报告人简介：
董毅教授1996年9月获北京理工大学物理电子与光电子学专业博士学位，1996年-2004年任清华大学博士后、讲师、副教授，2002年-2006年任新加坡信息通讯研究院（I2R）高级访问学者、Research Scientist。2006年至今任上海交通大学教授、博导，现担任“区域光纤通信网与新型光通信系统”国家重点实验室副主任。
主要从事“光信息传输与控制”研究。主持和参加多项国家自然科学基金重大和重点、国家863、国家973、国防预研等项目。在国内外学术期刊发表论文一百余篇。是国家杰出青年基金获得者，入选教育部新世纪优秀人才计划、国家863十五周年先进个人计划、江苏高层次创新创业人才计划、南京市“321”人才计划。
目前的研究兴趣是微波光子学和相干光子学，致力于解决微波光子器件及系统的相位噪声问题以及半导体激光器的相干性增强与控制问题。

Biography:
Yi Dong received the PH.D degree in photo-electronic engineering from Beijing Institute of Technology, China, in 1996. He joined Tsinghua University as a post-doctor from 1996 to 1998, and as a lecturer from 1999 to 2000, and as an Associate Professor from 2000 to 2002. From 2002 to 2006, he worked as a research scientist with the lightwave department of I2R, Singapore. In 2006, he joined Shanghai Jiao Tong University as an Associate Professor, and became a Professor in 2008. He is the vice-director of the State Key Laboratory of Advanced Optical Communication Systems and Networks. His research interests are microwave photonics, Analog Optical Signal Processing (AOSP) and optoelectronic measurement. He has published ~100 peering journals and international conferences papers.

报告摘要：
卫星遥感、深空探测、电子对抗以及基础科学研究等领域的发展，促进着微波系统向着高频、宽带、大动态范围、广域覆盖等方向发展。传统的微波系统在微波信号的生成、分配、控制、处理等方面面临巨大挑战。微波光子学是研究微波和光波相互作用规律及应用的一门新兴学科，它利用光子学方法产生、分配、控制与处理宽带毫米波信号，被普遍认为是应对上述重大挑战的有效途径。
本报告重点阐述微波光子技术的基本概念、发展历程及其应用前景；分析微波光子技术面临的动态范围、转换效率、相位噪声等方面的挑战以及最新的研究成果；介绍微波光子技术在干涉天线组阵、雷达模拟前端信号处理以及光钟方面的应用成果。

Abstract:
Microwave system capable of high frequency, broadband, large dynamic range and wide coverange is high demanded by the remote sensing, deep-space exploration and electronic countermeasures etc. These pose chanllanges on the generation, distribution, control and processing of the microwave signals in conventional microwave systems. Taking the advantages of the huge avaliable bandwidthe and ultra-high frequency, microwave photonic is one promising candidate as it provides unprecedental benefits in generation, distribution, control and process of the photonic generated microwave signals .
This report presents the basic concept, history and potential of microwave photonics, including the latest progresses in dynamic range, convertion efficiency and the phase noise as well as the progresses in fields of applications such as coherent atenna array, analog signal processing and optical clock.