Yahui Wang1; 1Taiyuan Univ. subject to subharmonic interfacing, Michele of China, China. "Quantum Zhen Tian1, Liqiang Zhang1 and Chun of Tech., China. Chaotic sensing modulation, Tilian Yang1, Xiaodong Muccini1, Stefano Toffanin1 and coherence resource theory allows for Nien Liu2; 1Liaocheng Univ., China; technology is a particularly compete- Lin1, Zhengmao Wu1 and Guang- Valentina Benfenati2; 1CNR-ISMN, a quantitative understanding of the 2National Chung Hsing Univ., Taiwan. tive method that enables both high qiong Xia1; 1Southwest Univ., China. Italy; 2CNR-ISOF, Italy. Here we super-position principle, with applic- We demonstrate high frequency, up spatial resolution and large measu- We propose and experiment-tally discuss the concept of Organic ations reaching from quantum com- to 1MHz, fiber vibration sensors rement range in distributed fiber demonstrate a scheme to acquire a Light-Emitting Transistors (OLETs), puting to quantum biology. Here, I using fiber modal interferometer sensors. Recent progresses in high- narrow-linewidth photonic micro- highlight their specific electrical, will report our recent works on with spatial mode beating in wave- resolution long-reach chaos distri- wave based on an optically injected optoelectronic and photonic charac- quantum coherence." length. The interferometer has hy- buted fiber sensor are reported. semiconductor laser modulated by a teristics with respect to OLEDs, and perfine structure of successive foci in subharmonic microwave from an discuss their potential for practical space for molecular high frequency optoelectronic oscillation. applications in various fields. vibration.

15:30-16:00 Poster Session 1 & Coffee Break, 4F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 22

ICOCN 2019—Tuesday, 6 August

Poster Session 1（Best Poster Award, 15:30-16:00）

P1.1 P1.4 P1.7 P1.10 Study on DFB semiconductor laser based Highly-Birefringent Solid-Core Bragg Fiber Optical fiber temperature sensor based on A New Method For Measuring Laser Noise on sampled moiré grating integrated with with a High-Index-Contrast Cladding, Liang Mach-Zehnder interferometer coated with Based On Non-Equilibrium Fiber Optic grating reflector, Min Chen1, Shengping Liu1, Shang1 and Sujuan Feng1; 1Qufu Normal Univ., a film of PDMS, Jiaqi Gong1, Changyu Shen1, Interference System, Xuqiang Wu1, Dong Yuechun Shi1, Pan Dai1, Yong Zhao1 and China. We propose a highly-birefringent Yike Xiao1, Shuyi Liu1, Chong Zhang1 and Zeyi Guang1, Shili Li1, Qiang Ge1, Wei Liu1 and Xiangfei Chen1; 1Nanjing Univ., China. We solid-core Bragg fiber (SC-BF) with a high- Ding1; 1China Jiliang Univ., China. An optical Benli Yu1; 1Anhui Univ., China. A new method proposed a new kind of distributed feedback index-contrast cladding by symmetrically fiber temperature sensor by using a Mach- is proposed to measure the intensity noise (DFB) semi-conductor laser based on the introducing two air holes into the solid core. Zehner interferometer coated with a film of and phase noise of laser by using the natural sampled moiré grating (SMG) integrated with The birefringence properties and their in- PDMS was proposed. Temperature detection drift of the working point of the non- a grating reflector. An 8-channel DFB laser fluencing factors are numerically investigated. sensitivity of 0.1957nm/ ℃ obtained range equilibrium fiber optic interferometer. array based on the proposed structure was from 40℃ to 120℃. simulated.

P1.2 P1.5 P1.8 P1.11

Tuesday, 6 August Temperature-insensitive Fiber Twist Sensor Deep Learning assisted Visible Light Time Delay Signature Suppression of Chaos Distribution Acoustic sensor based flow Based on A Reflective Microfiber Coupler, Communication based Intelligent Transport in a Semiconductor Laser Subject to measurement using flow-induced vibra- Yudan Zhang1, Yue Li1, Chi Zhang1, Zuxing System, Qinghua Xiang1, Yingxiu Li1, Wenting Feedback from Parallel-Coupled Triple Ring tions, Li Tong Da 1, Ai Fan1, Hu Jie1, He Tao 1, Zhang1 and Hongdan Wan1; 1Nanjing Univ. of Huang1, Wenxuan Ye1 and Jianhua Shen1; Resonator, Yajun Wang1, Ning Jiang1, Lu Li Hao1, Sun Yue Zhen1, Qiao Wei1, Yan Zhi Posts and Telecommunications, China. A 1Nanjing Univ. of Posts and Telecommuni- Chen1, Anke Zhao1, Shiqin Liu1, Baochuan Li1, Jun1, Sun Qi Zhen1 and Liu De Ming1; temperature-insensitive fiber twist sensor cations, China. Visible Light Communication Guilan Li2 and Kun Qiu1; 1Univ. of Science and 1Huazhong Univ. of Science and Tech., China. based on a reflective microfiber coupler with based Intelligent Transport System has been Tech. of China, China; 2Wuhan Fisilink we demonstrated a non-invasive flowmeter a high sensitivity of 2621.08 (a. u)/(rad/m) is widely accepted as a promising solution. This Microelectronics Technologies Co., Ltd, China. based on optical fiber distribution acoustic demonstrated. Modal interference of the paper proposes a deep learning assisted VLC We numerically demonstrated a time delay sensor (DAS) system, in which the flow rate is sensor is analysed by Fast Fourier transform unmanned vehicles system which can signature suppressed chaos generation measured by detecting Flow-Induced algorithm. automatically capture and identify different scheme by using external-cavity semicon- Vibrations(FIV) noise. traffic signs. ductor laser subject to feedback from parallel- coupled triple ring resonator. Simultaneously, P1.3 P1.6 the effective bandwidth of chaos can be also P1.12 Self-adaptive Bandwidth Scheduling based An improvement on the CNN-based OAM extended obviously. Single Bandpass Microwave Pho-tonic Filter on Improved Random Early Detection for Demodulator via Conditional Generative based on Gain-switched Distributed-feed- NG-PON, Xing Xu1, Bo Liu2, Lijia Zhang1, Yaya Adversarial Networks, Zhe Li1, Qinghua Tian1, P1.9 back Laser, Huatao Zhu1, Yuandong Li1 and Mao2, Xiangyu Wu1, Jianxin Ren1, Lei Jiang2, Qi Zhang1, Kuo Zhang1, Feng Tian1, Chenda Quasi-Tamm Plasmon Polaritons in metal- Tao Pu 1; 1National Univ. of Defence Tech., Shun Han2 and Xiangjun Xin1; 1Nanjing Univ. Lu1, Leijing Yang1 and Xiangjun Xin1; 1Beijing dielectric-metal waveguide and its sensing China; 2Army Engineering Univ. of PLA, China. of Information Science and Tech., China; Univ. of Posts and Telecommunications, China. application, Zhijin Chen1, Yu Chen1, Yaxin A single bandpass microwave photonic filter 2Beijing Univ. of Posts and Telecommuni- An Orbital Angular Momentum (OAM) Zhang1, Jiong Xu1, Yunqing Lu1, Ji Xu1, based on a gain-switched distributed feed- cations, China. A self-adaptive network band- demodulation method based on Conditional Zhongcheng Liang1 and Jin Wang1; 1Nanjing back laser is proposed and experimentally width scheduling approach based on Generative Adversarial Networks(CGAN) is Univ. of Posts and Telecommunications, China. demonstrated. Self-phase modul-ation effect improved random early detection (RED) is proposed to improve the accuracy of Convo- A novel metal-dielectricmetal waveguide is explored in the optical domain to enhance proposed to significantly reduce the average lutional Neural Networks (CNN) based structure is designed, where a novel type of the performance of the proposed MPF. packet latency and make the best of demodulator. Tamm states called quasi-Tamm plasmon bandwidth resources to accomplish high polaritons emerge and exhibit an efficient network utilization. local field enhancement.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 23

ICOCN 2019—Tuesday, 6 August

Poster Session 1（Best Poster Award Session）15:30-16:00

P1.13 P1.16 P1.19 P1.22 Low Noise Phi-OTDR Based on Frequency- High-power linearly-polarized supercon- Aminopeptidase N (CD13) Modified Gold Improved performance of fiber-optic Jitter-Free Heterodyne Demodulation tinuum generation from few-mode polari- Films for the Affinity Quantitative hydrogen sensor based on Mg-Ti alloys Scheme, Zewu Ju1, Yang Lu 1 and Zhou Meng1; zation-maintaining photonic crystal fiber, Detection of CNGRC-coupled Derivative, composite thin films, Zihui Yuan1, Yaqiang 1National Univ. of Defense Tech., China. A Yue Tao1 and Sheng-Ping Chen1; 1National Qing Huang1, Yong Wang 1, Wenjie Zhu1, Ma1, Yuhuan Qin1, Jixiang Dai1 and Minghong low-noise phi-OTDR based on the frequency- Univ. of Defense Tech., China. A high-power Shibin Ai2, Elfed Lewis3 and Minghong Yang1; Yang1; 1Wuhan Univ. of Tech., China. A novel 1 2 jitter-free heterodyne-modulation scheme is of 77.3 W all-fiber linearly-polarized super- Wuhan Univ. of Tech., China; Wuhan Univ., method was proposed to improve the August 6 Tuesday, proposed. The SNR of 57.78 dB and the noise continuum laser source ranging from 480 to China; 3Univ. of Limerick, Ireland. This article sensitivity of Mg-Ti based fiber optic level of -65.4 dB (re 1rad/ sqrt(Hz)) at 1 kHz are 2400 nm generated from multimode proposes a fiber optic SPR sensor system for hydrogen sensor by sputtering Mg-Ti-Ni achieved for phase retrieve of Rayleigh-light. polarization-maintaining photonic crystal quantitative detection of APN-targeting composite films on the end face of the fiber fiber is demonstrated. ligand CNGRC-coupled derivative, and as hydrogen sensitive layer. obtained a lower limit of detection determined to be 0.22 fg/ml.

P1.14 P1.17 P1.20 P1.23 Fast high-resolution spectral sensing with a Design and fabrication of high-Q silicon Compact silicon multicast switch for pCDC Quantitative Analysis of Materials Based on single frequency comb, Xinyi Ren1, Ming Yan1 micro-resonators, Qiansheng Wang1 and ROADM based on thermo-optic Mach- Terahertz Spectroscopy, Yuan Gao1, Yue and Heping Zeng1; 1East China Normal Univ., Jianji Dong1; 1Huazhong Univ. of Science and Zehnder interferometers, Shanglin Yang1, Zhou1 and Kun Xu1; 1Beijing Univ. of Posts and China. Transmission spectra of a phase-shift Tech., China. We design and fabricate two Ting Zhou1, Hao Jia1 and Lin Yang1; 1State Key Telecommunications, China. Combining the fiber Bragg grating and H13CN gas at comb- different micro-resonators in a silicon-on- Laboratory of Integrated Optoelectronics, terahertz time-domain spectroscopy tech- line-defined resolution of 54.5 MHz are insulator platform. Two device architectures Inst. of Semiconductors, Chinese Academy of nique with the gradient-enhanced decision measured within 2 us using heterodyne are non-concentric microring resonator and Sciences, China. We propose an optimized tree algorithm, the α-lactose content in the detection of a broadband comb and a microdisk resonator with ridge waveguide. multicast switch for colorless, directionless ruthenium mixture was quantitatively continuous wave laser. The highest Q-factor can be achieved at and partially contentionless ROADM and analyzed to obtain higher accuracy and better 8×10^4 and 1.9×10^5, respectively. experimentally demonstrate a 2×8 silicon fitting effect. multicast switch, which consists of six 3-dB P1.18 multimode interference splitters and four P1.24 P1.15 High Power-Efficient 4D Trellis Coded Mach-Zehnder 2×2 optical switches. Deep Transfer Learning Based Multi- SSB Modulation With Optimum Optical Modulation PS-8PSK for Long-Haul Optical impairment Diagnosis for PAM-4 Optical Carrier to Sideband Ratio Based on Polari- System, Zongyu Zhang1, Qi Zhang1, Xiangjun P1.21 Communication Systems, Yilan Xu1, Danshi zation modulated Optical Signal Injected Xin1, Qinghua Tian1, Feng Tian1, Jinlong Single Core-offset Alignment for SFS Wang1, Min Zhang1, Xian Zhou2, Zhiguo Into DFB Laser, Li Yuandong1, Zhu Huatao2, Zhang2 and Ming Lin3; 1Beijing Univ. of Posts Combs with High Extinction Radio, Jingjing Zhang1, Jin Li1, Yongming Zhu3, Peng Xie3 and Zheng Jilin1 and Pu Tao 1; 1Army Engineering and Telecommunications, China; 2Henan Univ., Zheng1, Shaoshuo Ma1, Zuliang Ruan1, Ji Nijiati Paerhati3; 1Beijing Univ. of Posts and Univ. of PLA, China; 2National Univ. of China; 3Guangdong Univ. of Tech., China. A Wang1, Jing Li1, Tigang Ning1 and Li Pei1; Telecommunications, China; 2Univ. of science Defence Tech., China. SSB modulation signal polarization-switched QPSK (PS-QPSK) based 1Beijing Jiaotong Univ., China. Alignment has and technology Beijing, China; 3State Grid with optimum carrier to sideband ratio (OCSR) four-dimensional trellis coded modulation a significant influence on the characteristics of Changji Electric Power Supply Company, of 0 dB and the amplitude difference of 44.87 polarization-switched 8PSK (4DTCM-PS-8PSK) SFS fiber interferometer. The SFS fiber comb China. An intelligent multi-impairment dB based on polarization modulated optical format with low decoding complexity and using single core-offset alignment is diagnosis technique based on eye-diagrams signal injected into DFB laser is proposed and high energy efficiency is proposed for the first presented. It provide good extinction ratio, analysis using deep transfer learning is experimentally demonstrated. time, which improves the bit-error-rate (BER) optimization fabrication, and good proposed. Six device imperfection-induced performance of PS-QPSK. repeatability. impairments are diagnosed and the whole accuracy of diagnostic results reaches 99.88%.

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ICOCN 2019—Tuesday, 6 August

Poster Session 1（Best Poster Award Session）15:30-16:00

P1.25 P1.29 P1.32 P1.35 Femtosecnod Laser Ablated Fiber SERS- An all-optical sampling system utilizing QD- All-Fiber Ultrasonic Sensor Based on In-fiber Surface Plasmon Resonance Tem- DNA Probe and Applications in Deafness SOA-based NOLM, Hui Xu1, Yongjun Wang1, Ultrathin Silica Reflective Diaphragm, perature Sensor Based on PDMS Infiltrated Gene Detection, Youfu Geng1, Yiwen Xu1 and Xinyu Liu1, Xiaoyuan Niu1, Yucheng Pan1 and Mengzhe Xiao1, Senhui Yin1, Shiyi Xie1, Cheng Hollow Core Fiber, Siyu E1, Ya-Nan Zhang1, Xiaoling Tan1; 1Shenzhen Univ., China. A fiber Jun Li1; 1BUPT, China. We proposed an all- Zhou1, Jiajun Tian1 and Yong Yao 1; 1Harbin Inst. Xuegang Li1, Yu Zheng2, Perry Ping Shum2 and SERS-DNA probe was fabricated with optical sampling system. The sampling of Tech., Shenzhen, China. We report a high Yong Zhao1; 1Northeastern Univ., China; femtosecond laser ablation and laser-induced module consists of a Nonlinear Optical Loop sensitivity ultrasonic/acoustic sensor based on 2Nanyang Technological Univ., Singapore. An silver particle deposition. Low concentration Mirror (NOLM) utilizing QD-SOA as the all-fiber Fabry-Perot interferometer. The pro- in-fiber surface plasmon resonance temper- of deafness DNA down to 10^-10 M was nonlinear element. posed sensor is made by splicing a single ature sensor based on Poly-dimethylsiloxane successfully detected with such a fiber SERS- mode fiber onto a fiber tube with an ultra-thin infiltrated hollow core fiber was proposed and DNA probe. silica diaphragm. experimentally demonstrated.

P1.26 P1.30 P1.33 P1.36 Hybrid Probabilistic-Geometric Shaping in Irreversible Photobleaching of BAC-Si in Optical Spectrum Measurement and Monitoring the deflection of bridge span 1 1 Tuesday, 6 August DP-NFDM Systems, Ruihua Yu , Zibo Zheng , Bi/Er Co-Doped Optical Fiber under 830 Analysis for Flexible WDM System Using with a spotreduced fiber optics source, Xulun Zhang1, Shucheng Du2, Lixia Xi1 and nm Pumping, Haijiao Xu1, Binbin Yan1, Faster R-CNN-based Object Detection, Mengnan Lu1 and Xiaopeng Dong1; 1Xiamen Xiaoguang Zhang1; 1BUPT, China; 2Beijing Chaofan Zhao1, Yanhua Luo2, Pengfei Lu1, Hongwei Lv1, Danshi Wang1, Min Zhang1, Univ., China. A novel method to increase the Normal Univ., China. We introduce con- Kuiru Wang1, Chongxiu Yu1, Jinhui Yuan1, Zhiguo Zhang1, Jin Li1, Luming Li2, Jiangxing measurement range and accuracy of bridge stellation shaping into a nonlinear frequency Xinzhu Sang1, Liwei Yang3 and Gang-Ding Chen2 and Xing Liu2; 1BUPT, China; deflection based on the laser datum scheme division multiplexing system for performance Peng2; 1BUPT, China; 2The Univ. of New South 2Information and Communications Branch, with reduced spot size of a fiber source is improvement. The numerical results show that Wales, Australia; 3China agricultural Univ., Jiangxi Electric Power Company, China. An proposed. probabilistic and geometric shaped QAM China. The pump-induced bleaching effects optical spectrum measurement and analysis lead to higher mutual information and further upon lumenescence of Bi/Er co-doped method using faster R-CNN-based object transmission distance. optical fiber (BEDF) have been investigated. detection technique is proposed. This The bismuth related luminescence is method can simultaneously analyze OSNR, P1.27 significantly bleached, especially BAC-Si, and bandwidth, and center wavelength of FWDM Deep Learning-Based Massive MIMO CSI can hardly recover to the initial level. system. The average accuracy reaches 98.6%. Feedback, Jialing Li1 and Qi Zhang1; 1BUPT, China. Massive multi-input and multi-output P1.34 P1.37 tech-nology is a key technology for future 5G Physical Encryption Based on Chaotic Novel Magnetometer Based on Magnetic wireless communication. P1.31 Sequence-assisted Pseudo QAM Systems, Fluid Coated Whispering Gallery Mode 1 1 1 All-fiber Mode Acousto-optic Mo-dulator in Yanping Sha , Mingyi Gao , Lei Wang , Resonator, Ji Xia1, Fuyin Wang2, Shuidong 2 2 Gas Absorption Mea-surement, Liu Hong Zhaoyun Li , Qingsong Luo and Gangxiang Xiong2, Guangya Zhou1, Yongming Hu2 and 1 1 1 1 1 2 P1.28 gang , Zhang Weijian , Meng Linghao , Yang Shen ; Soochow Univ., China; the 34th Qiong Yao2; 1National Univ. of Singapore, 1 1 1 Clock Recovery Based on Adaptive Phase Ao and Zeng Xianglong ; Shanghai Univ., Reseach Inst. of China Electronic Tech. Group Singapore; 2National Univ. of Defense Tech., Error Detection for Coherent Optical Trans- China. This paper mainly studies the Corporation(CETC34), China. We proposed a China. We presented an optical concept mission Systems, Xiaoyuan Niu1, Yongjun application of tunable laser and acoustic physical encryption scheme based on chaotic based on magnetic fluid (MF)-coated micro- Wang1, Xinyu Liu1, Hui Xu1, Yucheng Pan1, Jun grating in TDLAS gas sensoring. sequence-assisted pseudo quadrature amp- sphere for magnetic field detection. Li1 and Xiangjun Xin1; 1BUPT, China. The loop litude modulation (QAM) systems. We simu- calculates the current error by the error of the lated the proposed scheme and verified its previous moment. The algorithm reduces the feasibility by plotting BER curves and phase error jitter. constellation diagrams.

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ICOCN 2019—Tuesday, 6 August

Poster Session 1（Best Poster Award Session）15:30-16:00

P1.38 P1.41 P1.44 P1.47 Optically Adjustable Random Laser with Integrated Biosensor Based on Double- Bidirectional mode-locked fiber laser emit- Generation of Oam and Comparative Multi-phase Shifted Bragg Grating in Er/Yb layer Dielectric Loaded Graphene Plasm- ting scalar and vector noise-like pulses, Ran Analysis of Generation Methods Related to Co-doped Fiber, Ruifu Huang1, Xinyong onic Ridge Waveguide with Higher-Order Xia1, 2, Yang Xiang1, 2, Yiyang Luo1, 2, Bowen Polarization Dependency, Mariano Mahuvi Dong2 and Chengrong Shen1; 1CJLU, China; Modes, Tao Ma1, Heng Liu1, Jinhui Yuan2, Liu1, Yu Zheng2, Perry Ping Shum2, Qizhen Christian Mahissi1, Xinglin Tong1, Cui Zhang1, 2Guangdong Univ. of Tech., China. An Fang Wang1, Xu Wang1, Jue Wang1, Ruifang Sun1 and Xiahui Tang1; 1Huazhong Univ. of Sci. Chengwei Deng1, Michel Dossou2 and 1 2 1 2 1 1 optically controllable tunable Er/Yb-codoped Wang and Chongxiu Yu ; Henan Normal and Tech., China; Nanyang Tech. Univ., Chunjiao Jin ; Wuhan Univ. of Tech., China; August 6 Tuesday, random fiber laser is demon-strated. Univ., China; 2BUPT, China. We propose a Singapore. We report on a bidirectional non- 2École Polytechnique d'Abomey-Calavi, Stabilizing and control of the laser outputs is double-layer dielectric loaded graphene linear polarization rotation based mode- Université, Benin. We have simulated OAM achieved by a lateral pump of 980nm laser. plasmonic ridge waveguide (DLGPRW) using locked fiber laser emitting scalar and vector modes, made a comparative analysis followed higher-order modes for biochemical sensing. noise-like pulses in opposite directions. by a rigorous critique of the methods of The simulation results show that the shaping the orbital angular momentum propagation length and the sensing beams related to polarization dependency. sensitivities are greatly improved. P1.45

Dispersion-managed soliton molecules in an P1.48 P1.39 P1.42 all-fiber mode-locked fiber laser with near Fiber-optic MZI activity monitoring based Cascaded Fabry–Pérot Interferometers A High-selectivity Photonic Lantern zero dispersion, Yusong Liu1, Bowen Liu1, on RLS algorithm, Jiayu Wang1, Wei Xu2, Bo with Vernier effect for Gas Pressure Mea- Demultiplexer for Weakly-coupled Mode Yang Xiang1, Tao Liu1, Yiyang Luo1, 2, Zhijun Dong2, Changyuan Yu3 and Shuying Han4; surement, Hongfeng Lin1, Yanyan Xu1, Farhan Group Demul-tiplexing over MMF, Jian Cui1, Yan 1, Perry Ping Shum2, Qizhen Sun1 and 1National Univ. of Singapore Research Inst., Mumtaz1, Yutang Dai1 and Ai Zhou1; 1Wuhan Yuyang Gao1, Chunyan Du1, Yu Yang 1, Dawei Xiahui Tang1; 1Huazhong Univ. of Science and China; 2Xi'an Inst. of Optics and Precision Univ. of Tech., China. A sensitivity enhanced Ge1, Yongqi He1, Zhengbin Li1, Zhangyuan Tech., China; 2Nanyang Technological Univ., Mechanics, Chinese Academy of Sciences, gas pressure sensor with Vernier effect is Chen1 and Juhao Li1; 1Peking Univ., China. We Singapore. We report the formation of China; 3The Hong Kong Polytechnic Univ., proposed. The sensor is a cascade con- propose a high-selectivity photonic lantern dispersion-managed solitons in an all-fiber China; 4Soochow Univ., China. A non-invasive figuration which includes two Fabry-Pérot demultiplexer for weakly-coupled mode- laser passively mode-locked by a 45° tilted activity monitoring using Mach-Zehnder interferometers (FPIs) with different free group demultiplexing over MMF. The fiber grating. Moreover, the transient soliton interferometer (MZI) is presented and spectrum range (FSR). simulated mode-group demultiplexer shows dynamics is researched by dispersion Fourier recursive least square (RLS) algorithm is a mode-group selectivity higher than 28.2 dB transformation technique. performed to classify presence and absence for all 3 mode groups over the C-band. activity states with accuracy higher than 98.5% within 1 second. P1.40 P1.43 P1.46 Coreal imaging with extended imaging Ultrasensitive Microfiber Refractive Index Crosstalk-Aware Routing, Core, and P1.49 range using dual spectrometer high reso- Sensor Based on Mach-Zehnder Inter- Spectrum Assignment with Core Switching Highly sensitive RI and temperature sensor 1 1 lution SD-OCT, Lulu Wang1 and Linbo Liu1; ference of Core Offset Structure, Yuncheng in SDM-EONs, Yu Lei , Qi Chen , Yunfei based on cascaded LPGs at near the phase- 1 1 1 1Nanyang Technological Univ., Singapore. A Liao1, Zhiqiang Mao1, Bin Liu1, Ling Chen1, Jiang , Qianwu Zhang and Bowen Chen ; matching turning point, Wei Zhou1, Meng 1 dual spectrometer SD-OCT system with large Juan Liu1, Shengpeng Wan1, Xing Dao He1 Soochow Univ., Suzhou, China. We propose Zou1, Yarien Moreno1, 2, Yuezhen Sun1, Wei imaging area, high resolution was demon- and Qiang Wu2; 1Nanchang Hangkong Univ., a crosstalk-aware RCSA algorithm with core Zhang1, Zhijun Yan1, Qizhen Sun1 and Deming strated for pig anterior eye imaging ex vivo. China; 2Northumbria Univ., Ireland. A micro- switching to improve spectrum efficiency in Liu1; 1Huazhong Univ. of Science and Tech., Spectra from the two spectrometers are com- fiber based on core offset MZI was proposed SDM-EONs with MCF. Simulation results China; 2Univ. of Panama. We demonstrated a bined to achieve a 3.4 mm maximum depth for RI sensing. The sensor exhibits an demonstrate our proposed algorithm not only highly sensitivity refractive index (RI) and range. extremely high sensitivity of 16485 nm/RIU improves spectrum efficiency but also temperature sensor based on cascaded long- within the RI range between 1.410 and 1.413. reduces average crosstalk. period gratings operating at near the phase- matching turning point (PMTP).

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 26

ICOCN 2019—Tuesday, 6 August

Poster Session 1（Best Poster Award Session）15:30-16:00

P1.50 P1.53 P1.57 P1.60 Study of NLOS effect on Indoor Visible The high-temperature stability of fiber A 375Mb/s real-time internet of vehicles Soliton Self-Frequency Shift in Mode Locked Light Positioning in Different Room Sizes, Bragg gratings fabricated by 193 nm system based on automotive headlight Fiber Lasers, Mengmeng Han1, Yueqing Du1, Wusheng Fang1, Jian Chen1, Xiaodi You2 and excimer laser, Xiaolong Si1, Yunqi Liu1, utilizing OFDM-64QAM modulation format, Peiyun Cheng1 and Xuewen Shu1; 1HUST, Changyuan Yu2; 1Nanjing Univ. of Posts and Linfang Wu1, Chen Jiang1 and Chengbo Mou1; Chaofan Wang1, Yuanfan Liu1, Weiping Li1, China. We demonstrate the soliton evolution Telecommunications, China; 2The Hong Kong 1Shangahi Univ., China. We have demon- Fumin Wang1 and Nan Chi1; 1Fudan Univ., in a mode locked fiber laser with soliton self- Polytechnic Univ., Hong Kong. When the strated the FBG fabricated on different fibres China. We propose a 375Mb/ sreal-time IoV frequency shift by numerical simulation, and room size increases, positioning accuracy is by using 193 nm excimer laser. The relation- system based on an automotive headlight. analyze the effects of pump strength, length becoming higher. The effect of LED half ship between the wavelength shift of FBG and of dispersion shift fiber, and modulation. power angle and receiver field-of-view annealing time has been obtained. 6 August

changes on maximum positioning error. P1.54 Humidity and temperature sensor based on pokal-taper and lateral-offset structure, 1 1 Tuesday, P1.51 Yimei Zhong , Zhengrong Tong , Weihua P1.58 P1.61 Sensing Characteristics of Helical Long- Zhang1, Juan Qin1, Wenlin Gao1 and Xue Probabilistic shaping for direct detection Mode Transition in Conventional Step- Period Grating Inscribed in Graded Index Chen1; 1Tianjin Univ. of Tech., China. An transmission with kramers-Kronig receiver, Index Optical Fibers, Xiaokang Lian1, Gerald Few Mode Fiber, Zuyao Liu1, Yunqi Liu1, Xinyi interferometric optical fiber sensor based on Yichen Fan1, Xianfeng Tang1 and Xiaoguang Farrell1, Qiang Wu2, Wei Han1, Fangfang Wei1 Zhao1, Chengbo Mou1 and Songnian Fu2; pokal-taper structure and lateral-offset struc- Zhang1; 1BUPT, China. We introduce probab- and Yuliya Semenova1; 1Technological Univ., 1Shanghai Univ., China; 2Huazhong Univ. of ture is proposed. ilistic shaping into direct detection system Ireland; 2Northumbria Univ., United Kingdom. Science and Tech., China. Helical long-period with Kramers-Kronig receiver. There are The cladding modes distributions and the grating fabricated in graded-index few-mode P1.55 0.53/0.86/1.12dB OSNR improvements by transitions between the core and cladding fiber was experimentally demonstrated. The Tunable Microwave Photonic Filter with transmitting PS-16/64/256QAM signal com- modes in a three-layer step-index optical fiber high sensitivities corresponding to torque, Negative and Complex Coefficients, Zheng pared with the uniform 16/64/256QAM signal. model are analyzed. curvature, temperature and surrounding rong Tong1, Xue Chen1, Weihua Zhang1, Juan refractive index are up to 0.293 nm/rad/m, Qin1 and Yimei Zhong1; 1Tianjin Univ. of Tech., 2.486nm/m-1, 0.095 nm/℃ and 1242 nm/RIU, China. The 10 taps with 0.2nm are used as respectively. input optical source. The center frequency is continuously tuned from 0 to 34.97 GHz and the shape remains unchanged. P1.52 P1.59 P1.62 Wavelength Switchable Mode-Locked Fiber P1.56 Ambient Light Suppressed Free Space The application of PCA on Փ-OTDR sensing Laser with Tapered Two-Mode Fiber, Liqin Location-Recommendation-based Virtual Optical Communication System based on system for vibration detection, Atubga Xie1, Fang Fang1, Bing Sun1 and Zuxing Network Embedding Improved by Tra- FA D O F, Zhen Yang1, Xiaolei Guan2, Bin Luo2, David Atia Ibrahim1, Shengtao Lin1, Ji Xiong1, Zhang1; 1NUPT, China. An Er-doped mode- jectory Covering in FiWi Networks, Xiaoxue Longfei Yin1, Guanjun Gao1 and Jinbiao Jialin Jiang1, Yun Fu1 and Zinan Wang1; 1USTC, 1 1 1 locked fiber laser with a tapered two-mode Gong and Lei Guo ; CQUPT, China. The Chen2; 1BUPT, China; 2Peking Univ., China. A China. It presents Principal Component fiber for wavelength selection has been de- Virtual Networks coming from different user wireless optical communication system based Analysis technique in denoising phase sen- monstrated. Depending on the free spectral groups can be embedded into the same on FADOF is proposed to supress the am- sitive optical time domain reflectometry (Φ- range of TTMF filter, the central wavelengths substrate Data Center, hence decreasing the bient light. The Q factor of 20Mbit/s OFDM- OTDR) sensing data for vibration detection. of the mode-locking operation can be energy consumption of establishing inter-DC QPSK signal can be improved 9dB after switched. lightpaths. filtering the ambient light by using the FADOF.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 27

ICOCN 2019—Tuesday, 6 August

Poster Session 1（Best Poster Award Session）15:30-16:00

P1.63 P1.66 P1.69 P1.72 A SDN-enabled Integrated Space-Ground Multi-points ultrasound detection with Unraveling the Moisture-induced Decom- A sensitivity enhanced Sagnac temperature Information Network Simulation Platform, multiple FBGs and a pseudo-synchronous position Mechanism of Red-Emitting Pero- sensor utilizing high order modes Xiang Guo1, Bingli Guo1, Kexin Li1, Chao Fan2, method, Yunqing Guan1 and Xiaopeng Dong1; vskite CsPbBrI2 Nanocrystals and Enhancing interference, Shasha Fang1, Xuqiang Wu1, 2 1 1 1 1 1 1 1 Hongzhen Yang and Shanguo Huang ; BUPT, Xiamen Univ., China. A novel method to their Stability through Copper ( Ⅱ ) Sub- Gang Zhang , Shili Li , Wei Liu , Cheng Zuo August 6 Tuesday, China; 2Information & Telecommunication obtain the response of multi-FBGs to the stitution, Jibin Zhang1 and Guoli Tu1; 1HUST, and Benli Yu1; 1Anhui Univ., China. A Branch, State Grid Zhejiang Electric Power Co. burst ultrasound propagating on the surface China. The moistureinduced decomposetion temperature sensor is proposed by splicing a Ltd., China. This paper proposes an SDN- of metal plate pesudo-synchronously is mechanism of CsPbBrI2 NCs mechanism was section of thin polarization-maintaining fiber enabled integrated space-ground network proposed in this paper. given. And highly stable and luminescent red- in a Sagnac loop. The temperature sensitivity simulation platform. It could adapt a dynamic emitting perovskite CsPbBrI2 NCs were is enhanced by higher- order modes satellite network topology from the output of achieved through copper (Ⅱ) substitution and interference and reaches up to 1.7 nm/℃. satellite simulation tool, employ customized halide-rich passivation strategy. routing algorithm to establish end-to-end communi-cation path dynamically. P1.67 High sensitivity biosensor for Staphy- P1.64 lococcus Aureus detection based on P1.70 Effect of tapered fiber structure on the PbS tapered a singlemode-no core-singlemode High-efficiency soluble thermally activated Nanomaterials optical fiber amplifier fiber structure, Ling Chen1, Bin Liu1, delayed fluorescent OLED with multilayer excited by evanescent wave, Caiyun Su1, Yuncheng Liao1, Juan Liu1, Yuankui Leng1, hole transport layers, Yuxue Feng1, Hong Yanhua Dong1, Xiangping Pan1, Jianxiang Shengpeng Wan1, Xingdao He1, Jinhui Yuan2, Zhao1, Zugang Liu1 and Mei Yang1; 1China Wen1, Yangyang Zhao1, Yana Shang1, Fufei Nicole Pamme3 and Qiang Wu4; 1Nanchang Jiliang Univ., China. Solution processed Pang1 and Tingyun Wang1; 1Shanghai Univ., Hangkong Univ., China; 2Beijing Univ. of Posts organic light emitting devices (OLEDs) . PbS nanomaterials fiber amplifier was ; 3 incurporating a soluble thermally activated China and Telecommunications, China Univ. of Hull, fabricated by coating PbS nanomaterials onto United Kingdom; 4Northumbria Univ., Ireland. delayed fluorescent (TADF) emitter were tapered fiber. PbS is deposited by atomic The fibre sensor was functionalised by fabricated with three HTL, PVK, TFB, and layer deposition technique. The influence to depositing the pig IgG antibodies onto TFB/PVK as the multilayer HTL. optical properties is discussed when changing tapered biosensor surface. the structure of tapered fiber.

P1.65 P1.68 P1.71 High-linearity silicon modulator based on a Design and simulation of etched physical A Fast Point Cloud Segmentation Algorithm reconfigurable microring-assisted Mach- structure fiber Bragg grating for fabri- Based on Region Growth, Xiaofeng Ma1, Wei Zehnder interferometer, Shuhuang Chen1, cating high temperature sensors, Huaxian Luo1, Mingquan Chen1, Jiahui Li1, Xin Yan 2, Xia 1 1 1 Gangqiang Zhou , Linjie Zhou , Liangjun Lu , Duan1, Yu Sun1, Xu Jiang1, Xiliang Du1 and Zhang2 and Wei Wei3; 1Guangzhou Univ., Jianping Chen1; 1Shanghai Jiao Tong Univ., Guohui Lyu1; 1Heilongjiang Univ., China. Side- China; 2Beijing Univ., China; 3The Hong Kong China. We report a high-linearity silicon mo- polishing single-mode fiber (SP-SMF) to the Polytechnic Univ., China. We proposed a fast dulator using ring-assisted MZ Interferometer. D-fiber and etch the physical structure region growing algorithm through neighbor- The best spurious-free dynamic ran-ge of the Grating into the flat surface. The basic hood search, Euclidean clustering and region third-order inter-modulation distor-tion is 109 parameters of the side-polished fiber etched growth. The segmentation experiment of dB•Hz2/3. The linearity is compara-ble to the grating structure are determined by simula- indoor point cloud data shows that segmen- commercial lithium niobate modulators. tions of COMSOL and Rsoft. tation accuracy and efficiency were improved by the proposed algorithm.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 28

ICOCN 2019—Tuesday, 6 August

Room 2, Track 3 Room 3, YSA Room 5, Special 2 Room 6, Track 7

16:00-18:00 16:00-18:00 16:00-18:00 16:00-18:00 T3A • Optical networks I T3B • Young Scientist Award II T3C • Machine learning I T3D • Ultrafast & nonlinear optics II Presider: Juhao Li, Peking Univ., China Presider: Dongning Wang, China Jiliang Univ., China Presider: Lilin Yi, Shanghai Jiao Tong Presider: Shixun Dai, Ningbo Univ., China Univ., China

T3A.1 • 16:00 Invited T3B.1 • 16:00 T3C.1 • 16:00 Invited T3D.1 • 16:00 Invited Naïve Bayes Classifier-Assisted Atomic Layered 2d/3d Heterostructure for Sensitive Machine learning based Nonlinear Light-Matter Intera- Least Loaded Routing for Photodetection, Peng Wang1 and Weida Hu1; 1Shanghai Inst. signal processing for high ction Two-Dimensional Excito- Circuit-Switched Networks, of Tech. Physics, CAS, China. Vertical 2D-GaSe/3D-GaSb speed visible light communi- nics, Wei Ji1; 1National Univ. Gangxiang Shen1; 1Soochow Univ., heterostructure was fabricated by epitaxial growth and the cations, Nan Chi1; 1Fudan Univ., of Singapore. We present our China. We develop a new meth- device exhibits good photo-sensitivity and fast response China. We summarize the 2D excitonic models to quanti- odology, by incorporating a supervised speed of microsecond, which reveals a promising candidate latest research progresses applying tatively predict the giant optical non- naïve Bayes (NB) classifier, to assist Least for inter-generational development of photodetector. machine learning in visible light linearity in terms of 2PA or 3PA for Loaded (LL) routing and to further improve communication systems, including K- monolayer TMDCs or layered hybrid Tuesday, 6 August its performance that has remained the best T3B.2 • 16:15 means clustering, DBS, support vector perovskites. We find that our models are for the past several decades. Raman dissipative-soliton generation with a nonlinear machine and DNN. in agreement with the measurements, optical loop mirror in a polarization maintaining fiber cavity, within one order of magnitude. Jiaqi Zhou1, Weiwei Pan1 and Yan Feng1; 1Shanghai Inst. of Opt. and Fine Mechanics, CAS, China. We report a Raman dissipative soliton generated in a mode-locked fiber laser with a nonlinear optical loop mirror. It provides a method to obtain linearly polarized ultrafast laser at flexible wavelengths.

T3A.2 • 16:30 Invited T3B.3 • 16:30 T3C.2 • 16:30 Invited T3D.2 • 16:30 Invited Network Nervous System: Wh- Investigation of the Underwater Quantum Key Distribu- Machine Learning assisted Generation of multi- 1 1 en Multilayer Telemetry Meets tion, Wendong Li ; Ocean Univ. of China. We demonstrate intelligent optical fiber wavelength light pulses by AI-assisted Service Provisioning, the polarization preservation properties of the water channel transmissions, Jing Zhang1, femtosecond Bessel laser Jiawei Kong1, Bin Niu1, Shaofei in optical transmission and analyze the reason for the Yuzhong Feng1, Pingping Lei1 beam in silica glass, Weiwei Tang1, Yingcong Li1, Hong-qiang polarization preservation. A proof-of-principle experiment for and Kun Qiu2; 1USTC, China; Liu1; 1Nankai Univ., China Fang1, Wei Lu1 and Zuqing Zhu1; 1Univ. of the BB84 protocol QKD over a 2.3m water channel show that 2UESTC, China. We propose to use Science and Tech. of China, China. We QKD can be performed with a low quantum bit error rate, less machine learning assisted channel equa- present a network nervous system that than 3.5%, with different attenuation coefficients. lization in optical fiber communications. leverages hybrid centralized/distributed It is beneficial to polarization demulti- processing to achieve automatic and T3B.4 • 16:45 plexing and decision. effective network control and management Robust all polarization‑maintaining femtosecond fiber laser 1 1 for realizing artificial intelligence (AI) with various phase bias, Renlai Zhou , Xuanyi Liu , Guanyu 2 3 1 1 2 assisted service provisioning in IP over Liu , H. Y. Fu and Qian Li ; Peking Univ., China; Tsinghua elastic optical networks (IPoEONs). Univ., China. We demonstrate a novel architecture all polarization-maintaining mode-locked femtosecond fiber laser. The achieved laser directly delivers 926 fs, 0.56 nJ pulses at the repetition rate of 88.3 MHz.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 29

ICOCN 2019—Tuesday, 6 August

Room 7, Special 6 Room 8, Track 6 Room 10, Track 4 Room 11, Special 1 Room 12, Track 10

16:00-18:00 16:00-18:00 16:00-18:00 16:00-18:00 16:00-18:00 T3E • Random Fiber Lasers I T3F • Optical measurement II T3G • Optoelectronics I T3H • Organic & nano T3I • Quantum photonics II Presider: Yunjiang Rao, UESTC, Presider: Yunqi Liu, Shanghai Presider: Yaocheng Shi, Zhejiang optoelectronics II Presider: Wuming Liu, Inst. of China Univ., China Presider: Zheng Li, National Inst. Phy., CAS, China Univ., China of Metrology, China

T3E.1 • 16:00 Keynote T3F.1 • 16:00 Invited T3G.1 • 16:00 Invited T3H.1 • 16:00 Invited T3I.1 • 16:00 Invited Random Fiber Lasers Non-invasive smart heal- Hybrid-Cavity Semicon- All-inorganic perovskite Photonic quantum chip August 6 Tuesday, (RFL): From Optical Amp- th monitoring system ductor Lasers for Single quantum dots for flexible and analog quantum lifiers to Complex Photo- based on multi-core fiber, Mode Operation and high-definition QLED Dis- computing, Xianmin Jin1; nics, Anderson S.L. Changyuan Yu1; 1The Optical Signal plays, Haibo Zeng1; 1Shanghai Jiao Tong Univ., Gomes1; 1UFPE, Brazil. RFL Hong Kong Poly-technic Processing, Yongzhen 1Nanjing Univ. of Sci. and China. are cavityless fiber lasers, and the Univ., China. Multi-core fiber has Huang1, Youzeng Hao1, Fu-Li Wang1, Tech., China. We report the research feedback is provided by a scattering applications for both commu- JiaChen Liu1, Yue-De Yang1 and progresses on all-inorganic perov- medium. I will review their basic nication and sensing. Based on the JinLong Xiao1; 1Inst. of skite CsPbX3 QLEDs, including properties and recent applications in interference among cores in seven- Semiconductors, CAS, China. Mode room-temperature synthesis, the optical amplifiers, distributed sens- core fiber, an optical interferometric coupling between a microcavity and improvement of QLEDs via surface ors, observation of spin glass and system is demonstrated to monitor a Fabre-Perot results in mode Q control, and the great improvement turbulence behavior. the vital signs and activities of factor enhancement and stable of their stability through Mn doping patients on bed. single mode hybrid-cavity lasers. and control on space distribution. Furthermore, optical bista-bility laser is realized as the unbiased microcavity working as a saturable absorption.

T3E.2 • 16:45 T3F.2 • 16:30 Invited T3H.2 • 16:30 Invited T3I.2 • 16:30 Invited Fiber Oscillator Directly Pumped Passive miniature optical T3G.2 • 16:30 Invited Wavelength selective Quantum photonic sour- Cascaded Random Raman Fiber gyroscopes based on Silicon optical mode saturation in optical ces and logic gates on Laser with High Spectral Purity, integrated optics tech- switching devices, Lin absorption of array of silicon, Xifeng Ren1; 1Univ. Tianfu Yao1, Yizhu Chen1, Jiaxin nologies, Huilian Ma1; Yang 1; 1Inst. of selforganized InAs/GaAs of science and Tech. of Song1, Yang Zhang1, Jiangming Xu1 1Zhejiang Univ., China. We Semiconductor, CAS, QDs, Pavel Brunkov1 and China, China. and Pu Zhou1; 1National Univ. of will discuss the development and China. Andrej Gutkin1; 1Ioffe Inst., Russia. Defense Tech., China. We demons- evaluation of two types of passive The two-color experiments on trate an all-fiberized cascaded miniature optical gyroscopes for photocurrent study of a PIN GaAs random Raman fiber laser pumped tactical grade applications. One is diode incorporating InAs selforga- directly by a FBG-based oscillator. the resonant integrated optical nized QDs shows the possibility to The spectral purity reaches over 92% gyroscope, and the other is the burn a spectral hole in the QD for all 4 Stokes orders. Highest interferometric optical gyroscope. absorption spectrum with resonant output power is 15 W at 1355 nm. excitation of the dot states.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 30

ICOCN 2019—Tuesday, 6 August

Room 2, Track 3 Room 3, YSA Room 5, Special 2 Room 6, Track 7

T3A.3 • 17:00 Invited T3B.5 • 17:00 T3C.3 • 17:00 Invited T3D.3 • 17:00 Invited High-Dynamic Optical Network A Blur Equalization Method for Screen-to- Deep learning powered pho- Femtosecond laser induced Control Architecture Based on Camera Based Optical Camera Communications, tonic signal processing, luminescence in glasses, Quan- Spatiotemporal Synchronization, Chun Lin1, Bangjiang Lin1, Xuan Tang1, Xiaohuan Weiwen Zou1; 1Shanghai Jiao zhong Zhao1; 1Shanghai Inst. of Nan Hua1, Ruijie Luo1 and Xiaoping Shen1, Qiwei Lai1, Junxiang Xu1 and Sushank Tong Univ., China. Optics and Fine Mechanics, CAS, Zheng1; 1Tsinghua Univ., China. We Chaudhary1; 1Quanzhou Inst. of Equip. Manufact., China. Firstly, we will review the

present a novel high-dynamic optical net- CAS, China. We proposed a screen-to-camera ultrashort laser pulses induced lumine- work control architecture based on based OCC system, in which Wiener filter is used to scence phenomena. Then, we will present spatiotemporal synchronization. By introdu- reduce inter-symbol interference and image blurring. several progresses of ultrashort laser cing highprecision time synchronization, The BER performance can be improved using the pulses induced luminescence in glasses. control coordination among nodes and proposed equalizer. Finally, the potential applications of controllers can be established to improve induced luminescence will be demon- network dynamics by orders of magnitude. strated.

Tuesday, 6 August

T3A.4 • 17:30 Invited T3C.4 • 17:30 Invited T3D.4 • 17:30 Invited Experimental Assessment of Pho- Applications of Machine Lear- Tailoring the ultrafast optical tonic Integrated Switches Based ning in Free-space Optical Com- properties of novel materials Optical Data Center Networks munication Systems, Qinghua for information photonic de- with Virtual Network Slice Tian1; 1Beijing Univ. of Posts and vices, Fengqiu Wang1; 1Nanjing Services, Xuwei Xue1, Kristif Prifti1, Tele., China. Machine Learning Univ., China. Fu Wang1, Fulong Yan1, Bitao Pan1, Xiaotao as one kind of the AI technology has Guo1 and Nicola Calabretta1; 1Eindhoven successfully attracted researchers’ atten- Univ. of Tech., Netherlands. An SDN- tion and has been considered in optical controlled DCN based on photonic integ- communication. The application for the rated switches is experimentally asses-sed. combination between machine learning Network-slice can be reconfigured within and optical communication is introduced, 150ms and deployed photonic integrated and several our proposed methods based switches perform error-free 10Gb/s switching on machine learning in free-space optical with <2dB penalty and zero packet-loss. communication system are presented.

18:00-19:30 Dinner Break, Violet Hall (紫罗兰餐厅 ), 3F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 31

ICOCN 2019—Tuesday, 6 August

Room 7, Special 6 Room 8, Track 6 Room 10, Track 4 Room 11, Special 1 Room 12, Track 10

T3E.3 • 17:00 Invited T3F.3 • 17:00 Invited T3G.3 • 17:00 Invited T3H.3 • 17:00 Invited T3I.3 • 17:00 Invited High order and high High-precision optic fiber Large-scale arrayed wa- Luminescent materials for Orbital angular momen- spectral purity random time and frequency trans- veguide grating router laser-driven solid state tum state from a laser, Raman fiber lasers ， fer, Haiwen Cai1; 1Shang- for T-band communi- lighting, RongJun Xie1; Yong Zhang1; 1 Nanjing Jinyan Dong1, Lei Zhang2 hai Inst. of Optics and Fine cation, Hiroyuki Tsuda1; 1Xiamen Univ., China. In Univ. The rapid develop- and Yan Feng1; 1Shanghai Mechanics, China. We 1Keio Univ., Japan. The T- this presentation we will ments in optical commu-

Inst. of Optics and Fine Mechanics, demonstrate the optical frequency band (1000-1260 nm), which offers report some types of luminescent nication and quantum information August 6 Tuesday, Chinese Academy of Sciences, transmission of 700 km fiber link more than 60 THz worth of materials (phosphor-in-glass, phos- require high-quality orbital-angular- China; 2PreciLasers. Co. Ltd., China. using the cascaded optical injection bandwidth and wider than C- and L- phor films and phosphor ceramics) momentum laser modes. We demo- With cascaded Raman scattering in locking amplifier. We use the two band combined. The large scale for laser-driven solid state lighting. nstrate a low-threshold solid-state random fiber lasers, up to 11th repeater stations inside the fiber photonic router using 3-stage The optical properties and lumina- laser that can directly output sele- order Raman lasers have been link to suppress the noise of the arrayed-waveguide grating for T- nce saturation of those color cted high-purity OAM modes with generated. The effects that limit the fiber link and compensate the band and O-band is configured. converters will be discussed. high efficiency and controllability. higher order emission and spectral power loss caused by the fiber link. purity of the Raman output are investigated.

T3E.4 • 17:30 Invited T3F.4 • 17:30 Invited T3G.4 • 17:30 Invited T3H.4 • 17:30 T3I.4 • 17:30 Invited Manipulating optical Distributed fiber-optic Non-volatile silicon pho- Research on the degradation of Demonstration of high- field of random fiber dynamic strain sensing tonic devices enabled perovskite thin films based on dimensional quantum lasers, Hanwei Zhang1, based on Brillouin by phase change mate- spectrometric ellipsometry, Bian information tasks, Biheng Jiangming Xu1, Jun Ye1, backs-cattering signals, rial, Linjie Zhou1, Hanyu Subiao1, Changcai Cui1 and Huihui Liu1; 1Univ. of Sci. and Tech. Jiaxin Song1 and Pu Xinyu Fan1, Bin Wang1, Zhang1, Hao Hu1, Ning- Li1; 1Huaqiao Univ., China. Research of China, China. We show Zhou1; 1National Univ. of Defense Guang-yao Yang1, Yuanxiu Fu1 and ning Wang1, Liangjun Lu1, B. M. A. on the optical constant and the preparation of high-quality Tech., China. Random fiber Zuyuan He1; 1Shanghai Jiao Tong Rahman2 and Jianping Chen1; degradation of CH3NH3PbI3 high-dimensional entanglement laser has been widely studied in Univ., China. We will present the 1Shanghai Jiao Tong Univ., China; perovskite thin films under ambient using spatial mode of photons, and recent years. We would give a advances on dynamic strain 2City, Univ. of London, China. We condition (T:21℃RH:75％） based present the demonstration of high- review of our recent progress on measurement based on Brillouin review our research on silicon-Ge2- on spectrometric ellipsometry. dimensional quantum super-dense manipulating optical field of ran- backscattering signals in optical Sb2Te5 hybrid photonic devices. coding and high-dimensional dom fiber lasers. fiber, which enables to avoid the The optical transmission can be teleportation. fading phenomenon caused by varied by 20 dB using micron-length Rayleigh coherent signals. GST. The inherent "self-holding" feature of GST make it attractive for low-power applications.

18:00-19:30 Dinner Break, Violet Hall (紫罗兰餐厅 ), 3F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 32

ICOCN 2019—Wednesday, 7 August

Room 2, Track 2 Room 3, Track 3 Room 5, BSPA-Special 3 Room 6, BSPA-Special 4 & 6

08:00-10:00 08:00-10:00 08:00-10:00 08:00-10:00 W1A • Optical transmission II W1B • Optical networks II W1C • 2D-materials photonics II (BSPA) W1D • Novel laser sources (BSPA) Presider: Jing Xu, Zhejiang Univ., Presider: Yongli Zhao, BUPT, China Presider: Hongtao Lin, Zhejiang Univ., China Presider: Tianye Huang, China Univ. of Geoscien- ces, China China

W1A.1 • 08:00 Invited W1B.1 • 08:00 Invited W1C.1 • 08:00 Invited ☼W1D.1 • 08:00 Chaotic optical communica- Efficient Technique to Fiber all-optical light control with low- Tunable Random Raman Fiber Laser at 1.7 μm Region tions over 1000-km fiber Transfer Sensor Data on dimensional materials: thermo-optic with High Spectral Purity, Yang Zhang1, Jun Ye1, Jiaxin transmission, Lilin Yi1; Dynamically Changing SDN effect and saturable absorption, Kan Song1, Jiangming Xu1, Tianfu Yao1 and Pu Zhou1; 1Shanghai Jiao Tong Univ., Controlled Optical Network, Wu1; 1Shanghai Jiao Tong Univ., China. 1National Univ. of Defense Tech., China. We China. Shailendra Gaikwad1, Ting We summarize our recent works on fiber demonstrate a random Raman fiber laser at 1715μm Wang2, Sanjeev Tulasigeri1 and Zhongqi all-optical light control with low-dimensional with the record spectral purity of 98.29% using a Pan1; 1Univ. of Louisiana at Lafayette, materials (LDMs). Devices based on thermo-optic wavelength-linewidth-adjustable amplified spontane- United States; 2NEC Laboratories effect and saturable absorption of LDMs will be ous emission source. Furthermore, the wavelength America, United States. We propose an discussed. tenability from 1705 to 1725 nm is achieved.

efficient technique to transfer sensor ☼W1D.2 • 08:15 data over optical sensor network with ☼W1C.2 • 08:30 1.6 kW Raman fiber amplifier based on multimode software defined network control. The Graphene enhanced intra-resonator biochemical graded index fiber, Yizhu Chen1, Tianfu Yao1, Jinyong method improves total amount of sensor detection with individual molecule sensitivity Leng1, Hu Xiao1 and Pu Zhou1; 1National Univ. of data transfer by 6%, and effectively and selectivity, Zhongxu Cao1, Chenye Qin1, Lei Defense Tech., China. Power scaling of high power handle the churn effect. Bi1, Yuanfu Chen1, Zhenda Xie2 and Baicheng Yao3; Raman fiber amplifier is demonstrated in this paper.

1UESTC, China; 2Nanjing Univ., China; 3USTC, The maximum output power reaches 1603.4W at

China. Partially-reduced graphene oxide inner- 1130nm, which is the highest power achieved by Raman laser solely based on passive fiber. coated and fiber-calibrated FP dye resonator for Wednesday, 7 August 7August Wednesday, W1A.2 • 08:30 Invited W1B.2 • 08:30 Invited biochemical detection enables the functionalized ☼W1D.3 • 08:30 High Capacity Transmission Weakly-coupled mode divi- FRET-gain-assistance and intermode heterodyne Supercontinuum generation from PCF directly with Few-Mode Fibers, Georg sion multiplexing: enabling interference, we achieve individual molecule pumped by DSR laser with kW-level peak power, He Rademacher1; 1NICT, Japan. technologies for 10~20 sensitivity for dopamine, nicotine and ssDNA. Xu1, Shengping Chen1 and Zongfu Jiang1; 1National

We present our recent expe- MIMO-free linearly-polarized Univ. of Defense Tech., China. We demonstrate an all- rimental space division multip- (LP) modes, Juhao Li1; 1Peking ☼W1C.3 • 08:45 fiber SC source with pump power independent lexed transmission demonstrations over Univ., China. We propose multiple-ring Black Phosphorus Based Ultrafast Yb-doped spectral distribution by directly pumping DSR pulses with kW-level peak power into PCF. three-mode fibers with more than to 280 core structure to realize FMF supporting Fiber Laser: Principle, Mechanisms, and 1 1 1 Tbit/s over short distance and more 10~20 independent LP modes. Tripple- Applications, Tao Wang , Jin Wang , Xinyao Shi , ☼W1D.4 • 08:45 than 159 Tbit/s over more than 1000 km. ring-core FMF supporting 10 LP modes is Zhenghui Pan1, Jian Wu1, Kai Zhang1 and Pu Zhou1; Nonlinear propagation in few-mode fiber based on designed and fabricated. 10-mode MDM 1National Univ. of Defense Tech., China. Different principal modes, Hu Jinyao1, Wang Zhi1, Liu Yange 1 transmission over 10-km FMF is demon- Yb-doped pulse lasers based on black phosphorus and Zhang Luhe1; 1Nankai Univ., China. The theory of strated with 10-Gb/s on-off-keying and have been demonstrated. Our results extended principal modes provides a new method to analyses DSP-free direct detection. the application of BP in the spatial and temporal nonlinear propagation of a laser pulse in a few-mode domain. fiber, with the existence of linear modes coupling.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 33

ICOCN 2019—Wednesday, 7 August

Room 7, Track 1 Room 8, BSPA-Track 6 Room 10, Track 4 Room 11, Special 1 Room 12, Track 10

08:00-10:00 08:00-10:00 08:00-10:00 08:00-10:00 08:00-10:00 W1E • Novel fibers & devices II W1F • Optical measurement III W1G • Optoelectronics II W1H • Organic & nano W1I • Quantum photonics III Presider: Zhijun Yan, Huazhong (BSPA) Presider: Lin Yang, Inst. of optoelectronics III Presider: Heng Fan, Inst. of Univ. of Sci. & Tech., China Presider: Liyang Shao, Southern Physics, CAS, China. Semiconductors, CAS, China Presider: Stefano Toffanin, Univ. of Sci. & Tech., China CNR-ISMN, Italy

W1E.1 • 08:00 Invited W1F.1 • 08:00 Invited W1G.1 • 08:00 Invited W1H.1 • 08:00 Invited W1I.1 • 08:00 Invited All-solid fluorotellurite Optical fiber hetero- Ultra-high speed optical Development of Quan- Chemo-mechanical polish fibers and their applica- structure sensor, Qiang interconnects based on tum Dots for Optoele- lithography for large scale tions, Guanshi Qin1; 1Jilin Wu1; 1Northumbria Univ., silicon photonic modu- ctronic Devices–From photonic integration on lit- Univ., China. We demons- UK. Optical fiber hetero- lator, Fan Zhang1; Lab Bench to Commer- hium niobate on insulator, trated 20-W-level midinf- structure is one of the key 1Peking Univ., China. We cial Applications, Nigel Ya Cheng1; 1East China rared supercontinuum laser source, configurations for fiber based inter- review our recent work on ultra-high Pickett1; 1Nanoco Tech. Limited, Normal Univ., China. High quality ultrabroadband supercontinuum ge- ferometers. The typical heterostru- speed optical intercom-nects with United Kingdom. The development lithium niobate on insulator photonic neration from 600 to 5400 nm, and cture includes singlemode-multi- PAM-4/6/8 signals and silicon of QD materials from the lab bench integrated circuits are demonstrated broadband amplification in newlyde- mode, singlemode-hollow core, photonic modulator. Up to single to commercial production will be by chemo-mechanical polish lithog-

veloped all-solid fluorotellurite fibers. singlemode-no core fiber structure. lane 200G transmission is achieved discussed, with a particular focus on raphy, opening up possibilities in on- Wednesday, August7 In this talk, the fundamentals and by mitigating the limited modulator optoelectronic applications such as chip quantum information procesing, their applications such as tempe- band-width using digital signal electroluminescent displays. optical computations and communi- rature, strain, twist and biochemical processing. cations, and optical interconnection. sensing will be discussed.

W1E.2 • 08:30 Invited W1F.2 • 08:30 Invited W1G.2 • 08:30 Invited W1H.2 • 08:30 Invited W1I.2 • 08:30 Invited Hollow core optical fiber Real-time distributed Mid-infrared on-chip de- In-situ Fabricated Perov- Femtosecond laser and its applica-tions, fiber sensing based on vices based on SOI and skite Quantum Dots for bionic micro/nano fabri- Yingying Wang1; 1Beijing slope-assisted BOCDR, GOI technology, Zhen Display Applications, Hai cation, Feng Chen; Xi'an Univ. of Tech., China. We Heeyoung Lee1, Kohei zhou Cheng; Tianjin Univ., zheng Zhong1; 1Beijing Inst. Jiaotong Univ., China. present vari-ous types of Noda1, Yosuke Mizuno1 China. Here I report our of Tech., China. In-situ Biological micro/nano- hollow-core fibers developed at our and Kentaro Nakamura1; 1Tokyo Inst. research progress on mid-infrared fabricated perovskite quantum dots structures all comprise the goals for group. They exhibit combined merits of Tech., Japan. We introduce our silicon/germanium pho-tonics. The provide highly luminescence electro- the next-generation smart artificial of ultra-low loss, broad bandwidth, recent advances on slope-assisted study is expected to open an avenue luminescence films and composite materials and devices. This presen- low bending loss and high mode Brillouin optical correlation-domain to develop novel mid-infrared on- films for display applications. tation summarizes the recent pro- qua-lity, heralding new opportunities reflectometry, which enables real- chip devices for sensing and gress in the development of bioins- for telecommunication and laser time distributed strain and tempe- nonlinear optics. pired smart structures via femto- applications. rature measurements along optical second laser micro/nanofabrication. fibers. Some on-going experiments and future tasks are also presented.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 34

ICOCN 2019—Wednesday, 7 August

Room 2, Track 2 Room 3, Track 3 Room 5, BSPA-Special 3 Room 6, BSPA-Tracks 4 & 6

W1A.3 • 09:00 Invited W1B.3 • 09:00 Invited ☼W1C.4 • 09:00 ☼W1D.5 • 09:00 Kalman filter: an effective Intelligent Optical Network Germanium telluride nanosheets for ultra-fast 30-W Supercontinuum Generation in ZBLAN Fiber, equalization solution for with AI and Blockchain, Hui photonics, Mengyu Zhang1, Jiaqiang Zhang1, Linyong Yang1, Tianyi Wu1, Bin Zhang1, Ying Li1, Yijun optical fiber communication Yang1; 1BUPT., China. We pro- Hao Yuan1, Jinde Yin1, Hao Chen1, Jintao Wang1 Zhao1 and Jing Hou1; 1National Univ. of Defense Tech., systems, Xiaoguang Zhang1; pose a novel intelligent optical and Peiguang Yan1; 1Shenzhen Univ., China. We China. For the first time, the experimental results of 1BUPT, China. We present a network meeting the new kind prepare GeTe nanosheets with few-layer ZBLAN-fiber-based high-power supercontinuum (SC) thorough review of the applications of services promoting the reacha-bility with thickness by using LPE in deionized water laser source with maximal output power of over 30 W was Kalman filter in optical fiber communi- artificial intelligence and enhance the solvent and investigate their nonlinear optical demonstrated.

cations. trusty using blockchain technology. (NLO) response at 800 nm and 2 μm. ☼W1D.6 • 09:15 1.7–12.7μm coherent supercontinuum gene-ration in a ☼W1C.5 • 09:15 Te-based chalcogenide tapered fiber pumped in the High Performance Pdse2 Long-Wavelength normal dispersion regime, Nan Zhang1, Xuefeng Peng1, 1 Infrared Photodetector, Yang Wang , Fang Yingying Wang2, Peilong Yang1 and Shixun Dai1; 1Ningbo 1 1 1 1 Wang , Peng Wang and Weida Hu ; Shanghai Univ., China; 2Shanghai Jiao Tong Univ., China. We have Inst. of Technical Physics, Chinese Academy of reported a 1.7–12.7 μm ultra-broadband SC generation

， Sciences, China. In this work we demonstrate a with high coherent property from a 7 cm long all-normal long-wavelength infrared pho-todetector with dispersion Te-based chalcogenide tapered fiber pumped high performance and fast response speed, at 5.5μm. which provides a well paradigm for the next- W1A.4 • 09:30 Invited W1B.4 • 09:30 Invited generation long-wavelength infrared photo- ☼W1D.7 • 09:30 Look Deeper into Guidance Energy Efficiency in Flexible detectors based on two-dimensional Output Performance of an Incoherently Pumped Properties of Anti-Resonant Band-width Optical Net- nanostructures. Random Fiber Laser Dependence on the Pump 1 1 1 1 1 Hollow-Core Fiber, Fei Yu ; works, Bowen Chen ; Bandwidth, Jun Ye , Jiangming Xu , Jiaxin Song , Yang 1 1 1 1 1 1 Shanghai Inst. of Optics and Soochow Univ., China. Due to ☼W1C.6 • 09:30 Zhang , Jinyong Leng and Pu Zhou ; National Univ. of Fine Mechanics, CAS, China. For the accelerated evolution of Single-walled Carbon Nanotubes Operating Defense Tech., China. The output performance of an

Wednesday, 7 August 7August Wednesday, the first time we numerically demonstrate application services, the energy consum- as Normal Phototransistors towards Highly- incoherently pumped random fiber laser (RFL) that the modal dispersion of anti- ption is one of the great challenges to sensitive Infrared Detection, Peisong Wu1, Lili dependence on the pump bandwidth has been resonant hollow-core fiber can be guarantee these services in flexible Zhang1, Peng Wang1 and Weida Hu1; 1Shanghai investigated. This work could provide a new pumping effectively altered by the cladding bandwidth optical networks. We improve scheme for the high power RFLs. Inst. of Technical Physics, Chinese Academy of material refractive index. The modal energy efficiency by optimizing the Sciences, China. In this work we focused on ☼W1D.8 • 09:45 overlap over fiber material in the energy components. field-effect phototransistors based on disor- Two-color random fiber laser with flexible power antireasonant hollow-core fiber is also dered single-walled carbon nanotubes, and proportion based on phosphosilicate fiber, Jiaxin Song1, explored systematically. The optimized studied the effects of electrode contact and Jiangming Xu1, Yang Zhang1, Jun Ye1 and Pu Zhou1; design of antireasonant hollow-core fiber exaction response on the photo-response of 1National Univ. of Defense Tech., China. A two-color for low-loss transmission in the high- devices. random fiber laser based on phosphosilicate fiber with absorptive spectral window of cladding flexible power proportion and 117 nm wavelength material is proposed for the first time. interval was demonstrated. The power proportion of the silica-related Stokes light ranged from 99.0 % to 0 %.

10:00-10:30 Poster Session 2 & Coffee Break, 4F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 35

ICOCN 2019—Wednesday, 7 August

Room 7, Track 1 Room 8, BSPA-Track 6 Room 10, Track 4 Room 11, Special 1 Room 12, Track 10

W1E.3 • 09:00 Invited ☼W1F.3 • 09:00 W1G.3 • 09:00 Invited W1H.3 • 09:00 Invited W1I.3 • 09:00 Invited Distributed Acoustic Speckle-free high contrast bio-imaging in dental Subwavelength me- Standardization of Generation of light Sensing based on Draw hard tissue using random fiber laser in backscatter- tamaterial enginee- QD materials towar- beam with prescri- Tower Grating, Ming ring configuration, Jia Yu Guo1, Wei Li Zhang1, Yun ring for silicon ds display applica- bed coherence stru- hong Yang1; 1Wuhan Jiang Rao1, Hua Hui Zhang1, Rui Ma1, Izabella C. X. integrated devices, tion, Guanglu Ge1; cture and its pro- Univ. Tech., China. A new Lins2, Daniela S. Lopes2 and Anderson S. L. Gomes2; Yaocheng Shi1; 1NCNST., China. pagation through system of thousands of ultra-week 1UESTC, China; 2Univ. Federal of Pernambuco, Brazil. 1Zhejiang Univ., China. We will Quantum dots show great turbulent atmosphere, Yang fibre Bragg gratings array during We demonstrate the near-infrared random fiber laser introduce some of our recent potential in lighting and display jian Cai1; 1Shandong Normal the fibre drawing for distributed is ideally suitable for dental caries diagnosis owing to work on the silicon metama- applications. The recent stan- Univ., China. Laser beam with acoustic sensing is proposed and its near-infrared wavelength, high spectral density and terial based silicon integrated dardization activities in ISO and low spatial coherence named demonstrated with field test. low coherence. devices, including the bent IEC on QDs, such as particle partially coherent beam and it

multi-mode waveguides, multi- size and concentration, and with prescribed coherence stru- ☼W1F.4 • 09:15 A temperature sensing scheme realized with Sag- mode crossings, and polari- quantum yield will be described. cture exhibits many interesting nac Interferometer based microwave photonic zation beam splitters. properties and is preferred in filter, Xun Cai1, Xinying Chen1 and Hongyan Fu1; many applications. We will 1 introduce recent development

Xiamen Univ., China. A temperature sensing scheme Wednesday, August7 realized with Sagnac interferometer based MPF has on generation and propagation been proposed. of partially coherent beams.

W1E.4 • 09:30 Invited ☼W1F.5 • 09:30 W1G.4 • 09:30 Invited W1H.4 • 09:30 Invited W1I.4 • 09:30 Invited Advances in mid- Hybrid Polarizing grating and TFBG based SPR Enabled silicon pho- Cadmium-free Quan- Photovoltaic Effect infrared fiber lasers at refractive index sensor, Yarien Moreno1, Qingguo tonic technologies tum dots for Wide of Atomtronics Indu- 3-4 µm, Jianfeng Li1; Song2, Zhijun Yan2, Zhikun Xing2, Tean Lu 2, Huabao on advanced CMOS Gamut Displays with ced by an Artificial 1Univ. of Ele-ctronic Sci. Qin2, Yuezhen Sun2, Wei Zhou2, Wei Zhang2, Qizhen platform, Guangwei High Efficiency and Gauge Field, Wu and Tech. of China. Our Sun2 and Deming Liu2; 1Univ. of Panama; 2Huazhong Cong1, Keijiro Suzuki1, Reliability, Yongyin ming Liu; Inst. of Phy., Univ. of Sci. and Tech., China. We report a SPR SRI 1 1 1 recent pro-gress on mid-infrared Yuriko Maegami , Makoto Oka- Kang ; Najing Tech. CAS, China. fiber lasers at 3-4μm, including sensing system based on a hybrid grating structure no1, Morifumi Ohno1, Noritsugu Corporation LTD., China. Here, tunable passive Q-switching Dy3+- comprising of a 45º TFBG and a silver coated small Yamamoto1, Kazuhiro Ikeda1, we report a novel Cd-free high- angle TFBG. 1 ☼W1I.5 • 10:00 doped ZBLAN fiber laser, watt- Hitoshi Kawashima , Shu Nami- quality QDs based on InZnP 1 1 1 Splicing ET (error-tolerant) level dual-wavelength pumped ☼W1F.6 • 09:45 ki and Koji Yamada ; AIST, /ZnSe/ZnS core/shell/shell stru- 3+ quantum computing system, gain switched Er -doped ZBLAN Vector Magnetic Field Sensor Based on Polarization- Japan. We will review our cture by using a heating-up Guangyao Sun1; 1Fudan Univ., fiber laser, tunable passive Q- Maintaining Fiber Long-period Grating with activities to leverage AIST method. The InZnP-based QDs China. In this paper, we develop switching, and parallel dual- 1 1 1 300mm CMOS line as the most show the PL emissions for the Magnetic Fluid, Chen Jiang , Yunqi Liu , Xiaolong Si , a system with redundant wavelength pumping method will 1 1 1 competitive silicon photonic green of ～ 532 nm and red Jianxiang Wen and Chengbo Mou ; Shanghai Univ., splicing topology by studying be introduced. China. We present a vector magnetic field sensor platform. of ～ 630 nm with narrow FWHM of 38 and 43 nm, and the ET (error-tolerant) system, based on long-period grating inscribed in thin- and study its unique advantages cladding polarization-maintaining fiber and immersed high quantum yield of 68% and 67%, respectively. in topology. And tapped the the grating in magnetic fluid which can measure both potential of application in magnetic intensity and orientation simultaneously. quantum computing.

10:00-10:30 Poster Session 2 & Coffee Break, 4F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 36

ICOCN 2019—Wednesday, 7 August

Poster Session 2（10:00-10:30）

P2.1 P2.4 P2.7 P2.11 Uniform-Multilevel Amplitude Regeneration Research on Laser Cavity Ring-down Polysilicon light source with novel structure Disturbed PD Detection System Based on using a Polarization-orthogonal Continuous- Spectroscopy and Fiber-Based Measure- of metal-like oxide semiconductor, Kang Ai1, Improved φ-OTDR Assisted by wFBG Array, wave-light-assisted Nonlinear-optical Loop ment for SF6 Decomposed Gases, Shiling Kaikai Xu1 and Hongliang Sun1; 1uestc, China. Peng Zhu1, Hongqiao Wen1 and Qian Che1; Mirror, Biao Guo1, Feng Wen1, Baojian Wu1, Zhang1; 1State Grid Chongqing Electric Power A new structure of silicon luminescence, 1Wuhan Univ. of Tech., China. We experi- Fan Sun1 and Kun Qiu1; 1Univ. of Electronic Company Chongqing Electric Power realizes the increase of impact ionization rate mentally demonstrate an improved disturbed Science and Tech. of China, China. We Research Inst., China. Online monitoring and the improvement of luminous efficiency. acoustic sensing system based on φ-OTDR experimentally investigate a multilevel device for SF6 decomposition gas based on assisted by wFBG array. amplitude regeneration of NRZ-PAM4 signals the laser absorption spectroscopy is deve- P2.8 using a novel polarization-orthogonal loped. The calibration algorithm is proposed Cascade Co-pumping – From a Comparison P2.12 continuous-wave-light-assisted nonlinear- and verified by experiment. Within the range View, Zhaoxia Sheng1, Qun Han2, Xueru Polymer/Silica Hybrid Three-Dimension optical loop mirror (PC-NOLM) subsystem, of 0~200ppm, the stability is less than 2%. Zhao2, Dan Wang2, Haofeng Hu2, Mei Sang2 Integrated Multiplexer Based on MDM and which creates the uniform noise-suppression and Keming Ma2; 1Tianjin Univ. of Tech. and WDM, Liang Tian1, Hui Gao1, Ye Deng1 and be-havior on multiple amplitude levels. Education, China; 2Tianjin Univ., China. Maobin Wang1; 1Nanjing Research Inst. of Cascade co-pumping EYDFL is studied. Electronics Tech., China. A polymer/silica

Cascade co-pumping is the most effective hybrid three-dimension integrated multi- P2.2 P2.5 method among the existing power scalling plexer based on MDM and WDM is proposed. Near-balance Mach-Zehnder interfere- Study on the Effect of System Parameters methods in efficiency, stability, compactness, WDM is implemented on different layers by ometer based on hollow-core photonic on Physical-Layer Security of Optical CDMA and cost-effectiveness. two multimode interference couplers, and bandgap fiber for pressure sensing, Chun Systems, Yeteng Tan1, Tao Pu1 and Jilin MDM is achieved by a three-dimension Mao1, Bo Huang1 and Ying Wang1; 1Shenzhen Zheng1; 1Army Engineering Univ. of PLA, P2.9 integrated asymmetric directional coupler. Univ., China. A novel optical fiber pressure China. Secrecy capacity is employed as an A Highly Sensitive Liquid-Level Modal sensor fabricated by hollow-core photonic indicator to estimate the effects of system Sensor Utilizing Thin-Core Fiber, Wei Liu1, P2.13 bandgap fiber based on a near-balanced parameters on the security of OCDMA Xuqiang Wu1, Gang Zhang1, Shili Li1, Dong Embedding Hose-Model virtual Network in Mach-Zehnder interferometer for air pressure systems. Choosing the code words with Guang1, Cheng Zuo1, Shasha Fang1 and Benli Flexgrid Optical Networks, Fengqing Liu1 1 1 2 1 2 Wednesday, 7 August 7August Wednesday, sensing. The proposed gas pressure sensor better cross-correlation characteristics can Yu ; Anhui Univ., China. An optical modal and Longzhu Guo ; NUPT, China; Hohai achieves an ultrahigh sensitivity, up to 2.39 improve the security of OCDMA systems. interferometer based on thin-core fiber (TCF) Univ., China. It studies the problem of hose- nm/kPa. for liquid-level sensing is proposed. The model virtual network embedding in flexgrid wavelength shift sensitivity is -0.124 nm/mm optical networks. Problem definition is given, P2.6 within the measurement range of 15mm. and four heuristic algorithms are proposed. P2.3 Fiber optic planar accelerometer based on An MMF-NCF-MMF Structure Based SPR modal interferometer, Gang Zhang1, P2.10 P2.14 Sensor for Highly Sensitive Detection of Xuqiang Wu1, Hui Wang2, Shili Li1, Wei Liu1, Measurement and Analysis of Radiation Fabrication of surface corrugated Long Glucose and Salt Solutions, Zhao Yang1, Li Cheng Zuo1, Shasha Fang1 and Benli Yu 1; Calibration Uncertainty of Multi-Band Period Gratings on Plastic Optical Fibers Xia1 and Wei Li1; 1Huazhong Univ. of Science 1Anhui Univ., China; 2Anhui Zhibo Opto- Polarization Imager, Quan Zhang1; 1Anhui for Refractive Index Sensing, Peng Xue1, and Tech., China. An optic-fiber SPR sensor Electronic Tech. Co., Ltd, China. A fiber optic Inst. of Optics and Fine Mechanics, Chinese Fangda Yu1 and Jie Zheng1; 1Jilin Univ., China. based on no-core fiber (NCF) is presented planar accelerometer for low frequency micro- Academy of Sciences, China. The principle of Surface corrugated long period gratings are and available for microfluidic chip. Our sensor vibration detection is proposed. The me- multi-band polarization imager is introduced. fabricated on commercial plastic optical fibers has advantages of high sensitivity (3094 asured sensitivity, resolution and directional Instrument was tested and analyzed by by die press print method. The so-obtained nm/RIU), wide RI range (1.333-1.405) and crosstalk are 227.82 mV/g, 12.54 μg/√Hz and - radiation calibration. The radiation calibration LPGs are proposed as refractive index (RI) compactness. 45.88 dB (8-100 Hz). The temperature accuracy is better than 2%. sensors and the RI sensing performance is crosstalk is -0.5 nm/℃. studied.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 37

ICOCN 2019—Wednesday, 7 August

Poster Session 2（10:00-10:30）

P2.15 P2.18 P2.21 P2.24 An optofluidic microcapillary biosensor for Broadband Optical Router Based on Power Supply System of High-voltage Fiber Optic Seismic Monitoring System for label-free, low glucose concentration Photonic-plasmonic Hybrid Switches, Ziyan Towers Based on Multi-core Energy Highway Rock Slope, Binxin Hu1, Guofang detection, Jijing Chen1, Quan Zhou1, Cheng Li1, Kun Wang1, Bowen Zhang1 and Huaxi Gu1; Transmission Fiber, Lin Cheng1, Yi Jiang1, Gao2, Feng Zhu1, Hua Zhang1, Guangdong Wan2, Hongdan Wan1 and Zuxing Zhang1; 1Xidian Univ., China. Optical router is the key Zhengyang Liu1 and Qiang Gao2; 1Wuhan Nari Song1, Jiangbo Pang2, Guodong Zhong2 and 1NUBT, China; 2Peking Univ., China. A micro- element for Optical Network-on-chip. We Limited Liability Company Of State Grid Ni Quan2; 1Laser Inst., Qilu Univ. of Tech. capillary with a Q factor of 1.3×106 and a 2- propose Zander, a five-port non-blocking Electric Power Research Inst., China; 2State (Shandong Academy of Sciences), China; μm wall thickness is functionalized to detect broadband optical router based on photonic- Grid Liaoning Electric Power Co., Ltd., China. 2Baiquan Branch, Shaanxi Province Highway glucose concentration of 2.78 mM, with plasmonic hybrid switches. Further-more, We propose an improved structure of the Construction Group Company, China. This sensitivity of 0.974 pm/mM and small sample Zander-XY is proposed for XY dimension- power-over-fiber receiving module to reduce paper presents a fiber optic seismic volume ~ 90 nL. order routing. the impact of the environment on high-power monitoring system for highway rock slope towers. And we design a multi-core energy using FBG geophone and VCSEL-based transmitting fiber for this structure. interrogator. The results show that this system has great potential for stability monitoring of P2.16 P2. 19 P2.22 highway rock slope. Calculation on parallelism error of optical A fiber etched cavity for microsphere Adaptive Bandwidth Allocation Strategy axis in optical communication pod, Bo Xu1, whispering-gallery-mode excitation, Xue for Satellite Communication, Yi Liu1, Le Li2 P2.25 Wednesday, August7 Zhichao Qu1, Shichen Wu1, Xiangxiang Meng1 qian Bai1 and Dongning Wang1; 1China Jiliang and Hai-Bo Liu1; 1China Satellite Maritime Mach-Zehnder interferometer in no-core and Kun Cheng1; 1Shandong Inst. of Univ., China. In this paper, we demonstrate a Tracking and Control Department, China; fiber based on femtosecond laser inscribed Aerospace Electronics Tech., China. Tempera- whispering-gallery-mode microsphere reson- 2Audit Office of Central Military Commission, waveguides, Hua Zhang1 and Dongning ture variation leads to thermal deformation of ator. The device is fabricated by etch to create China. Traditional bandwidth allocation Wang1; 1China Jiliang Univ., China. We optical axis in the airborne optical communi- an arc shaped cavity, with a microsphere methods cannot grantee detailed granularity. demonstrated a fiber in-line Mach-Zehnder cation pod. The influence of the temperature glued at its bottom. The device has a Q-factor This paper proposes a strategy, which can be interferometer constructed by femtosecond change on parallelism of optical axis is of 1.21X10^4. mapped to the randomized time-varying laser written waveguides in no-core fiber. The analyzed. knapsack problem. Experiments prove that device based on internal structure can be

the strategy can effectively allocate the used for temperature and strain and external limited bandwidth. refractive index measurement.

P2.17 P2.20 P2.23 P2.26 Improved spectral performance of fiber An in-fiber Acceleration Sensor based on Performance evaluation for polarization Construction of Mach-Zehnder interfere- sensor using Brillouin slow light, Fan Wang1, Fabry–Perot Cavity, Yulian Wang1, Liyue shift keying modulation in atmospheric ometer in no-core fiber using single Kai Qian2, Shenglai Zhen1, Xuqiang Wu1 and Jiang1, Wei Liu1, Zhigang Cao1, Shenglai turbulence channel, Li Zhang1, Peng Xiang1, straight in-fiber waveguide, Weiwei Li1, Benli Yu1; 1Anhui Univ., China; 2Hubei Univ. for Zhen1 and Feng Xu1; 1Anhui Univ., China. A Jiyong Zhao1, Hua Zhou1, Jilin Zheng1, Han Dongning Wang1, Hua Zhang1 and Chunliu Nationalities, China. We design a scheme that compact fiber-optic acceleration sensor Zhang2, Yuehong Shen1 and Tao Pu1; 1Army Zhao1; 1China Jiliang Univ., China. We the spectral performance of a sensor can be based on Fabry–Perot interferometer is Engineering Univ. of PLA, China; 2No.724 demonstrated a in-fiber Mach-Zehnder improved by introducing a Brillouin slow light proposed and fabricated. Results show that Research Inst. of CSIC, China. Exponentiated interferometer in no-core fiber based on into it. Results show that spectral sensitivity is the minimum detectable acceleration of the Weibull distribution is adopted in FSO system. single straight waveguide fabricated by enhanced by about 1.145 time. accelerometer is 0.928 and the available Results show the effects of aperture averaging femtosecond laser. The device can be used bandwidth is 10-90 Hz. on the average BER under different for high temperature, bend sensing and the turbulence strengths. The POLSK modulated free spectral range can be controlled. FSO systems can offer better BER performance compared to OOK scheme.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 38

ICOCN 2019—Wednesday, 7 August

Poster Session 2（10:00-10:30）

P2.27 P2.31 P2.35 P2.38 Enhanced Adaptive DBP Using Extended Switchable Dual-wavelength Erbium- Resonance Energy Leakage in Hollow Core Numerical study on a proposed photonic Godard’s Error for 16-QAM Coherent doped Fiber Laser with High OSNR and Fiber for Sensitive Liquid Level Mea- crystal fiber with large modal separation, Optical Systems, Guangze Ge1, Bo Xu1, Jing Stability Using PM-FBG and CFBG, Meili surement, Lifeng Bao1; 1China Jiliang Univ., Xiu Zhang1, Zhengxiong Zhang1, Wenhui Zhang1 and Xingwen Yi2; 1Univ. of Science and Jiang1, Ting Feng1, Da Wei1, Mingming China. A liquid-level sensor based on energy Jiang1, Panyun Gao1, Liang Chen1, Peng Tech. of China, China; 2Sun Yat-sen Univ., Wang1, Aihua Liu1, Peng Hao1 and X. Steve leakage of anti-resonant reflecting guidance Wang Wang1, Yong Zhou1, Wei Zhang1 and China. An enhanced adaptive digital back- Yao 1; 1Hebei Univ., China. We demonstrate a in hollow core fiber is experimentally Weiqing Gao1; 1Hefei Univ. of Tech., China. propagation scheme based on extended high performance switchable dual-wave- demonstrated. Liquid-level measurement was We investigate the characteristics of optical Godard’s error is proposed and demon- length linear-cavity erbium-doped fiber laser achieved with sensitivity of 7.64dB/mm, which modes in a new designed hollow-core pho- strated for 16-quadra-ture amplitude and based on a polarization maintaining FBG and is several times higher than that of normal tonic crystal fiber, including chromatic disper- higher order modulation formats. a chirped FBG. sensors. sion and the large effective refractive index difference between the four vector beams. P2.28 P2.32 P2.36 Research on Nonlinear Fiber Laser with Optimization of Dead Time in SPAD-based Investigations on FM-to-AM modulation P2.39 Short Brillouin Gain Fibers, Si Chen1, Photon-Counting Communication System compensation using all-fibered wide-range An adaptive non-uniform PSK modulation 1 1 1 1 1

Qinghua Yu and Bo Cong ; China Satellite with Afterpulsing, Chen Wang , Jingyuan tunable filter, Mengqiu Fan , Xiaocheng scheme for elastic optical network, Bingyan Maritime Tracking and Control Department, Wang1, Zhiyong Xu1, Jianhua Li1, Jiyong Zhao1, Tian1, Zhaoyu Zong1, Dandan Zhou1, Na Zhu1 Wang1, Feng Tian1, Qi Zhang1, Yongjun China. Nonlinear fiber lasers with short single- Chuanxin Wu1, Yimei Wei1 and Yong Zhu1; and Dangpeng Xu1; 1Laser Fusion Research Wang1, Qinghua Tian1, Bo Liu1, Chuxuan mode fibers (≤ 100m) are investigated. The 1Army Engineering Univ. of PLA, China. The Center, China Academy of Engineering Wang1 and Xiangjun Xin1; 1BUPT, China. This effects of the length of the Brillouin gain fiber, optimization of dead time in different bit Physics, China. An all-fibered wide-range paper proposes a novel adaptive non-uniform and the optical filter are studied. times and background photon levels is tunable filter to compensate FM-to-AM PSK modulation scheme that achieves flexible investigated. conversion in laser facility is investigated and signal transmission, reduces the receiver demonstrated. Jones matrix method is complexity and maximizes the system P2.29 P2.33 refered to investigate the filter. In the efficiency while guaranteeing the acceptable Economical Solution for Cladding Etched Highly sensitive refractive index sensor demonstrated experiment, FM-to-AM index error rate at the same time. 1 1 Wednesday, 7 August 7August Wednesday, Optical Fibers, Hongwei Ding , Jingda Shi , with fiber in-line Fabry-Perot interfere- is reduced to 3.12%. Tau Wan Lim1, Yung Chuen Tan1 and Wenn ometers based on vernier effect, Fengping P2.40 Jing Lai1; 1Nanyang Tech. Univ., Singapore. Zhao1, Ben Xu1 and Dongning Wang1; 1CJLU, A Novel Chaos-Based Three-Dimensional We demonstrate an economical wet etching China. A highly sensitive refractive index (RI) P2.37 Constellation Rotation Encryption Algo- solution for optical fibers using glass etching sensor with two cascaded fiber in-line FPIs has Design of a low-dispersion ring-core rithm for OFDM-PON, Lu Chen1, Ning Jiang1, cream. The etching performance and surface been demonstrated. The sensor exhibits a photonic crystal fiber supporting 26 OAM Yajun Wang1, Shuqing Lin2, Shiqin Liu1, quality on optical fibers are investigated. The compact size and has the a high RI sensitivity. modes, Dong An1, Jiajing Tu1 and Keping Baochuan Li1 and Kun Qiu1; 1Univ. of Science solution offers good controllability and Long1; 1Univ. of Science and Tech., China. We and Tech. of China, China; 2The 44th Research repeatable outcomes. P2.34 propose a novel fiber with a stable physical Inst. of China Electronic Science and Tech. Low Polarization Dependent Loss Two- structure, two-layer triangular arrangement air Group, China. A physical layer security P2.30 Dimensional Grating Coupler, Yanyun Xue1, hole structure, to protect the air holes from encryption algorithm in OFDM-PON is Study on the Transmission Characteristics of Hao Chen1, Yujin Bao1, Jianji Dong1 and deformation, which contributes to low proposed which combines three-dimensional Laser Detection System in Rain, Jing Guo1 Xinliang Zhang1; 1HUST, China. We design confinement loss and relatively flat chromatic constellation and chaotic mapping. The and Hai-Ting Zhu1; 1NUPT, China. The and demonstrate a two-dimensional grating dispersion. numerical results show that it has high security transmission characteristic of laser in rain was coupler with a lowest polarization dependent and better BER performance compared with discussed and the impact of rain attenuation loss based on the silicon-on-insulator traditional two-dimensional modulation. to laser detection was analyzed. platform.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 39

ICOCN 2019—Wednesday, 7 August

Poster Session 2（10:00-10:30）

P2.41 P2.44 P2.48 P2.51 Theoretical and experimental study on Temperature Sensor Based on Mach- Error Analysis of the Impulse Response on A tunable dual-frequency optoelectronic optical fiber microseismic accelerometer Zehnder Interferometer with Corroded VCSEL-based Optical Wireless Communi- oscillator based on opical FBG-FP filter and based on cantilever beam structure, Hua Photonic Crystal Fiber, Yuwei Zhang1, Kai Ni1, cation Channel Using a Monte Carlo Ray- electrical YIG filter, Haida Yang1, Jianghai Zhang1, Binxin Hu1, Guofang Gao1, Feng Zhu1, Liuwei Wan1, Qian Yu 1 and Weijian Tian1; Tracing Algorithm, Simei Mao1, Zixian Wei1, Wo1, Maolong Zhang2, Ranran Liu1, Xiong Guangdong Song1, Jiangbo Pang2, Guodong 1CJLU, China. A temperature sensor by using Yuhan Dong1 and H. Y. Fu1; 1Tsinghua Univ., Luo1, Wenshan Cong1, Anle Wang1, Jin Zhong2 and Ni Quan Quan2; 1Laser Inst., Qilu a corroded photonic crystal fiber based on China. We propose a Monte Carlo ray-tracing Zhang1, Yalan Wang1 and Lan Yu1; 1Air Force Univ. of Tech. (Shandong Academy of Mach-Zehnder interferometer is proposed method (MCRM) based on Gaussian beam Early Warning Academy, China; 2Air Force Sciences), China; 2Baiquan Branch, Shaanxi and experimentally demonstrated. emitter source for optical wireless communi- Communication NCO Academy, China. A Province Highway Construction Group cation (OWC) channel estimation and novel scheme of dual-frequency optoelec- Company, China. Optical fiber microseismic P2.45 establishes two typical indoor communication tronic oscillator based on fiber Bragg grating accelerometer based on cantilever beam Design of A New Thresholder Using For systems as uplink and full-link models. Fabry-Perot (FBG-FP) filter and YIG filter is structure is put forward, and its mechanical Spiking Photonic Neuron, Ming Xu1, Minjun proposed and proved by experiment. model is established, its sensitivity is analyzed, Zhai1, Zhiyang Ni1 and Jianhua Ji1; 1Shenzhen P2.49 and tested by B&K shaking table test system. Univ., China. An spiking photonic neuron Parallel and Pipelined CMA for High-Speed illustrated with a new thresholder based on a and Real-Time Optical Coherent Receivers, designed Sagnac loop. Thresholder is passive Yue Dong1, Liqian Wang1, Zhiguo Zhang1, P2.52 Wednesday, P2.42 with outside pump source in a photonic Shanyong Cai1, Luming Li2, Jiangxing Chen2 Direct oscillation of ultrafast HOM in Yb- Research on the Gain Saturation Induced crystal fiber. and Xing Liu2; 1Beijing Univ. of Posts and doped fiber laser, Han Yao1, Xianglong Noise in an Optical Fiber Sensing System, Telecommunications, China; 2Jiangxi Electric Zeng1, Fan Shi1, Teng Wang1 and Yiping Tang 1, Cao1, Yao 1, Wang1, Hu1 and Feng1; P2.46 Power Company, China. We proposed a new Huang1; 1Shanghai Univ., China. We demon-

1

National Univ. of Defense Tech., China. The MIMO equalization for few-mode fiber error accumulation method based on parallel strated direct oscillation of high order modes August 7 paper analyzed the impact of gain saturation transmission systems, Fangbi Wang1, Jian structure of CMA. The simulation results show in a mode-locking Yb-doped fiber laser, in and pulse distortion on the relative intensity Xu1 and Bo Xu1; 1Univ. of Science and Tech. of that the optimized algorithm can accelerate which a pair of mode-selective couplers act as noise and phase noise of the fiber sensing China, China. The Least Mean Square the convergence speed and reduce the an efficient mode conversion centered time division multiplexing system. algorithm and the Normalized LMS algorithm steady-state MSE and BER. around 1064 nm. are applied to multiple-input multiple-output equalization, and the equalization perfor- P2.50 P2.43 mance of the NLMS is more stable under the Overhead Transmission Line Tensiometer P2.53 Real-time observation of Q-switched same power. It is verified in experiments. on Insulator String Based on Fiber Bragg Electrical degradation behavior in metal mode-locking dynamics in a fiber laser, Grating, Zhehao Yan1, Zhiguo Zhang1, Qin oxide thin film transistor under negative Xiaoyue Wang1, Ming Yan1 and Heping Zeng1; P2.47 Mei2, Xiaoxiao Wang1, Rui Zhou1, Chao Shen2, bias-illumination stress, Youhang Zhou1 and 1East China Normal Univ., China. The build-up Microfiber coupler with a Sagnac loop for Feng Guo2 and Tong Zhai1; 1Beijing Univ. of Jun Li1; 1Shanghai Univ., China. The electrical of a self-started stretched-pulse fiber laser water pollution detection, Lijiao Zu1, Posts and Telecommunications, China; 2Wuxi degradation behavior in metal oxide thin film was experimentally investigated using time- Hongmin Zhang1, Yinping Miao1 and Bin Li1; Power Supply Company, China. This paper transistor (TFT) under negative bias-illumina- stretched dispersive Fourier transform spec- 1Tianjin Univ. of Tech., China. A chloride ion proposes an overhead transmission line tion stress (NBIS) is one of the biggest troscopy. Soliton pulsations were observed in sensor based on a microfiber coupler is tensiometer on insulator string based on fiber obstacles for its applications in flat panel a set of clustered Q-switching bunches in the proposed. Experimental results show that the Bragg grating and cantilever beam. display. turbulent and rapidly-evolving pre-mode- sensitivity reaches a maximum of 423 pm/‰ According to the simulation and experiment, locking states. and that the detection limit for the chloride the tensiometer is suitable for overhead ion concentration is 0.447‰. transmission line breakage warning.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 40

ICOCN 2019—Wednesday, 7 August

Poster Session 2（10:00-10:30）

P2.54 P2.58 P2.61 P2.65 Mode-locked Pulsed Fiber Laser with Study On Connotation of Generalized Massive MIMO Precoding Based On Passively mode-locked Er- and Tm-doped Graphene Solution as Saturable Absorber Aperture Radar Imaging, Wang Tianyun1, Liu Channel Condition Number, Qiaoqiao Zhao1, fiber lasers by microfiber based Bismuth Deposited in Photonic Crystal Fiber, Tan Sin Bing1, Wei Qiang1, Kang Kai1 and Yu Qinghua1; Qi Zhang1, Xiangjun Xin1, Feng Tian1, saturable absorber, Hao Yuan1, Jintao Wang1, Jin1; 1KDU UC, Malaysia. We experimentally 1China Satellite Maritime Tracking and Qinghua Tian1, Ying Tao 2, Yufei Shen2, Hao Chen1, Mengyu Zhang1, Jinde Yin1 and demonstrated mode-locked EDFL using Control Department, China. This paper Guixing Cao2, Bo Zhang2, Yongjun Wang1 and Peiguang Yan1; 1Shenzhen Univ., China. graphene filled in 1.5cm long PCF. Pulse establishes a unified description of radar Leijing Yang1; 1BUPT, China; 2China Academy Ultrafast pulses trains at both 1.5 and 2 μm repetition rate of 11.1MHz and pulse width of imaging. The concept of generalized aperture of Space Tech., China. In order to solve the spectral ranges are generated using the 0.88ps was generated. imaging is presented. The resolution factors interference caused by the instability of the microfiber-based Bi-SA in an erbium-doped are discussed. Generalized aperture imaging channel environment in Massive MIMO to the fiber laser (EDFL) and a thulium-doped fiber P2.55 is applied for three typical radar systems. transmitted signal, it proposes a precoding laser (TDFL), respectively. A Fiber Bragg Grating-based Wind Erosion method based on the channel condition Monitoring System, Yao Zhou1, Zhiguo number. Zhang1 and Limin Cui2; 1BUPT; 2State Grid P2.59 P2.66 Xinjiang Information & Telecommunication Effectiveness Evaluation Model of P2.62 Phase noise estimation for nonlinear fre-

Company, China. This paper proposes a fiber Laser/Microwave Satellite Communication Extended Path-finding RWA Algorithm quency division multiplexing system, Xulun Bragg grating-based wind erosion monitoring System Based on Ambient Fuzzy Operator, Based on ACO in Optical Satellite Network, Zhang1, Zibo Zheng1, Ruihua Yu1, Shucheng system. This system is suitable for long-term Anning Xu1, Qi Zhang1, Xiangjun Xin1, Wei Zhou1 and Qi Zhang1; 1BUPT, China. An Du2, Lixia Xi1 and Xiaoguang Zhang1; 1Beijing measurement in real time in the field. Qinghua Tian1, Feng Tian1, Ying Tao 2, Guixing extended pathfinding routing and wave- Univ. of Posts and Telecommunications, China; Cao2, Dong Chen2, Yongjun Wang1 and length assignment algorithm based on ant 2Beijing Normal Univ., China. For nonlinear P2.56 Leijing Yang1; 1BUPT, China; 2China Academy colony optimization is proposed in order to frequency division multiplexing system, a 2x2 Polarized MIMO Antenna Selection of Space Tech., China. Effectiveness evalua- enhance the global exploratory capability. transmission model in the presence of phase Based on Correlation Coefficients, Lin Hai1 tion model based on ambient fuzzy operator noise was derived, and a blind phase noise and Shifang Dai2; 1NUPT, China; 2Nanjing Univ. is proposed for laser/microwave satellite P2.63 estimation method based on decision direct- of Finance & Economics, China. MIMO system communication system (L/MSCS), in order to 2D materials Saturable absorber integ- ed free technology was exploited and verified. 1 Wednesday, 7 August 7August Wednesday, with zero correlation may perform even less evaluate the effectiveness of L/MSCS more rated on seven-core fiber, Zhuochi Ma , than some actual case. Some pairs of scientifically. Peiguang Yan1 and Jinde Yin1; 1Shenzhen antennas of electric or magnetic antenna Univ., China. We demonstrate a new integ- dipoles are found to achieve better P2.60 ration fiber device for the usage of SA by P2.67 performance because of specific correlation Research on Adaptive Optimal Shaping Gain depositing 2D materials on the side core of a The Nonlinear optical properties of Few- coefficients. Selection MethodBased on Huffman Coding, seven-core fiber (SCF). layer VSe2 nanosheets and their applica- Ziqi Ren1, Qi Zhang1, Xiangjun Xin1, Feng tions for pulsed fiber lasers, Jiaqiang Zhang1, P2.57 Tian1, Qinghua Tian1, Ming Lin2, Yang Wang 3, P2.64 Hao Chen1, Mengyu Zhang1, Hao Yuan1, Jinde Gnss Passive Radar Imaging Based On Yongjun Wang1, Leijing Yang1 and Jinlong Ultra-Broadband and Low Dispersion in Yin1, Jintao Wang1 and Peiguang Yan1; Differential Aperture, Wang Tianyun1, Liu Zhang4; 1BUPT, China; 2Guangdong Univ. of Silicon-As2s3 Slab/slot Waveguides for 1Shenzhen Univ., China. We prepared VSe2 Bing1, Wei Qiang1, Cong Bo1 and Yin Zhiping2; Tech., China; 3China Electric Power Research Supercontinuum Generation, Qiqing Li1, Lan nanoflakes by liquid phase exfoliation. We 1China Satellite Maritime Tracking and Inst., China; 4School of Physics and Electronics Rao1 and Xiaoli Yin1; 1BUPT, China. A novel utilized Z-scan technique to prove its non- Control Department, China; 1Hefei Univ. of Henan Univ., China. In this paper, an adaptive silicon-As2s3 slab/slot waveguide with an linear optical properties and prepared VSe2 Tech., China. Passive imaging with differential optimal shaping gain selection method based ultra-broadband and low dispersion is based saturable absorbers by using vacuum aperture based on multiple GNSS satellites on huffman coding is proposed. proposed. It can be used to generate ultra- filtration technique to achieve mode-locked and receivers is studied. broad supercontinuum. operation.

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ICOCN 2019—Wednesday, 7 August

Poster Session 2（10:00-10:30）

P2.68 P2.71 Polarization Sensitivity of Silicon Integrated LDPC channel coding in ultraviolet Optical Antenna for Laser Communication communication system, Weiwei Wang1, Ping on Small Satellite, Yang Gao1, Jiali Liao2, Jun Su1 and Jianshe Ma1; 1Tsinghua Univ., China. Xu1, Zhanrong Zhou1, Chao Meng1 and We apply Low-Density-Parity-Check code into Zhaoyuan Chen1; 1Xi’an Research Inst. of High ultraviolet communication system. LU Tech., China; 2Xidian Univ., China. An decomposition algorithm is adopted as the integrated optical antenna is proposed for channel coding method. Simulations are laser communication on small satellite. It is condu-cted to compare the performance of demonstrated that the optical antenna is different LDPC decoding algorithm in UV sensitive to polarization angle and convenient communication system. to be installed on the surface of the carrier.

P2.69 P2.72 A Quantization Scheme by Slicing Super- A Unified Form of Common Model Wednesday, August7 continuum Spectrum in an All-Normal Predictive Control Algorithms, Kai Li1; 1China Dispersion Silicon Nitride Ridge Waveguide, Satellite Maritime Tracking and Control Shipei Jing1, Rui Ma1, Kuiru Wang1, Jinhui Department, China. This paper establishes a Yuan 1, Chao Mei1, Binbin Yan 1, Xinzhu Sang1 unified mathematical form for common and Chongxiu Yu1; 1BUPT, China. We propose model predictive control, which provides an all normal dispersion silicon nitride wave- conditions for building a unified forecasting guide for optical quantization. A 6-bit control algorithm simulation platform and quantization resolution is achieved with an other requirements. effective number of bit of 5.978 bit.

P2.70 A widely tunable single longitudinal mode erbium-doped fiber laser based on a microfiber knot resonator, Chaoqun Cai1, Fengkai Han1, Chi Zhang1, Hongdan Wan1 and Zuxing Zhang1; 1NUPT, China. A widely tunable single longitudinal mode erbium- doped fiber laser based on a microfiber knot resonator is proposed. The laser is tuned from 1545 ~ 1565 nm with a high side-mode suppression ratio of 55 dB.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 42

ICOCN 2019—Wednesday, 7 August

Room 2, BSPA-Tracks 2 & 9 Room 3, BSPA-Tracks 3 & 5 Room 5, BSPA-Special 2 Room 6, BSPA-Track 7

10:30-12:00 10:30-12:00 10:30-12:00 10:30-12:00 W2A • BSPA-Tracks 2 & 9 W2B • BSPA- Tracks 3 & 5 W2C • Machine learning II (BSPA) W2D • Ultrafast & nonlinear optics III Presider: Jiangbing Du, Shanghai Jiao Presider: Shilong Pan, Nanjing Univ. of Presider: Weiwen Zou, Shanghai Jiao (BSPA) Tong Univ., China Aeronautics & Astronautics, China Tong Univ., China Presider: Luming Zhao, Jiangsu Normal Univ., China

☼W2A.1 • 10:30 ☼W2B.1 • 10:30 W2C.1 • 10:30 Invited ☼W2D.1 • 10:30 A PolDemux scheme using extended Kal- Optical Back Propagation using Raman A VNF Deployment Method based All-fiber Passively Mode-locked Femto- man filter in probabilistic shaping stokes Pumped Dispersion Compensating Fibers, on DRL in IP over EON Networks, second Laser Based on a Femtosecond vector direct detection system, Xue Li1, Elham Bidaki1 and Shiva Kumar1; 1McMaster Bin Chen1; 1Shenzhen Univ., China. Laser Inscribed 45° Tilted Fiber Grating, Qisong Shang1, Zibo Zheng1, Nan Cui1, Univ., Canada. An optical back propagation The virtual network function (VNF) Zinan Huang1, Qianqian Huang1, Antreas Xiaoguang Zhang1, Nannan Zhang1, Wenbo (OBP) technique using Raman pumped combined with the elastic optical Theodosiou2, Kyriacos Kalli2 and Chengbo Zhang1 and Lixia Xi1; 1Beijing Univ. of Posts dispersion compensation fibers (DCF) is network (EON) can significantly improve the Mou1; 1Shanghai Univ., China; 2Cyprus Univ. of and Tele., China. We propose a Kalman filter investigated to compensate for nonlinear network flexibility and reduce the operating Tech., Cyprus. A femtosecond erbium-doped based PolDemux scheme to cope with impairments in WDM systems in real time. expenses. In this work, we propose a VNF fiber laser using a 45° tilted fiber grating probabilistic shaped 16QAM signals in Stokes deployment method in IP over EON based on fabricated by direct femtosecond laser vector direct detection system. It can track the deep reinforcement learning (DRL). inscription is experimentally demonstrated. SOP variation up to 2Mrad/s at a relative The laser generates stable short pulses with lower OSNR. pulse width of 752 fs at 1562 nm.

☼W2A.2 • 10:45 ☼W2B.2 • 10:45 ☼W2D.2 • 10:45 A Traffic-Balanced and Thermal-Fault Tole- Multi-path based Quasi-real-time Quantum Performance of Bi-Directional Mode- rant Routing Algorithm for Optical Netwo- Key Distribution in Software Defined Quan- Locked Fiber Laser at 2μm, Yiming Li1, Ke rk-on-Chip, Lijing Zhu1 and Huaxi Gu1; 1Xidian tum Key Distribution Networks (SD-QKDN), Yin2, Qinghui Deng1 and Xin Zhang1; Wednesday, 7 August 7August Wednesday, Univ., China. TBTFTA is proposed for optical Xiang Liu1, Xiaosong Yu1, Yongli Zhao1, 1National Univ. of Defense Tech., China; network-on-chip to relieve nonuniform adap- Xiaotian Zhou2, Shimulin Xie3 and Jie Zhang1; 2Military academy, China. We demonstrate a tiveness and thermal-fault problem, which 1BUPT, China; 2Science and Tech. on bidirectional mode-locked laser with SWNT considers traffic and temperature information Communication Networks Lab., China; 3State as the saturable absorber. By manipulating simultaneously. It can handle the congestion Grid Info-Telecom Great Power Sci. and Tech. the polarization controller and pump power ， and thermal-faulty nodes by designed path Co., LTD., China. We propose a multi-path shortening the cavity length, we obtain three selection strategy. based quasi-real-time quantum key distribu- different repetition frequencies and adju- tion scheme in software defined quantum key stable repetition rate differences. distribution networks (SD-QKDN). Simulation results show the proposed scheme performs well in terms of service successful probability and secret-key utilization.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 43

ICOCN 2019—Wednesday, 7 August

Room 7, BSPA-Track 1 Room 8, BSPA-Track 6 Room 10, BSPA-Track 4 Room 11, Special 1 Room 12, Track 10

10:30-12:00 10:30-12:00 10:30-12:00 10:30-12:00 10:30-12:00 W2E • Novel fibers & devices III W2F • Optical measurement IV W2G • Optoelectronics III W2H • Organic & nano W2I • Quantum photonics IV (BSPA) (BSPA) (BSPA) optoelectronics IV Presider: Qiang Lin, Zhejiang Presider: Guanshi Qin, Jilin Univ., Presider: Xuping Zhang, Nanjing Presider: Jianji Dong, Huazhong Presider: Daiwen Pang, Nankai Univ. of Tech., China Univ. of Sci. & Tech., China China Univ., China Univ. Wuhan, Univ., China.

W2E.1 • 10:30 Invited ☼W2F.1 • 10:30 ☼W2G.1 • 10:30 W2H.1 • 10:30 Invited W2I.1 • 10:30 Invited Ultralow loss and high Bipolar coding for phase-demodu- Polarization-insensitive Waveguide Towards high-performa- Measurement of human- strength splicing betw- lated Φ-OTDR with coherent Cros-sings Based on SWGs-assi- nce light-emitting diodes body magnetic field by een conventional fibers detection, Yue Wu 1, Zinan Wang1, Ji sted MMI, Sailong Wu1, Xin Mu1, based on quantum dots, the interaction between and large mode area Xiong1 and Yunjiang Rao1; 1Univ. of Lirong Cheng1, Xin Tu2 and H.Y. Fu1; Yizheng Jin1; 1Zhejiang light and atoms, Qiang photonic crystal fibers, Sci. and Tech. of China. The bipolar 1Tsinghua Univ., China; 2China Univ. Univ., China. Here we Lin1; 1Zhejiang Univ. of Limin Xiao1; 1Fudan Univ., China. A code is successfully employed in of Geosciences, China. Polariz-ation- review our activities associated with Tech., China. The weak magnetic novel approach for ultralow-loss and phase-demodulated Φ-OTDR utilize- insensitive waveguide crossings quantum-dot light-emit-ting didoes fields produced by human body high-strength splicing between con- ing heterodyne detection. Compa- based on SWGs-assisted MMI are (QLEDs), including material chemi- contain a wealth of physiological and ventional single mode fibers (SMFs) red with unipolar scenario, the supe- proposed. Insertion loss of 0.69 (0.61) stry of charge-transporting layers pathological information. Two

and large mode area photonic crystal rior performance is demonstrated in dB and crosstalk below -45 (-35) dB and optimization and mechanism kinds of optically pumped atomic Wednesday, August7 fibers (LMA-PCFs) is demonstrated. 10 km sensing experiment with dou- for TE (TM) polarization at 1550nm studies of prototype devices. magnetometers to detect the bled response bandwidth for pertur- are achieved with 12.5um×12.5um cardiac and brain magnetic fields bation and pico-strain resolution. footprint. were reported in this talk.

☼W2F.2 • 10:45 ☼W2G.2 • 10:45 Triple Closed-Loop Resonant Fiber Graphene-based Hybrid Plasmonic Optic Gyroscope, Junyu Tu1, Modulator with High Modulation Hanzhao Li1, Sen Ye1 and Huilian Ma1; Efficiency, Jianyao Jiao1 and Ran

1Zhejiang Univ., China. "To improve Hao1; 1Zhejiang Univ., China. We the reciprocity of the signal proposed a graphene-based hybrid processing systems, a triple closed- plasmonic modulator (GHPM) with a loop resonant fiber optic gyroscope simulated modulation efficiency of is proposed. Enhanced long-term 0.417 dB/μm. The measurement and thermal bias stability is results demonstrate that the GHPM successfully demonstrated thanks to can work in a broadband from 1530 the reciprocal configuration." nm to 1570 nm.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 44

ICOCN 2019—Wednesday, 7 August

Room 2, BSPA-Tracks 2 & 9 Room 3, BSPA-Tracks 3 & 5 Room 5, BSPA-Special 2 Room 6, BSPA-Track 7

☼W2A.3 • 11:00 ☼W2B.3 • 11:00 ☼W2C.2 • 11:00 ☼W2D.3 • 11:00 Machine Learning Scheme for Geometri- Joint optimization of amplitude shifting and Post Equalization Scheme Based on Deep All few-mode fiber passively mode-locked cally-shaped Constellation Classification uti- clipping for KK receiver, Jie Bai1, Long Neural Network for a Probabilistic Shaping figure-8 cavity laser, Yang Xu 1, Da Wang1, Su lizing Support Vector Machine in Multiaccess sheng Li1, Yan Fu1, Haiyun Xin1, Xin Miao1 and 128 QAM DFT-S OFDM Signal in Under- Chen1 and Zuxing Zhang1; 1Nanjing Univ. of Internet of Vehicle Lighting, Wenqing Niu1, Weisheng Hu1; 1Shanghai Jiao Tong Univ., water Visible Light Communication System, Posts and Telecomm-unications, China. We Yinaer Ha1 and Nan Chi1; 1Fudan Univ., China. China. To minimize the devastating zero-by Yinaer Ha1, Wenqing Niu1 and Nan Chi1; demonstrate an all few-mode fiber passively We propose a multiaccess Internet of Vehicles noise effect of KK receiver, amplitude shifting 1Fudan Univ., China. We demonstrated a data mode-locked figure-8 cavity laser. The hand- scheme based on multi-band DFTS-OFDM and clipping are coordinated with optimal rate of 1.74Gbit/s PS128QAM DFT-s-OFDM made mode division multiplexing-mode VLC system. With the bandwidth of 62.5MHz, configu-ration. And it improves 3-dB modulation based on DNN post equalization selective coupler makes it possible for LP11 the dynamic range was enhanced 1.6dBm sensitivity at 6-dB CSPR for 112-Gbps QAM16 in Underwater VLC system. The proposed mode at 980 nm to be used as pump light employing SVM in Geometrically-shaped signal after 80-km SSMF. method increases the data rate by 90 Mbps source. 16QAM and overall capacity is 250Mbps. while capacity is increased by 5.4%.

☼W2A.4 • 11:15 ☼W2B.4 • 11:15 ☼W2C.3 • 11:15 ☼W2D.4 • 11:15 Two-way Optical Phase Comparison at 10- Characteristics of 1×2 Silicon Wavelength Calibration of a 2×2 Optical Switch Based on Microfiber Controlled Wavelength-tunable 21 Level over 200km fiber link, Zang Qi1, Selective Switch Using Arrayed-Waveguide the Back-Propagation Artificial Neural Mode-locked Erbium-Doped Fiber Laser Deng Xue1, Jiao Dongdong1, Liu Jie1, Zhang Gratings with Fold-Back Waveguides, Fumi Network, Wei Gao1, Liangjun Lu1, Linjie Zhou1 using Carbon Nanotube Polymer Film, Xiang1, Gao Jing1, Wang Dan1 and Liu Tao 1; Nakamura1, Hideaki Asakura1, Keijiro Suzuki2, and Jianping Chen1; 1Shanghai Jiao Tong Lilong Dai1, Qianqian Huang1, Zinan Huang1, 1National Time Service Center, CAS, China. Ken Tanizaawa3, Minoru Ohtsuka2, Nobuyuki Univ., China. We calibrate 2×2 optical switch Chuanhang Zou1, Yuanda Ling1 and Chengbo

Wednesday, 7 August 7August Wednesday, This works demonstrates an improved local Yokoyama2, Kazuyuki Matumaro2, Miyoshi based on a BP-ANN to the cross or bar state Mou1; 1Shanghai Univ., China. We demon- two-way optical phase comparison method Seki2, Kazuhiro Ikeda2, Shu Namiki2, Hitoshi at any operating wavelength in an FSR. It can strated a wavelength-tunable passively mode- without the requirement of synchronization Kawashima2 and Hiroyuki Tsuda1; 1Keio Univ., be adopted for calibration of switch elements locked erbium-doped fiber laser based on over 200km fiber links. The frequency stability Japan; 2Tokyo Inst. of Tech., Japan; in large-scale switch fabrics. carbon nanotube and intermodal interference reaches E-21 level. 3Tamagawa Univ., Japan. We report charac- of the microfiber. Continuously tuning range teristics of 200 GHz-spaced 20-channel 1×2 from 1569.6 nm to 1561.57 nm is achieved wavelength selective switch using single under single pulse operation. arrayed-waveguide grating with fold-back waveguides. The average insertion loss is 29.6 dB and the average extinction ratio is 10.9 dB.

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☼W2E.2 • 11:00 ☼W2F.3 • 11:00 ☼W2G.3 • 11:00 W2H.2 • 11:00 Invited W2I.2 • 11:00 Invited Fabrication and sensing character- New Interpolation Method for A novel polarization-insensitive High-efficiency Perovs- Bloch-Siegert Shift and ristics of 2 μm long period fiber Shape Sensors based on Fiber optical fil-ter on silicon, Dajian Liu1 kite Light Emitting Exotic fluorescence grating written in double cladding Bragg Grating, Jingying Wu1, Jing and Daoxin Dai1; 1Zhejiang Univ., Diodes, Baoquan Sun1, spectrum of a strongly fiber by CO2 laser, Lu Huang1, Chen Xu1, Yang Qiu 2, Yezhou Wu1 and Bing China. A silicon-based pola-rization- Yeshu Tan1, Tao Song1 and driven two-level system, Jiang1, Xinyi Zhao1 and Yunqi Liu1; Sun3; 1Zhejiang Univ., China; insensitive optical filter is designed Muyang Ban1; 1Soochow Hang Zheng1; 1Shanghai 1Shanghai Univ., China. We demon- 2Southwest Univ. for Nationalities, and demonstrated by using dual Univ., China. The OHP crystallite Jiao Tong Univ., China. strate the fabrication of long-period China; 3Nanjing Univ. of Posts and multim-ode-waveguide-gratings. distribution and phase separation fiber gratings (LPFGs) in double Telecomm-unications, China. New For the ~300μm-long device, the can be precisely contro-lled by cladding fiber in mid-infrared wave- interop-lation for shape sensors 3dB-bandwidth is ~11nm and the adding a molecule that sup-presses length. The experimental results based on fiber bragg grating (FBG) is excess loss is ~1.5dB for both crystallization of the organic phase. show that the LPFGs with a proposed. Spline interpolation is polarizations. We achieve OHP light-emitting resonance dip in mid-infrared wave- employed to characterize relation- diodes with an external quantum length have much higher sensitivity. ship between curvature and arc efficiency of 15.5%. length. Experiment results show that spline interpolation induces lower Wednesday, August7 error than linear interpolation.

☼W2E.3 • 11:15 ☼W2F.4 • 11:15 ☼W2G.4 • 11:15 CO2-laser written helical long- 100 MHz Reconfigurable Ultrafast A Compact Adiabatic Silicon period gratings with resonance at Swept Source by Time Stretching of Photonic Edge Coupler Based on second-order diffraction, Cheng 100 nm Flat-top Spectrum, Silicon Nitride/Silicon Trident cheng Xu1, Yunqi Liu1, Chen Jiang1 Dongmei Huang1, Feng Li1, Chao Structure, Xin Mu1, Sailong Wu1, and Tingyun Wang1; 1Shanghai Univ., Shang1, Zihao Cheng1 and P. K. A. Lirong Cheng1, Xin Tu2 and H.Y. Fu1;

China. We demonstrate the fabric- Wai1; 1The Hong Kong Polytechnic 1Tsinghua Univ., China; 2China Univ. ation of helical long-period gratings Univ. Shenzhen Research Inst., China. of Geosciences, China. We firstly with resonance at second-order diff- In this paper, we report an ultrafast propose an adiabatic fiber-to-chip raction for the first time. The torsion, time stretching swept source with up edge coupler based on a silicon temperature and bending sensing to 100 MHz repetition rate and 100 nitride/silicon trident structure. It characteristics are investigated nm flattop spectrum. The repetition achieves up to 81% efficiency in an experimentally. rate can be reconfigured by ultra-broad bandwidth and enables incorporating with an optical adiabatic mode conversion with a 80- modulator. um length.

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☼W2A.5 • 11:30 ☼W2B.5 • 11:30 W2C.4 • 11:30 ☼W2D.5 • 11:30 Characterization of a MOPA system used for DNN-Based Channel Estimation for Non- Two methods of accurate indoor positioning Monolithic Linearly Polarized Nanosecond underwater optical communication, Chao linear Impairments-Aware RMSA Algorithm, based on visible light communication system Fiber Laser with Record Peak Power and Zhang1, Xiao Chen1, Yang Qiu 2, Amjad Ali1 Lin Guan1, Hui Yang1, Ao Yu1, Zhen Xu1, and artificial neural network, Shencheng Ni1, Near-Transform-Limited Linewidth, Long and Jing Xu1; 1Zhejiang Univ., China; Qiuyan Yao1 and Jie Zhang1; 1BUPT, China. Feng Wang1, Shuying Han1, Jie Pang1 and Huang1, Wenchang Lai1, Rongtao Su1, Pengfei 2Southwest Univ. for Nationalities, China. We Considering nonli-near impairments in EON, Shanhong You1; 1Soochow Univ., China. We Ma1, Man Jiang1, Jian Wu1, Yanxing Ma1 and theoretically simulate the large-signal we use DNN to conduct channel estimation, proposed two methods based on ANN and Pu Zhou1; 1National Univ. of Defense Univ., modeling of the amplified laser light and the then proposed a modified RMSA algorithm VLC to realize accurate indoor positioning. China. An all-fiberized linearly polarized frequency response of a MOPA system and by clustering and guard-band redistribution, The average positioning error of two methods nanosecond fiber laser with record peak chose Manchester Encoding to modulate the which reduces net-work congestion and are 3.29cm and 2.78cm, respectively, and over power and near-transfrom-limited linewidth is amplified 1064-nm laser light to achieved 100- improves spectrum utili-zeeation while 90% of the results are under 5cm. demonstrated based on master oscillator Mbps transmission. ensuring transmission accuracy. power amplifier structure.

☼W2A.6 • 11:45 W2B.6 • 11:45

Underwater wireless-to-plastic optical fiber THz-wave Signal Generation based on communication systems with a passive front Optical Frequency Comb by One Single- end, Amjad Ali Amjad1, Chao Zhang2, Syed Drive MZM, Kaile Li1, Yongtao Huang1, Yitong Agha Hassnain Mohsan1, Weichao Lyu2, Riffat Li1, Jie Ma1, Yuanxiang Chen1, Xinguo Li2 and Tehseen1, Xiao Chen2 and Jing Xu2; 1Zhejiang Jianguo Yu1; 1BUPT, China; 2Wuhan Accelink Univ., Pakistan; 2Zhejiang Univ., China. We Tech. Co. Ltd., China. We propose a novel experimentally demonstrate underwater Terahertz-wave (THz-wave) signal generation wireless-to-plastic optical fiber communica- based on optical frequency comb by only one tion system with a fully passive optical lens single-drive MZM in 0.4 THz band by installed at the front end of the POF. A high simulation. Bit-error-ratio (BER) curves of the Wednesday, 7 August 7August Wednesday, coupling efficiency of 88% was measured. QPSK and 16QAM signal proved feasible.

☼W2A.7 • 12:00 Chaotic discrete cosine transform for phy- sical-layer data encryption in OFDM-PON, Liuming Zhang1, Adnan Hajomer1, Zanwei Shen1 and Xuelin Yang1; 1Shanghai Jiao Tong Univ., China. Chaotic discrete cosine trans- form is proposed to enhance both the phy- sical-layer security and the transmitssion per- formance in OFDM-PON. Secure transmission of 13.3Gb/s OFDM signals shows a ~1.5 dB (BER@10-3) improvement in receiver sensitivity.

12:00-13:30 Lunch Break, Violet Hall (紫罗兰餐厅), 3F

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☼W2E.4 • 11:30 ☼W2F.5 • 11:30 ☼W2G.5 • 11:30 W2H.3 • 11:30 Invited W2I.3 • 11:30 Invited Suppressing the Influence of CCD In vivo and online temperature mo- On-demand design of nanopho- The commercialization of Comprehensive search Vertical Blooming on M^2 Deter- nitoring based on fiber Bragg gra- tonic gratings using recurrent QLEDs：from materials， for topolo-gical materials mination through Deep Learning, tings during tumor treatment with neural networks, Beihua Fang1, devices to inkjet printing using symmetry Yi An1, Liangjin Huang1, Jun Li1, nanosecond pulse electric field, Yuanfu Lu1, Linfeng Yang1 and manufa-cturing, Lei Qian1; indicators, Xiangang Wan1; Jinyong Leng1, Lijia Yang1 and Pu Tianheng Lu1, Guofeng Yan2, Chun Guangyuan Li1; 1Shenzhen Inst. of 1TCL, China. We are devo- 1Nanjing Univ., China. Zhou1; 1National Univ. of Defense zhou Wu1, Siqi Hu1 and Xinhua Chen1; Advanced Tech., Chinese Academy ted to developing the top notch Tech., China. In this paper, a new 1Zhejiang Univ., China; 2 Zhejiang Lab, of Sciences, China. We report on- protocols and know-hows for inkjet scheme based on deep learning to China. A FBG sensing system was demand design of photonic gratings printed displays using quantum dots suppress the influence of CCD proposed and demonstrate to online using a recurrent neural network. By based light emitting devices(QLED). vertical blooming on M^2 deter- monitor the temperature at the using a long and short term memory The ultimate goal of our efforts is to mination is proposed for the first surface of / inside the liver tissue of a neural network model, we show that facilitate the process of commercial time, which is of high accuracy and rabbit under nanosecond pulse a nanophotonic grating can be desi- applications. real-time ability. electric field. gned with predesignated responses.

☼W2E.5 • 11:45 W2F.6 • 11:45 ☼W2G.6 • 11:45 Anti-resonant reflecting effect in Optical Sensors Based on Nano- Ultra-broadband Reflector based Wednesday, August7 large-core hollow-core photonic composite Film, Xiaobo Xing1, on Subwavelength All-Dielectric crystal fiber for temperature sen- Sheng Xue1 and Mingyu Chen1; Grating, Xingzhe Shi1, Yuanfu Lu1, sing, Yu Zheng1, Ping Shum1, Shuhui 1South China Normal Univ., China. Changshui Chen2, Songhao Liu2 and Liu2, Wenjun Ni3, Yiyang Luo1, We report an optical humidity sensor Guangyuan Li1; 1Shenzhen Inst.s of Zhifang Wu4, Xuan Quyen Dinh1, and an optical formaldehyde sensor Advanced Tech., Chinese Academy Jean-Louis Auguste5 and Georges based on nanocomposite films. of Sciences, China; 2South China Humbert5; 1Nanyang Tech. Univ., Normal Univ., China. We report the Singapore; 2Wuhan Inst. of Tech., design an ultra-broadband highly 3 China; Nanyang Tech. Univ., China; reflective subwavelength grating 4Huaqiao Univ., China; 5XLIM Resear- that covers almost the entire visible ch Inst., France. Optical fiber sensors region. Results show that high reflec- based on anti-resonant reflecting tivity above 90% covering 450–700 effect have attracted widespread nm can be achieved, corresponding attention in recent years. A compact to Δλ/λ=43%. and robust all-fiber device is pro- posed and developed based on anti- resonant reflecting effect.

12:00-13:30 Lunch Break, Violet Hall (紫罗兰餐厅), 3F

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13:30-15:30 13:30-15:30 13:30-15:30 13:30-15:30 W3A • Optical transmission III W3B • Optical signal processing W3C • 2D-materials photonics III W3D • Supercomtinuum sources I Presider: Hui Yang, BUPT., China Presider: Shiming Gao, Zhejiang Univ., China Presider: Kan Wu, Shanghai Jiao Tong Presider: Shengping Chen, National Univ. Univ., China of Defense Tech., China

W3A.1 • 13:30 Invited W3B.1 • 13:30 Invited W3C.1 • 13:30 Invited W3D.1 • 13:30 Invited Recent developments on high- Field programmable silicon temporal Chalcogenide glass on two- Progress in Mid-Infrared Super- capacity SDM systems using cloak for data shield, Jianji Dong1, Feng dimensional materials photonics, Continuum Generation in Chalco- deployable fibers, Ruben Zhou1 and Xinliang Zhang1; 1Huazhong Hongtao Lin1; 1Zhejiang Univ., genide Glass Fibers, Shixun Dai1; Soares Luis1, Georg Radema- 1Univ. of Sci. and Tech., China. We China. Photonic integration with 2- 1Ningbo Univ., China. Chalcoge- cher1, Benjamin Puttnam1, demonstrate a field-programmable tem- D materials conventionally relied nide glasses have the advent-ages Yoshinari Awaji1 and Naoya Wada1; 1NICT, poral cloak with potential applications in data shield, on transfer processes. We developed an of a wide transparency window and high Japan. We review recent works on the use enabling to share some public data to the user but approach to monolithically fabricate pho- optical non-linearity, making them good of high-capacity SDM systems using conceal other private data in real time. tonic devices on 2-D materials including candidates for mid-infrared super-continuum single/few-mode multi-core fibers with graphene and demonstrated its significant generation. We describe both the history and physical properties capable of withstanding potential for high-performance photonic recent developments in mid-infrared super- deployment. We specifically address the integration. continuum generation from chalk-ogenide crosstalk impact and the spectral efficiency fibers according to three kinds of fiber struc- of such systems. tures: step-index, microstructured and taper- ed fibers. We also review the coherence properties of mid-infrared supercontinuum day, 7August generation and all-fiber supercontinuum sources based on chalcogenide fibers.

Wednes W3A.2 • 14:00 Invited W3B.2 • 14:00 Invited W3C.2 • 14:00 Invited W3D.2 • 14:00 Invited Low Power Consumption SDM Distributed coherent signal gene-ration Observation of ballistic avalan- Large energy pulse generation in Technologies using Multi-core and processing, Shangyuan Li1 and che phenomena in nanoscale fiber lasers by new-designed satu- Amplifier, Keiichi Matsumoto1, Xiaoping Zheng1; 1Tsinghua Univ., China. vertical InSe/B Pheterostru- rable absorbers, Peiguang Yan1; Hitoshi Takeshita1, Shigeyuki Since microwave photonics radar ctures, Xiaomu Wang1; 1Nanjing 1Shenzhen Univ., China. We summa- Yanagimachi1 and Emmanuel Le provides many attractive features for Univ., China. Here we report the rized a new type of saturable absor- Taillandier de Gabory1; 1NEC Corp., Japan. traditional radars technology, distributed coherent observation of ballistic avalanche pheno- bers fabricated by the magnetron sputtering We report low power consumption multi- signal generation and processing using microwave mena in sub-mean free path (MFP) scaled deposition method and achieved stable high- core amplifiers. The study focuses on power photonics are more promisingly and probably vertical InSe/black phosphorus (BP) hetero- energy soliton pulse generation at 1.5, and 2.0 efficient use of both cladding and core adopted by distributed coherent aperture radar in structures. The devices show a low μm waveband by using the SAs, respectively. pumping, emphasizing on the system the future. avalanche threshold (<1 volt), low noise design and the benefits for SDM techno- figure and distinctive density spectral shape. logies.

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13:30-15:30 13:30-15:30 13:30-15:30 13:30-15:30 13:30-15:30 W3E • Novel fibers & devices IV W3F • Optical measurement V W3G • Optoelectronics IV W3H • Organic & nano W3I • Quantum photonics V Presider: Li Pei, Beijing Jiaotong Presider: Limin Xiao, Fudan Univ., Presider: Jin Wang, NUPT, China optoelectronics V Presider: Hang Zheng, Shanghai Univ., China China Presider: Pavel Brunkov, Ioffe Jiao Tong Univ., China.

Inst., Russia

W3E.1 • 13:30 Invited W3F.1 • 13:30 Invited W3G.1 • 13:30 Invited W3H.1 • 13:30 Invited W3I.1 • 13:30 Invited Single polarization hollow Measurement of vibra- Progress of energy effi- Printing electrolumines- Quantum simulation in core fiber and device, tion and dynamic defle- cient photonic integrated cent materials and display, superconducting quan- Shuqin Lou1; 1Beijing ction of a bridge span lasers, Shinji Matsuo1; Junbiao Peng1; 1South tum circuits, Heng Fan1; Jiaotong Univ., China. with optical fiber sensors, 1NTT Device Innovation China Univ. of Tech., China. 1Inst. of Physics, Chinese Xiaopeng Dong1, Yunqing Center, Japan. A matrix OLED display Academy of Sci., China. Guan1 and Mengnan Lu1; 1Xiamen with high resolution was fabricated Univ., China. Real-time on-line by using electrohy-drodynamic prin- detection of the characteristics of ting method. The inks were based on bridge span is important in its struc- poly (dibenzothiophene-S, S-dioxi-

ture health monitoring. We present de-co-9,9-dioctyl-2,7-fluorene) (PPF- Wednesday, August7 novel methods for the bridge SO) and its derivatives, quantum deflection and vibration frequency dots. A mono-color passive matrix detection with fiber strain sensors display with resolution over 2000 PPI and source. was realized.

W3E.2 • 14:00 Invited W3F.2 • 14:00 Invited W3G.2 • 14:00 Invited W3H.2 • 14:00 Invited W3I.2 • 14:00 Invited Helical Long-Period Fiber Fiber optofluidic laser and FPGA Investigation on OLED materials made in Echo-Ramsey Interfero- Gratings: Fabrication and its applications in bioassay, Error Floor Characteris- China--trial and metry with Atomic Quan- Applications, Yunqi Liu1; Yuan Gong1; 1Univ. of tics of LDPC Convolu- tribulation, Fred Chen1; tum Motional States, 1Shanghai Univ., China. We Science and Tech. of China, tional Codes for Optical 1Shanghai Taoe Chemical Xiaoji Zhou, Beijing Univ., demonstrate the fabrica- China. Optofluidic laser is Fiber Communications, Yi Tech., China. China. tion of helical long-period gratings an emerging techno-logical platform Cai1; 1ZTE Optics Lab, USA. (HLPGs) by using focused carbon for biochemical detection. In this Employing FPGA emulations, we dioxide laser. The HLPGs could have presentation the recent advances in investigate effects of code length, promising application as all fiber fiber optofluidic laser and its applica- girth, decoding buffer size on the mode converters for mode-division- tions in bioassay will be included. error floor characteristics of LDPC multiplexing optical communica- convolutional codes. We investigate tionns and high sensitivity optical concatenation schemes for error sensors. floor suppression.

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W3A.3 • 14:30 Invited W3B.3 • 14:30 W3C.3 • 14:30 Invited W3D.3 • 14:30 Invited High-capacity optical transmit- Research of all-optical broadcast UWB pulse Infrared emitters and photode- 100W level ultrafast fiber laser ssion based on silicon photonics, shape modulation signals based on semicon- tectors based on two-dimen- and supercontinuum source with Xi Xiao1, Lei Wang1, Bo Zhang2, Di ductor fiber ring lase, Zanshan Zhao1; 1Inst. of sional materials, Yaqing Bie1; 1Sun their applications in industrial, Zhang2, Xiang Li1, Ming Luo1 and Acoustics, CAS, China. A scheme for all-optical Yat-sen Univ., China. I will talk Weijia Yang1; 1YSL Photonics, Shaohua Yu1; 1Wuhan Research generate UWB PSM signals based on SFRL is about 2D emitters/detectors cou- China. Current ultrafast fiber laser Inst. of Posts and Tele., China; 2Accelink proposed. It shows that the perfor-mance of PSM pled with silicon photonic cavities and systems provide single pulse energy of over Tech. CO., LTD., China. Silicon photonic signals within the UWB regulation. waveguides. The van der Waals interaction 200 microjoules and burst pulse energy of

transmitters and receivers developed for W3B.4 • 14:45 at the interface minimizes the introduction over 500 microjoules with pulse widths of the next-generation optical trans-missions Photonics-based receiver for decoupled velocity of surface defects and provides new approximately 300fs to 10ps adjustable, are present, with the speed of 64Gbaud/s and range measurement, Jiewen Ding1, Dan Zhu1, opportunities for integrated optoelectronic which allows effective micromachining of the and beyond. Pb/s transmission over 19-core Bowen Zhang1, Wenjuan Chen1 and Shilong Pan1; systems. most material with high effici-ency. Average single mode fiber is also demonstrated with 1Nanjing Univ. of Aeronautics and Astronautics, power of these systems is scalable up to the above devices. China. Photonics-based radar receiver for decoupled 100W allowing for very high speed material target velocity and range measurement is proposed. micromachinging. The frequency components corresponding to the tar- get range and velocity are obtained simultaneously.

W3A.4 • 15:00 Invited W3B.5 • 15:00 W3C.4 • 15:00 Invited W3D.4 • 15:00 Invited Probabilistically shaped 100G The Power-dependent Phase Change in a Low-bias The third-order nonlinear optics Mid-infrared super-continuum IM-DD optical interconnection, High-speed Modified Uni-traveling Carrier of two-dimensional topological generation in the soft-glass 1 1 Jiangbing Du1, Lin Sun1 and Photodetector, Dan Yang , Yongqing Huang , Tao insulators, Chujun Zhao1; 1Hunan micro-structured optical fibers, 1 1 1 1 Zuyuan He1; 1Shanghai Jiao Tong Liu , Xiaofeng Duan , Kai Liu and Xiaomin Ren ; Univ., China. The broadband Tonglei Cheng1; 1Northeastern 1 Univ., China. In this paper, we Beijing Univ. of Posts and Telecommunication, China. nonlinear absorption behavior Univ., China. Soft-glass microstru- present a review about our recent works of The characterization of the phase change of 60-GHz and application in broadband pulsed laser ctured optical fibers include fluoride, tellu-

Wednesday, 7 August 7August Wednesday, probabilistic shaping for optical inter- sinusoidal in the modified uni-traveling carrier generation with topological insulator has rite, and chalcogenide MOFs, which present connection applications. PS for PAM and photodetector is reported. The absolute phase been investigated. In addition, the strong a wider transparency window in the mid- DMT were introduced for achieving 100- change is observed smallest when the differential Kerr nonlinearity from the topological infrared region. They are good candidates capacitance equals to zero. Gbps over IM-DD VCSEL-MMF optical material has been extracted by different for MIR supercontinuum generation. interconnection link. W3B.6 • 15:15 methods. Optical-injection-seeded Optical Frequency Comb Generation Promoted by the Sub-harmonic Modu- lation, Mingfei Ge1, Yali Zhang1, Yuan Xia1, Zhiyao Zhang1, Shangjian Zhang1 and Yongliu Liu1; 1Univ. of Science and Tech. of China, China. We propose and verify an optical-injection-seeded optical frequency comb generation scheme promoted by sub- harmonic modulation, An optical frequency combs with 17 comb lines is obtained in a flatness of 2.3dB.

15:30-16:00 Poster Session 3 & Coffee Break, 4F

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Room 7, Track 1 Room 8, Track 6 Room 10, Track 4 Room 11, Special 1 Room 12, Track 10

W3E.3 • 14:30 Invited W3F.3 • 14:30 Invited W3G.3 • 14:30 Invited W3H.3 • 14:30 Invited W3I.3 • 14:30 Invited Expanded Jones model Optical Fiber Sensing A novel structure for AC Improvement of efficien- Quantum networks based to describe arbitrary spa- System for Safe Mainte- driven electrolumines- cy and efficiency roll off in on cold atomic ensemble tial states with a single nance and Early Warning cent displays: methods white OLEDs, Dongge and narrowband Photons, azimuthal order in fiber, of High-Speed Train Rail- and applications, Hong Ma1; 1South China Univ. of Hui Yan 1; 1South China Baiwei Mao1, Hongwei way Based on optical Meng1; 1Peking Univ. Tech.. Normal Univ., China. Quan- Zhang1 and Yange Liu1; 1Nankai Univ., Spectrum Calibration, Tigang Ning1 Shenzhen Graduate School, China. tum networks play a key role in China. An expanded Jones complex and Jian Xu1; 1Beijing Jiaotong Univ., ACEL displays basing on a novel quantum communication, quantum space model to describe arbitrary China. We developed an novel structure. Multifunctional ACEL dis- computation and quantum simula- higher-order spatial states in a optical fiber security system based plays using a polar-electrode-bridge tion. Quantum information is gene- particular order in fiber is proposed on optical sensing technology, which instead of expensive transparent rated, processed and stored within and demonstrated. is able to overcome the shortcom- electrodes were demonstrated and quantum nodes and transferred by ings of traditional technology. Com- attractive applications such as opti- flying qubits between different quan- bined with video recognition techno- cally monitored sensors, light emit- tum nodes. The cold atomic ense- logy, effectiveness of video monitor ting graphics tablets were achieved. mble and photons are selected to build the quantum networks. system is greatly increased. Wednesday, August7

W3H.4 • 15:00 W3I.4 • 15:00 Invited W3E.4 • 15:00 Invited W3F.4 • 15:00 Invited W3G.4 • 15:00 Invited Inkjet-printed large-area perovskite Quantum entanglement High power fiber lasers: Fiber optic Fabry-Perot Co-Integrated optoelect- solar cells, Yiqiang Zhang1, Yanling with photonic orbital an- key components, digital interferometers for single ronics for millimeter-wave Song2; 1Zhengzhou Univ., China; 2Inst. gular momentum, Xi-Lin design and recent prog- /multi-point relative humi- frequency radio-over-fiber, of Chemistry, CAS, China. Research Wang1; 1Nanjing Univ., ress, Pu Zhou1; 1National dity and temperature Xin (Scott) Yin1; 1Ghent on the large-area perovskite solar China. I will focus on Univ. of Defense Tech., sensing, Guofeng Yan1; Univ., Belgium cells based on inkjet printing method, generation and application of quan- China. In this presentation, we will 1Smart sensing research center, including printing substrate design, tum entanglement with photonic talk about the recent research Zhejiang Lab, China. Based on sider- printing solvent engineering, and orbital angular momentum, inclu- progress on enabling techniques hole fiber, a Fabry-Perot interfero- post-vacuum annealing optimization. ding quantum teleportation of including key components (such as meter was proposed for simulta- multiple degrees of a single photon, high brightness pump source and neous measurement of RH and W3H.5 • 15:15 and 18-qubit entanglement with passive fiber components) and temperature. For multi-point moni- Organic Afterglow Materials: Lumi- photon’s three degrees of freedom. digital design (theoretical modeling toring application, a hybrid Hybrid- nescent Mechanism, Molecular and software integration), based on cavity fabry-perot interferometer and Design, and Applications, Runfeng which varies kinds of high power sensing scheme was proposed and Chen1; 1NUPT, China. Organic fiber lasers will be reviewed. experimentally demonstrated. afterglow, also named as Ultra-long

roomtempe-rature phosphorescen-

ce, is not only fundamentally impor-

tant in organic optoelectronics but

also practically attractive for novel

device applications.

15:30-16:00 Poster Session 3 & Coffee Break, 4F

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ICOCN 2019—Wednesday, 7 August

Poster Session 3（15:30-16:00）

P3.1 P3.5 P3.9 P3.13 Image Registration SIFT Algorithm Based on Simultaneous measurement of temperature Hybrid Plasmonic Waveguide based 3×3 WDM optical steganography based on Adaptive Adjustment of Grayscale Weight, and pressure based on Fabry Perot and Multimode Interferometer for Compact super-continuum light source, Guorui Su1, Yucheng Pan1, Yongjun Wang1, Hui Xu1, Antiresonant mechanisms, Shiyi Xie1, Yang 120° Optical Hybrid, Tian Wang1, Nannan Tao Pu1 and Weifeng Mo1u; 1Army Engi- Xiaoyuan Niu1, Jun Li1 and Xinyu Liu1; 1BUPT, Shen1, Mengzhe Xiao1, Senhui Yin1, Chong Ning1, Xuan Tang1, Yunqing Lu1, Jin Wang1 neering Univ. of PLA, China. A 10 Gb/s stealth China. In view of the low color contrast of the He1, Jiajun Tian1 and Yong Yao1; 1Harbin Inst. and Qifa Liu1; 1NUPT, China. Based on hybrid channel based on super-continuum light foreground in the image of aero-engine of Tech., Shenzhen, China. A fiber-optic plasmonic waveguide, we propose a compact source in 120km SSMF transmission system is blades, we optimize the SIFT algorithm which sensor for simultaneous measurement of 3×3 multimode interferometer for 120°optical experimented, which can be hidden under was commonly used in image registration. temperature and pressure is proposed and hybrid. Tapered HPW sections are imple- the public WDM channel in both time and experimentally demonstrated based on the mented to improve the coupling efficiencies frequency domain. P3.2 FPI combined with antiresonant mechanism. for lights coupled into/out of the multimode Photon correlation method for acoustic section. pressure measurement in free sound field, P3.6 P3.14 Jianfeng Zhang1, Zhemin Chen1, Ning Chen1, Research on Scanning Method in Satellite P3.10 Passively mode-locked soliton fiber laser Sunqiang Pan1 and Pengbin Hu1; 1Zhejiang Laser Communication, Shiyu Qi1 and Qi Structure Colors Realized by TiN-Si3N4-Si based on a hybrid plasmonic microfiber 1 1 1 1

Inst. of Metrology, China. Research on a non- Zhang ; BUPT, China. Satellite laser Nanostructure Array, Jun Tan , Yanlong knot resonator, Zi-Xuan Ding , Sheng-Jie invasive method for acoustic pressure measu- communication has high operating frequency Meng1, Kai Xu1, Lingli Wang1 and Guojun Jin1; Wan1, Cheng-Bo Mou2 and Fei Xu1; 1Nanjing rement in free sound field based on photon and strong direction. It has the advantages of 1China Jiliang Univ., China. A TiN-Si3N4-Si Univ., China; 2Shanghai Univ., China. A correlation. high transmission code rate, small antenna nanostructure array designed in form of passively mode-locked ring-cavity fiber laser size and strong confidentiality. triangular prism is proposed to achieve a based on nonlinear polarization rotation P3.3 variety of colors such as purple, green, cyan, utilizeing a hybrid plasmonic microfiber knot Measurement of the position and orienta- P3.7 orange, and red. resonator is proposed and experimentally tion of mechanical arm based on laser Five-port non-blocking silicon optical rou- demonstrated. tracker, Ning Chen1, Pengbing Hu1, Gang ter based on mode-selective property, Hao P3.11 xiang Guo1 and Jianfeng Zhang1; 1Zhejiang Jia1, Ting Zhou2, Shanglin Yang2, Xin Fu2, Lei Optical-fiber-compatible Graphene hetero- P3.15 2 2 1 1 Wednesday, 7 August 7August Wednesday, Inst. of Metrology, China. The estimation of Zhang and Lin Yang ; Lanzhou Univ., China; structure photodetector, Yifeng Xiong , Designing of Surface Plasmon Sensor in a position and orientation of mechanical arm 2Inistitute of Semiconductors, CAS, China. We Haoshang Wang1 and Fei Xu1; 1Nanjing Univ., Side Hole Fiber with Simultaneous Double based on laser tracker is implemented. The propose and demonstrate a five-port optical China. We fabricated an all-in fiber Channel Detection, Yatao Yang1,2, Liyang angle and trajectory can be derived so that router based on mode-selective property. It photodetector (FPD) by integrating a micro- Shao2, Guoqiang Gu2, Sankhyabrata the differences between designed and the utilizes modes as labels to distinguish its meter-scale multilayer graphene-MoS2-WS2 Bandyopadhyay4, Yanjun Liu2, Jiandong Hu1, measured angle can be obtained. routing paths. The optical signal-to-noise heterostructure film to a fiber facet. Chao Wang2,5 and Zeng Peng2,3; 1Henan ratios for all paths are larger than 16.3 dB. Agricultural Univ., China; 2Southern Univ. of P3.4 P3.12 Science and Tech., China; 3Harbin Inst. of NIST randomness tests on the extended key P3.8 Fiber Nonlinearity Equalizer using MLP-ANN Tech., China; 4Southern Univ. of Science and of quantum noise random stream cipher, Signal and noise analysis in resonant for Coherent Optical OFDM, Haojie Zhang1, Tech., India; 5Univ. of Kent, United Kingdom. Haiqin Shi1, Tao Pu 1, Weifeng Mou1 and Yukai photoacoustic spectroscopy using fast Zhenming Yu1, Liang Shu1, Zhiquan Wan1, A surface plasmon resonance sensor with high Chen1; 1Communications Engineering Colle- Fourier transform, Sunqiang Pan1, Jianfeng Yilun Zhao1 and Kun Xu1; 1BUPT, China. We sensitivity and symmetrical dual-channel is ge, China. We performed NIST tests on the Zhang1, Zhemin Chen1 and Pengbing Hu1; propose a novel nonlinearity equalizer based proposed. A side-hole fiber has been con- extended key of QNRC. A new Hash 1Zhejiang Inst. of Metrology, China. A simple on multiple layers perceptron for 16- sidered as a platform of the proposed sensor. algorithm with higher efficiency in counter method based on fast Fourier transform (FFT) quadrature amplitude modulation coherent Detailed numerical calculation is carried out mode was proposed. Both CTR-AES and CTR- is used to analyze the signal and noise in optical orthogonal frequency division with the full-vector finite-element method. Hash can satisfy the randomness requirement. resonant photoacoustic spectroscopy. multiplexing system.

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ICOCN 2019—Wednesday, 7 August

Poster Session 3（15:30-16:00）

P3.16 P3.20 P3.24 P3.28 Twin tunable laser system with wavelength Exciplex emission based on Lewis acid-base Vibration Sensor Based On Graphene- Bend performance of single trench large calibration for Tera-Hertz spectrometer, interaction, Minli Zhang1, Jun Cheng1 and Jin coated Excessively Tilted Fiber Grating, mode area fiber with step-index core, Xin Lianfeng Ren1, Yi Li1, Qiaoyun Wang1, Bilun Xu1; 1Jianghan Univ., China. We exemplify a Lang Xie1 and Binbin Luo1; 1Chongqing Univ. Wang1, Zhen Xing1 and Shuqin Lou1; 1Beijing Lu1, Hongmei Li1, Zhi Hong1 and Jianjun Liu1; new exciplex emission system based on an of Tech., China. We report the bending strain Jiaotong Univ., China. Bend performance of a 1China Jiliang Univ., China. We demonstrated appropriate electron donor and a borane and low frequency vibration characteristics of single trench large mode area fiber with a the THz spectrometer using two laser beat Lewis acid as electron acceptor. X-ray few-layers graphene-coated excessively tilted step-index core is investigated. The designed sources. The laser output wavelength is photoelectron spectroscopy proved that N-B fiber grating (ExTFG), which enhanced the fiber can achieve a high loss ratio at 2 μm calibrated by a wavelength calibration device bond make the charge transfer process more mechanical characteristics at the expense of when the bend radius is 10 cm. to obtain an accurate beat frequency. efficient. sensitivity. P3.29 P3.17 P3.21 P3.25 Strain Sensor Based on Mach-Zehnder Study of temperature controlling of a solid Immunosensor based on cladding-etched Ultrafast fiber laser by HfSe2-based satur- Interferometers by Waist-enlarged Struc- Fabry–Pérot etalon, Lianfeng Ren1, Yi Li1, excessively tilted fiber grating coated with able absorber, Zewen Zhou Zhou1, Jinde Yin ture and Spherical Structure, Qirui Feng1, Qiaoyun Wang1, Bilun Lu1, Yanqing Qiu1 and graphene oxide, Yajie Wang1, Binbin Luo1, Yin1 and Peiguang Yan1; 1Shenzhen Univ., Yanpeng Wang1, Rui He1, Tingyu Meng1, Bangning Mao1; 1China Jiliang Univ., China. Shenghui Shi1, Qingming Lv1, Zhijiang Liu1, China. By incorporating the microfiber-based Hanguang Liu1 and Huaifeng Wang1; We designed a temperature Insulation struc- Qinglin Nie1, Mingfu Zhao1 and Decao Wu1; HfSe2 SA into the cavity, we achieved a soliton 1CNOOC Safety & Tech. Services Co., Wednesday, August7 ture and employed a PID controlling algori- 1Chongqing Univ. of Tech., China. A bovine fiber laser with pulse duration of 297 fs, output Ltd, China. Optical fiber strain sensors based thm. The temperature influence on the etalon serum albumin immunosensor based on power/pulse energy of 48.5 mW/2.68 nJ, and on M-Z interferometers fabricated by waist- transmission spectrum is also discussed graphene oxide (GO) modified cladding- slope efficient up to 12.8%. enlarged structure and spherical structure according to its temperature characteristics. etched excessively tilted fiber grating (ExTFG) were proposed. The sensing characteristics of is proposed. P3.26 the two kinds of sensors were investigated. P3.18 Supercontinuum generation in cascaded Compensation of Laser Phase Noise Based P3.22 photonic crystal fiber tapers, Yichi Zhang1, P3.30 on Polar-Coordinate Decision, Lei Wang1, Supercontinuum generation by dual-pulse- Jinhui Yuan1, Kuiru Wang1, Yujun Cheng1, Exciton tunneling behaviors in two 1 1 1 1 1 1 1 1 Yuanyuan Ma , Mingyi Gao , Yanping Sha pumping in photonic crystal fibers, Ying Li Feng Xu , Binbin Yan , Xinzhu Sang and dimensional halide perovskite, Song Wang , and Weidong Shao1; 1Soochow Univ., China. and Ding Ding1; 1National Univ. of Defense Chongxiu Yu1; 1BUPT, China. We propose two- Peiqing Cai1 and Zugang Liu1; 1China Jiliang We proposed and experimentally demon- Tech., China. We numerically investigate stage cascaded photonic crystal fiber tapers Univ., China. Two-dimensional (2D) halide strated a phase-noise-mitigation scheme supercontinuum generation from photonic for the supercontinuum (SC) generation. The perovskite materials. based on polar coordinate decision in the 16- crystal fibers using dual-pulse-pumping at nonlinear evolution of the SC generation is QAM coherent optical communication system. 1064nm. This pump way can make good use numerically investigated when pump pulses P3.31 The BER curves are measured to verify the as long as the offset time is small enough. with different peak powers are used. Deep neural network-based QoT estimation feasibility of the scheme. for gain-unflatness EDFA lightpath P3.23 P3.27 provisioning in optical networks, Yin P3.19 Erbium-Doped Fiber Dual-Wavelength Dual-Parameter Modulation Leads to Chaos Meihuan1 and Xu Bo1; 1Univ. of Science and Research on the resonance frequency Mode Locked Laser With Few-Layer NiPS3, in an Erbium-Doped Fiber Laser, Yan Senlin1; Tech. of China, China. A deep neural network reduction of the single fiber scanner, Jin Wang1, Tao Wang 1, Xinyao Shi1, Jian Wu1, 1Nanjing Xiaozhuang Univ., China. We study is firstly proposed to estimate the optical Hongmei Li1, Yi Li1, Yanlong Meng1, Haiyang Kai Zhang1, Pu Zhou1 and Zongfu Jiang1; dual-parameter modulating how to lead to signal-to-noise ratio (OSNR) of to-be- Yu 1, Tianliang Wang1, Qiaoyun Wang1 and Jun 1National Univ. of Defense Tech., China. We chaos in an erbium-doped fiber laser. When established lightpaths, taking into account Tan 1; 1China Jiliang Univ., China. We proposed and demonstrated dual-wave- the pump and photon decay rate of the laser the gain flatness of Erbium-doped fiber proposed a new method to lower the re- length mode-locked EDFL by utilizing the is modulated, a few paths to chaos are amplifier(EDFA), nonlinear interference sonance frequency of the single fiber scanner. few-layer NiPS3 as the saturable absorber (SA). discussed. between spectrum neighboring channels.

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ICOCN 2019—Wednesday, 7 August

Poster Session 3（15:30-16:00）

P3.32 P3.35 P3.39 P3.42 Cascaded TCF with WO3 film based Mach– Experimental Research on Polar Code Theoretical analysis of a wide detection Experimental study of the resonant frequ- Zehnder interferometer for hydrogen based on Gaussian Approximation for VLC range refractive index sensor based on ency of an optical fiber vector sensor with sensing, Chong Zhang1, Changyu Shen1, system, Shuyun Wen1, Min Zhang1, Dahai exposed core tellurite micro-structured different packages, Shan Huang1, Jianfei Zhiqiang Sun1 and Jiaqi Gong1; 1China Jiliang Han1 and Jianming Zhang1; 1BUPT, China. This optical fiber, Xue Zhou1, Tonglei Cheng1, Wang1, Mo Chen1 and Zhou Meng1; 1National Univ., China. A gas sensor based on TCF with paper presents a comparative study of polar Xuegang Li1, Xuenan Zhang1 and Shuguang Univ. of Defense Tech., China. The character- WO3 film was demonstrated. By detecting codes constructed by Gaussian Approxi- Li1; 1Northeastern Univ., China. A novel ristic of resonant frequency of three different spectral shifts, the proposed sensor showed a mation(GA) considering the characteristic of refractive index sensor based on an exposed- OFVS operating in water were studied. high sensitivity of 100 ppm under the Visible Light Communication(VLC). The core tellurite microstructure optical fiber has hydrogen concentration of 0 to 2%. impact of key parameters in coding and been implemented. The sensitivity of sensor P3.43 decoding scheme is investigated through is up to 2919.4nm/RIU. Research and Application of Network numerical simulations. Behavior Feature Detection Model Based P3.33 P3.40 on Knowledge Base, Hui Zhu1, Jialing Yu1 Relative Intensity Noise Measurement of a P3.36 120m 10Mbps Ethernet Transmission and Yang Wang1; 1China Satellite Marine Fiber Laser, Xin Cheng1, Weiwei Pan1, Jinyan Universal Imaging of Full Strain Tensor in 2D Based on Visible Light Communication Track and Control Department, China. This 1 1 1

Dong and Yan Feng ; Shanghai Inst. of Crystals with Third-Harmonic Generation, using a Single Commercially Available LED, model combines fast multi-pattern matching Optics and Fine Mechanics, CAS, China. Jing Liang1 and Kaihui Liu1; 1Peking Univ., Hongyu Zhou1, Minglun Zhang1, Xiaozheng technology, which can match the existing Relative intensity noise (RIN) is used to China. A universal methodology to measure Wang1, Youyuan Sun1, Yufeng Zhang1, Chen behavior features in the knowledge base characterize the temporal stability of a the full strain tensor in any 2D crystalline Wei1, Wen He1, Wenfei Sun1, Chongshuang quickly, efficiently and accurately in the standard fiber laser. And the RIN spectra of an material by polarized third-harmonic genera- Qin1, Chuanliang Guan1 and Xiaomin Ren1; network environment with large traffic. oscillator and a master oscillator power tion is reported since the nonlinear suscepti- 1BUPT, China. A VLC system is implemented, amplifier at same output power are compared bility has a one-to-one correspondence to which combines with existing network P3.44 strain tensor via a photoelastic tensor. (10Base-T). The transmitter uses a LED, and A Long Distance Real-time DPSK Visible the receiver uses an APD. The system can Light Communication System Based on P3.34 P3.37 realize real-time data transmission of 10Mbps FPGA, Yufeng Zhang1, Minglun Zhang1, 1 1 1 Wednesday, 7 August 7August Wednesday, Generating Ultra-Wideband LFM Wave- Application of Micro-Nano Grating in Ethernet over 120m under strong background Hongyu Zhou , Youyuan Sun , Chen Wei and forms with large time duration Based on Photonic Regulation, Qifa Liu1, Huihui Wang1, light. Wen He1; 1BUPT, China. We design a real-time Frequency-sweeping Optoelectronic Oscilla- Jin Wang1, Lihui Zhu1, Meiyu Liu1; 1NUPT, DPSK VLC System Based on FPGA. Under tion, Ranran Liu1, Pengfei Du1, Chunqiang Fu2, China. This paper introduces the research P3.41 strong background light, the transmission Xiong Luo1, Haida Yang1, Jianghai Wo1, Yalan status of micro-nano gratings in the field of Diketopyrrolopyrrole-Based Conjugated distance is up to more than 66m at a real-time Wang1, Jin Zhang1 and Anle Wang1; 1Air Force photon regulation. Polymers for High-Mobility Organic Thin- data rate of 10Mbps, with a BER below 10-5. Early Warning Academy, China; 1No. 94326 Film Transistors Processed from Non-Chlori- Unit, the PLA, China. A frequency-sweeping P3.38 nated Solvents, Zhongli Wang1, Yang Han1 P3.45 OEO based on a low-loss microwave photonic Analysis of core eccentricity on the long and Yanhou Geng1; 1Tianjin Univ., China. Two Design of a current modulation driver for filter with ultra-wide reflection bandwidth is period grating in eccentric core fiber, non-chlorinated solvent processable DPP- an ultra-compact RGB laser, Xiaohai Wang1, proposed. Near-zero-dispersion single mode Xiaofeng Xu1, Yujia Zhao1, Peizhen Jiang1, Ai based conjugated polymers of simple Yi Li1, Hongmei Li1 and Qiaoyun Wang1; fiber and large-reflection-bandwidth fiber- Zhou1 and Hongfeng Lin1; 1Wuhan Univ. of structures are synthesized, and the better 1China Jiliang Univ., China. We designed a Bragg-grating Fabry-Perot are used to Tech., China. The model of the long period performing polymer processed from o-xylene current driver circuit for an ultra-compact RGB enlarge time duration and bandwidth of LFM fiber grating (LPFG) inscribed in the eccentric achieved reliable high hole mobility of up to laser, which allows for high speed driving waveforms. core fiber (ECF) is proposed and analyzed 9.24 cm2/(V·s) in organic thin film transistors. current modulations. theoretically.

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ICOCN 2019—Wednesday, 7 August

Poster Session 3（15:30-16:00）

P3.46 P3.50 P3.54 P3.57 Analysis on Gain and Noise Figure of Direct Curvature sensing based on the reflection A Novel Optimized PTS for PAPR reduction Monitoring ammonia through cavity- Modulation RoF Link, Hui Gao1 and Zhipeng spectrum of a hybrid-structure fiber sensor, of an DMT signal, Jingyan Li1, Qinghua Tian1, enhanced absorption spectroscopy, Peng Zhou1; 1National Key Lab. of Antenna and Yiyun Li1; 1China Jiliang Univ., China. Zexuan Jing1, Qi Zhang1, Yongjun Wang1, bing Hu1, Zhemin Chen1, Sunqiang Pan1, Microwave Tech., China. The equivalent cir- Simultaneous measurement of curvature and Feng Tian1, Leijing Yang1 and Xiangjun Xin1; Jianfeng Zhang1 and Ning Chen1; 1Zhejiang cuit model of direct modulation RoF link is temperature by monitoring the transmission 1BUPT, China. Based on the Partial-Transmit- Inst. of Metrology, China. An optical off-axis introduced. The mathematical expressions of spectrum of a hybrid-structure fiber sensor Sequence technique, Progressive-Seg-men- enhanced cavity sensor was developed for link gain and noise figure are both derived. which consists of two peanut-shape structures ted PTS and its improved algorithm named ammonia monitoring. Maximum measuring The methods to optimize this links transmit- and a FBG is proposed. IPS-PTS are proposed. They can reduce the error of only 2% is achieved ranging from 0 to ssion performance are further analyzed. PAPR and get a balance between perfor- 1000 ppm, showing a higher performance for P3.51 mance and computational complexity. ammonia gas detection. P3.47 Research on strong background light sup- Fiber Bragg grating in seven core fiber ression technology based on power inver- fabricated with infrared femtosecond laser sion, Ling Qin1, Kening Song1, Yong zhen Hu1, pulses and a phase mask , Shuhui Liu1 and Baoshan Li1 and Yongxing Du1; 1Inner Shun Wang1; 1Wuhan Inst. of Tech., China. Mongolia Univ. of Sci. and Tech., China. We P3.55 P3.58 Fibre Bragg grating is inscribed into a seven establish VLC system under strong back- Security authentication based on genera- A High Sensitivity Methane Detector Based Wednesday, August7 core fiber by use of femtosecond laser. ground light, then introduces PI algorithm to ted address algorithm for software-defined on Laser Absorption Spectrum, Yubin Wei1, 1 2 1 Multiple peaks in the spectrum are observed. suppress the influence of strong background optical communication network, Tao Liu1, Tongyu Liu , Jie Hu , Tingting Zhang , 1 1 1 A sensitivity of 12 pm/oC is achieved between light, then analyzes the bit BER of the systems Yongli Tang1 and Panke Qin1; 1Henan Polyt. Yanfang Li , Yin Wang and Zhaowei Wang ; 1 2 room temperature and 1000 oC. under different SIR. Univ., China. We propose an authentication Qilu Univ. of Tech., China; Shandong Micro- scheme based on the crypto-graphically sensor Phot. Ltd, China. A high Sensitivity P3.48 P3.52 generated and the hash generated address trace methane analyzer based on TDLAS Design of Suspended Sub-wavelength Optical Fiber Refractive Index Sensor algorithms. The scheme completes the first technology was design, using low noise 20m Terahertz Waveguide, Chen Ming-Yang 1, Xu Composed of Quartz Capillary, Huiling Hu1, and the non-first authentication. Herriott cell and direct absorption method to -6 1 1 1 1 1 1 Hang , Bai Tong-Tong and Zhang Yuan ; Jie Wang and Chao Jiang ; Hubei Normal realize 0.09*10 of detection limit. 1Jiangsu Univ., China. The design of a sub- Univ., China. A refractive index sensor is wavelength terahertz waveguide in presented. designed with quartz capillary. The sensor is The high transmission efficiency of the sensitive to environmental refractive index. waveguide and the good coupling between The maximum sensitivity of refractive index is P3.56 P3.59 the components are demonstrated by using 122.3nm/RIU. The sensor can eliminate cross Circularly polarized Airy beam generation Micro-displacement sensor with tempera- ture compensation based on double-ball finite element method and beam propagation sensitivity of temperature to refractive index. with hyperbolic metamaterials at telecom 1 1 1 cascade and fiber Bragg grating, Juan Qin , method. wavelengths, Huihui Li , Weiming Hao and 1 1 1 1 Zhengrong Tong , Shuo Yuan , Weihua P3.53 Chen Lin ; Huazhong Univ. of Sci. & Tech., Zhang1, Yimei Zhong1 and Wenlin Gao1; 1TJUT, P3.49 A spectral domain OCT system using All- China. Hyperbolic metamaterial waveguide China. A micro-displacement sensor with Multimode waveguide Bragg gratings on fiber probe, Chunjiao Jin1, Xinglin Tong1, array is proposed to generate circularly temperature compensation is proposed and SOI platform, Huiye Qiu1, Xiong Liang1 and Qiao Xiong1, Cui Zhang1 and Chengwei polarized Airy beam at telecom wavelengths verified experimentally. It reduces the Jing Lv1; 1Longyan Univ., China. Multimode Deng1; 1WUT, China. We introduce a spectral with both phase and amplitude modulation, influence of cross sensitivity between waveguide Bragg gratings (MWBGs) are domain optical coherence tomography sys- and verify the excellent performance with temperature and displacement. demonstrated on silicon-on-insulator (SOI) tem using all-fiber microsphere probe instead simulation. platform for on-chip applications. of traditional sample arm.

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Poster Session 3（15:30-16:00）

P3.60 P3.64 P3.67 P3.70 Influence of inter-channel nonlinear inter- Research on real-time BER estimation in An Image Deblurring Algorithm Based on Efficient and Range-Variable Laser Wireless ference on the QoT estimation for elastic satellite downlink, Qinghua Yu1, Bin Qiu1, Bo Edge Selection, Tingting Liu1, Kai Kang1, Charging Technology, Chaofan Lu1, Zhiguo optical fiber networks, Jing Bai1, Yifan Shen1, Cong1 and Tianyun Wang1; 1China Satellite Tianyun Wang1, Guoquan Zhu2 and Jianxin Zhang1, Luming Li2, Jiangxing Chen2, Xing Cheng Xu1 and Guanjun Gao1; 1BUPT, China. Maritime Tracking and Control Department, Zhou2; 1Dept. of China Satellite Maritime Liu2 and Ziyang Xiao2; 1BUPT, China; 2Jiangxi The influence of interfering channel modul- China. A real-time BER estimation method Tracking and Control, China; 2Univ. of Science Electric Power Company, China. This paper ation format, channel spacing, and optical based on EVM is proposed, and a test system and Tech. of China, China. An image proposes an efficient laser wireless charging power on the QoT estimation is compared is built to simulate the satellite downlink. deblurring algorithm based on edge selection scheme with variable charging distance and a and analyzed. GN model can underestimate results show that deviation between the is proposed, which can be used to estimate simple tracking system, and realizes this Q factor by 3.6 dB for ICNI limited systems. predicted and measured is no more than 33%. blurring kernel and latent clear image sim- scheme. ultaneously under the framework of maximum P3.61 a posterior probability estimation. High Efficiency Fused-Biconical Type Mode Selective Coupler Using Four-Mode Fiber, P3.71 Da Wang1, Jiahui Yang1, Su Chen1, Yang Xu1 Strong fiber Bragg grating sensor based on and Zuxing Zhang1; 1NUPT, China. We demo- P3.65 P3.68 optoelectrical oscillation for ultra-fast and nstrate a fused-biconical type mode selective A Fiber-Optic Channel Modeled Through Numerical Simulation of Chaotic Ultra- ultra-stable position-finding and coupler that couples the LP01 mode in single- BiLSTM Technique, Yuchen Song1, Danshi Wideband Fiber Communication, Yan measurement, Wenxuan Wang1, Yi Liu2, Yan mode fiber and the high-order modes in four- Wang1, Min Zhang1 and Qichuan Cui1; 1BUPT, Senlin1; 1Nanjing Xiaozhuang Univ., China. A Li2, Changyuan Yu2 and Xiangfei Chen1; mode fiber. China. We model the fiber-optic channel with long-distance high-rate chaotic ultra-wide- 1Nanjing Univ., China; 2The Hong Kong bidirtectional LSTM struture, which shows the band fiber communication system at 1.31nm Polytechnic Univ., Hong Kong. A quasi- P3.62 similar performance with the conventional wavelength is presented and simulated. The distribute sensor based on optoelectrical Superposition Construction of NB-QC- method, while greatly reduced the need for amplitude or intensity of digital modulation oscillator incorporating a strong uniform fiber LDPC Codes for optical communication expert konwledge and complexity. and demodulation of the chaotic ultra- Bragg grating is proposed. When reflection 1 1 systems, Zhihui Wang , Liqian Wang and wideband fiber communication are discussed. spectrum moves to longer wavelength due to Dongdong Wang2; 1BUPT, China; 2the 54th Wednesday, 7 August 7August Wednesday, external changes, target position will be Research Inst. of China Elec. Tech. China. We mapped into oscillating frequency. consider the construction of NB-QC-LDPC code based on superposition for the optical communication systems. Simulation results P3.66 P3.69 P3.72 show the constructed codes could achieve Study of Infrared Image Denoising Three-stage dynamic bandwidth allocation Design and Implementation of Commu- 0.1dB ~0.4dB NCG. Algorithm Based on Steering Kernel based on fairness in software-defined nication Data Quality Analysis Software

Regression Image Guided Filter, Kai Kang1, hybrid passive optical network, Chen Qian1, System, Zhao Liu1; 1China Satellite Maritime P3.63 Tingting Liu1, Xianchun Xu1, Guoquan Zhu2 Yifan Li1 and Min Wang1; 1Shanghai Univ., Tracking and Control Department, China. This Multipoint temperature sensor based on and Jianxin Zhou2; 1Dept. of China Satellite China. A three-stage dynamic bandwidth paper mainly introduces the design method PDMS-filled Fabry Perot interferometer Maritime Tracking and Control, China; 2Univ. allocation algorithm based on fairness for of communication data quality analysis with an Array-Waveguide Grating, Jiali Li1, of Science and Tech. of China, China. The original and new VPONs in software-defined software based on Linux system, and Chunliu Zhao1, Qianmin Dong1, Juan Kang1, shape and size of the steering kernel are firstly HPON is proposed. The performances in implements the communication data quality Changyu Shen1 and Dongning Wang1; 1CJLU, determined according to the local gradient bandwidth utilization, access probability of analysis software under Qt environment. China. A multipoint temperature sensor information of the image, and then the new VPONs and fairness index are simulated. based on PDMS-filled Fabry Perot interfe- filtering weightis used to modify the analysis rometer is proposed. Average sensitivity of window of image guided filter. the temperature sensor is -1.238dBm/℃.

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Wednesday, August7

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16:00-18:00 16:00-18:00 16:00-18:00 16:00-18:00 W4A • Optical transmission IV W4B • Optical networks III W4C • Machine learning III W4D • Ultrafast & nonlinear optics IV Presider: Guijun Hu, Jilin Univ., China Presider: Bowen Chen, Soochow Univ., Presider: Qunbi Zhuge, Shanghai Jiao Presider: Xinhuan Feng, Jinan Univ., China Tong Univ., China China

W4A.1 • 16:00 Invited W4B.1 • 16:00 Invited W4C.1 • 16:00 Invited W4D.1 • 16:00 Invited Industry Trends for 400 Gb/s and Photonic burst switching for space Power of deep learning for optical L band harmonically mode locked Beyond Applications, Yang Yue1; backbone network in support of physical layer, Danshi Wang1; Erbium doped fiber laser, Chengbo 1Juniper Networks, United States. multi-QoS services, Hongxiang 1Beijing Univ. of Posts and Tele., Mou1; 1Shanghai Univ., China. We After the implementation of 100- Guo1, Qing Zhang1, Cen Wang1 and China. Deep learning as a powerful will present our latest results on L Gb/s pluggable optics, the optical Jian Wu1; 1BUPT, China. We propose interdisciplinary tool has been well band harmonically mode locked communications industry is marching towards a GEO/LEO based satellite backbone leveraged in optical communications. This Erbium doped fiber lasers. Applications of 400-Gb/s era. We will review our recent network through the timeslot-based optical invited talk focuses on the latest applications fiber based nonlinear polarization rotation demonstration and study for 400 Gb/s and burst switching (OBS), which can provide high of deep learning in optical physical layer, and carbon nanotube based mode lockers beyond client and line side optical capacity and low latency to support various involved with intelligent transceiver, end-to- will be discussed. interconnect. traffic with diverse QoS requirements. end learning, channel modelling, impairment diagnosis, etc.

Wednesday, 7 August 7August Wednesday, W4A.2 • 16:30 Invited W4B.2 • 16:30 Invited W4C.2 • 16:30 Invited W4D.2 • 16:30 Invited A burst-mode optical amplifier for Baseband unit aggregation based Machine learning in 5G optical Pulse formation for achieving TWDM-PON, Tianze Wu1, Xiaobo on deep reinforcement learning transport networks, Jiawei higher peak power in ultrafast fiber Zhu2, Xiang Jia2 and Wenhua Gu2; in cloud radio access networks, Zhang1; 1Beijing Univ. of Posts and lasers, Luming Zhao1; 1Jiangsu 1Nanjing Univ., China; 2Nanjing Univ. Min Zhu1, Jiahua Gu1, Bin Chen1, Tele., China. Normal Univ., China. Principles of of Sci. and Tech., China. One of the Tianyu Shen1 and Xueqi Ren1; pulse shaping aiming larger pulse critical challenges for TWDM-PON is that the 1Southeast Univ., China. We propose a deep energy in ultrafast fiber lasers are summarized. optical amplifiers need to run in the burst- reinforcement learning based BBU aggre- Dissipative-soliton-resonance is a possible mode, with an up to 40 dB dynamic range. gation policy, which can increase energy way to achieve endless pulse energy boost. This presentation discusses the efficiency and maintain users’ QoS. Different The challenges and opportunities in ultrafast corresponding requirements and solutions. saved energy consumption and decreased fiber lasers are discussed. migrated traffic drop can be achieved by tuning rpc/mt.

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16:00-18:00 16:00-18:00 16:00-18:00 16:00-18:00 16:00-18:00 W4E • Random Fiber Lasers II W4F • Optical measurement VI W4G • Optoelectronics V W4H • Organic & nano W4I • Quantum photonics VI Presider: Qian Li, Peking Univ. Presider: Yuan Gong, Univ. of Presider: Anbang Wang, optoelectronics VI Presider: Ya Cheng, East China Shenzhen Graduate School, Electronic Sci. & Tech. of China, Taiyuan Univ. of Tech., China Presider: Junbiao Peng, South Normal Univ., China China China China Univ. of Tech., China

W4E.1 • 16:00 Invited W4F.1 • 16:00 Invited W4G.1 • 16:00 Invited W4H.1 • 16:00 Invited W4I.1 • 16:00 Invited Random fiber lasers with Multidomain biosensing with Applications of silica- Through-Space Charge Flexibly engineering multi-wavelength and nanocoated optical fiber based PLC for flexible Transfer Polymers for quantum states by tenability, Xuewen Shu1; devices, Mateusz Smietana1, and large capacity pho- Solution-processed OL- using quantum 1Huazhong Univ. of Dariusz Burnat1, Pawel Nied- tonic network, Osamu EDs, Lixiang Wang1; interference, Xiaoying Science and Tech., China. zialkowski2, Wioleta Bialobr- Moriwaki1; 1NTT, Japan. 1Changchun Inst. of App- Li; Tianjin Univ., China. We will present our recent research zeska2, Petr Sezemsky3, Marcin Koba4, This talk presents the general and lied Chemistry, Chinese Academy of Using spontane-ous four-wave work on tunable and multi- Marta JanczukRichter5, Vitezslav Stranak3, advanced applications of silica- Sciences, China. This presentation mixing in nonlinear interferometer wavelength random fiber lasers. Joanna Niedziolka-Jonsson5 and Robert based PLC devices such as AWG will discuss through-space charge (NLI) for temporal mode shaping, Random fiber lasers with different Bogdanowicz6; 1Warsaw Univ. of Tech., and Thermo-Optic switches that transfer non-conjugated polymers we efficiently generate heralded 2 3 configurations and gain Poland; Univ. of Gdansk, Poland; Univ. realizes flexible, low power consu- and hexaarylbenzene dendrimers single photons with near ideal Wednesday, August7 mechanisms will be discussed. of South Bohemia, Czechia; 4National mption and large capacity photonic with thermally activated delayed modal purity and heralding Inst. of Tele., Poland; 5Inst. of Phy. Che., network. fluorescence effect and efficiency by changing the stage Poland; 6Gdansk Univ. of Tech., Poland. A aggregation-induced emission (AIE) number of NLI. dual-domain label-free bio-sensing con- effect, for full color and white light cept based on optical fibre coated with emission. conductive film is discussed. The optical device can be simultaneously processed and investigated electrochemically.

W4E.2 • 16:30 Invited W4F.2 • 16:30 Invited W4G.2 • 16:30 Invited W4H.2 • 16:30 Invited W4I.2 • 16:30 Invited Random fiber lasers and Realizing high performance Trends in III/V-on-Silicon Metal-organic frame- Ultra-bright single phot- imaging application, measurement with UWFBG laser integration for da- work based OLED for on and entangled phot- Weili Zhang1; 1Univ. of array based on double-pulse tacom applications and visible light communi- on sources based on Science and Tech. of demodulation method, Feng more, Yingtao Hu1, Di cation, Jin Wang1, Ying quantum dots in broad- China. Being collective Wang1, Yu Liu1, Yixin Zhang1 Liang1, Geza Kurczveil1 Yu 1, Xiaoli Liu1, Yunchao band photonic nanost- notion of random lasers and fiber and Xuping Zhang1; 1Nanjing Univ., China. and Raymond Beausoleil1; 1Hewlett Zhang1, Xinhui Zhou1 and Yunqing ructures, Juntao Li1; 1Sun Yat-sen lasers, random fiber lasers (RFLs) High performance distributed vibration Packard Enterprise, USA. We review Lu1; 1NUPT, China. MOF materials Univ., China. Here we introduce a provide new opportunities for deve- sensing is realized with double-pulse that building heterogeneous Si can encapsulate organic dye mole- nano-resonance to enhance the lopment of the two laser comm- based on the principle of Φ-OTDR lasers by using III/V multi-quantum cules and realize new OLEDs for extraction efficiency of the selfassm unities. We present our research on assisted by UWFBG array. It has great well and quantum-dots, with con- VLC system. We present spectrally ble semiconductor quantum dots, i RFLs and application in imaging. potential in improving the SNR, ventional III/V-to-Si wafer bonding flat white OLED based on red- n order to demonstrate the high qu sensitivity and frequency range of Φ- technology and newly developed yellow-green-blue dye-loaded ality sigle photon and entangled p OTDR. bonding plus regrowth advanced MOFs and linearly polarized warm- hoton sources. integration platform. yellow MOF-OLED.

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W4A.3 • 17:00 Invited W4B.3 • 17:00 Invited W4C.3 • 17:00 Invited W4D.3 • 17:00 Invited Progress on SDM optical fiber How to Deploy and Employ Qua- Exploiting AI technology to miti- Lasing and frequency comb appli- technology, Yuto Sagae1; 1NTT ntum Key Distribution with Clas- gate fragmentation and crosstalk cations of Ultrahigh-Q silica micro- Access Network Service Systems sical Optical Networks, Yongli in SDM-EONs, Yu Xiong1; cavities, Lei Shi1; 1Huazhong Univ. Lab.， Japan. Zhao1; 1Beijing Univ. of Posts and 1Chongqing Univ. of Posts and Tele., of Science and Tech., China. Telecommunications, China. Some China. This report mainly presents a Tunable lasing and optical frequen- topics in QKD-enabled optical networks will crosstalk-aware spectrum fragmentation avoi- cy comb generation with the sub-mW thre- be discussed, such as resource allocation for dance strategy and a blocking-aware sholds based on Ultrahigh-Q functionalized different channels, survivability solutions for spectrum defragmentation strategy based on silica micro-bottle and microsphere cavities failures, construction schemes of quantum machine learning in SDM-EONs, which used have been proposed and experimentally key pools, and last mile solution for quantum in the different situation before and after demonstrated. key provisioning. resource allocation, respectively.

W4A.4 • 17:30 Invited W4B.4 • 17:30 W4C.4 • 17:30 W4D.4 • 17:30 Invited

Simplified implementation of SD- Novel Four-Level Manchester Coding Tech- An Improved Method of PS-QPSK Based Versatile coherent light sources: LDPC for probabilistically shaped nique for Optical Access Networks, Festus on Kmeans for Optical Systems, Jie Ma1, from fiber optics to nanophotonics, constellations, Xingwen Yi1, Jing Oluwajobi1, Nguyen Dong-Nhat2, Nafizah Jianguo Yu1, Yuanxiang Chen1, Kaile Li1, Lili Gui1; 1Beijing Univ. of Posts and Zhang2 and Zhaohui Li1; 1Sun Yat- Khan1 and Amin Malekmohammadi3; 1Univ. of Yitong Li1, Yongtao Huang1 and Xinguo Li2; Tele., China. Bright, tunable and Sen Univ., Australia; 2Univerisity of Nottingham, Malaysia; 2Faculty of Electrical 1Beijing Univ. of Posts and Tele., China; coherent light sources are desirable Electronic Science and Tech. of China, China. Engineering Czech Tech. Univ. in Prague, 2Wuhan Accelink Tech. Co. Ltd., China. To in many applications such as optical commu- We present a simplified log likelihood ratio Czechia; 3California Polytechnic State Univ., mitigate nonlinear impairments in optical PS- nications and integrated optics. Here I will (LLR) for LDPC decoding in probabilistically USA. Four-level Manchester coding technique QPSK transmission, Kmeans methods are introduce our recent work for developing such shaped constellations. The improvement of investigated for high-speed optical access proposed for signal decision. Numerical sources by fiber optics and nonlinear post-FEC BER is 1.17 dB for PS-16QAM. networks. Results show that 4-MC has 3.5dB results show that Kmeans can effectively plasmonics.

Wednesday, 7 August 7August Wednesday, better receiver sensitivity compared to 4-PAM, reduce the BER after 1600km transmission which makes 4-MC an alternative to 4-PAM while little extra complexity increase. together with self-clocking feature advantage.

W4B.5 • 17:45 W4C.5 • 17:45 LOOP: A Low-Loss Compact Plasmonic Optimization BM3D algorithm based on Router for ONoC, Jingyao Zhang1 and Huaxi pseudo-3D transform, Tao Song1, Ying Liu2 & Gu1; 1Xidian Univ., China. We propose a low- Mingfu Zhao1; 1Chongqing Univ. of Tech.; loss compact plasmonic router for optical 2Chongqing Inst. of Qual. & Stand., China. An Network-on-Chip. By adopting new topology, optimization BM3D algorithm based on high operation frequency and unique shape pseudo-3D transformation is proposed to of plasmonic devices are finely tuned to high- reduce the computation of image denoising performance optical switching. algorithm.

18:30-21:00 Banquet and Awards Ceremony, Xiangming Hall（香茗厅）, 2F

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W4E.3 • 17:00 Invited W4F.3 • 17:00 Invited W4G.3 • 17:00 Invited W4H.3 • 17:00 Invited W4I.3 • 17:00 Invited Coherent Brillouin High-sensitivity and multi- Silicon nitride photonic Sensitized Emitters for Towards optimal single- random fiber laser and its parameter measu-rement integrated chips and Solution-Processed Org- photon sources from pola- applica-tions, Liang based on the multi-cavity FP some applications, Jijun anic Light-Emitting Devi- rized microcavities, Si Zhang1; 1Shang hai Univ., fiber-optic sensor, Jiajun Feng1; 1Univ. of Shanghai ces, Guohua Xie1, Chen1, 1USTC, China. China. Coherent Brillouin Tian1, Cheng Zhou1, Chong for Sci. and Tech., China. Tengxiao Liu1, Jiajia Luo1 Solidstate sources of indis- random fiber lasers with unique He1, Mengzhe Xiao2, Shiyi Xie1; 1Harbin and Chuluo Yang1; 1Wuhan Univ., tinguishable single photons had to spectral and noise features are Inst. of Tech., Shenzhen, China; 2Harbin China. High-performance solution- rely on polarization filtering which actively being develop-ped in terms Inst. of Tech., China. We investigate the processed organic light-emitting reduced the efficiency by 50%. We of laser performance as well as working principle of multi-cavity FP fib- devices based on sensitized emit- coherently driving quantum dots diverse practical potentials, which er-optic sensor and discuss the struc- ters have been demonstrated by deterministically coupled to polari- will be presented in this talk. tural conditions for amplified sensitivity managing the cascade energy zationselective Purcell microcavities. and multi-parameter mea-surement. transfer.

Invited W4E.4 • 17:30 Invited W4F.4 • 17:30 Invited W4G.4 • 17:30 Invited W4H.4 • 17:30 Invited W4I.4 • 17:30 High resolution strain Helical-structured fiber The Application of Photo- Efficient fluorescent Networking and sensor based on random sensor design and fabri- thermal Microfluidic organic light-emitting resource assignment on Wednesday, August7 fiber lasers, Wentao cation, Zhifang Wu1; Vortex Integrated in the devices based on novel quantum key distribution Zhang1, Shuaijie Miao1, 1Huaqiao Univ., China. We Microfluidic Channel, anthracene derivatives based optical networks Peide Liu1, Wenzhu will introduce our recent Xiaobo Xing1 and Jianxin with low efficiency roll- (QKD-ON), Xiaosong Yu; Huang1 and Fang Li1; 1Inst. of works on helical-structured fiber based Yang1; 1South China Academy of off, Lei Wang1; 1Huazhong Univ. of Beijing Univ. of Posts and Tele., Semicon-ductors, CAS, China. sensors. By using CO2 laser processing Advanced Optoelectronics, College Science and Tech., China. OLEDs China. This talk will address the Random fiber lasers are used as the system, we fabricated different types of of Bio-photonics, South China have been commercialized in flat networking and resource allocation light sources or sensing element in helical-structured multicore fibers and Normal Univ., China. We report a panel displays and white light illu- problem in optical networks secured the strain sensing system. Due to then constructed HSMCFs based photo-thermal microfluidic vortex, mination field. However, it’s an by QKD. Technologies on Virtual their narrow linewidth, an ultra-high sensors for different applications. which can be applied to selectively enormous challenge to realize high Key Pool (VKP) construction, net- strain resolution can be achieved. trap and directionally delivering efficiency, thermal stability, suffi- work survi-vability, as well as virtual mesoscopic object in the micro- ciently long lifetime, and saturated QKD networks will be involved. fluidic chip. deep-blue emission with a Commi-

ssion Internationale de l'Eclairage coordinate of y <0.10 simultane- ously. We reported several novel anthracene-based compounds.

18:30-21:00 Banquet and Awards Ceremony, Xiangming Hall（香茗厅）, 2F

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08:00-10:00 08:00-10:00 08:00-10:00 08:00-10:00 Th1A • Optical transmission V Th1B • Space communications I Th1C • Fiber magnetic devices I Th1D • Supercomtinuum sources II Presider: Xingwen Yi, Sun Yat-sen Univ., Presider: Bo Cong, China Satellite Presider: Shengli Pu, Univ. of Shanghai Presider: Tonglei Cheng, Northeastern China Maritime Tracking and Control for Sci. & Tech., China Univ., China Department, China

Th1A.1 • 08:00 Invited Th1B.1 • 08:00 Invited Th1C.1 • 08:00 Invited Th1D.1 • 08:00 Invited Transmission in high-core count, Underwater Wireless Optical Com- Graphene-integrated fiber magn- Experiment and numerical study of single mode MCF systems, Ben munications based on Multipixel etic field sensors, Fei Xu; Nangjing Raman soliton at 2μm in Puttnam1; 1National Inst. of Photon Counters, Jing Xu1; Univ., China. Here we demonstrate picosecond pumped super- Information and Communications 1Zhejiang Univ., China. The trans- a high spatial resolution fiber-optic continuum by a weak CW trigger, Tech., Japan. Space-division-multi- mission distance of underwater magnetic field sensors based on Qian Li1, Renlai Zhou1, Rongle plexing is proposed as a means of increasing wireless optical communication (UWOC) is Lorentz force or magnetic particles in a Huang1 and H.Y. Fu2; 1Peking Univ., China; capacity and efficiency in optical fiber severely limited by the rapid decay of light graphene NEMS. The ultra-compact design 2Tsinghua-Berkeley Shenzhen Inst. (TBSI), communication by using fibers with multiple intensity in water. Ultra-sensitive multi-pixel of this all-fiber-based sensor is achieved by China. Raman soliton at 2μm is experimentally cores, cores supporting multiple modes and photon counter (MPPC) opens the door integrating a modified graphene membrane observed in the CW-triggered picosecond fibers utilizing both approaches to maximize toward designing long-reach UWOC systems. onto the hollow endface of a single-mode pulse pumped super-continuum (SC) gene- the number of spatial channels. Here, we fiber. ration in a highly nonlinear dispersion shifted focus on single-mode multi-core fibers and fiber (HNL-DSF). We will discuss our expe- related components. We describe experi- riment findings and simulation results. ments that aim to characterize their basic properties, describe how they can be used to increase efficiency and cost savings and demonstrate the potential for ultrahigh- capacity transmission.

Th1A.2 • 08:30 Invited Th1B.2 • 08:30 Invited Th1C.2 • 08:30 Invited Th1D.2 • 08:30 Invited

Ultra-long-haul transmission using Networking in Space Terrestrial Fiber polarization modulation Spectral detection and target multi-core fibers, Itsuro Morita1; Integrated Networks, Baokang based on magnetic fluid, Rende recognition based on super- 1KDDI Research, Japan. Zhao1, Changjiang Fei1, Wanrong Ma1 and Yunjie Xia1; 1Qufu Normal continuum broadband laser Yu 1 and Chunqing Wu1; 1National Univ., China. We demonstrate in-line illumination, Xiaohui Gao1; 1Xi'an Univ. of Defense Tech., China. We fiber polarization modulators based Inst. of Optics and Precision propose an IP-based hierarchical space terre- on the magneto-optical dichroism of Mechanics, China. The super-continuum laser strial integrated network architecture. In HIPA, magnetic fluid. Modulations of both polari- technology can provide illumination for hyper- the space-based network is divided into three zation degree and polarization direction were spectral sensors in order to break many limits

Thursday, 8 August levels: intra-satellite network, inter-satellite realized. Fiber magnetic field sensor and of hyperspectral imagers that rely on solar network and satellite-ground network, each of biosensor were also developed. illumination. It can also improve target which uses IP protocol. detection performance of hyper-spectral imaging systems.

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08:00-10:00 08:00-10:00 08:00-10:00 08:00-10:00 08:00-10:00 Th1E • Novel fibers & devices V Th1F • Optical measurement VII Th1G • Optoelectronics VI Th1H • Organic & nano Th1I • Quantum photonics VII Shuqin Lou Xiaopeng Dong Presider: , Beijing Presider: , Presider: Zhenzhou Cheng, optoelectronics VII Presider: Feng Chen, Xi'an Jiaotong Univ., China Xiamen Univ., China Tianjin Univ., China Lixiang Wang, Presider: Jiaotong Univ., China Changchun Inst. of App-lied

Th1E.1 • 08:00 Invited Th1F.1 • 08:00 Invited Th1G.1 • 08:00 Invited Th1H.1 • 08:00 Invited Th1I.1 • 08:00 Invited Research progress of Sensitivity-enhanced ref- Chaotic dynamics and Interfacial modification for Multiphoton entangle- photonic crystal fiber ractive index sensor applications of semicon- flexible organic and pero- ment and its applications, and its applications, based on series struc- ductor laser with chirped vskite solar cells, Changqi He Lu1; 1Shandong Univ., Meisong Liao1; 1Shanghai ture of two microfiber grating feedback, Ma1; 1Suzhou Inst. of Nano- China. Inst. of Optics and Fine knot resonators with Anbang Wang1; 1Taiyuan Tech and Nano-Bionics, Mechanics, China. Vernier effect, Zhiwei Lu1 and Yunxu Univ. of Tech., China. China. Flexibility is one of the most Sun1; 1Harbin Inst. of Tech., Shenzhen, important features of polymer and China. This paper proposes and ex- perovskite solar cells that are perimentally demonstrates a sensi- different to the traditional inorganic tivity-enhanced refractive index (RI) solar cells. Special emphasis will be sensors based on Vernier effect. put into the development of Vernier effect achieved by series interface materials for these cells. structure of two microfiber knot resonators.

Th1E.2 • 08:30 Invited Th1F.2 • 08:30 Invited Th1G.2 • 08:30 Invited Th1H.2 • 08:30 Invited Th1I.2 • 08:30 Invited Excessively tilted fiber A Nonlinear Tuning Routing of photonic Pintable Mesoscopic Measuring the quantum

grating based fiber sen- Compensation Method integrated circuits for Perovskite Solar Cells, measure-ment, Lijian August 8 Thursday, sors, Zhijun Yan1, Yuezhen for OFDR System Based mode division multipl- Hongwei Han1; 1Huazhong Zhang1; 1Nanjing Univ., Sun1, Tean Lu 1, Chengbo on Polynomial Regre- exing, Ke Xu1; 1Harbin Inst. Univ. of Science and Tech., China. Mou2, Qizhen Sun1, ssion Algorithm, Jianfei of Tech., Shenzhen, China. China. The printable pero- Kaiming Zhou3, Deming Liu1 and Lin Liu1, Xujun Fan1, Mingming Luo1, We demonstrate the first MDM vskite solar cells were developed Zhang4; 1Huazhong Univ. of Science Xiangye Zeng1, Jie Liu1 and Wenrong circuits which have extremely com- with triple mesoscopic layers. The Tech., China; 2Shanghai Univ., China; Yang 1; 1Hebei Univ. of Tech., China. A pact footprints. Three channels of conjugated or non-conjugated bifu- 3Aston Univ., UK; 4Aston Univ., China. nonlinear tuning compensation me- 112 Gbit/s signals encoded on each nctional molecules were introduced

We would give a detailed review thod for optical frequency domain mode are arbitrarily routed through into the perovskite materials to about Ex-TFGs, including its theore- reflection systems based on polyn- the circuits consists of many sharp enhance their stability and efficiency. tical and experimental analysis of Ex- omial regression algorithm is propo- bends and compact crossing. TFGs, fabrication method, and sed. sensing applications in bio-sensing, loading, twisting, bending, vector magnetometer field.

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ICOCN 2019—Thursday, 8 August

Room 2, Track 2 Room 3, Track 9 Room 5, Special 5 Room 6, Special 4

Th1A.3 • 09:00 Invited Th1B.3 • 09:00 Invited Th1C.3 • 09:00 Invited Th1D.3 • 09:00 Invited Nonlinearity-tolerant multidimensional Optics and photonics illuminate All- fiber high-order mode (HOM) Design and fabrication of modulation formats for high speed the future of space TT&C System, beam generation and applica- chalcogenide waveguides for optical communications, Bin Chen1, Haifeng Yang1, Lin Chai1, Dian Li1, tion in magnetic field sensor, nonlinear optical applications, Sjoerd Heide1, Yi Lei2, Chigo Okonkwo1 Li Lei1 and Jianping Hu1; 1South- Xianglong Zeng1; 1Shanghai Univ., Bin Zhang1; 1sun yat-sen Univ., and Alex Alvarado1; 1Eindhoven Univ. of west China Inst. of Electronic Tech., China. Using mode interference in China. I will summarize the recent Tech., Netherlands; 2Hefei Univ. of Tech., China. A China. Currently, the TT&C system are all-fiber structure, we achieve strain sensor, prograss of nonlinearity application inclu- novel 4D 64-ary polarization-ring-switching format limited by "electronic bottle-necks." There- refractive index sensor and magnetic field ding super-continuum, optical frequency is investigated in WDM systems. Numerical simu- fore, the introduction of laser and photonic sensor based on the wavelength selection comb and sensors based on ultralow loss lations and experimental results show a reach inc- technology may change the existing TT&C and application of ring cavity fiber laser. Also chalcogenide chips. rease of 16% with respect to PM-8QAM. system. An overview of laser and photonics an all-fiber acousto-optic frequency shifter technology in TT&C system is presented. based on mode conversion is demonstrated Th1D.4 • 09:30 to obtain micro-vibration measurement. The Effects of Laser Polarization on The Performance of Terahertz Time-domain Spectrometer, Qing Sun1, Meiqi Feng1, Qing Ding2, Yuqiang Deng1 and Zheng Li1; Th1A.4 • 09:30 Invited Th1B.4 • 09:30 Th1C.4 • 09:30 Invited 1National Inst. of Metrology, China; 2China Remote mode forming over multimode An Optical Communication System Recent progress of fiber-optic National Inst. of Standardization, China. A fiber, Haoshuo Chen1; 1Nokia Bell Labs, Adjusting Method for GEO Satellites, weak magnetic field sensor, Qi fiber-type terahertz time-domain USA. we use reflective spatial pilots at Yuwei Su1, Jie Yin1, Tao Dong 1, Huifeng Shi1 Wang1; 1Northeastern Univ., China. spectrometer was designed by combining the distal end of the MMF to measure and Shiliang Li2; 1State Key Laboratory of The application of optical fiber fiber femtosecond laser with fiber-coupled transfer matrix remotely. Transmitter-side Space-Ground Integrated Information Tech., sensor in weak magnetic field photo-conductive antenna. The effects of MIMO-processing is applied for mode forming China; 2Inst. of Spacecraft Application detection has its unique advantages and has laser polarization on the terahertz time- over MMF. System Engineering China Academy of broad application prospects in weak domain waveform, intensity and spectral Space Tech., China. This paper proposed an magnetic field detection. In view of the characteristics are studied experimentally. optical communication system adjusting current situation of optical fiber magnetic

method for the GEO satellites to guarantee field sensor, the principle and characteristics not only the coherent detection of the sensor are studied and analyzed, Th1D.5 • 09:45 communications among the GEO satellites which provides a new method for theoretical Time Advancement Induced by Forward but also the direct detection research and practical appli-cation of weak Stimulated Brillouin Scattering in Small- communications with the LEO satellite. magnetic field measurement technology. core Photonic Crystal Fibers, Dongming 1 1 1 1

y, 8 August 8 August y, Wu , Shanglin Hou , Jingli Lei , Xiaoxiao Li , Daobin Wang1, Huiqin Wang1 and Minghua Cao1; 1Lanzhou Univ. of Tech., China. The time advancement is derived by using the Thursda three-wave coupled wave equations of FSBS. By the finite element method, the Brillouin frequency shift and gain factor of FSBS are simulated.

10:00-10:30 Poster Session 4 & Coffee Break, 4F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 65

ICOCN 2019—Thursday, 8 August

Room 7, Track 1 Room 8, Track 6 Room 10, Track 4 Room 11, Special 1 Room 12, Track 10

Th1E.3 • 09:00 Invited Th1F.3 • 09:00 Invited Th1G.3 • 09:00 Th1H.3 • 09:00 Invited Th1I.3 • 09:00 Invited Sapphire fiber Bragg High-sensitive all-fiber Bulk Heterojunction-Assisted Pe- Coupled nanogenerators Network architecture and gratings for high-tempe- Fabry-Perot interferome- rovskite Grain Growth for High- and sensors, Ya Yang 1; error-suppressed quan- rature measureements, ter gas refractive index Performance Photovoltaic Devices, 1Beijing Inst. of Nano- tum computation, Ying Li1; Jun He1, Xizhen Xu1, sensor based on lateral Yanliang Liu, Sung Heum Park; Puk energy and Nanosystems, 1China Academy of Changrui Liao1 and Yiping offset splicing and Ver- yong National Univ., South Korea. China. Engineering Phy., China. Wang1; 1Shenzhen Univ., China. nier effect, Yuqiang Yang1, Yuxin Perovskite optoelectronic devices Quantum error correction can tell us Sapphire fiber Bragg gratings Zhao1 and Yongguang Wang1; 1HUST, have attracted significant attention how to design a quantum computing (SFBGs) were fabricated by a China. A FP interferometer gas refra- as promising candidates for next- network. Quantum error mitigation femtosecond laser multi-layer line- ctive index sensor based on lateral generation optoelectronic devices. can reduce the effect of errors in by-line scanning technique. The offset splicing and Vernier effect is simple computations. Without quan- SFBGs have an increased reflectivity demonstrated, which is fabricated by Th1G.4 • 09:15 tum error correction, we need to of 36.67% and can withstand a high splicing a SMF between the lead-in High speed and high power pho- build nearterm quantum computers temperature of 1612 °C. SMF and another SMF with a specific todiode with 50 GHz band-width, supporting error mitigation. length. Yaojiang Chen1 and Baile Chen1; 1 Th1E.4 • 09:30 Invited Th1F.4 • 09:30 ShanghaiTech Univ., China. We Th1H.4 • 09:30 Invited Th1I.4 • 09:30 High-density multi-fiber Ellipsometry characterization of ul- report a normal incident high speed A feasible choice for Vector Vortex Beam Emitter connection technology tra-fine amorphous layer on sap- high power modified uni-traveling biotrac-king, Daiwen Embedded in a Photonic Chip, Yuan for multi-core fibers, Yuki phire substrate surface, Huihui Li1, carrier photodiode with 3dB band- Pang1; 1Nankai Univ., Chen1, Jun Gao1 and Xianmin Jin 1; Saito1, Tetsuya Hayashi1, Changcai Cui1 and Subiao Bian1; width of 50 GHz and responsivity of Wuhan Univ., China. 1Shanghai Jiao Tong Univ., China. We Ken Manabe1, Shuhei 1Huaqiao Univ., China. The thickness 0.1 A/W at -3 V bias voltage. demonstrate vector vor-tex beam Toyokawa1, Tetsu Morishi-ma1, Takuji of nano-meter amorphous layer and emitter embedded in a photonic Nagashima1, Tetsuya Nakanishi1 and surface roughness on sapphire sub- Th1G.5 • 09:30 chip. It makes vector vo-rtex beam Tomomi Sano1; 1Sumitomo Electric strate surface were measured rapidly Liquid Crystal Tunable Narrow directly ready for further transmission, Industries, Ltd., Japan. We will review and non-destructively using spectral Linewidth Filter Based On Sub- manipulation, and emission without multi-fiber connection technology ellipsometry. wave-length Gratings Reflector, any additional interconnection. Baoying Liu1, Yongqing Huang1 and for multi-core fibers, which enabled August 8 Thursday, Th1F.5 • 09:45 1 1 ultra-high-density 256-core MPO Huanhuan Wang ; BUPT, China. We Th1I.5 • 09:45 Highly Sensitive Fiber Optic present an electro-tunable liquid cone-ctor with standard 22-N mating Pressure Sensor Based on Silica Quantum plasmonic N00N state in crystal(LC) filter consisting of a DBRs 1 force, and passive rotational align- Diaphragm Fabricated by MEMS, a silver nanowire, Yang Chen and and SWGs reflectors which enables 1 1 ment of double-D-shaped MCFs on 1 1 Xifeng Ren ; Univ. of Science and Xu Guo , Jing Cheng Zhou , Cong uniform alignment of LC. The filter V-groove array with <0.5-dB inser- Du1 and Xingwei Wang1; 1Univ. of Tech. of China, China. We tion loss. achieves a wide-continuous tuning experimentally demonstrate the Massachusetts Lowell, USA. We range of 60nm and a linewidth of less present the fabrication procedure of excitation and propagation of a two- than 1nm. plasmon entangled N00N state in a 1.2-μm thick silica diaphragms using MEMS technique. A fiber optic FP silver nanowire. pressure sensor was made with the diaphragm. The obtained sensor has a pressure sensitivity of 12.4 nm/kPa.

10:00-10:30 Poster Session 4 & Coffee Break, 4F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 66

ICOCN 2019—Thursday, 8 August

Poster Session 4（10:00-10:30）

P4.1 P4.4 P4.8 P4.11 PEG based Construction of Irregular QC- The Highly Tunable Graphene Ring Modul- Dynamic Neural Network Enabled 50 Gb/s Sensitive detection of humidity based on LDPC Codes by jointly Optimizing the Girth ator, Yuhan Yang1, Feng Zhou1; 1The Highly PAM-4 IM/DD Transmissions Based on 10G- tilted fiber Bragg grating coated with and the Number and ACE of Short cycles, Tunable Graphene Ring Modulator, China. Class Optical Devices, Qianwu Zhang1, Hai Graphene oxide and multi-walled carbon Dongdong Wang1, Yantao Guo1, Zhihui We propose a ring modulator based on few- Zhou1, Min Liu1, Tingting Xu1, Yuntong Jiang1, nanotubes, Yang Zhang1, Yan Qiao1, Fang Wang2, Liqian Wang2 and Xue Chen2; 1the layer graphene. The shift of resonance wave- Aoqun Jian2, Yingxiong Song1, Yingchun Li1, Wang1, Yifan Duan1, Zhenguo Jing1, Zhenlin 54th Research Inst. of China Electronics Tech. length can be enlarged to 20.3 nm and a large Junjie Zhang1, Jian Chen1 and Bingyao Cao1; Wu1, Yuan Gong2 and Wei Peng1; 1Dalian Univ. Group Corporation, China; 2BUPT, China. By extinction ratio of 15.5 dB can be obtained. 1Shanghai Univ., China; 2Taiyuan Univ. of Tech., of Tech., China; 2Univ. of Science and Tech. of jointly optimizing the Girth and the Number China. Dynamic neural network based China, China. A functionalized TFBG sensor and ACE of Short cycles of irregular QC-LDPC P4.5 equalization scheme is experimentally based on GO and MNCNT was proposed for codes, better error floor performance is Improving Multicast Routing Performance demonstrated for 50 Gb/s PAM-4 signal tran- the detection of environmental relative achieved when compared with the recent in Surface Wave Optical Network-on-Chip, smissions based on 10G-class optical devices. humidity. The relative humidity detection proposed construction methods. Chuang Liu1 and Weigang Hou1; 1Chongqing range is 30%-90%, the maximum sensitivity is Univ. of Posts and Telecommunications, China. 0.32/%RH. Considering the broadcasting communi- P4.2 cation feature of surface wave, we construct a P4.9 P4.12 An Improved FPGA Parallel Design of two-layer hybrid ONoC architecture, and a Long Distance IM/DD Transmission with Ultrasensitive refractive index sensor based Frequency Offset Estimation, Yupeng multicast routing strategy suitable for this OFDM-QAM based Quantum Noise Stream on Cascaded tilted fiber Bragg grating, Lin Wang1, Liqian Wang1, Zhiguo Zhang1, architecture is also proposed. Cipher, Wenyan Mao1, Yifan Shen1 and Jin1 and Yonglin Huang1; 1NUPT, China. An Shanyong Cai1, Luming Li2, Jiangxing Chen2, Haidan Liu1; 1BUPT, China. We propose a ultrasensitive refractive index sensor based on Xing Liu2 and Ziyang Xiao2; 1BUPT, China; P4.6 QAM-based quantum noise stream cipher cascaded tilted fiber Bragg grating is 2Jiangxi Electric Power Company, China. In Research on all-fiber deep sea pressure (QNSC) scheme for IM/DD transmission proposed and simulated, when the surround- coherent optical communication QPSK sensor, Liang Cao1, Yu 1, Xiao1, Junbo Yang2, employing orthogonal frequency division ing refractive index increases from 1.44322 to system, an improved FPGA parallel design of Zhang1 and Zhou Meng2; 1Hunan Aerospace multiplexing (OFDM) modulation. Secure 1.44330, the sensitivity of the sensor is frequency offset estimation with low Inst. of Electromechanical Devices and transmission of 2.5Gbit/s IMDD-OFDM signal 9.39×105 dB/RIU. complexity is proposed. The BER simulation Special Material, China; 2National Univ. of is demonstrated over 1000 km distance.

results compared with serial scheme verify the Defense Tech., China. Theoretically analyzed feasibility of the parallel design. and experimentally demonst-rated an all-fiber pressure sensor based on a microfiber coupler combined SAGNAC loop. The work P4.13 P4.3 of this pa-per proves the usability of the P4.10 High-power vertical-cavity surface-emitting Composite transparent conductive structure in the deep sea environment. The Study of Data Processing System for the laser with a metal/DBR hybrid reflector, electrode for printed electronic devices, Hu FBG Temperature Sensor Network Based on Junwei Luo1, Kai Liu1, Qi Wei1, Yongqing Meimei1, Liu Zugang1 and Dong Qianmin1; P4.7 the Hadoop Platform, Guoyu Li1, Kang Yang1, Huang1, Xiaofeng Duan1, Qi Wang1, Xiaomin 1China Jiliang Univ., China. Transparent Quantum-dot light-emitting diodes with Zhihui Wang1, Mengyun Pan1 and Yan Li1; Ren1 and Shiwei Cai1; 1BUPT, China. The Thursday, 8 August conductive electrode consists of three NiO and NiO:Mg as hole injection layer, 1Handan Univ., China. A data processing design and fabrication of a hybrid metal– materials: AgNWs /ZnO -NPs/ rGO. The Liwei Zheng1, Xin Wang1 and Zugang Liu1; system based on the Hadoop platform is semiconductor Distributed Bragg Reflector composite electrode have low sheet 1CJLU, China. The energy band structures of proposed. The design of the system provides (DBR) for optically pumped vertical-cavity resistance of 9.96 Ω and high optical NiO can be adjusted by Mg doping. NiO and a basic platform to the big data for FBG surface-emitting laser(VCSEL) are proposed. transmittance about 71% (T550), which has Mg-doped NiO serve as a good hole injection temperature sensor network. This structure can decrease the series long-term stability in air. layer materials for QLED. resistance, and improve the output power of VCSEL.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 67

ICOCN 2019—Thursday, 8 August

Poster Session 4（10:00-10:30）

P4.14 P4.17 P4.20 P4.24 Capacity Expansion based Network Failure A Deep Learning Based RSA Strategy for Application of ultra-stable laser in coherent Numerical Simulation of Ground-to-Satellite Recovery with Genetic Algorithm, Geng Elastic Optical Networks, Jiaoliang Yu1, optical frequency transfer, Dongdong Jiao1, Laser Transmission based on Unequal Zhang1, Xueyu Kang2, Yanan Wang1, Meng Cheng Hang1, Jianhua Shen1, Bokai Cheng1, Linbo Zhang1, Qi Zang1, Xue Deng1, Jing Gao1 Spacing Phase Screen, Xuzhou Liu1, Qi Llian2, Yang Wang1, Rentao Gu2 and Huixia Yunfei Hu1, Shixin Liu1 and Yutong Wang1; and Xiang Zhang1; 1National time service Zhang1, Xiangjun Xin1, Qinghua Tian1, Ying Ding1; 1China Electric Power Research Inst., 1NUPT, China. A deep learning based routing center, China. An ultra-stable laser with a Tao 2, Feng Tian1, Yufei Shen2, Guixing Cao2, China; 2BUPT, China. To overcome the net- and spectrum assignments (RSA) strategy is linewidth of 0.6 Hz is used in optical frequency Dong Chen2, Yongjun Wang1 and Leijing work bottleneck when a failure occurs, a proposed, which will find the optimal RSA transfer over a 112 km-long urban fiber link, Ynag1; 1BUPT, China; 2China Academy of capacity-expansion based recovery model is method for a specific network, thus improving the transfer instability of 5.0× 10-17at 100 s are Space Tech., China. The numerical simulation established, and is solved by genetic algo- the overall network performance. obtained. method of multi-layer phase screen step-by- rithm under link recovery and path recovery step transmission is used to study the strategies, achieving the minimal network P4.18 P4.21 influence of atmospheric turbulence on the expansion cost. Polarization-fading-free distributed acoustic Refractive index sensing based on upstream transmission of satellite-ground sensing system, Tingxi Sun1, Xiaohui Hu2, claddingless fiber and core-offset structure, optical communication. P4.15 Sheng Wang1, Feng Xie2 and Jiangjing Cui1; Qihang Cheng1, Ailing Zhang1, Wen Li1 and An Optimization Scheme based on 1Zhuhai Power Supply Bureau, China Ce Sun1; 1Tianjin Univ. of Tech., China. A P4.25 Transmitters Selection for MIMO VLC Southern Power Grid, China; 2Allian Stream Mach-Zehnder interferometer based on Two-Dimensional Mixed Lead-Tin Halide Systems, Cheng Hang1, Jiaoliang Yu1, Bokai Photonics Tech. Company, China. A fiber- singlemode- claddingless - singlemode core- Perovskites for Visble Light-Emitting Diodes, Cheng1, Yutong Wang1, Yunfei Hu1, Shixin optic distributed acoustic sensing system offset structure is proposed and experiment- Jing Wang1, Zugang Liu1, Junjie Si1 and Liu1 and Jianhua Shen1; 1NUPT, China. This based on polarization diversity technology is tally demonstrated. The refractive index sen- Minghao Lu1; 1China Jiliang Univ., China. We paper presents an in-depth study on the proposed and demonstrated. Without the sitivity is 162.64 nm/refractive index unit (RIU). report the gradual reduction of lead content channel matrix of the MIMO visible light polarization fading phenomenon, the false in two-dimensional perovskites by substi- communication system. The singular value alarm rate is considerably reduced, making P4.22 tuting lead with non-toxic tin for preparation decomposition (SVD) is used to select the the system much practicable for real Optimized Quantum Dot Light-emitting- of two-dimensional perovskites light-emitting transmitters which have good performance applications. device with Insulating Layer, Xin Wang1 and diodes (PeLEDs) with different tin-lead ratios. for transmission. Zugang Liu1; 1China Jiliang Univ., China. We reported the preparation of CdSe/CdS/ZnS Thursday, 8 August 8 Thursday, P4.16 P4.19 based quantum dot light-emitting-devices P4.26 Functional-Link Neural Network Based Two-mode multiplexer based on the with an ultra-thin PMMA layer. A Large Dynamic Range Interferometric Nonlinear Equalizer, Pinping Lei1, Shaohua multilayer Si-SiN platform for 2μm Fiber Strain Sensor, Liang Zhang1, Zijie Zhu1, Hu1, Jing Zhang1, Bi Tang 1, Yuzhong Feng1, waveband, Wanjun Wang1, Jia Xu Brian Sia1, P4.23 Mengke Yin1 and Yuming Dong1; 1Shenzhen Kun Qiu2 and Jin Huang3; 1Univ. of Science Zhongliang Qiao1, Xiang Li1, Xin Guo1, Jin Sensitivity Optimization Analysis of Phase Inst.s of Advanced Tech., Chinese Academy of and Tech. of China, China; 2Univ. of Elec. Scie. Zhou1, Chongyang Liu1, Callum G. Littlejohns2, Modulated Fiber Sensor, Wen Li1, Ailing Sciences, China. A large dynamic range &Tech. of China, China; 3Chengdu Univ. of Graham T. Reed2 and Hong Wang1; 1Nanyang Zhang1, Qihang Cheng1 and Ce Sun1; 1Tianjin interferometric strain sensor based on a information technology, China. We propose Technological Univ., Singapore; 2Univ. of Univ. of Tech., China. A D-type phase- specifically designed interferometry is pro- and experimentally demonstrate a simple and Southampton, United Kingdom. We experi- modulated optical fiber sensor model using posed. We simultaneously achieve a high versatile nonlinear equalizer based on mentally demonstrated a two-mode multi- graphene and oxide is proposed and resolution of 0.22 micro-strain as well as a functional-link neural network in a 128-Gb/s plexer in the multi-layer Si-SiN platform for sensitivity is optimized from the type and large measurement range of 750 micro-strains. single carrier dual-polarization 16-QAM signal 2um waveband. The insertion loss of the thickness of oxide. The sensitivity of sensor transmission over 600 km. The BER can be mode multiplexer link is less than 2.2 dB using graphene-TeO2(35nm) achieved 134670 reduced by half. across the wavelength 1945 nm-1985 nm. deg/RIU.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 68

ICOCN 2019—Thursday, 8 August

Poster Session 4（10:00-10:30）

P4.27 P4.30 P4.34 P4.37 Dynamic Service Provisioning Algorithm Energy Efficiency with Minimized-Regener- Wide-spectrum properties of Yb: YAG The Loss Characteristics of Curved Fiber at Based on Degree of Spectrum-Time ators Placement in IP-Over-Flexible Band- crystal-derived fiber, Ying Wan1, Jianxiang Small Radius, Lei Feng1, Fuyin Wang1, Fragmentation of AR Requests in Elastic width Optical Networks, Jiang Yunfei1, Chen Wen1, Ming Jia1, Zheng Liu1, Ziwen Zhao1, Shuidong Xiong1, Chunyan Cao1, Qiong Yao 1 Optical Networks, Yiqiang Li1, Qi Zhang1, Qi1, Lei Yu1, Zhang Qianwu2 and Chen Bowen1; Zhenyi Chen1 and Tingyun Wang1; 1Shanghai and Qiyong Tang1; 1National Univ. of Defense Xiangjun Xin1, Qinghua Tian1, Ying Tao2, 1Soochow Univ., China; 2Country Key Univ., China. We designed and fabricated an Tech., China. The bending loss characteristic Guixing Cao2, Feng Tian1, Yongjun Wang1, Laboratory of Specialty Fiber Optics and Yb: YAG crystal-derived fiber (YDF) by CO2- of curved fiber at small radius is theoretically Zhaoyu Wang1 and Dong Chen; 1Beijing Univ. Optical Access Networks, China. We propose laser drawing tower. The fluorescence spectra analysed and experimentally demonstrated. of Posts and Telecommunications, China; an optimized energy-efficient algorithm and amplifier characteristics were discussed in A modified five-layer slab waveguide theory is 2China Academy of Space Tech. (CAST), China. (OEEA) with minimized-regenerators place- detail. used. The bend loss has distinct oscillations at The dynamic service provisioning of AR ment to reduce energy consumption in IP- small radius. request in EONs is studied. The routing, over-flexible bandwidth optical networks. modulation, spectrum and time allocation P4.38 algorithm based on Spectrum-Time Fragmen- A novel hypergraph structured optical tation is proposed. The proposed algorithm P4.31 P4.35 network model, Sen Sun1 and Zu Yunxiao1; reduces blocking rate and request initial delay. Temperature sensitive Properties of Eu2+/ Generation of L-band Vector Soliton from 1BUPT, China. A new optical network model Mn2+ Co-doped Ca2Sr (PO4) 2, Yanting Zhu1, Dispersion-managed Er-doped Mode- based on hypergraph structure is proposed. Chenxia Li1 and Degang Deng1; 1CJLU, China. locked Fiber Laser, Zilong Li1, Huanhuan Liu1, The advantage of the model is verified by P4.28 Eu2+ / Mn2+ co-doped Ca2Sr (PO4) 2 Qiao Jiang1, Ye Yu 1 and Fufei Pang1; simulation ppba algorithm Enhanced Magneto-Optical Effects in phosphors have excellent optical temper- 1Shanghai Univ., China. The polarization- Magnetic Photonic Crystal Fiber Based on ature sensing properties. locked L-band vector solitons were generated P4.39 Yttrium Iron Garnet, Khadidja Saker1, Touraya from dispersion-managed Er-doped fiber Wavelength-tunable square pulse Bouchemat1, Mahieddine Lahoubi1, laser incorporating with carbon nanotubes for generation based on dissipative soliton Mohamed Bouchemat1, Shengli Pu2 and Yong P4.32 the first time. The vector solitons operate at resonance, Zihao Li1, Dongfang Jia1 and Xu liang Zhao2; 1Les Frères Mentouri Constantine Improvement of soliton pulse energy in wavelength near 1594.7 nm with repetition Sun1; 1Tianjin Univ., China. The generation of Univ., Algeria; 2Univ. of Shanghai for Science thulium-doped fiber laser, Quan Yuan1, Hao rate of 12.13 MHz. square pulses with different wavelengths 1 1 1 and Tech., China. A magnetic photonic crystal Xiong , Haiying Ji , Desheng Zhao , Runmin based on dissipative soliton resonance has fiber of YIG is presented. The results reveal an Liu1 and Tianshu Wang1; 1Changchun Univ. of been investigated. By fixing the pump power increased Faraday rotation and a reduced Science and Tech., China. We report a and changing the orientations of polarization modal birefringence. thulium-doped fiber. By adjusting cavity controllers, wavelength-tunable square wave parameters, Gaussian pulse with high pulse P4.36 pulses have been obtained. energy can be achieved. The pulse duration Harmonic noise-like square pulse in an Er: P4.29 of de-chirped pulse is 553 fs. The maximum Yb co-doped fiber laser at 1.61μm, Zhiyuan P4.40 A Miniature Near-infrared Spectrometer pulse energy is 2.96nJ. Dou1, Bin Zhang1, Shuailin Liu1 and Jing Hou1; Research on image feature matching Based on Linear Variable Filter, Zhen Wang1, 1National Univ. of Defense Tech., China. The algorithm based on feature optical flow and Thursday, 8 August Yanqing Qiu1, Bangning Mao1, Shangzhi P4.33 generation of high-power harmonic noise-like corner feature, Tao Song1 and Mingfu Zhao1; Zhong1 and Shenghua Zhou1; 1China Jiliang Circuit System Design of Handheld Near square pulses (NLSPs) is realized at 1.61 μm in 1Chongqing Univ. of Tech., China. In order to Univ., China. A miniature near-infrared spec- Infrared Spectrometer, Zhong Shangzhi1 and an Er: Yb co-doped all-fiber mode-locked improve the accuracy of feature point trometer based on LVF was developed. The Qiu Yanqing1; 1CJLU, China. A short overview laser for the first time. The maximum average matching for visual odometry, an accurate and working wavelength range of the spectro- on the building principles of novel handheld output power is about 1.26 W. fast algorithm combining the pyramid feature meter is 970nm-1630nm. The resolution spec- systems will be provided. optical flow and corner features based on trometer at the central wavelength is 15nm. image feature matching was proposed.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 69

ICOCN 2019—Thursday, 8 August

Poster Session 4（10:00-10:30）

P4.41 P4.44 P4.47 P4.50 Continuously Tunable Fano Resonance Ultra-thin optical hydrophone array based A Mathematical Expression of Bit Error Rate Ultraviolet Micro Optical-Fiber Spectro- Filter in a Fiber Taper Coupled Conical on fiber Bragg gratings, Zhen Guo1, Kan of PCM/FM Using Non-coherent Detection, meter Based on Linear array CMOS, Microcavity, Xiaozheng Tang1, Jieqing Deng2, Gao1, Hui Yang1, Zhiguo Dai1, Jun Zhang1 and Cong Bo1, Duan Qingguang1, Xia Lili1, Wang Shenghua Zhou1, Yanqing Qiu1 and Youxiang Yu Lu 3, Xu Wei2, Zhong Fan2, Chunlei Yu1, Bingyan Wu1; 1No. 23 Research Inst. of China Tianyun1, Yu Qinghua1, Gu Fufei1 and Chen Si1; Ye 1; 1Chongqing Univ. of Tech., China. An Xiang Zhang1, Lin Shi1, Mi Li3 and Yuejiang Electronic Tech. Corporation Group, China. A 1China Satellite Maritime Tracking and ultraviolet micro optical-fiber spectrometer Song3; 1State Grid Jiangsu Electric Power 32-elements hydrophone array with diameter Control Department, China. Based on the based on linear array CMOS is designed. The Maintenance Branch Company, China; 2State of 20mm is obtained based on the FBG-FP analysis of non-coherent detection, a mathe- resolution is better than 0.1 nm in the range Grid Jiangsu Electric Power Company, China; interferometer. Average acoustic pressure matical expression is derived. The analytical of 180-290nm. The wavelength error after 3Nanjing Univ., China. We have demonstrated sensitivity is -143.9dB re rad/μPa. Intrinsic result is verified by computer simulation and calibration is less than 0.03 nm. a continuously tunable optical filter based on noise, as crosstalk and polarization induced compared with other schemes. Fano resonance in fiber taper coupled conical fading, are investigated and restrained. P4.51 microcavity. Such the bandpass filter has a Simulation of analogue of electro- wavelength tunable coefficient of 0.22nm/mm. magnetically induced transparency (EIT) based on metal metamaterials, Jinjie Tao1, Gangqi Wang1 and Tingting Lang1; 1China P4.42 P4.45 P4.48 Jiliang Univ., China. The phenomenon of Surface modification of CdSe/CdS/ZnS Power generation and performance analysis Chaos in Frequency Domain using analogue of electromagnetically induced quantum dots with mercapto acid, Qi Meng1, of Bi-facial vs Mono-facial 10KW Photo- Multistable System with Fiber Michelson transparency (EIT) was theoretically realized Zugang Liu1, Jie Huang1, Tianmou Xu1, voltaic power station, H.D.Milan Ravinath interferometer, Yan Zhang1, Xu Jiang1, using metal metamaterials based on periodic Peiqing Cai1 and Yang Li2; 1China Jiliang Univ., Perera1 and Huiqing Wen2; 1Xi’an Jiaotong- Huiying Wang1, Bohan Luan1 and Guohui Lyu1; arrangement of one I-type cut wire (ICW) and China; 2Poly OptoElectronics Co. Ltd, China. Liverpool Univ., Sri Lanka; 2Xi’an Jiaotong- 1Heilongjiang Univ., China; 1Heilongjiang two spiral ring resonators (SRRs). We reported a simple method for cap Liverpool Univ., China. This paper is based College of Business and Tech., China. exchange of quantum dots using thiol and written on performance analysis of a Wavelength is used to induce optical P4.52 functional ligands. We transfer QDs from non- 10kW Grid connected solar power system nonlinearities and to generate chaos of Development of an ultrastable laser at polar to polar solvents by utilizing this facile with a comparison in integration of bifacial multistable state from a tunable fiber laser 1.5μm, Dongdong Jiao1 and Jing Gao1; method without significant fluorescence photovoltaic systems vs mono-facial photo- with fiber Michelson interferometer (FMI). 1National time service center, China. We Thursday, 8 August 8 Thursday, quenching. voltaic system. report the development of a narrow-linewidth laser at 1.5μm, the linewidth of 0.8 Hz and the fractional frequency instability of 3.4×10-15/s P4.43 P4.46 P4.49 are achieved. Volterra-based fiber nonlinearity impair- Hot-wire Anemometer Based on Etched A Novel Ship-rocking Forecasting Method ment modeling for OFDM/OQAM systems, Fiber Bragg Grating Coated with Silver based on Hilbert Transform, Yujian Li1, P4.53 Xi Fang1, Yixin Fu1, Ding Ding1, Lei Zhang1 and Film, Xuke Chen1, Xinyong Dong2 and Yixiang Xaohui Jiang1, Deyong Kang1 and Zhi Chen2; A Review of The Research of Microstrip Xianwei Gao1; 1Beijing Electronic Science and Sun3; 1China Jiliang Univ., China; 2Guangdong 1China Satellite Maritime Tracking and Array Antennas Based on Metamaterials, Tech. Inst., China. We have reported for the Univ. of Tech., China; 3Huazhong Univ. of Sci. Control Department, China; 2Univ. of Science Xuemei Zheng1 and Zhiqi Rong1; 1Northeast first time the application of Volterra-based and Tech., China. Hot-wire anemometer is and Tech. of China, China. We have analysed Electric Power Univ., China. The gain and fiber nonlinearity impairment modeling for proposed based on a Etched FBG coated with groups of ship-rocking time series utilizing a directivity of microstrip array antenna can be OFDM/OQAM systems. Based the proposed silver film assisted by a waist-enlarged optical Hilbert based method, which affects the improved by loading supermaterial structure. model, a novel compensation method can be fiber bitaper. Bragg wavelength of the FBG accuracy of the ocean-based aerospace Therefore, metamaterial array antenna is presented by simulations later. changes with velocity of airflow according to vehicle measurement. becoming a research hotspot. a certain relationship.

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Poster Session 4（10:00-10:30）

P4.54 P4.58 P4.61 P4.64 Measurement of profile height for plate Optical frequency transfer over 200km Study on Temperature Rise Characteristic of Mode-locked Er-doped and Yb-doped fiber surface with fiber Bragg grating, Naikui fiber link with an instability at 10-19 level, LED Lighting Fixture under Different lasers by using MoS2/SiO2 saturable Ren1 and Youlong Yu1; 1Hefei Univ. of Tech., Wang Dan1 and Liu Bo1; 1National Time Conditions, Limin Hu1, Mingzhong Xu1, absorber, Lu Li1; 1Xi'an Univ. of Posts and China. Measurement of profile height for Service Center, China. We have demonstrated Binqing Wu1, Zhangwan Wang1, Lei Zhang1, Telecommunications, China. A novel type of plate with fiber Bragg grating is proposed. an optical frequency transfer over 200 km fiber Yu Xia 1, Meijuan Hong1, Yangli Zhu1, Yanhua MoS2-doped sol-gel glass composite ma- Relationship between arithmetical mean link. Through phase noise cancellation, a Han1, Bin Ru1, Yueyang Yu1 and Yong Shu1; terial is prepared. By using the MoS2/SiO2 as height and maximum amplitude in fast transfer instability of 1E-16 @ 1 s and 4.5E-19 1hangzhou hpwinner opto corporation, China. saturable absorber, stable conventional and Fourier transformation of strain is linear and @ 100 s is achieved. The paper studied temperature rise charac- dissipative soliton are successfully generated sensitivity is 0.109με/μm. teristic of LED lighting fixture under different with pulse width of 780 fs and 13.8 ps. conditions, the influence of the cover on the P4.55 heat dissipation of LED lighting fixture was P4.65 Coherent phase transfer via urban fiber P4.59 larger than the dust. Erbium-doped random laser based on fiber links, Xue Deng1 and Jing Gao1; 1National Long-distance multi-site high-precision random grating, Chengrong Shen1, Ruifu time service center, China. We have optical fiber time transfer equipment, Bo Huang1 and, Xinyong Dong2; 1China Jiliang demonstrated coherent phase transfer via a Liu1, Kan Zhao1, Bo Li1, Faxi Chen1 and Dan Univ., China; 2Guangdong Univ. of Tech., 666 km urban fiber link. The phase noise Wang1; 1National Time Service Center, P4.62 China. A random fiber laser based on random introduced by the fiber is suppressed and a Chinese Academy of Science, China. Long- Peanut-type fiber based hydrogen sensor grating with a half-open cavity is experi- transfer instability of 4E-18 at 10000 s is distance multi-station high-precision optical coated by PDMS covered with WO3/SiO2, mentally demonstrated in this paper. The achieved. fiber time transfer equipment can synchronize Shuyi Liu1, Changyu Shen1, Chong Zhang1, pump threshold is only 17 mW by using a 980 the time and frequency of multiple receivers Huitong Deng1, Jing Yu1 and Jiahao Fang1; nm pump laser. P4.56 by using a transmitter, and can realize the 1China Jiliang Univ., China. A hydrogen sensor Development of Optical Cavity for Trans- time and frequency synchronization of long- based on a Peanut-type fiber coated with a P4.66 portable Ultrastable Laser, Guanjun Xu1; distance multi-station. film of PDMS covered with WO3/SiO2 hybird Novel NOMA System for Optical 1National Time Service Center, China. 1.55 um powder was proposed. The hydrogen Communications Based on OFDM/OQAM, ultra-stable laser is a key for high-precision sensitivity of 15 nm/% was obtained. Yueyang Yu1, Xi Fang1 and Lei Zhang1; 1Beijing

coherent phase transmission in optical fiber Electronic Science Technology Institute, links. A spherical cavity for transportable ultra- P4.60 China. We present a NOMA-based OFDM/ stable lasers is designed. An analysis of the abnormal condition of OQAM system theoretically. Our method photoelectric deviation of a task on ship- P4.63 outperformed OFDM system on the total user P4.57 borne equipments, Chen Hongying1, Yang Measurement of complex optical suscep- throughput and spectral efficiency evidently. Coherent optical frequency transfer over a Lei1 and Guo Caifa1; 1China Satellite Maritime tibility for individual carbon nanotubes by 232+128km fiber link with a fractional Tracking and Controlling Department, China. elliptically polarized light excitation, Fengrui P4.67 frequency instability of 10^-19 level, Zhang Aim at measuring ship at some the accuracy Yao 1; 1Peking Univ., China. we report a Ultracompact add-drop filters based on Xiang1, Xue Deng1, Jie Liu1, Qi Zang1, Kan authenticate process front the one mission methodology to measure the complex optical single-nanobeam photonic crystal cavities,

Thursday, 8 August Zhao1, Jing Gao1, Dongdong Jiao1 and Tao measure equipments Photoelectric deviation susceptibility of individual 1D materials by an Ping Yu1; 1Zhejiang Univ., China. We report Liu1; 1National Time Service Center, China. abnormality, equipments light axis and elliptical-polarization-based optical homo- our simulations and experiments on ultra- This work demonstrates an optical frequency electricity axis calibration, find out dyne detection. We successfully demon- compact add-drop filters based single-nano- transfer link over a 232+128km commercial understanding measure definitely, for follow- strate its application in determining complex beam photonic crystal cavities. The proposed fiber networks with a fractional frequency up mission data processing. susceptibility of individual chirality-defined device requires only one nanobeam photonic instability 3×10-19@10000s. carbon nanotubes. crystal cavity which is more compact and would consume fewer tuning power.

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P4.68 P4.71 A Review of the Development of Microstrip Location Method Based on Support Vector Filters, Xuemei Zheng1 and Xudong Wang1; Machine for Distributed Sagnac Fiber 1Northeast Electric Power Univ., China. This Sensing System, Jidong Lv1, Nian Fang1 and 1 1 paper summarizes the research of microstrip Lutang Wang ; Shanghai Univ., China. A bandpass filters in recent years, and provides location method based on support vector ideas for future research. machine for distributed Sagnac fiber sensing system is proposed. The location of different fiber segments is converted into a multi- classification problem of interference signals caused by external disturbances.

P4.69 P4.72 First Principles study of nanostructured VS2 On-Line Collision Hazard Assessment for electrodes for Na-ion batteries, Shenghua Fractionated Satellite Clusters with Zhou1, Youxiang Ye1 and Haihua Li1; 1CJLU, Proximity Relative Motion, Weiwei Yang1, China. The dynamic structural evolution and Fuchun Nian1 and Yubo Li1; 1China Satellite reaction kinetics of VS2-based nanosheets as Maritime Tracking and Control Department, anode materials for NIBs was reported by China. A new collision hazard assessment using DFT calculations. method based on performance parameters is presented that accounts for the navigation system, the control capability and the communication performance. Simulation results show its efficiency for fractionated P4.70 satellite clusters. Analysis of phase difference of acceleration Thursday, 8 August 8 Thursday, fiber optic vector hydrophone based on signal-to-noise ratio, Chuntao Wang1, Shu qing Ma1, Zhou Meng1 and Jianfei Wang1; 1College of Meteorology and Oceanography, National Univ. of Defense Tech., China. The influence of SNR and frequency on the phase difference of the acceleration fiber optic vector hydrophone is analyzed and verified by simulation, laboratory measurement and experimental data at sea.

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Room 2, Track 2 Room 3, Track 9 Room 5, Special 5 Room 6, Track 7

10:30-12:30 10:30-12:30 10:30-12:30 10:30-12:30 Th2A • Optical transmission VI Th2B • Space communications II Th2C • Fiber magnetic devices II Th2D • Ultrafast & nonlinear optics V Presider: Danshi Wang, BUPT, China Presider: Jianfei Liu, Hebei Univ. of Presider: Changyu Shen, China Jiliang Presider: Peiguang Yan, Shenzhen Univ., Tech., China China Univ., China

Th2A.1 • 10:30 Invited Th2B.1 • 10:30 Invited Th2C.1 • 10:30 Invited Th2D.1 • 10:30 Invited Energy saving technique for real- Adaptive beam control techniques Cavity optomechanical magneto- Deterministic single soliton time OFDM-PON, Junjie Zhang1, for high-altitude airborne free- metry, Beibei Li1; 1Inst. of Physics, generation driven by chirped Jiahe Zhao1, Qinyang Yu1, Hanzi space optical communication sys- Chinese Academy of Sciences, optical pulses in Kerr micro- Huang1, Jian Chen1, Yingxiong Song1, tems, Vuong V. Mai1 and Hoon Kim1; China. We have achieved ultra- resonator, Jianxing Pan1, Qian Yingchun Li1, Bingyao Cao1 and 1Korea Advanced Inst. of Sci. & sensitive magnetometry by Wei1, Zhuo Cheng1, Tianye Qianwu Zhang1; 1Shanghai Univ., China. To Tech., South Korea. We present a rapid and sputter coating a thin layer of magne- Huang1, Chaolong Song1, Ping Shum2 and reduce the high power consumption in future computation power-efficient adaptive beam tostrictive material into a high-Q optical Gilberto Brambilla3; 1China Univ. of Geos- optical access networks, novel DSP complexity control technique for high-altitude airborne microcavity. We also demonstrated quantum ciences (Wuhan), China; 2NTU, Singapore; reduction schemes for real-time IMDD-OFDM- free-space optical communication systems light enhanced magnetometry. 3Univ. of Southampton, UK. Deterministic PONs based-on the effective word-length to mitigate the deleterious effects of angle- single soliton can be produced when the optimization and energy-saving techniques are of-arrival fluctuation and pointing error chirp parameter is larger than the threshold introduced and experimental demonstrated on simultaneously. with proper final pump phase detuning. The FPGA-based platform. soliton peak power and bandwidth can be simply controlled by the final detuning. Th2A.2 • 11:00 Invited Th2B.2 • 11:00 Invited Th2C.2 • 11:00 Invited Invited High speed secure optical Spatial diversity based on recei- High-sensitive magnetic field Th2D.2 • 11:00 communication based on optical ver array for high-sensitivity free- sensor based on serial-tilted- Ultrafast fiber lasers and their code processing, Zhensen Gao1, Xu space optical communications, tapered fiber, Yinping Miao1; applications in fiber nonlinearities, Xiaohui Li1; 1Shaanxi Normal Univ., Wang2 and Yuncai Wang1; 1Guangdong Shiming Gao1; 1Zhejiang Univ., 1Tianjin Univ. of Tech., China. An China. Some progresses in the field Univ. of Tech., China; 2Heriot-Watt Univ., China. Spatial diversity based on optical fiber sensor for magnetic- of ultrafast fiber lasers, such as the United Kingdom. In this paper, we review the direct-detection coherent receiver array is field measurement was proposed based on dissipative soltion resonance in fiber laser, recent advances and demonstrations of time evaluated for high-sensitivity free-space the serial-tilted-tapered fiber (STTF), which near-transform-limited pulse generation, domain pseu-dorandom optical phase encoding optical communications by using full-link can be considered as two tightly self-compression pulse, some novel 2-D technology for high speed 40Gb/s OOK and model in atmospheric turbulence. concatenated micro Mach-Zehnder inter- material for the ultrafast photonics will be DPSK secure optical communication systems. ferometers (MZIs). It can realize point introduced. detection in limited space. Th2A.3 • 11:30 Multi-Mode OFDM System with Multiple 1

Thursday, 8 August Conste-llations, JunGu Lee and Heung-Gyoon Ryu1; 1Chungbuk National Univ., South Korea. A new multi-mode OFDM system of multiple constella-tions is studied for imp-roving OFDM system efficiency. The multi-mode OFDM system has more flexible by combining several types of non-overlap-ping constellation diagrams.

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Room 7, Track 1 Room 8, Track 6 Room 10, Track 8 Room 11, Special 1 Room 12, Track 10

10:30-12:30 10:30-12:30 10:30-12:30 10:30-12:30 10:30-12:30 Th2E • Novel fibers & devices Th2F • Optical measurement VIII Th2G • Photonics for energy I Th2H • Organic & nano Th2I • Quantum photonics VIII VI Presider: Wentao Zhang, Inst. of Presider: Anlian Pan, Hunan optoelectronics-VIII Presider: Xiangang Wan, Presider: Meisong Liao, SIOM, Semiconductors, CAS, China Univ., China Presider: Fred Chen, Shanghai Nanjing Univ., China.

CAS, China Taoe Chemical Tech., China.

Th2E.1 • 10:30 Invited Th2F.1 • 10:30 Th2G.1 • 10:30 Invited Th2H.1 • 10:30 Invited Th2I.1 • 10:30 Invited High Spatial Resolution Integrated optical sensors, Qin Chen1; Broadband hot-elec- Towards high perfro- Opportunities in Optomechanical time- 1Jinan Univ., China. A bio-sensor with direct tron photoconversion: mance broad spectral quantum simulators domain analysis, Yong electrical read-out sensing capacity was design and experiment, response photodete- subject to par-ticle non- kang Dong1; 1Harbin Inst. demonstrated with a detection limit on the Cheng Zhang1 and ctors exloiting organic conserving pro-cesses, of Tech., China. Guided order of 1e-6 RIU in 400-1700 nm. Xiaofeng Li1; 1Soochow semiconductors, Ying Carlos Navarrete- 1 1 1 1 1 aco-ustic wave Brillouin scattering Th2F.2 • 10:45 Univ., China. We propose and quan Peng , Wenli Lv , Sunan Xu , Benlloch ; Shanghai Jiao Tong 1 1 1 has gained considerable interests Quantitative Analysis of Heavy Metal Com- experimentally demonstrate the Lei Sun and Ying Wang ; China Univ., China. Quantum simu-lators beca-use of its capacity to detect ponents in Soil by Laser-induced Break- broadband super-absorber based Jiliang Univ., China. Based on naturally allow for the inclusion of mecha-nical property of materials down Spectroscopy Based on Principal on metallic NRs with considering heterostructures of two and three particle non-conserving processes surrou-nding the optical fiber. Component Analysis, Jiaqing Chen1 and the hot-electron photo-conversion component organic bulk-hetero- (coherent injection or losses) in Here we propose a novel optome- Qianming Dong1; 1China Jiliang Univ., China. applications, which show over 30- junction/p-Si, perovskite/p-Si, con-densed-matter models that chanical time-domain analysis with The calibration curves of heavy metal ele- fold enhancement in IPCE relative perovskite/lead phthaloocyanine- typically conserve particle number. compact setup to greatly imp-rove ments Cd and Ni were established based on to the reference. and perovskite/tin phthaloocya- We will explore some opport- the spatial resolution. laser induced breakdown spectroscopy of nine, we fabricated high perfor- unities that such scenario opens.

standard soil and soil to be tested. mance broad spectral response photodiodes. Th2F.3 • 11:00 Th2E.2 • 11:00 Invited Auto-correction method for Incident Light Th2G.2 • 11:00 Invited Th2H.2 • 11:00 Invited Th2I.2 • 11:00 Invited Novel fiber lasers Instability and Temperature 3D Display Super-multi-junction so- High Mobility Conjuga- Dynamical universality 1 based on bidirectional Technology in RDTS, Baoqiang Yan , Ming lar cells, a new configu- ted Polymers for classes towards infinite 1 1 1 used linearly-chirped jiang Zhang , Jianzhong Zhang , Lijun Qiao ration of the robust and Organic Thin-Film temperature state, Zi August 8 Thursday, 1 1 FBG, Xinhuan Feng1; and Tao Wang ; Taiyuan Univ. of Tech., China. high-efficiency solar cell Transistors, Yanhou Cai1; 1Shanghai Jiao 1Jinan Univ., China. We present an incident light fluctuation com- and its application – Geng1; 1Tianjin Univ., Tong Univ., China. We pensation algorithm and temprature 3D Operation model based on the China. High mobi-lity ambipolar will report the universal classes of display technology to locate RDTS. annual monitoring of the multi- and n-type conjuga-ted polymers the noise-induced heating Th2F.4 • 11:15 junction PV modules, Kenji Araki1, for OTFTs were synthesized via dynamics of disordered interacting Optical fiber relative humidity sensor based Yasuyuki Ota2, Kan-Hua Lee1, direct arylation polycondensation. quantum systems, and their on FBG embedded in SMS fiber structure, Kensuke Nishioka2 and Masafumi With appro-priate coating method, relations with the intensively 1 1 1 1 1 studied many-body localization Shuying Han , Feng Wang , Shencheng Ni , Yamaguchi ; Toyota tech. Inst., OTFTs with mobility approaching Ying Shen1 and Shanhong You1; 1soochow Japan; 2Univ. of Miyazaki, Japan. 10 cm2/Vs were successfully phenomena. Univ., China. A novel optical fiber humidity We found multiple methods could fabricated. sensor based on FBG embedded in SMS improve the robustness to the fiber structure is proposed. It solves the spectrum sensitivity, including cross-sensitive problem of temperature. enhancing luminescence coupling, using a validated operation model.

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Room 2, Track 2 Room 3, Track 9 Room 5, Special 5 Room 6, Track 7

Th2A.4 • 11:45 Th2B.3 • 11:30 Invited Th2C.3 • 11:30 Invited Th2D.3 • 11:30 Invited Coherent Optical Orthogonal Frequency Division High-capacity free-space optical Fiber magnetic sensors based Ultrafast fiber lasers for linear Multiplexing with Index Modu-lation, Yuanxiang commu-nication based on mode on mode interference, Qun optical sampling, Zhichao Wu1, Chen1, Yongtao Huang1, Pengqi Yin1, Jie Ma1, Kaile diversity, Feng Wang1 and Guijun Han1 and Zhaoxia Sheng2; Tianye Huang1, Songnian Fu2 and Li1, Yitong Li1, Xinguo Li2 and Jianguo Yu1; 1BUPT, Hu1; 1Jilin Univ., China. We 1Tianjin Univ., China; 2Tianjin Deming Liu2; 1China Univ. of China; 2Wuhan Accelink Tech. Co. Ltd, China. CO- investigatged the performance of Univ. of Tech. and Education, Geosciences, China; 2Huazhong OFDM with index modulation is proposed. The mode diversity reception performance of China. Mode interference based fiber mag- Univ. of Science and Tech., China. The proposed scheme can improve spectral efficiency high-order modulated signals Nyquist- netic sensors will be discussed, including implementation scheme of linear sampling up to 6.25% with similar transmission performance. 4PPM-QPSK for high-capacity free-space the working principle, temperature com- pulsed laser source is comprehensively optical transmission under atmospheric pensation, dynamic characterristics, and investigated. Also, based on an ultrafast turbulence. demodulation techniques as well. fiber laser, an engineering prototype of broadband high-speed all-optical modu- Th2A.5 • 12:00 Th2B.4 • 12:00 Th2C.4 • 12:00 Invited lation format analyzer is successfully Cluster Synchronization of Semiconductor Lasers Optimization of Wide-Spectral Mode-Loc- Fiber Single-fiber Sagnac developed. Network with Heterogeneous Coupling Delays, king Fiber Laser Carriers in Free Space Interferometer for Atomic Shiqin Liu, Ning Jiang, Anke Zhao, Yajun Wang, Lu Op-tical Communication, Ce Yu, Ziqi Jiang, Spin Precession Detection in Chen, Baochuan Li and Kun Qiu; Univ. of Sci. and Zhi wen Sun, Peng Lin, Fang Dong, Ying atomic magnetometer, Ming Th2D.4 • 12:00 Tech. of China. The cluster synchronization of mu- Zhang and Tianshu Wang; National and Ding1; 1Beihang University, A Passively Mode-locked Tm-doped Fiber tually coupled semiconductor lasers network with Local Joint Engineering Research Center of China. Laser Based on PbS Nanoparticles as heterogeneous delays is systematically investigated. Space Optoelectronics Tech., China. We Saturable Absorber, Fei Liu1, Jianfeng Li1, demonstrate an optimization of wide- Fei Yan1, Xiaodong Wu1, Zhu Hu1 and Yong spectral mode-locking fiber laser carriers by Liu1; 1Univ. of Science and Tech. of China, the introduction of two-pulse pump scheme China. A satble passively mode-locked Tm- with fiber dispersion management, and doped fiber laser was experimentally verify the transmission performance of achieved by using PbS nanoparticles as a optimized wider-spectral carriers in 1km saturable absorber (SA). The results indicate

simulated atmospheric turbulent. that PbS is a type of promising SA for 2-μm

Th2A.6 • 12:15 Th2B.5 • 12:15 ultra-short pulse generation. Experimental demonstration of atmospheric cha- A FSO Transmission System Based on nnel reciprocity in fiber receiving systems, Hai Partially Coherent Beam Source, Qiaochu feng Yao, Lei Xiang, Xiaolong Ni, Chunyi Chen, Zhi Yang 1, Zhiwen Sun1, Ziqi Jiang1, Peng Lin1, Liu, Shoufeng Tong, Huilin Jiang and Minghui Cong; Ce Yu 1, Tianshu Wang1 and Huilin Jiang1; Changchun Univ. of Sci. and Tech., China. This paper 1CUST, China. We experimentally demon- designs a reciprocity measurement system for strated a 4Gbit/s trans-mission experiment Atmospheric channel for the first time in China. The using a low noise partially coherent beam Thursday, 8 August mean of reciprocity is higher than 0.8, which proves (PCB) source based on wide-spectrum that the atmospheric channel has strong reciprocity. filtered from supercontinuum which generated from picosecond mode-locked fiber laser pumping highly nonlinear fiber.

12:30-13:00 Lunch Break, Violet Hall (紫罗兰餐厅 ), 3F

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Room 7, Track 1 Room 8, Track 6 Room 10, Track 8 Room 11, Special 1 Room 12, Track 10

Th2E.3 • 11:30 Invited Th2F.5 • 11:30 Th2G.3 • 11:30 Invited Th2H.3 • 11:30 Invited Th2I.3 • 11:30 Invited Broadband Laser-tuned A closed micro-cavity in-fiber air Multi-physics of plasmo- Organic light-emitting Second order nonlinear Whispering Gallery Mode pressure sensor, Tianzong Xu1, nic nanostructures for transistor as nanoscale optical effects in on-chip in Micro-Structu-red Fiber Yinming Liu1, Yanhua Ma1, Jiahui highly efficient solar cells, light source for optical periodically poled lithium Embedded with Ironoxide Huang1 and Lijun Li1; 1Shandong Univ. Wallace C.H. Choy1; 1The sensing, Stefano Toffanin; niobate micro-resonators, Nanopar-ticles, Ming Deng1 of Science and Tech., China. An air Univ. of Hong Kong, Hong CNR-ISMN, Italy. The Fang Bo1; 1Nankai Univ., and Yufan Wang1; 1Chongqing Univ., pressure sensor is demonstrated Kong. With the incorporation of engineering of organic light-emitting China. We fabricated periodically China. A grape-fruit micro-structured based on a closed micro-cavity FP metal nanostructures in organic solar transistor as a light-source to be poled lithium niobate microdisk fiber-based resonator embedded optical fiber interferent sensing stru- cells, the performances are modified integrated into a miniaturized pho- resonators with a radial domain pat- with iron-oxide nanoparticles is cture. The interferent wavelengths by the plasmon induced optical and tonic sensor for validated and in-field tern of a ~2-μm spatial period, where demonstrated in this paper. present red-shift with the air pressure electrical effects. Overall, the power multiplexing screening of analytes second harmonic generation using increase. Its sensing sensitivity can conversion efficiency of optimized for sustainable food safety and food d33 is paving the way to efficient get 1.271nm/MPa. OSCs can be further improved. quality will be reported. nonlinear wavelength conversion.

Th2E.4 • 12:00 Invited Th2F.6 • 11:45 Th2G.4 • 12:00 Invited Th2H.4 • 12:00 Invited Th2I.4 • 12:00 Invited Optical fiber micro- Temperature and Salinity Sensing Flexible organic light emi- Recent advances in 2D SOI photonic crystal slab cavities and applica-tions Experiment Based on Microfiber tting devices and solar materials-based multi- for topological valley trans- on sensors, Chunliu Zhao1; Coupler Combined Sagnac Loop, cells based on ultra- wavelength ultrafast port, Jianwen Dong1; 1Sun 1China Jiliang Univ., China. Cao1, Yu 1, Xiao1, Yang 1, Zhang1 and smooth and ultrathin photonics, Bo Guo1; Yat-Sen Univ., China. I will In this talk, optical fiber Meng1; 1National Univ. of Defense electrode, Yuefeng Liu1; 1Harbin Engineering Univ., show our recent works micro-cavities and their applications Tech., China. A microfiber coupler 1Jilin Univ., China. In our work, China. Here, we review the recent about the exploration of all-diele- are demonstrated. These sensors conbined SAGNAC loop is fabri- improved performances of flexible advances in the exploitation of 2D ctric valley photonic crystal towards have many advantages, such as high cated for seawater temperature and OLEDs and OSCs have been materials in multi-wavelength ultra- the discovery of topological nano- sensitivities, simple and compact salinity sensing experiment. The demonstrated with ultra-smooth and fast photonics. Study found that, 2D photonics, particular for the silicon- structures, and low-cost. experimental results show that the ultrathin metal by template-stripping materials-based nonlinear optical on-insulator slab in telecommuni- sensitivity is high, and its dynamic process and nucleation-inducing device is an ideal platform for non- cation wavelength. range can meet the marine environ- seed layer, respectively. linear pulse dynamics study. Thursday, 8 August 8 Thursday, ment monitoring demand. Th2I.5 • 12:30 Dynamical detection of topology in two-dimensional waveguide 1 1 lattices, Yongheng Lu , Yao Wang and Xianmin Jin1; 1Shanghai Jiao Tong Univ., China. Direct detection of to-pology in higher-dimensional pho-tonics system remains elusive.

We present a direct dynamical dete- ction of the 2D topological invaria- nts via bulk-state single-photon real space dynamics in large-scale 2D photonics lattices on a chip.

12:30-13:00 Lunch Break, Violet Hall (紫罗兰餐厅 ), 3F

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Room 3, Track 3 Room 5, Track 1 Room 6, Track 8 Room 10, Special 1 Room 11, PDP

14:00-16:00 14:00-16:00 14:00-16:00 14:00-16:00 14:00-15:15 Th3B • Optical networks IV Th3C • Novel fibers & devices Th3D • Photonics for energy I Th3G • Organic & nano Th3H • Post-Deadline Paper Presider: Zhensen Gao, VII Presider: Xiaofeng Li, Soochow optoelectronics-IX Presider: Chunliu Zhao, China

Guangdong Univ. of Tech., China Presider: Yunxu Sun, Harbin Inst. Univ., China Presider: Nigel Pickett, Nanoco Jiliang Univ., China

of Tech. Shenzhen Graduate Tech. Limited, United Kingdom

Th3B.1 • 14:00 Invited Th3C.1 • 14:00 Invited Th3D.1 • 14:00 Invited Th3G.1 • 14:00 Invited Th3H.1 • 14:00 Equalization Techniques Passively mode-locked All-Inorganic CsPbI3-xBrx Manufacturing large area A novel kind of pulsating soliton in for NGPON with 50Gb/s/λ thulium-doped fiber laser Perovskite Solar Cells with precision thin films with mode-locked fiber lasers, Yueqing data rate and Beyond, based on a D-shaped fiber High Efficiency and slot-die coating, Jin Shan Du1, Mengmeng Han1 and Xuewen Zhengxuan Li1, Yun Li1, deposited with PbS Excellent Thermal-Stability, Wang1; 1Shanghai Shu1; 1Huazhong Univ. of Sci. and Chengcheng Li1, Yingxiong nanoparticles, Weiqing Jiandong Fan1; 1Jinan Univ., Precision Systems, Inc, Tech., China. We find a pulsating Song1, Jian Chen1 and Min Wang1; Gao1; 1Hefei Univ. of Tech., China. China. The present study opens a China. Using SDC to make large area soliton with broadened Kelly side- 1Shanghai Univ., China. The We demonstrate a passively mode- new direction in the development of nanoscale thin films in applications bands. By simulation, we find the equalization techniques for enabling locked thulium-doped fiber laser inverted all-inorganic perov-skite with precise control of the film wavelength of the soliton oscillates 50-Gb/s/λ and beyond are explored. based on a D-shaped fiber solar cells with highly thermal thickness and uniformity. due to the interaction with the unsyn- Optimization of the Volterra and deposited with PbS nano-particles. stability and efficiency, which proves chronized resonant dispersive wave. MLSE equalizers and the tap-training The pulse duration is 1.3 ps. The 3 dB to be an important step for ongoing Th3H.2 • 14:15 methods are presented. bandwidth is 3.2 nm. developments in solar cells. Demonstration of Image Proces-

sing Based on Reinforcement Lear-

ning in Multi-Modal Optical Trans-

port Networks, Haoli Ma1, Yongli

Zhao1 and Yajie Li1; 1BUPT, China. In

OTN, orchestrating concurrent servi-

ces may consume extra O/E ports for Th3B.2 • 14:30 Th3C.2 • 14:30 Invited Th3D.2 • 14:30 Invited Th3G.2 • 14:30 Invited optical-electric conversion. We dem- An incentive auction-based Ultra-broadband fiber High performance of all- Tunable frequency shift onstrate an image processing based coopera-tive re-source mode conver-ters based inorganic perovskite opt- for distortion free chip- reinforcement-learning algorithm for provisioning scheme for edge on long-period gratings, oelectronic devices by based wide field super- concurrent service orchestration in compu-ting over passive optical Yunhe Zhao1 and Yunqi using ZnO nanoparticles, resolution imaging, Qing multi-modal optical networks. networks, Shifang Dai1, Lin Hai2, Yan Liu2; 1Shanghai Maritime Zhigang Zang1; 1Chong- Yang 1; 1Zhe jiang Univ., Li1 and Zhen Zhang1; 1Nanjing Univ. Univ., China; 2Shanghai Univ., China. qing Univ., China. We demonstrate China. We pro-pose wide-field far- Th3H.3 • 14:30 of Finance & Economics, China; We demonstrate the broadband that by simply introducing ZnO NPs field super-resolu-tion imaging chip Edge-coupled III-V/Si3N4 hybrid 2NUPT, China. We study the coo- fiber mode converters based on into the CsPbBr3 precursor solution, based on tunable frequency shift. By external cavity laser, Yuyao Guo1, perative resou-rce provisioning CO2-laser-inscribed long-period the CsPbBr3: ZnO films synthesized frequency shift and iteratively Linjie Zhou1, Gangqiang Zhou1, Ruiling Zhao1, Liangjun Lu1 and Thursday, 8 August among cloudlets for service for gratings, including tilted gratings by one-step spin-coating method stitching different spatial frequency resource limitation in EC integrated and apodized gratings. exhibit enhanced crystallization, range together in Fourier space, 2D Jianping Chen1; 1Shanghai Jiao Tong PONs. An auction-based scheme is improved PL intensity and prolonged distortion-free imaging was achieved Univ., China. We demonstrated an III- proposed to motivate clou-dlets to lifetime. in a wide FOV. V/silicon nitride hybrid external share their resources. cavity laser (ECL). The ECL exhibits a tuning range of 45 nm, a side-mode suppression ratio (SMSR) of 60 dB, and a linewidth of round 100 kHz.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 77

ICOCN 2019—Thursday, 8 August

Room 3, Track 3 Room 5, Track 1 Room 6, Track 8 Room 10, Special 1 Room 11, PDP

Th3B.3 • 14:45 Th3H.4 • 14:45 An Equalization Method based on Large-range Dynamic Strain Mea- W-KNN for PON with PAM4, Xunan surement Using Chaotic BOCDA, Zheng1, Jie Liu1 and Jianfei Liu1; Yahui Wang1, Le Zhao1, Mingjiang 1Hebei Univ. of Tech., China. We Zhang1 and Jianzhong Zhang1; proposed a machine learning 1Taiyuan Univ. of Tech., China. We equalization technique based on demonstrate a wide-range dynamic weighted KNN for 50Gbps PAM4 strain measurement system using PON systems. The simulation results chaotic BOCDA. This experiment is show that 35dB loss budget is the first that a dynamic strain of 1200 achieved by Weighted-KNN με can be accurately identified using equalization technique. the single-slope assisted method.

Th3B.4 • 15:00 Th3C.3 • 15:00 Th3D.3 • 15:00 Th3G.3 • 15:00 Invited Th3H.5 • 15:00 Time-Division based Scheduling The Spectrum Characteristics and Improved inverted perovskite solar The modification of the Object Wedge Angle and Direction Scheme for Hybrid Optical fabrica-ting mechanism of Fiber cell via solution-processed MoOx functionality of pimole- Identification Using Machine /Electrical Data Center Network, Gratings by point-by-point direct- hole transport layer and F4-TCNQ cules through the struc- Learning Algorithms, Yiwen Zhang1, Shangqi Ma1, Xiaoshan Yu1, Kun writing based on femto-second modification, Lijun Chen1, Qiaomu tural adjustment, Zhen Li1; Yongxiong Ren2, Guodong Xie2, Zhi Wang1, Yi Zeng1 and Huaxi Gu1; laser pulses, Zhu Yuyu1, Zhang Yani2, Xie1, Li Wan1, Wenxiao Zhang1, 1Tianjin Univ./Wuhan Univ., Wang1, Hao Zhang1, Tianxu Xu1, Hao 1Xidian Univ., China. Previous Optical Xue Lu1, Jiang Peng1 and Wang Sheng Fu1 and Hai-Qiao Wang1; China. Huang2, Changjing Bao2, Zhongqi Circuit Switch (OCS) based Chaojin1; 1Baoji Univ. of Arts & Sci., 1Ningbo Inst. of Materials Tech. and Pan2 and Yang Yue1; 1Inst. of Modern proposals suffer from high packet China; 2 Univ. of Arts & Sci., China. Engineering, CAS, China. With solu- Optics, Nankai Univ., China; 2Univ. of queuing delay during recon- They include the fourth-order FBG, tion-processed and F4-TCNQ modi- Southern California, China. We figuration intervals. We propose a FBG FP cavity, sampling FBG and fied MoOx HTL, improved inverted demonstrate identification of object scheduling scheme call TDS to cascaded long period fiber grating. MAPbI3 perovskite solar cells were wedge angle and direction using diminish the impact of the long demonstrated. Champion PCE of machine learning algorithms based reconfi-guration delay of OCS. 16.26% was achieved with negligible

on received beam intensity profiles. August 8 Thursday, hysteresis. CNN outperforms other algorithms with 100% accuracy. Proposed Th3B.5 • 15:15 Th3C.4 • 15:15 Th3D.4 • 15:15 technique reduces the complexity of An Integrated Service Function Research on Fabrication Method of Differential Power Processing hardware implementation. Chainings Mapping Algorithm High Stability Long Period Fiber based Photovoltaic Power Systems: Based on Betweenness Cent-rality, Grating, Jie Jiang1, Li Li1 and Guoyu A Review, Huiqing Wen1, Chenyang Zhanqi Xu1, Jie Wu1, Shuiyan Zhang1 Li1; 1Inst. of information Tech., Lin1 and Guanying Chu1; 1Xi’an and Shuang Du1; 1Xidian Univ., China. Handan College, China. A new JiaoTong-Liverpool Univ., China. It This proposed algorithm concurre- method of LPFG writing with fiber presents a compre-hensive review of ntly considers betweenness centrali- fixation in the prestressed state is different DPP archite-ctures in terms ties of DC nodes, reuses of VNFs and proposed. The experimental results of the connection, power converter comprehensive link weights in the show the proposed method has a topologies, and MPPT control. The substrate network to accomplish better effect of writing stability, conclusion was drawn based on the SFCs mapping. Simulation indi-cates deeper modulation depth and literature review and evaluation. the effectiveness of CSM-BC. narrower bandwidth.

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 78

ICOCN 2019—Thursday, 8 August

Room 3, Track 3 Room 5, Track 1 Room 6, Track 8 Room 10, Special 1 Room 11, PDP

Th3C.5 • 15:30 Th3G.4 • 15:30 Invited More-than-95-line fiber laser The synthesis of trans- based on hybrid gain from the parent pol-yimide with Brillouin effect and erbium- low CTE and their doped fiber, Panyun Gao1, Zheng- applications in opto- xiong Zhang1, Wenhui Jiang1, Xiu elec-tronics, Guoli Tu1; Zhang1, Yong Zhou1, Wei Zhang1, 1Huazhong Univ. of Science and Liang Chen1, Peng Wang1 and Tech.,China.We have designed an Weiqing Gao1; 1Hefei Univ. of d synthesized a series of transpare Tech., China. We demonstrate a nt polyimides based on isomerize multi-wave-len-gth Brillouin fiber d rigid semialicyclic diamine and a laser based on a dual ring structure rigid semialicyclic modified dianh to take advantage of the forward ydride monomer, which possessin and backward Brillouin gain g excellent performance with low simultaneously with an injected CTE and application in the optoel tunable scanning lasing. ectronics.

Th3G.5 • 16:00 Invited Solution-processed Ino- rganic Char-ge Trans- port Layers for High- perfor-mance Quantum Dot Light-Emitting Diodes, Xuyong Yang1; 1Shanghai

Univ., China. Solution-processed metal-oxide thin films show the great potential for long ope- rational life-time optoelec-tronic devices. We will present our latest advances in improving perfor- mance and stability of QLEDs by using solution-processed inorga- nic carrier transport layers. Thursday, 8 August

16:00-16:30 Coffee Break, 4F

International Conference on Optical Communications and Networks (ICOCN) ● 5 August 2019 - 8 August 2019 ● Page 79

Key to Authors and Presiders A Bian Subiao - T3H.4 Changjing Bao - Th3H.5 Cheng-Kai Yao - T2E.4 Dan Zhu - T2G.1, W3B.4 Adnan Hajomer - W2A.7 Biao Guo -P2.1 Changqi Ma - Th1H.1 Chengrong Shen - P1.38, P4.65 Dandan Zhou - P2.36 Ai Fan - P1.11 Biheng Liu - T3I.4 Changrui Liao - Th1E.3 Chengwei Deng - P3.53, P1.47 Dangpeng Xu - P2.36 Ai Zhou - P1.39, P3.38 Bilun Lu - P3.16, P3.17 Changshui Chen - W2G.6 Chenxia Li - P4.31 Daniela S. Lopes - W1 F. 3 Aihua Liu - P2.31 Bin Chen - Th1A.3, W4B.2, W2C.1 Changyu Shen - P1.7, P3.32, P4.62, Chenyang Lin - Th3D.4 Danshi Wang - P1.24, P1.33, P3.65, Ailing Zhang - P4.21, P4.23 Bin Li - P2.47 P3.63 Chenye Qin - W1C.2 W4C.1 Alex Alvarado - Th1A.3 Bin Liu - P1.43, P1.67 Changyuan Yu - T2A.4, P1.48, P1.50, Chi Zhang - P1.2. P2.70 Daobin Wang - Th1D.5 Amin Malekmohammadi - W4B.4 Bin Luo - P1.59 T3F. 1, P3.71 Chigo Okonkwo - Th1A.3 Daoxin Dai - T2C.1, W2G.3 Amjad Ali - W2A.5 Bin Niu - T3A.2 Chao Deng - T2H.3 Chong He - W4F.3, P3.5 Dariusz Burnat - W 4F. 1 Amjad Ali Amjad - W2A.6 Bin Qiu - P3.64 Chao Fan - P1.63 Chong Zhang - P1.7, P3.32, P4.62 Dawei Ge - P1.42 Anbang Wang - TH1G.1 Bin Ru - P4.61 Chao Jiang - P3.52 Chongshuang Qin - P3.40 Decao Wu - P3.21 Anderson Gomes - T3E.1 Bin Wang – T3F. 4 Chao Mei - P2.69 Chongxiu Yu - P2.69, P1.30, P3.26, Degang Deng - P4.31 Anderson S. L. Gomes - W 1F.3 Bin Zhang - Th1D.3, W1D.5, P4.36 Chao Meng - P2.68 P1.41 Deming Liu - T2F.3, W1F.5, P1.49, Andrej Gutkin - T3H.2 Binbin Luo - P3.21, P3.24 Chao Shang - W 2 F. 4 Chongyang Liu - P4.19 Th1E.2, Th2D.3 Anke Zhao - Th2A.5, P1.8 Binbin Yan - P2.69, P1.30, P3.26 Chao Shen - P2.50 Chuang Liu - P4.5 Deng Xue - W2A.4 Anle Wang - P2.51, P3.34 Bing Sun - P1.52, T2E.3, W2F.3 Chao Wang - T2G.2, P3.15 Chuanhang Zou - W2D.4 Desheng Zhao - P4.32 Anlian Pan - T2C.4 Bingli Guo - P1.63 Chao Zhang - W2A.5, W2A.6 Chuanliang Guan - P3.40 Deyong Kang - P4.49 Anning Xu - P2.59 Bingyan Wang - P2.39 Chaofan Lu - P3.70 Chuanxin Wu - P2.32 Di Liang - W4G.2 Antreas Theodosiou - W2D.1 Bingyan Wu - P4.44 Chaofan Wang - P1.57 Chujun Zhao - W3C.4 Di Zhang - W3A.3 Ao Yu - W2B.5 Bingyao Cao - Th2A.1, P4.8 Chaofan Zhao - P1.30 Chuluo Yang - W4H.3 Dian Li - Th1B.3 Aoqun Jian - P4.8 Binqing Wu - P4.61 Chaolong Song - Th2D.1 Chun Lin - T3B.5 Ding Ding - P3.22, P4.43 Atubga David Atia Ibrahim - P1.62 Binxin Hu - P2.24, P2.41 Chaoqun Cai - P2.70 Chun Mao - P2.2 Dingshan Gao - T2B.4 Azusa Inoue - T2E.2 Bitao Pan - T3A.4 Chen Bowen - P4.30 Chunjiao Jin - P3.53, P1.47 Dong An - P2.37 B Bo Cong - P2.28, P3.64 Chen Hongying - P4.60 Chunlei Yu - P4.41 Dong Chen - P2.59, P4.24, P4.27 B. M. A. Rahman - T3G.4 Bo Dong - P1.48 Chen Jiang - W1F.6, W2E.3, P1.53, Chunliu Zhao - P2.26, P3.32, P4.62, Dong Guang - P2.9, P1.10 Bai Tong-Tong - P3.48 Bo Guo - Th2H.4 W2E.2 P3.63, Th2E.4 Dong Qianmin - P4.3 Baicheng Yao - T2C.3, W1C.2 Bo Huang - P2.2 Chen Lin - P3.56 Chun-Nien Liu - T2E.4 Dong Ruifang - W2A.4 Baile Chen - Th1G.4 Bo Li - P4.59 Chen Ming-Yang - P3.48 Chunqiang Fu - P3.34 Dongdong Jiao - P4.20, P4.57, P4.52 Baiwei Mao - W3E.3 Bo Liu - P1.3, P2.39, P4.59 Chen Qi - P4.30 Chunqing Wu - Th1B.2 Dongdong Wang - P3.62, P4.1 Bangjiang Lin - T3B.5 Bo Xu - P2.16, P2.27, P2.46 Chen Qian - P3.69 Chuntao Wang - P4.70 Dongfang Jia - P4.39 Bangning Mao - P3.17, P4.29 Bo Zhang - P2.61, W3A.3 Chen Si - P4.47 Chunyan Cao - P4.37 Dongge Ma - W3H.3 Baochuan Li - Th2A.5, P1.8, P2.40 Bohan Luan - P4.48 Chen Wang - P2.32 Chunyan Du - P1.42 Dongmei Huang - W 2F. 4 Baojian Wu - P2.1 Bokai Cheng - P4.17, P4.15, Chen Wei - P3.40, P3.44 Chunyi Chen - Th2A.6 Dongming Wu - Th1D.5 Baokang Zhao - Th1B.2 Bowen Chen - P1.46, W1B.4 Chenda Lu - P1.6 Chunzhou Wu - W 2 F. 5 Dongning Wang - P2.19, P2.25, Baoqiang Yan - T h 2 F. 3 Bowen Liu - P1.44, P1.45 Cheng Hang - P4.17, P4.15 Chuxuan Wang - P2.39 P2.26, P2.33, P3.63 Baoquan Sun - W2H.2 Bowen Zhang - P2.18, W3B.4 Cheng Wan - P2.15 Cong Bo - P2.57, P4.47 Duan Qingguang - P4.47 Baoshan Li - P3.51 C Cheng Xu - P3.60 Cong Du - T h 1 F. 5 E Key to Authors Baoying Liu - Th1G.5 Caiyun Su - P1.64 Cheng Zhang - Th2G.1 Cui Zhang - P3.53, P1.47 Elfed Lewis - P1.19 Beibei Li - Th2C.1 Callum G. Littlejohns - P4.19 Cheng Zhou - W4F.3, P1.32 D Elham Bidaki - W2B.1 Beihua Fang - W2G.5 Cao - P2.42, Th2F.6 Cheng Zuo - P2.6, P2.9, P1.72 Da Wang - P3.61, W2D.3 Emmanuel Le Taillandier de Gabory Ben Puttnam - Th1A.1 Carlos Navarrete-Benlloch - Th2I.1 Chengbo Mou - W4D.1, W2D.1, Da Wei - P2.31 - W3A.2 Ben Xu - P2.33 Ce Sun - P4.21, P4.23 W1F.6, P1.51, P1.53, W2D.4, Dahai Han - P3.35 F Ce Yu - Th2B.4, Th2B.5 Th1E.2 Daiwen Pang - Th1H.4

Benjamin Puttnam - W3A.1 Fan Shi - P2.52 Benli Yu - P2.6, P2.9, P2.17, P1.10, Cen Wang - W4B.1 Cheng-Bo Mou - P3.14 Dajian Liu - W2G.3 Fan Sun -P2.1 P1.72 Changcai Cui - Th1F.4, T3H.4 Chengcheng Li - Th3B.1 Dan Wang - P2.8, P4.59 Fan Wang - P2.17 Bi Tang - P4.16 Changjiang Fei - Th1B.2 Chengcheng Xu - W2E.3 Dan Yang - W3B.5 Fan Zhang - W1G.1

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Key to Authors and Presiders

Fang Bo - Th2I.3 Gangqi Wang - P4.51 H Heng Fan - W3I.1 Th3B.4 Fang Dong - Th2B.4 Gangqiang Zhou - P1.65, Th3H.3 H. Y. Fu - P2.48, T3B.4 Heng Liu - P1.41 Huaxian Duan - P1.68 Fang Fang - P1.52 Gangxiang Guo - P3.3 H.D.Milan Ravinath Perera - P4.45 Heping Li - T2D.2 Hui Gao - P2.12, P3.46 Fang Li - W4E.4 Gangxiang Shen - T3A.1, P1.34 H.Y. Fu - W2G.4, W2G.1, Th1D.1 Heping Zeng - P2.43, P1.14 Hui Wang - P2.6 Fang Wang - P1.41, P4.11, W1C.5 Gao Jing - W2A.4 Hai Zhou - P4.8 Heung-Gyoon Ryu - Th2A.3 Hui Xu - P3.1, P1.28, P1.29 Fangbi Wang - P2.46 Geng Zhang - P4.14 Hai-Bo Liu - P2.22 Hideaki Asakura - W2B.4 Hui Yan - W3I.3 Fangda Yu - P2.14 Georg Rademacher - W3A.1 Haibo Zeng - T3H.1 Hiroyuki Tsuda - T3G.3, W2B.4 Hui Yang - W2B.5, P4.44, W1B.3 Fangfang Wei - P1.61 Georg Rademacher - W1A.2 Haida Yang - P2.51, P3.34 Hitoshi Kawashima - W2B.4, W1G.4 Hui Zhu - P3.43 Farhan Mumtaz - P1.39 Georges Humbert - W2E.5 Haifeng Yang - Th1B.3 Hitoshi Takeshita - W3A.2 Huifeng Shi - Th1B.4 Faxi Chen - P4.59 Gerald Farrell - P1.61 Haifeng Yao - Th2A.6 Hong Meng - W3G.3 Huihui Li - Th1F.4, P3.56, T3H.4 Fei Liu - Th2D.4 Geza Kurczveil - W4G.2 Haihua Li - P4.69 Hong Wang - P4.19 Huihui Wang - P3.37 Fei Xu - P3.11, P3.14, Th1C.1 Gilberto Brambilla - Th2D.1 Haijiao Xu - P1.30 Hong Zhao - P1.70 Huilian Ma - T3F.2, W2F.2 Fei Yan - Th2D.4 Graham T. Reed - P4.19 Hailong Zhou - T2B.4 Hongchen Chen - P3.32 Huilin Jiang - Th2B.5, Th2A.6 Fei Yu - W1A.4 Gu Fufei - P4.47 Hai-Qiao Wang - Th3D.3 Hongdan Wan - P2.15, P1.2, P2.70, Huiling Hu - P3.52 Feng - P2.42 Guangdong Song - P2.24, P2.41 Haiqin Shi - P3.4 T2E.3 Huiqin Wang - Th1D.5 Feng Chen - W1I.2 Guanglu Ge - W1H.3 Hai-Ting Zhu - P2.30 Hongfeng Lin - P1.39, P3.38 Huiqing Wen - Th3D.4, P4.45 Feng Guo - P2.50 Guangqiong Xia - T2G.4 Haiwen Cai - T3F. 3 Hongliang Sun - P2.7 Huixia Ding - P4.14 Feng Li - W 2F. 4 Guangwei Cong - W1G.4 Haiyang Yu - P3.19 Hongmei Li - P3.16, P3.19, P3.45 Huiye Qiu - P3.49 Feng Tian - P1.6, P2.39, P1.18, P2.59, Guangya Zhou - P1.37 Haiying Ji - P4.32 Hongmin Zhang - P2.47 Huiying Wang - P4.48 P2.60, P2.61, P3.54, P4.24, P4.27 Guangyao Sun - W1I.5 Haiyun Xin - W2B.3 Hongqiang Fang - T3A.2 I Feng Wang - Th2B.3, W4F.2, W2C.4, Guangyao Yang - T3F. 4 Haizheng Zhong - W1H.2 Hongqiao Wen - P2.11 Itsuro Morita - Th1A.2 Th2F.4 Guangyuan Li - W2G.5, W2G.6 Han Yao - P2.52 Hongtao Lin - W3C.1 Izabella C. X. Lins - W 1F. 3 Feng Wen - P2.1 Guangze Ge - P2.27 Han Zhang - P2.23, T2C.2 Hongwei Ding - P4.28 J Feng Xie - P4.18 Guanjun Gao - P3.60, P4.9, P1.59 Hang Zheng - W2I.2 Hongwei Han - Th1H.2 Jean-Louis Auguste - W2E.5 Feng Xu - P2.20, P3.26 Guanjun Xu - P4.56 Hanguang Liu - P3.29 Hongwei Lv - P1.33 Ji Wang - P1.21 Feng Yuan - P1.2, P2.70 Guanshi Qin - W1E.1 Han-Ping D. Shieh - T2H.1 Hongwei Zhang - W3E.3 Ji Xia - P1.37 Feng Zhou - W3B.1, P4.4 Guanying Chu - Th3D.4 Hanwei Zhang - T3E.4, T2B.5 Hongxiang Guo - W4B.1 Ji Xiong - W2F.1, P1.62 Feng Zhu - P2.24, P2.41 Guanyu Liu - T3B.4 Hanyu Zhang - T3G.4 Hongyan Fu - W 1 F. 4 Ji Xu - P1.9 Fengkai Han - P2.70 Guijun Hu - Th2B.3 Hanzhao Li - W 2F. 2 Hongyu Zhou - P3.40, P3.44 Jia Xu Brian Sia - P4.19 Fengping Zhao - P2.33 Guilan Li - P1.8 Hanzi Huang - Th2A.1 Hongzhen Yang - P1.63 Jia Yu Guo - W 1F. 3 Fengqing Liu - P2.13 Guixing Cao - P2.59, P2.61, P4.24, Hao Chen - P2.34, P2.65, P2.67 Hoon Kim - T2A.3, Th2B.1 Jia-Chen Liu - T3G.1 Fengqiu Wang - T3D.4 P4.27 Hao Hu - T3G.4 Hu - P2.42 Jiahao Fang - P3.32, P4.62 Fengrui Yao - P4.63 Guo Caifa - P4.60 Hao Huang - Th3H.5 Hu Jie - P1.11 Jiahe Zhao - Th2A.1 Festus Oluwajobi - W4B.4 Guodong Xie - Th3H.5 Hao Jia - P1.20, P3.7 Hu Jinyao - W1D.4 Jiahua Gu - W4B.2 Fred Chen - W3H.2 Guodong Zhong - P2.24, P2.41 Haoli Ma - Th3H.2 Hu Meimei - P4.3 Jiahui Huang - T h 2 F. 5 Fuchun Nian - P4.72 Guofang Gao - P2.24, P2.41 Hu Xiao - W1D.2 Hao Xiong - P4.32 Jiahui Li - P1.71 Fu Wang - T3A.4 Guofeng Yan - W2F.5, W3F.4 Hao Yuan - P2.65, P2.67 Hua Hui Zhang - W 1 F. 3 Jiahui Yang - P3.61 Fufei Pang - P1.64, P4.35 Guohua Xie - W4H.3 Hao Zhang - Th3H.5 Hua Zhang - P2.24, P2.25, P2.26, Jiajia Luo - W4H.3 Fu-Li Wang - T3G.1 Guohui Lyu - P1.68, P4.48 Haofeng Hu - P2.8 P2.41, T2C.4 Jiajing Tu - P2.37 Fulong Yan - T3A.4 Guojun Jin - P3.10 Haojie Zhang - P3.12 Hua Zhou - P2.23 Jiajun Tian - P3.5, P1.32 Fumi Nakamura - W2B.4 Guoli Tu - P1.69, Th3G.4 Haoshang Wang - P3.11 Huabao Qin - W 1F. 5 Jiali Jiali Li - P3.63 Fumin Wang - P1.57 Guoqiang Gu - P3.15 Haoshuo Chen - Th1A.4 Huaifeng Wang - P3.29 Jiali Liao - P2.68 Fuyin Wang - P1.37, P4.37 Guoquan Zhu - P3.66, P3.67 He Lu - Th1I.1 Huanhuan Liu - P4.35

Key to Authors Authors to Key Jialin Jiang - P1.62 G Guorui Su - P3.13 He Tao - P1.11 Huanhuan Wang - Th1G.5 Jialing Li - P1.27 Gang Zhang - P2.6, P2.9, P1.72 Guoyong Xiang - T2I.4 He Xu - W1D.3 Huatao Zhu - P1.12 Jialing Yu - P3.43 Gang-Ding Peng - P1.30 Guoyu Li - P4.10, Th3C.4 Heeyoung Lee - W 1 F. 2 Huaxi Gu - P2.18, W4B.5, W2A.2, Jian Chen - Th2A.1, T2A.4, Th3B.1,

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Key to Authors and Presiders P1.50, P4.8 Jiao Dongdong - W2A.4 Jing Lv - P3.49 Junbiao Peng - W3H.1 Khadidja Saker - P2.29 Jian Cui - P1.42 Jiaoliang Yu - P4.17, P4.15 Jing Wang - P4.25 Junbo Yang - P4.6 Kohei Noda - W 1F. 2 Jian Wang - T2A.2 Jiaqi Gong - P1.7, P3.32 Jing Xu - W2F.3, W2A.5, W2A.6, Jun-Gu Lee - Th2A.3 Koji Yamada - W1G.4 Jian Wu - P3.23, W1C.3, W2D.5, Jiaqi Zhou - T3B.2 Th1B.1 Junjie Si - P4.25 Kristif Prifti - T3A.4 W4B.1 Jiaqiang Zhang - P2.67 Jing Yu - P4.62 Junjie Zhang - Th2A.1, P4.8 Kuiru Wang - P2.69, P1.30, P3.26 Jian Xu - W3F.3, P2.46 Jiaqing Chen - Th 2F. 2 Jing Zhang - W4A.4, P2.27, T3C.2, Juntao Li - W4I.2 Kun Cheng - P2.16 Jiandong Fan - Th3D.1 Jiawei Kong - T3A.2 P4.16 Junwei Luo - P4.13 Kun Qiu - P2.1, Th2A.5, P1.8, P2.40, Jiandong Hu - P3.15 Jiawei Zhang - W4C.2 Jingcheng Zhou - Th 1F. 5 Junwen Li - T2D.2 T3C.2, P4.16 Jianfei Liu - T2B.2, Th1F.2, Th3B.3 Jiaxin Song - T3E.2, W1D.1, T3E.4, Jingda Shi - P4.28 Junxiang Xu - T3B.5 Kun Wang - P2.18, Th3B.4 Jianfei Wang - P3.42, P4.70 T2B.5, W1D.7, W1D.8 Jingjing Zheng - P1.21 Junyu Tu - W 2 F. 2 Kun Xie - T2B.1 Jianfeng Li - Th2D.4, W1E.4 Jiayu Wang - P1.48 Jingli Lei - Th1D.5 K Kun Xu - P1.23, P3.12 Jianfeng Zhang - P3.2, P3.3, P3.57, Jibin Zhang - P1.69 Jingshu Guo - T2C.1 Kai Kang - P3.66, P3.67 Kuo Zhang - P1.6 P3.8 Jidong Lv - P4.71 Jingyan Li - P3.54 Kai Li - P2.72 Kyriacos Kalli - W2D.1 Jiang Li - T2C.1 Jie Bai - W2B.3 Jingyao Zhang - W4B.5 Kai Liu - W3B.5, P4.13 L Jiang Peng - Th3C.3 Jie Hu - P3.58 Jingying Wu - W 2 F. 3 Kai Ni - P2.44 Lan Rao - P2.64 Jiang Yunfei - P4.30 Jie Huang - P4.42 Jingyuan Wang - P2.32 Kai Qian - P2.17 Lan Yu - P2.51 Jiangbing Du - W3A.4 Jie Jiang - Th3C.4 Jinhui Yuan - P2.69, P1.30, P3.26, Kai Xu - P3.10 Lang Xie - P3.24 Jiangbo Pang - P2.24, P2.41 Jie Liu - Th1F.2, Th3B.3, P4.57 P1.41, P1.67 Kai Zhang - P3.23, W1C.3 Lanjian Chen - T2B.7 Jianghai Wo - P2.51, P3.34 Jie Ma - W4C.4, W2B.6, Th2A.4 Jinjie Tao - P4.51 Kaihui Liu - P3.36 Le Li - P2.22 Jiangjing Cui - P4.18 Jie Pang - W2C.4 Jin-Long Xiao - T3G.1 Kaikai Xu - P2.7 Le Zhao - Th3H.4 Jiangming Xu - T3E.2, W1D.1, T3E.4, Jie Wang - P3.52 Jinlong Zhang - P1.18, P2.60 Kaile Li - W4C.4, W2B.6, Th2A.4 Lei Bi - W1C.2 T2B.5, W1D.7, W1D.8 Jie Wu - Th3B.5 Jin-Shan Wang - Th3G.1 Kaiming Zhou - Th1E.2 Lei Feng - P4.37 Jianguo Yu - W4C.4, W2B.6, Th2A.4 Jie Yin - Th1B.4 Jintao Wang - P2.65, P2.67 Kaiwei Feng - T2H.2 Lei Guo - P1.56 Jiangxing Chen - P2.49, P1.33, P3.70, Jie Zhang - W2B.5, W2B.2 Jinyan Dong - T3E.3, P3.33 Kan Gao - P4.44 Lei Jiang - P1.3 P4.2 Jie Zheng - P2.14 Jinyong Leng - W1D.2, W2E.4, T2B.1, Kan Wu - W1C.1 Lei Qian - W2H.3 Jianhua Ji - P2.45 Jieqing Deng - P4.41 W1D.7 Kan Zhao - P4.57, P4.59 Lei Shi - W4D.3 Jianhua Li - P2.32 Jiewen Ding - W3B.4 Jiong Xu - P1.9 Kang Ai - P2.7 Lei Sun - Th2H.1 Jianhua Shen - P1.5, P4.17, P4.15 Jijing Chen - P2.15 Jiuxing Jiang - T h 1 F. 3 Kang Kai - P2.58 Lei Wang - P3.18, P1.34, W3A.3, Jianji Dong - W3B.1, P2.34, T2B.4, Jijun Feng - W4G.3 Jixiang Dai - P1.22 Kang Yang - P4.10 W4H.4 P1.17 Jilin Zheng - P2.5, P2.23 Jiyong Zhao - P2.23, P2.32 Kan-Hua Lee - Th2G.2 Lei Xiang - Th2A.6 Jianjun Liu - P3.16 Jin Huang - P4.16 Joanna Niedziolka-Jonsson - W 4F. 1 Kazuhiro Ikeda - W2B.4, W1G.4 Lei Yu - P4.30 Jianming Zhang - P3.35 Jin Li - P1.24, P1.33 Juan Kang - P3.63 Kazuyuki Matumaro - W2B.4 Lei Zhang - T3E.3, P3.7, P4.66, P4.43, Jianping Chen - W2C.3, P1.65, Jin Wang - W4H.2, P1.9, P3.9, P3.23, Juan Liu - P1.43, P1.67 Ke Wei - T2H.2 P4.61 T3G.4, Th3H.3 P3.37, W1C.3 Juan Qin - P3.59, P1.54, P1.55 Ke Xu - Th1G.2 Leijing Yang - P1.6, P2.59, P2.60, Jianping Hu - Th1B.3 Jin Xu - P3.20 Jue Wang - P1.41 Ke Yin - W2D.2 P2.61, P3.54 Jianqi Cai - T2H.2 Jin Zhang - P2.51, P3.34 Juhao Li - P1.42, W1B.2 Keiichi Matsumoto - W3A.2 Leijing Ynag - P4.24 Jianshe Ma - P2.71 Jin Zhou - P4.19 Jun Cheng - P3.20 Keijiro Suzuki - W2B.4, W1G.4 Li Hao - P1.11 Key to Authors Jianwen Dong - Th2I.4 Jinbiao Chen - P1.59 Jun Gao - Th1I.4 Keming Ma - P2.8 Li Lei - Th1B.3 Jianxiang Wen - W1F.6, P1.64, P4.34 Jinde Yin - P2.63, P2.65, P2.67 Jun He - Th1E.3 Ken Manabe - Th1E.4 Li Li - Th3C.4 Jianxin Ren - P1.3 Jinde Yin Yin - P3.25 Jun Li - P2.53, P3.1, P1.28, P1.29, Ken Tanizaawa - W2B.4 Li Pei - P1.21, T2E.1 Jianxin Yang - W4G.4 Jing Bai - P3.60 W2E.4 Kening Song - P3.51 Li Tong Da - P1.11 Jianxin Zhou - P3.66, P3.67 Jing Gao - P4.55, P4.20, P4.57, P4.52 Jun Tan - P3.10, P3.19 Kenji Araki - Th2G.2 Li Wan - Th3D.3 Jianxing Pan - Th2D.1 Jing Guo - P2.30 Jun Xu - P2.68 Kensuke Nishioka - Th2G.2 Li Xia - P2.3

Jianyao Jiao - W2G.2 Jing Hou - T2B.7, W1D.5, P4.36 Jun Ye - W1D.1, T3E.4, T2B.5, W1D.7, Kentaro Nakamura - W 1 F. 2 Li Yuandong - P1.15 Jianzhong Zhang - Th 2F. 3, T2F. 4, Jing Li - P1.21 W1D.8 Keping Long - P2.37 Li Zhang - P2.23 Th3H.4 Jing Liang - P3.36 Jun Zhang - P4.44 Kexin Li - P1.63 Lianfeng Ren - P3.16, P3.17

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Key to Authors and Presiders Liang Cao - P4.6 P4.1 Meili Jiang - P2.31 Mingyi Gao - P3.18, P1.34 Pawel Niedzialkowski - W 4F. 1 Liang Chen - Th3C.5, P2.38 Liqiang Zhang - T2E.4 Mengmeng Han - Th3H.1 Mingyu Chen - W 2F. 6 Peide Liu - W4E.4 Liang Shang - P1.4 Liqin Xie - P1.52 Meiqi Feng - Th1D.4 Mingzhong Xu - P4.61 Peiguang Yan - W1C.4, P2.63, P2.65, Liang Shu - P3.12 Lirong Cheng - W2G.4, W2G.1 Meisong Liao - Th1E.1 Minjun Zhai - P2.45 P2.67, P3.25, W3D.2 Liang Tian - P2.12 Liu Bing - P2.57, P2.58 Meiyu Liu - P3.37 Minli Zhang - P3.20 Peilong Yang - W1D.6 Liang Zhang - W4E.3, P4.26 Liu Bo - P4.58 Meng - Th 2F. 6 Minoru Ohtsuka - W2B.4 Peiqing Cai - P3.30, P4.42 Liangjin Huang - W2E.4, T2B.1 Liu De Ming - P1.11 Meng Linghao - P1.31 Miyoshi Seki - W2B.4 Peisong Wu - W1C.6 Liangjun Lu - W2C.3, P1.65, T3G.4, Liu Honggang - P1.31 Meng Llian - P4.14 Mo Chen - P3.42 Peiyun Cheng - P1.60 Th3H.3 Liu Jie - W2A.4 Meng Zou - P1.49 Mohamed Bouchemat - P2.29 Peizhen Jiang - P3.38 Lifeng Bao - P2.35 Liu Tao - W2A.4 Mengke Yin - P4.26 Morifumi Ohno - W1G.4 Peng Hao - P2.31 Lihui Zhu - P3.37 Liu Yange - W1D.4 Mengmeng Han - P1.60 Muyang Ban - W2H.2 Peng Lin - Th2B.4, Th2B.5 Lijia Yang - W2E.4, T2B.1 Liu Zugang - P4.3 Mengnan Lu - P1.36, W3F.1 N Peng Wang - Th3C.5, T3B.1, W1C.5, Lijia Zhang - P1.3 Liuming Zhang - W2A.7 Mengqiu Fan - P2.36 Na Zhu - P2.36 W1C.6 Lijian Zhang - Th1I.2 Liuwei Wan - P2.44 Mengyu Zhang - W1C.4, P2.65, Nafizah Khan - W4B.4 Peng Wang Wang - P2.38 Lijiao Zu - P2.47 Liwei Yang - P1.30 P2.67 Naikui Ren - P4.54 Peng Xiang - P2.23 Lijing Zhu - W2A.2 Liwei Zheng - P4.7 Mengyun Pan - P4.10 Nan Chi - W2C.2, W2A.3, P1.57, Peng Xie - P1.24 Lijun Chen - Th3D.3 Lixia Xi - W2A.1, P2.66, P1.26 Mengzhe Xiao - W4F.3, P3.5, P1.32 T3C.1 Peng Xue - P2.14 Lijun Li - Th 2F. 5 Lixiang Wang - W4H.1 Mi Li - P4.41 Nan Cui - W2A.1 Peng Zhu - P2.11 Lijun Qiao - Th2F.3, T2F.4 Liyang Shao - P3.15 Michel Dossou - P1.47 Nan Hua - T3A.3 Pengbai Xu - T2B.6 Lili Gui - W4D.4 Liyue Jiang - P2.20 Michele Muccini - T2H.4 Nan Zhang - W1D.6 Pengbin Hu - P3.2 Lili Zhang - W1C.6 Long Huang - T2B.5, W2D.5 Min Chen - P1.1 Nan-Kuang Chen - T2E.4 Pengbing Hu - P3.3, P3.57, P3.8 Lilin Yi - W1A.1 Longfei Yin - P1.59 Min Liu - P4.8 Nannan Ning - P3.9 Pengfei Du - P3.34 Lilong Dai - W2D.4 Longsheng Li - W2B.3 Min Wang - Th3B.1, P3.69 Nannan Zhang - W2A.1 Pengfei Lu - P1.30 Limin Cui - P2.55 Longzhu Guo - P2.13 Min Zhang - P1.24, P1.33, P3.35, Naoya Wada - W3A.1 Pengfei Ma - W2D.5 Limin Hu - P4.61 Lu Chen - Th2A.5, P1.8, P2.40 P3.65 Nguyen Dong-Nhat - W4B.4 Pengqi Yin - Th2A.4 Limin Xiao - W2E.1 Lu Huang - W2E.2 Min Zhu - W4B.2 Ni Quan - P2.24 Perry Ping Shum - P1.35, P1.44, Lin Chai - Th1B.3 Lu Li - P4.64 Ming Deng - Th2E.3 Ni Quan Quan - P2.41 P1.45 Lin Cheng - P2.21 Lulu Wang - P1.40 Ming Ding - Th2C.4 Nian Fang - P4.71 Petr Sezemsky - W 4F. 1 Lin Guan - W2B.5 Luming Li - P2.49, P1.33, P3.70, P4.2 Ming Jia - P4.34 Nicola Calabretta - T3A.4 Ping Lu - T 2 F. 3 Lin Hai - Th3B.2, P2.56 Luming Zhao - W4D.2 Ming Lin - P1.18, P2.60 Nicole Pamme - P1.67 Ping Shum - Th2D.1, W2E.5 Lin Jin - P4.12 Lutang Wang - P4.71 Ming Luo - W3A.3 Nigel Pickett - W1H.1 Ping Su - P2.71 Lin Shi - P4.41 M Ming Xu - P2.45 Nijiati Paerhati - P1.24 Ping Yu - P4.67 Lin Sun - W3A.4 Mahieddine Lahoubi - P2.29 Ming Yan - P2.43, P1.14 Ning An - T2C.3 Pingping Lei - T3C.2 Lin Yang - P1.20, P3.7, T3G.2 Makoto Okano - W1G.4 Mingfei Ge - W3B.6 Ning Chen - P3.2, P3.3, P3.57 Pinping Lei - P4.16 Lin Zhang - Th1E.2 Man Jiang - W2D.5 Mingfu Zhao - W4C.5, P3.21, P4.40 Ning Jiang - Th2A.5, P1.8, P2.40 Pu Tao - P1.15 Linbo Liu - P1.40 Minghao Lu - P4.25 Pu Zhou - T3E.2, W1D.1, W1D.2,

Maobin Wang - P2.12 Ningning Wang - T3G.4 Linbo Zhang - P4.20 Maolong Zhang - P2.51 Minghong Yang - P1.19, P1.22, Nobuyuki Yokoyama - W2B.4 T3E.4, P3.23, T2B.5, W1C.3, Linfang Wu - P1.53 Marcin Koba - W 4 F. 1 W1E.3 Noritsugu Yamamoto - W1G.4 W2D.5, W2E.4, T2B.1, W1D.7, Linfeng Yang - W2G.5 Mariano Mahuvi Christian Mahissi - Minghua Cao - Th1D.5 O W1D.8, W3E.4 Ling Chen - P1.43, P1.67 P1.47 Minghui Cong - Th2A.6 Osamu Moriwaki - W4G.1 Q Ling Qin - P3.51 Marta Janczuk-Richter - W 4 F. 1 Mingjiang Zhang - Th2F.3, T2F.4, P Qi Chen - P1.46 Lingli Wang - P3.10 Th3H.4 Masafumi Yamaguchi - Th2G.2 P. K. A. Wai - W 2 F. 4 Qi Meng - P4.42 Linjie Zhou - W2C.3, P1.65, T3G.4, Mateusz Smietana - W 4 F. 1 Minglun Zhang - P3.40, P3.44 Qi Wang - P4.13, Th1C.4 Key to Authors Authors to Key Pan Dai - P1.1 Th3H.3 Mingming Luo - T2B.2, Th1F.2 Mei Sang - P2.8 Panke Qin - P3.55 Qi Wei - P4.13 Linyong Yang - W1D.5 Mingming Wang - P2.31 Mei Yang - P1.70 Panyun Gao - Th3C.5, P2.38 Qi Zang - P4.20, P4.57 Liqian Wang - P2.49, P3.62, P4.2, Mingquan Chen - P1.71 Meijuan Hong - P4.61 Pavel Brunkov - T3H.2 Qi Zhang - P1.6, P2.39, P1.18, P2.59,

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Key to Authors and Presiders P2.60, P2.61, P2.62, P1.27, P3.6, Qiqing Li - P2.64 Sen Sun - P4.38 Shiqin Liu - Th2A.5, P1.8, P2.40 Sushank Chaudhary - T3B.5 P3.54, P4.24, P4.27 Qirui Feng - P3.29 Sen Ye - W 2 F. 2 Shiva Kumar - W2B.1 Syed Agha Hassnain Mohsan - Qian Che - P2.11 Qisheng Zhang - T2H.3 Senhui Yin - P3.5, P1.32 Shiwei Cai - P4.13 W2A.6 Qian Li - Th1D.1, T3B.4 Qisong Shang - W2A.1 Shailendra Gaikwad - W1B.1 Shixin Liu - P4.17, P4.15 T Qian Wei - Th2D.1 Qiu Yanqing - P4.33 Shan Huang - P3.42 Shixun Dai - W1D.6, W3D.1 Taiju Tsuboi - T2H.3 Qian Yu - P2.44 Qiuyan Yao - W2B.5 Shangjian Zhang - W3B.6 Shiyi Xie - W4F.3, P3.5, P1.32 Takayuki Kawashima - T2G.3 Qiang Gao - P2.21 Qiwei Lai - T3B.5 Shanglin Hou - Th1D.5 Shiyu Qi - P3.6 Takuji Nagashima - Th1E.4 Qiang Ge - P1.10 Qiyong Tang - P4.37 Shanglin Yang - P1.20, P3.7 Shoufeng Tong - Th2A.6 Tan Sin Jin - P2.54 Qiang Lin - W2I.1 Qizhen Sun - P1.44, W1F.5, P1.45, Shangqi Ma - Th3B.4 Shu Namiki - W2B.4, W1G.4 Tang - P2.42 Qiang Wu - P1.43, P1.61, P1.67, P1.49, Th1E.2 Shanguo Huang - P1.63 Shuaijie Miao - W4E.4 Tao Dong - Th1B.4 W 1F. 1 Quan Yuan - P4.32 Shangyuan Li - W3B.2 Shuailin Liu - P4.36 Tao Liu - W3B.5, P1.45, P3.55, P4.57 Qianmin Dong - P3.63 Quan Zhang - P2.10 Shangzhi Zhong - P4.29 Shuang Du - Th3B.5 Tao Ma - P1.41 Qianming Dong - Th 2F. 2 Quan Zhou - P2.15 Shanhong You - W2C.4, Th2F.4 Shucheng Du - P2.66 Tao Pu - P2.5, P2.23, P1.12, P3.4, Qianqian Huang - W2D.1, W2D.4 Quanzhong Zhao - T3D.3 Shanshan Zeng - T2H.2 Shuguang Li - P3.39 P3.13 Qiansheng Wang - P1.17 Qun Han - P2.8, Th2C.3 Shanyong Cai - P2.49, P4.2 Shuhei Toyokawa - Th1E.4 Tao Song - W2H.2, W4C.5, P4.40 Qianwu Zhang - Th2A.1, P1.46, P4.8 R Shaofei Tang - T3A.2 Shuhuang Chen - P1.65 Tao Wang - P3.23, W1C.3, Th2F.3, Qiao Jiang - P4.35 Ran Hao - W2G.2 Shaohua Hu - P4.16 Shuhui Liu - P3.47, W2E.5 T2F. 4 Qiao Wei - P1.11 Ran Xia - P1.44 Shaohua Yu - W3A.3 Shuidong Xiong - P1.37, P4.37 Tau Wan Lim - P4.28 Qiao Xiong - P3.53 Ranran Liu - P2.51, P3.34 Shaoshuo Ma - P1.21 Shuiyan Zhang - Th3B.5 Tean Lu - W1F.5, Th1E.2 Qiaochu Yang - Th2B.5 Raymond Beausoleil - W4G.2 Shasha Fang - P2.6, P2.9, P1.72 Shun Han - P1.3 Teng Wang - P2.52 Qiaomu Xie - Th3D.3 Rende Ma - Th1C.2 Shencheng Ni - W2C.4, Th2F.4 Shun Wang - P3.47 Tengxiao Liu - W4H.3 Qiaoqiao Zhao - P2.61 Renlai Zhou - Th1D.1, T3B.4 Sheng Fu - Th3D.3 Shuo Yuan - P3.59 Tetsu Morishima - Th1E.4 Qiaoyun Wang - P3.16, P3.17, P3.19, Rentao Gu - P4.14 Sheng Wang - P4.18 Shuqin Lou - P3.28, W3E.1 Tetsuya Hayashi - Th1E.4 P3.45 Riffat Tehseen - W2A.6 Sheng Xue - W2F.6 Shuqing Lin - P2.40 Tetsuya Nakanishi - Th1E.4 Qichuan Cui - P3.65 Robert Bogdanowicz - W 4 F. 1 Shenghua Zhou - P4.29, P4.69, P4.50 Shuqing Ma - P4.70 Tian - W 4 F. 3 Qifa Liu - P3.9, P3.37 Rong-Jun Xie - T3H.3 Shenghui Shi - P3.21 Shuyi Liu - P1.7, P3.32, P4.62 Tian Wang - P3.9 Qihang Cheng - P4.21, P4.23 Rongle Huang - Th1D.1 Sheng-Jie Wan - P3.14 Shuying Han - P1.48, W2C.4, Th2F.4 Tianfu Yao - T3E.2, W1D.1, W1D.2 Qin Chen - T h 2 F. 1 Rongrong Wen - T2H.2 Shenglai Zhen - P2.17, P2.20 Shuyun Wen - P3.35 Tianheng Lu - W 2F. 5 Qin Mei - P2.50 Rongtao Su - W2D.5 Shengli Pu - P2.29 Si Chen - P2.28, W4I.3 Tianliang Wang - P3.19 Qing Ding - Th1D.4 Ruben Soares Luis - W3A.1 Shengpeng Wan - P1.43, P1.67 Simei Mao - P2.48 Tianmou Xu - P4.42 Qing Huang - P1.19 Rui He - P3.29 Shengping Chen - W1D.3 Siqi Hu - W 2F. 5 Tianshu Wang - Th2B.4, Th2B.5, Qing Sun - Th1D.4 Rui Ma - W1F.3, P2.69 Sheng-Ping Chen - P1.16 Siyu E - P1.35 P4.32 Qing Yang - Th3G.2 Rui Song - T2B.7 Shengping Liu - P1.1 Sjoerd Heide - Th1A.3 Tianwai Bo - T2A.3 Qing Zhang - W4B.1 Rui Zhou - P2.50 Shengtao Lin - P1.62 Song Wang - P3.30 Tianxu Xu - Th3H.5 Qingguo Song - W 1 F. 5 Ruifang Wang - P1.41 Shibin Ai - P1.19 Songhao Liu - W2G.6 Tianye Huang - Th2D.1, Th2D.3 Qinghua Tian - P1.6, P2.39, P1.18, Ruifu Huang - P1.38, P4.65 Shichen Wu - P2.16 Songnian Fu - P1.51, Th2D.3 Tianyi Wu - W1D.5 P2.59, P2.60, P2.61, P3.54, P4.24, Ruihua Yu - P2.66, P1.26 Shifang Dai - Th3B.2, P2.56 Stefano Toffanin - T2H.4, Th2H.3 Tianyu Shen - W4B.2 Key to Authors P4.27, T3C.4 Ruijie Luo - T3A.3 Shigeyuki Yanagimachi - W3A.2 Su Chen - P3.61, W2D.3, T2E.3 Tianyun Wang - P3.64, P3.67 Qinghua Xiang - P1.5 Runfeng Chen - W3H.5 Shili Li - P2.6, P2.9, P1.10, P1.72 Subiao Bian - Th 1F. 4 Tianze Wu - W4A.2 Qinghua Yu - P2.28, P3.64 Ruiling Zhao - Th3H.3 Shiliang Li - Th1B.4 Sucheng Du - P1.26 Tianzong Xu - T h 2 F. 5 Qinghui Deng - W2D.2 Runmin Liu - P4.32 Shiling Zhang - P2.4 Sujuan Feng - P1.4 Tigang Ning - W3F.3, P1.21 Qinglin Nie - P3.21 S Shilong Pan - T2G.1, W3B.4 Sun Qi Zhen - P1.11 Tilian Yang - T2G.4 Qingming Lv - P3.21 Shiming Gao - Th2B.2 Sun Yue Zhen - P1.11 Ting Feng - P2.31

Sailong Wu - W2G.4, W2G.1 Qingsong Luo - P1.34 Sanjeev Tulasigeri - W1B.1 Shimulin Xie - W2B.2 Sunan Xu - Th2H.1 Ting Wang - W1B.1 Qinyang Yu - Th2A.1 Sankhyabrata Bandyopadhyay - Shinji Matsuo - W3G.1 Sung Heum Park - P2.2 Ting Zhou - P1.20, P3.7 Qiong Yao - P1.37, P4.37 P3.15 Shipei Jing - P2.69 Sunqiang Pan - P3.2, P3.57, P3.8 Tingting Lang - P3.32, P4.51

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Key to Authors and Presiders Tingting Liu - P3.66, P3.67 Weihua Zhang - P3.59, P1.54, P1.55 Xaohui Jiang - P4.49 Xiaohui Li - Th2D.2 Xinguo Li - W4C.4, W2B.6, Th2A.4 Tingting Xu - P4.8 Weijia Yang - W3D.3 Xi Fang - P4.66, P4.43 Xiaoji Zhou - W3I.2 Xingwei Wang - Th 1F. 5 Tingting Zhang - P3.58 Weijian Tian - P2.44 Xi Xiao - W3A.3 Xiaokang Lian - P1.61 Xingwen Yi - W4A.4, P2.27 Tingxi Sun - P4.18 Weili Zhang - W4E.2 Xia Lili - P4.47 Xiaolei Guan - P1.59 Xingzhe Shi - W2G.6 Tingyu Meng - P3.29 Weiming Hao - P3.56 Xia Zhang - P1.71 Xiaoli Liu - W4H.2 Xinhua Chen - W 2 F. 5 Tingyun Wang - W2E.3, P1.64, P4.34 Weiping Li - P1.57 Xiahui Tang - P1.44, P1.45 Xiaoli Yin - P2.64 Xinhuan Feng - Th2E.2 Tomomi Sano - Th1E.4 Weiqiang Yang - T2B.7 Xian Zhou - P1.24 Xiaoling Tan - P1.25 Xinhui Zhou - W4H.2 Tong Zhai - P2.50 Weiqing Gao - Th3C.5, Th3C.1, Xianchun Xu - P3.66 Xiaolong Ni - Th2A.6 Xinliang Zhang - W3B.1, P2.34, Tonglei Cheng - P3.39, W3D.4 P2.38 Xianfeng Tang - P1.58 Xiaolong Si - W1F.6, P1.53 T2B.4 Tongyu Liu - P3.58 Weisheng Hu - W2B.3 Xiang Guo - P1.63 Xiaomin Ren - W3B.5, P3.40, P4.13, Xinyao Shi - P3.23, W1C.3 Touraya Bouchemat - P2.29 Weiwei Li - P2.26 Xiang Jia - W4A.2 T2I.1 Xinyi Ren - P1.14 V Weiwei Liu - T3D.2 Xiang Li - P4.19 W3A.3, Xiaomu Wang - W3C.2 Xinyi Zhao - P1.51, W2E.2 Valentina Benfenati - T2H.4 Weiwei Pan - T3B.2, P3.33 Xiang Liu - W2B.2 Xiaopeng Dong - P1.36, P1.66, Xinying Chen - W 1F. 4 Vitezslav Stranak - W 4F. 1 Weiwei Wang - P2.71 Xiang Zhang - P4.20, P4.41 W 3F. 1 Xinyong Dong - P1.38, P4.65, P4.46 Vuong V. Mai - Th2B.1 Weiwei Yang - P4.72 Xiangang Wan - W2I.3 Xiaoping Zheng - T3A.3, W3B.2 Xinyu Fan - T3F. 4 W Weiwen Zou - T3C.3 Xiangfei Chen - P1.1, P3.71 Xiaoshan Yu - Th3B.4 Xinyu Liu - P3.1, P1.28, P1.29 Wallace C.H. Choy - Th2G.3 Wen He - P3.40, P3.44 Xiangjun Xin - P1.3, P1.6, P2.39, Xiaosheng Xiao - T2D.4 Xinzhu Sang - P2.69, P1.30, P3.26 Wang - P2.42 Wen Li - P4.21, P4.23 P1.18, P2.59, P2.60, P2.61, P1.28, Xiaosong Yu - W2B.2, W4I.4 Xiong Liang - P3.49 Wang Chaojin - Th3C.3 Wenbo Zhang - W2A.1 P3.54, P4.24, P4.27 Xiaotao Guo - T3A.4 Xiong Luo - P2.51, P3.34 Wang Dan - W2A.4, P4.58 Wenchang Lai - W2D.5 Xianglong Zeng - P2.52, Th1C.3 Xiaotian Zhou - W2B.2 Xiu Zhang - Th3C.5, P2.38 Wang Tianyun - P2.57, P2.58, P4.47 Wendong Li - T3B.3 Xiangping Pan - P1.64 Xiaoxiao Li - Th1D.5 Xiulai Xu - T2I.2 Wang Zhi - W1D.4 Wenfei Sun - P3.40 Xiangxiang Meng - P2.16 Xiaoxiao Wang - P2.50 Xizhen Xu - Th1E.3 Wanjin Zhang - T2F. 3 Wenhua Gu - W4A.2 Xiangye Zeng - Th 1F. 2 Xiaoxue Gong - P1.56 Xu Bo - P3.31 Wanjun Wang - P4.19 Wenhui Jiang - Th3C.5, P2.38 Xiangyu Qu - T2H.2 Xiaoying Li - W4I.1 Xu Guo - T h 1 F. 5 Wanrong Yu - Th1B.2 Wenjie Zhu - P1.19 Xiangyu Wu - P1.3 Xiaoyuan Niu - P3.1, P1.28, P1.29 Xu Hang - P3.48 Wei Gao - W2C.3 Wenjuan Chen - T2G.1, W3B.4 Xianmin Jin - Th2I.5, T3I.1 Xiaoyue Wang - P2.43 Xu Jiang - P1.68, P4.48 Wei Han - P1.61 Wenjun Ni - W2E.5 Xianmin Jin; - Th1I.4 Xiaozheng Tang - P4.41 Xu Sun - P4.39 Wei Ji - T3D.1 Wenli Lv - Th2H.1 Xianwei Gao - P4.43 Xiaozheng Wang - P3.40 Xu Wang - T2B.4, Th2A.2, P1.41 Wei Li - P2.3 Wenlin Gao - P3.59, P1.54 Xiao - Th2F.6, P4.6 Xifeng Ren - Th1I.5, T3I.2 Xu Wei - P4.41 Wei Li Zhang - W 1 F. 3 Wenn Jing Lai - P4.28 Xiao Chen - W2A.5, W2A.6 Xiliang Du - P1.68 Xuan Quyen Dinh - W2E.5 Wei Liu - P2.6, P2.9, P2.20, P1.10, Wenqing Niu - W2C.2, W2A.3 Xiaobo Xing - W4G.4, W2F.6 Xi-Lin Wang - W3I.4 Xuan Tang - P3.9, T3B.5 P1.72 Wenrong Yang - T h 1 F. 2 Xiaobo Zhu - W4A.2 Xin (Scott) Yin - W3G.4 Xuanyi Liu - T3B.4 Wei Lu - T3A.2 Wenshan Cong - P2.51 Xiaocheng Tian - P2.36 Xin Cheng - P3.33 Xudong Wang - P4.68 Wei Luo - P1.71 Wentao Zhang - W4E.4 Xiaodi You - T2A.4, P1.50 Xin Fu - P3.7 Xudong Zhao - P1.54 Wei Peng - P4.11 Wenting Huang - P1.5 Xiaodong Lin - T2G.4 Xin Guo - P4.19 Xue Chen - P1.54, P1.55, P4.1 Wenxiao Zhang - Th3D.3 Xiaodong Wu - Th2D.4 Xin Miao - W2B.3 Xue Deng - P4.55, P4.20, P4.57 Wei Qiang - P2.57, P2.58 Wei Wei - P1.71 Wenxiong Du - T2D.2 Xiaofeng Duan - W3B.5, P4.13 Xin Mu - W2G.4, W2G.1 Xue Li - W2A.1 Wei Xu - P1.48 Wenxuan Ye - P1.5 Xiaofeng Li - Th2G.1 Xin Tu - W2G.4, W2G.1 Xue Lu - Th3C.3 Wei Zhang - Th3C.5, P2.38, W1F.5, Wenxuan Wang - P3.71 Xiaofeng Ma - P1.71 Xin Wang - P3.28, P4.7, P4.22 Xue Zhou - P3.39 P1.49 Wenyan Mao - P4.9 Xiaofeng Xu - P3.38 Xin Yan - P1.71 Xuefeng Peng - W1D.6 Wei Zhou - P2.62, W1F.5, P1.49 Wenzhu Huang - W4E.4 Xiaoguang Zhang - W1A.3, W2A.1, Xin Zhang - W2D.2 Xuegang Li - P1.35, P3.39 Weichao Lyu - W2A.6 Wioleta Bialobrzeska - W 4 F. 1 P2.66, P1.26, P1.58 Xing Dao He - P1.43 Xuelin Yang - W2A.7 Wuming Liu - W1I.4 Xiaohai Wang - P3.45 Xing Liu - P2.49, P1.33, P3.70, P4.2 Xuemei Zheng - P4.68, P4.53

Key to Authors Authors to Key Weida Hu - T3B.1, W1C.5, W1C.6 Weidong Shao - P3.18 Wusheng Fang - P1.50 Xiaohuan Shen - T3B.5 Xing Xu - P1.3 Xueming Liu - T2D.1 Weifeng Mou - P3.4, P3.13 X Xiaohui Gao - Th1D.2 Xingdao He - P1.67 Xuenan Zhang - P3.39 Weigang Hou - P4.5 X. Steve Yao - P2.31 Xiaohui Hu - P4.18 Xinglin Tong - P3.53, P1.47 Xueqi Ren - W4B.2

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Key to Authors and Presiders Xueqian Bai - P2.19 Yang Shen - P3.5 Yeshu Tan - W2H.2 Yinming Liu - T h 2 F. 5 Yong-Zhen Huang - T3G.1 Xueru Zhao - P2.8 Yang Wang - P3.43, P2.60, P4.14, Yeteng Tan - P2.5 Yinping Miao - P2.47, Th2C.2 Yoshinari Awaji - W3A.1 Xuewen Shu - W4E.1, P1.60, Th3H.1 W1C.5 Yezhou Wu - W 2 F. 3 Yiping Huang - P2.52 Yosuke Mizuno - W 1 F. 2 Xueyu Kang - P4.14 Yang Xiang - P1.44, P1.45 Yi An - W2E.4, T2B.1 Yiping Wang - Th1E.3 Youfu Geng - P1.25 Xujun Fan - Th 1F. 2 Yang Xu - P3.61, W2D.3, T2E.3 Yi Cai - W3G.2 Yiqiang Li - P4.27 Youhang Zhou - P2.53 Xuke Chen - P4.46 Yang Yue - W4A.1, Th3H.5 Yi Chen - T2H.2 Yiqiang Zhang - W3H.4 Youlong Yu - P4.54 Xulun Zhang - P2.66 Yang Zhang - T3E.2, W1D.1, T2B.5, Yi Jiang - P2.21 Yitong Li - W4C.4, W2B.6, Th2A.4 Youxiang Ye - P4.69, P4.50 Xun Cai - W 1 F. 4 P4.11, W1D.7, W1D.8 Yi Lei - Th1A.3 Yiwen Xu - P1.25 Youyuan Sun - P3.40, P3.44 Xunan Zheng - Th3B.3 Yange Liu - W3E.3 Yi Li - P3.16, P3.17, P3.19, P3.45 Yiwen Zhang - Th3H.5 You-Zeng Hao - T3G.1 Xunlun Zhang - P1.26 Yangjian Cai - W1I.3 Yi Liu - P2.22 Yixin Fu - P4.43 Yu - Th2F.6, P4.6 Xuping Zhang - W4F.2, T2F.1 Yangli Zhu - P4.61 Yi Liu - P3.71 Yixin Zhang - W 4 F. 2 Yubo Li - P4.72 Xuqiang Wu - P2.6, P2.9, P2.17, Yangyang Zhao - P1.64 Yi Zeng - Th3B.4 Yiyang Luo - P1.44, P1.45, W2E.5 Yu Xiong - W4C.3 P1.10, P1.72 Yanhou Geng - Th2H.2, P3.41 Yichen Fan - P1.58 Yiyun Li - P3.50 Yu Chen - P1.9 Xuwei Xue - T3A.4 Yanhua Dong - P1.64 Yichi Zhang - P3.26 Yizheng Jin - W2H.1 Yu Chen – P4.70 Xuyong Yang - Th3G.5 Yanhua Han - P4.61 Yifan Duan - P4.11 Yizhu Chen - T3E.2, W1D.2 Yu Lei - P1.46 Xuzhou Liu - P4.24 Yanhua Luo - P1.30 Yifan Li - P3.69 Yong Liu - T2D.2, Th2D.4 Yu Liu - W 4F. 2 Y Yanhua Ma - Th 2F. 5 Yifan Shen - P3.60 Yong Shu - P4.61 Yu Lu - P4.41 Ya Cheng - W1I.1 Yanjun Liu - P3.15 Yifeng Xiong - P3.11 Yong Wang - P1.19 Yu Qinghua - P2.58, P4.47 Ya Yang - Th1H.3 Yanjun Zhong - T2A.4 Yijun Zhao - W1D.5 Yong Yao - P3.5, P1.32 Yu Sun - P1.68 Yahui Wang - T2F. 4, Th3H.4 Yanliang Liu - P2.2 Yikai Su - T2A.1 Yong Zhang - T3I.3 Yu Xia - P4.61 Yajie Li - Th3H.2 Yanling Song - W3H.4 Yike Xiao - P1.7 Yong Zhao - P1.1, P1.35 Yu Yang - P1.42 Yajie Wang - P3.21 Yanlong Meng - P3.10, P3.19 Yilan Xu - P1.24 Yong Zhou - Th3C.5, P2.38 Yu Zheng - P1.35, P1.44, W2E.5 Yajun Wang - Th2A.5, P1.8, P2.40 Yanlong Yin - T2C.1 Yilun Zhao - P3.12 Yong Zhu - P2.32 Yuan Chen - Th1I.4 Yalan Wang - P2.51, P3.34 Yanpeng Wang - P3.29 Yimei Wei - P2.32 Yongguang Wang - Th 1F. 3 Yuan Gao - P1.23 Yali Zhang - W3B.6 Yanping Sha - P3.18, P1.34 Yimei Zhong - P3.59, P1.54, P1.55 Yongheng Lu - Th2I.5 Yuan Gong - P4.11, W3F.2 Yan Feng - T3E.3, T3B.2, P3.33 Yanqing Qiu - P3.17, P4.29, P4.50 Yiming Li - W2D.2 Yongjun Wang - P2.39, P2.59, P2.60, Yuan Xia - W3B.6 Yan Fu - W2B.3 Yantao Guo - P4.1 Yin Meihuan - P3.31 P2.61, P3.1, P1.28, P1.29, P3.54, Yuanda Ling - W2D.4 Yan Li - Th3B.2, P4.10 Yanting Zhu - P4.31 Yin Wang - P3.58 P4.24, P4.27 Yuandong Li - P1.12 Yan Li - P3.71 Yanxing Ma - W2D.5 Yin Zhiping - P2.57 Yongkang Dong - T2B.6, Th2E.1 Yuanfan Liu - P1.57 Yan Qiao - P4.11 Yanyan Xu - P1.39 Yinaer Ha - W2C.2, W2A.3 Yongli Tang - P3.55 Yuanfu Chen - W1C.2 Yan Senlin - P3.27, P3.68 Yanyun Xue - P2.34 Ying Li - P3.22, W1D.5, Th1I.3 Yongli Zhao - W2B.2, W4B.3, Th3H.2 Yuanfu Lu - W2G.5, W2G.6 Yan Zhang - P4.48 Yao - P2.42 Ying Liu - W4C.5 Yongliang Zhao - P2.29 Yuankui Leng - P1.67 Yan Zhi Jun - P1.11 Yao Wang - Th2I.5 Ying Shen - Th2F.4 Yonglin Huang - P4.12 Yuanxiang Chen - W4C.4, W2B.6, Yana Shang - P1.64 Yao Zhou - P2.55 Ying Tao - P2.59, P2.61, P4.24, P4.27 Yongliu Liu - W3B.6 Th2A.4 Yanan Wang - P4.14 Yaocheng Shi - W1G.3 Ying Wan - P4.34 Yongming Hu - P1.37 Yuanxiu Fu - T3F. 4 Ya-Nan Zhang - P1.35 Yaojiang Chen - Th1G.4 Ying Wang - P2.2, Th2H.1 Yongming Zhu - P1.24 Yuanyuan Ma - P3.18 Yanfang Li - P3.58 Yaqiang Ma - P1.22 Ying Yu - W4H.2 Yongqi He - P1.42 Yubin Wei - P3.58 Key Yang - T h 2 F. 6 Yaqing Bie - W3C.3 Ying Zhang - Th2B.4 Yong-Qiang Liu - T2B.3 Yuchen Song - P3.65

Yang Ao - P1.31 Yarien Moreno - W1F.5, P1.49 Yingchun Li - Th2A.1, P4.8 Yongqing Huang - W3B.5, Th1G.5, Yucheng Pan - P3.1, P1.28, P1.29 to Authors Yang Chen - Th1I.5 Yasuhiro Koike - T2E.2 Yingcong Li - T3A.2 P4.13 Yudan Zhang - P1.2 Yang Gao - P2.68 Yasuyuki Ota - Th2G.2 Yingquan Peng - Th2H.1 Yongtao Huang - W4C.4, W2B.6, Yue Dong - P2.49 Yang Han - P3.41 Yatao Yang - P3.15 Yingtao Hu - W4G.2 Th2A.4 Yue Li - P1.2 Yang Lei - P4.60 Yaxin Zhang - P1.9 Yingxiong Song - Th2A.1, Th3B.1, Yongxing Du - P3.51 Yue Tao - P1.16 Yang Li - P4.42 Yaya Mao - P1.3 P4.8 Yongxiong Ren - Th3H.5 Yue Wu - W 2 F. 1 Yang Lu - P1.13 Ye Deng - P2.12 Yingxiu Li - P1.5 Yongyin Kang - W1H.4 Yue Zhou - P1.23 Yang Qiu - W2F.3, W2A.5 Ye Yu - P4.35 Yingying Wang - W1E.2, W1D.6 Yongzhen Hu - P3.51 Yuechun Shi - P1.1

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Key to Authors and Presiders Yue-De Yang - T3G.1 Yutang Dai - P1.39 Zhen Li - Th3G.3 Zhiqi Rong - P4.53 Zuliang Ruan - P1.21 Yuefeng Liu - Th2G.4 Yuto Sagae - W4A.3 Zhen Tian - T2E.4 Zhiqiang Mao - P1.43 Zuqing Zhu - T3A.2 Yuehong Shen - P2.23 Yutong Wang - P4.17, P4.15 Zhen Wang - P4.29 Zhiqiang Sun - P3.32 Zuxing Zhang - P2.15, P1.2, P3.61, Yuejiang Song - P4.41 Yuwei Su - Th1B.4 Zhen Xing - P3.28 Zhiquan Wan - P3.12 P1.52, W2D.3, P2.70, T2E.3 Yueqing Du - P1.60, Th3H.1 Yuwei Zhang - P2.44 Zhen Xu - W2B.5 Zhiwei Lu - T h 1 F. 1 Zuyao Liu - P1.51 Yueyang Yu - P4.66, P4.61 Yuwen Qin - T2B.6 Zhen Yang - P1.59 Zhiwen Sun - Th2B.4, Th2B.5 Zuyuan He - W3A.4, T3F. 4 Yuezhen Sun - W1F.5, P1.49, Th1E.2 Yuxin Zhao - T h 1 F. 3 Zhen Zhang - Th3B.2 Zhiyang Ni - P2.45 Yufan Wang - Th2E.3 Yuxue Feng - P1.70 Zhenda Xie - W1C.2 Zhiyao Zhang - W3B.6 Yufei Shen - P2.61, P4.24 Yuyang Gao - P1.42 Zheng Jilin - P1.15 Zhiyong Xu - P2.32 Yufeng Zhang - P3.40, P3.44 Yuyao Guo - Th3H.3 Zheng Li - Th1D.4 Zhiyuan Dou - P4.36 Yuhan Dong - P2.48 Yuzhong Feng - T3C.2, P4.16 Zheng Liu - P4.34 Zhong Fan - P4.41 Yuhan Yang - P4.4 Z Zhengbin Li - P1.42 Zhong Shangzhi - P4.33 Yuhe Zhao - T2B.4 Zang Qi - W2A.4 Zhenghua An - T2I.3 Zhongcheng Liang - P1.9 Yuhuan Qin - P1.22 Zanshan Zhao - W3B.3 Zhenghui Pan - W1C.3 Zhongli Wang - P3.41 Yujia Zhao - P3.38 Zanwei Shen - W2A.7 Zhengmao Wu - T2G.4 Zhongliang Qiao - P4.19 Yujian Li - P4.49 Zeng Peng - P3.15 Zhengrong Tong - P3.59, P1.54, Zhongqi Pan - W1B.1, Th3H.5 Yujin Bao - P2.34 Zeng Xianglong - P1.31 P1.55 Zhongxu Cao - T2C.3, W1C.2 Yujun Cheng - P3.26 Zewen Zhou Zhou - P3.25 Zhenguo Jing - P4.11 Zhou Meng - P1.13, P3.42, P4.6, Yukai Chen - P3.4 Zewu Ju - P1.13 Zhengxiong Zhang - Th3C.5, P2.38 P4.70 Yuki Saito - Th1E.4 Zexuan Jing - P3.54 Zhengxuan Li - Th3B.1 Zhu Hu - Th2D.4 Yulian Wang - P2.20 Zeyi Ding - P1.7 Zhengyang Liu - P2.21 Zhu Huatao - P1.15 Yuliya Semenova - P1.61 Zhang - Th2F.6, P4.6 Zhenlin Wu - P4.11 Zhu Yuyu - Th3C.3 Yuming Dong - P4.26 Zhang Luhe - W1D.4 Zhenming Yu - P3.12 Zhuang Wang - T2D.2 Yun Fu - P1.62 Zhang Qianwu - P4.30 Zhensen Gao - Th2A.2 Zhuo Cheng - Th2D.1 Yun Jiang Rao - W 1 F. 3 Zhang Shougang - W2A.4 Zhenyi Chen - P4.34 Zhuochi Ma - P2.63 Yun Li - Th3B.1 Zhang Weijian - P1.31 Zhenzhou Cheng - W1G.2 Zi Cai - Th2I.2 Yuncai Wang - Th2A.2 Zhang Xiang - W2A.4, P4.57 Zhi Chen - P4.49 Zibo Zheng - W2A.1, P2.66, P1.26 Yunchao Zhang - W4H.2 Zhang Yani - Th3C.3 Zhi Hong - P3.16 Zihao Cheng - W 2F. 4 Yuncheng Liao - P1.43, P1.67 Zhang Yuan - P3.48 Zhi Liu - Th2A.6 Zihao Li - P4.39 Yunfei Hu - P4.17, P4.15 Zhangwan Wang - P4.61 Zhi-Chao Luo - T2D.3 Zihui Yuan - P1.22 Yunfei Jiang - P1.46 Zhangyuan Chen - P1.42 Zhi Wang - Th3H.5 Zijie Zhu - P4.26 Yung Chuen Tan - P4.28 Zhanqi Xu - Th3B.5 Zhichao Qu - P2.16 Zilong Li - P4.35 Yunhe Zhao - Th3C.2 Zhanrong Zhou - P2.68 Zhichao Wu - Th2D.3 Zinan Huang - W2D.1, W2D.4 Yunjiang Rao - W 2F. 1 Zhao Yang - P2.3 Zhifang Wu - W2E.5, W4F.4 Zinan Wang - T2F.2, W2F.1, P1.62 Yunjie Xia - Th1C.2 Zhao Liu - P3.72 Zhigang Cao - P2.20 Ziqi Jiang - Th2B.4, Th2B.5 Yunqi Liu - W1F.6, W2E.3, P1.51, Zhigang Zang - Th3D.2 Ziqi Ren - P2.60

Zhaohui Li - W4A.4 P1.53, W3E.2, W2E.2, Th3C.2 Zhaowei Wang - P3.58 Zhiguo Dai - P4.44 Ziwen Zhao - P4.34 Yunqing Guan - P1.66, W3F.1 Zhaoxia Sheng - P2.8, Th2C.3 Zhiguo Zhang - P2.49, P2.50, P2.55, Zixian Wei - P2.48 Yunqing Lu - W4H.2, P1.9, P3.9 Zhaoyu Wang - P4.27 P1.24, P1.33, P3.70, P4.2 Zi-Xuan Ding - P3.14 Yuntong Jiang - P4.8 Zhaoyu Zong - P2.36 Zhihui Wang - P4.10, P3.62, P4.1 Ziyan Li - P2.18 Yunxu Sun - T h 1 F. 1 Zhaoyuan Chen - P2.68 Zhijiang Liu - P3.21 Ziyang Xiao - P3.70, P4.2 Yupeng Wang - P4.2 Zhaoyun Li - P1.34 Zhijin Chen - P1.9 Zongfu Jiang - P3.23, W1D.3 Yuqiang Deng - Th1D.4 Zhe Li - P1.6 Zhijun Yan - W1F.5, P1.45, P1.49, Zongyu Zhang - P1.18 Key to Authors Authors to Key Yuqiang Yang - T h 1 F. 3 Zhehao Yan - P2.50 Th1E.2 Zu Yunxiao - P4.38 Yuriko Maegami - W1G.4 Zhemin Chen - P3.2, P3.57, P3.8 Zhikun Xing - W 1F. 5 Zugang Liu - P3.30, P4.7, P4.22, Yusong Liu - P1.45 Zhen Guo - P4.44 Zhipeng Zhou - P3.46 P4.25, P1.70, P4.42

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