S
Shan You
Researcher at SenseTime
Publications - 49
Citations - 1532
Shan You is an academic researcher from SenseTime. The author has contributed to research in topics: Computer science & Discrete cosine transform. The author has an hindex of 14, co-authored 46 publications receiving 882 citations. Previous affiliations of Shan You include Peking University & Tsinghua University.
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Proceedings ArticleDOI
The Seventh Visual Object Tracking VOT2019 Challenge Results
Matej Kristan,Amanda Berg,Linyu Zheng,Litu Rout,Luc Van Gool,Luca Bertinetto,Martin Danelljan,Matteo Dunnhofer,Meng Ni,Min Young Kim,Ming Tang,Ming-Hsuan Yang,Abdelrahman Eldesokey,Naveen Paluru,Niki Martinel,Pengfei Xu,Pengfei Zhang,Pengkun Zheng,Pengyu Zhang,Philip H. S. Torr,Qi Zhang Qiang Wang,Qing Guo,Radu Timofte,Jani Käpylä,Rama Krishna Sai Subrahmanyam Gorthi,Richard M. Everson,Ruize Han,Ruohan Zhang,Shan You,Shaochuan Zhao,Shengwei Zhao,Shihu Li,Shikun Li,Shiming Ge,Gustavo Fernandez,Shuai Bai,Shuosen Guan,Tengfei Xing,Tianyang Xu,Tianyu Yang,Ting Zhang,Tomas Vojir,Wei Feng,Weiming Hu,Weizhao Wang,Abel Gonzalez-Garcia,Wenjie Tang,Wenjun Zeng,Wenyu Liu,Xi Chen,Xi Qiu,Xiang Bai,Xiaojun Wu,Xiaoyun Yang,Xier Chen,Xin Li,Alireza Memarmoghadam,Xing Sun,Xingyu Chen,Xinmei Tian,Xu Tang,Xue-Feng Zhu,Yan Huang,Yanan Chen,Yanchao Lian,Yang Gu,Yang Liu,Andong Lu,Chen Yanjie,Yi Zhang,Yinda Xu,Yingming Wang,Yingping Li,Yu Zhou,Yuan Dong,Yufei Xu,Yunhua Zhang,Yunkun Li,Anfeng He,Zeyu Wang Zhao Luo,Zhaoliang Zhang,Zhen-Hua Feng,Zhenyu He,Zhichao Song,Zhihao Chen,Zhipeng Zhang,Zhirong Wu,Zhiwei Xiong,Zhongjian Huang,Anton Varfolomieiev,Zhu Teng,Zihan Ni,Antoni Chan,Jiri Matas,Ardhendu Shekhar Tripathi,Arnold W. M. Smeulders,Bala Suraj Pedasingu,Bao Xin Chen,Baopeng Zhang,Baoyuan Wu,Bi Li,Bin He,Bin Yan,Bing Bai,Ales Leonardis,Bing Li,Bo Li,Byeong Hak Kim,Chao Ma,Chen Fang,Chen Qian,Cheng Chen,Chenglong Li,Chengquan Zhang,Chi-Yi Tsai,Michael Felsberg,Chong Luo,Christian Micheloni,Chunhui Zhang,Dacheng Tao,Deepak K. Gupta,Dejia Song,Dong Wang,Efstratios Gavves,Eunu Yi,Fahad Shahbaz Khan,Roman Pflugfelder,Fangyi Zhang,Fei Wang,Fei Zhao,George De Ath,Goutam Bhat,Guangqi Chen,Guangting Wang,Guoxuan Li,Hakan Cevikalp,Hao Du,Joni-Kristian Kamarainen,Haojie Zhao,Hasan Saribas,Ho Min Jung,Hongliang Bai,Hongyuan Yu,Houwen Peng,Huchuan Lu,Hui Li,Jiakun Li,Luka Čehovin Zajc,Jianhua Li,Jianlong Fu,Jie Chen,Jie Gao,Jie Zhao,Jin Tang,Jing Li,Jingjing Wu,Jingtuo Liu,Jinqiao Wang,Ondrej Drbohlav,Jinqing Qi,Jinyue Zhang,John K. Tsotsos,Jong Hyuk Lee,Joost van de Weijer,Josef Kittler,Jun Ha Lee,Junfei Zhuang,Kangkai Zhang,Kangkang Wang,Alan Lukezic,Kenan Dai,Lei Chen,Lei Liu,Leida Guo,Li Zhang,Liang Wang,Liangliang Wang,Lichao Zhang,Lijun Wang,Lijun Zhou +179 more
TL;DR: The Visual Object Tracking challenge VOT2019 is the seventh annual tracker benchmarking activity organized by the VOT initiative; results of 81 trackers are presented; many are state-of-the-art trackers published at major computer vision conferences or in journals in the recent years.
Proceedings ArticleDOI
Learning from Multiple Teacher Networks
TL;DR: This paper presents a method to train a thin deep network by incorporating multiple teacher networks not only in output layer by averaging the softened outputs from different networks, but also in the intermediate layers by imposing a constraint about the dissimilarity among examples.
Proceedings Article
CNNpack: packing convolutional neural networks in the frequency domain
TL;DR: In this article, the authors proposed to decompose convolutional filters as common parts (i.e., cluster centers) shared by other similar filters and their individual private parts (e.g., individual residuals).
Proceedings ArticleDOI
GreedyNAS: Towards Fast One-Shot NAS With Greedy Supernet
TL;DR: This paper proposes a multi-path sampling strategy with rejection, and greedily filter the weak paths to ease the burden of supernet by encouraging it to focus more on evaluation of those potentially-good ones, which are identified using a surrogate portion of validation data.
Posted ContentDOI
On the learnability of quantum neural networks
TL;DR: This paper derives the utility bounds of QNN towards empirical risk minimization, and shows that large gate noise, few quantum measurements, and deep circuit depth will lead to the poor utility bounds, and proves that QNN can be treated as a differentially private model.