姓名: | 许雄 | |
性别: | 男 | |
职称: |
副研究员、博士生导师 | |
籍贯: |
四川南充 | |
邮箱: |
xvxiong@tongji.edu.cn | |
简介: |
主要从事多源遥感数据处理、视觉导航定位等领域的研究。主持国家自然科学基金项目3项、国家重点研发计划项目子课题2项、中国博士后科学基金2项,参与及完成国家863计划重大项目、国家973计划、国家自然科学基金重点项目、装发预研等多项项目。获国家教学成果二等奖1项、中国测绘科技进步一等奖3项,发表论文60余篇,其中SCI检索40余篇,申请专利20余项。担任遥感学报编委,Remote Sensing期刊客座主编,中国测绘学会位置服务工作委员会、中国生态学学会第三届生态遥感专业委员会专家委员,是中国首次火星探测任务科学研究团队成员,任多个国内外核心期刊及国际会议审稿人。
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教育与工作经历 副研究员,44118太阳成城集团,44118太阳成城集团,2018.03 至今 助理研究员,44118太阳成城集团,44118太阳成城集团,2013.10-2018.03 博士后,高光谱计算实验室,埃斯特雷马杜拉大学,2014.09-2017.09(合作导师:童小华教授,Antonio Plaza) 工学博士,测绘遥感信息工程国家重点实验室,武汉大学,2008.09-2013.06(博士导师:张良培教授,钟燕飞教授) 工学学士,遥感信息工程学院,武汉大学,2004.09-2008.06 研究方向 多源遥感数据智能处理、融合与应用,三维重建与视觉导航定位研究 科研工程项目 [1]基于空地影像匹配的火星巡视器自主全局定位方法研究,国家自然科学基金专项项目,在研,项目负责人 [2]较大空谱分辨率差异下的多源遥感影像亚像元变化检测研究,国家自然科学基金面上项目,在研,项目负责人 [3]地形特征识别跟踪及增强系统,航天合作项目,在研,项目负责人 [4]新型城镇化建设与管理空间信息综合服务及应用示范,国家重点研发计划,结题,子课题负责人 [5]高光谱遥感影像混合像元分解定位联合模型研究,国家自然科学基金青年项目,结题,项目负责人 [6]基于像元混合模型的高光谱影像超分辨率重建方法研究,中国博士后科学基金(特别资助),结题,项目负责人 [7]多时相遥感影像亚像元定位研究,中国博士后科学基金(一等资助),结题,项目负责人 [8]分布式微纳遥感网高精度载荷数据融合与反演技术,国家重点研发计划,结题,子课题负责人 [9]基于遥感技术的城市热岛效应分析,企业合作项目,结题,项目负责人 奖励与荣誉 [1]国家教学成果二等奖,2023年 [2]中国测绘学会测绘科学技术一等奖,2023年 [3]中国测绘学会测绘科学技术一等奖,2021年 [4]中国测绘学会测绘科技进步一等奖,2019年 [5]第八届高校GIS论坛优秀教学成果奖,2020年 [6]高校GIS新锐,2020年 [7]《遥感学报》优秀审稿专家,2018年 [8]“挑战杯”全国老员工课外学术科技作品竞赛“揭榜挂帅”专项赛全国特等奖 指导教师,2023年 [9]全国老员工测绘学科科技论文竞赛特等奖 指导教师,2022年 [10]44118太阳成城集团本科生学科竞赛优秀指导教师,2022年 代表性论文 [1]Xu, Xiong, Tao Cheng, Beibei Zhao, Chao Wang, Xiaohua Tong, Yongjiu Feng, Huan Xie, and Yanmin Jin. "A Novel Object Detection Method for Solid Waste Incorporating a Weighted Deformable Convolution." Photogrammetric Engineering & Remote Sensing 89, no. 11 (2023): 679-689. [2]Xu X, Pei H, Wang C, et al. Long-term analysis of the urban heat island effect using multisource Landsat images considering inter-class differences in land surface temperature products[J]. Science of The Total Environment, 2023, 858: 159777. [3]Wang C, Li Z, Xu X, et al. Performance of the Large Field of View Airborne Infrared Scanner and its application potential in land surface temperature retrieval[J]. Frontiers of Earth Science, 2023: 1-13. [4]Wang, Chao, Siji Sanlang, Xiaohua Tong, Xiong Xu, Yongjiu Feng, and Zhiyuan Li. "Exploring the effects of the rocket exhaust of the Chang'E-5 lander on the lunar regolith using LROC NAC and landing camera images." Icarus (2023): 115649. [5]曹子龙, 童小华, 许雄, 叶真, 肖长江. 基于空地影像多层级匹配的火星巡视器定位与地面验证[J]. 测绘学报, 2023, 52(4): 579-587. [6]Liao S, Xu X, Xie H, et al. A Modified Shape Model Incorporating Continuous Accumulated Growing Degree Days for Phenology Detection of Early Rice[J]. Remote Sensing, 2022, 14(21): 5337. [7]Xu X, Zhao B, Tong X, et al. A Data Augmentation Strategy Combining a Modified pix2pix Model and the Copy-Paste Operator for Solid Waste Detection With Remote Sensing Images[J]. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2022, 15: 8484-8491. [8]Guo Y, Tong X, Xu X, et al. An Anchor-Free Network With Density Map and Attention Mechanism for Multiscale Object Detection in Aerial Images[J]. IEEE Geoscience and Remote Sensing Letters, 2022, 19: 1-5. [9]Wang C, Li Z, Xu X, et al. A Coarse-To-Fine Approach to Detect Shadows in the Chang’E-4 VNIS Hyperspectral Images[J]. Earth and Space Science, 2022, 9(7): e2022EA002387. [10]Pan H, Tong X, Xu X, et al. Updating of land cover maps and change analysis using globeland30 product: A case study in shanghai metropolitan area, china[J]. Remote Sensing, 2020, 12(19): 3147. [11]Zhang H, Kang J, Xu X, et al. Accessing the temporal and spectral features in crop type mapping using multi-temporal Sentinel-2 imagery: A case study of Yi’an County, Heilongjiang province, China[J]. Computers and Electronics in Agriculture, 2020, 176: 105618. [12]Xu X, Tong X, Plaza A, et al. A new spectral-spatial sub-pixel mapping model for remotely sensed hyperspectral imagery[J]. IEEE Transactions on Geoscience and Remote Sensing, 2018, 56(11): 6763-6778. [13]Zhai H, Zhang H, Xu X, et al. Kernel sparse subspace clustering with a spatial max pooling operation for hyperspectral remote sensing data interpretation[J]. Remote Sensing, 2017, 9(4): 335. [14]Xu X, Tong X, Plaza A, et al. Joint sparse sub-pixel mapping model with endmember variability for remotely sensed imagery[J]. Remote Sensing, 2016, 9(1): 15. [15]Xu X, Tong X, Plaza A, et al. Using linear spectral unmixing for subpixel mapping of hyperspectral imagery: A quantitative assessment[J]. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2016, 10(4): 1589-1600. [16]Xie H, Luo X, Xu X, et al. Automated subpixel surface water mapping from heterogeneous urban environments using Landsat 8 OLI imagery[J]. Remote sensing, 2016, 8(7): 584. [17]Xie H, Luo X, Xu X, et al. Evaluation of Landsat 8 OLI imagery for unsupervised inland water extraction[J]. International Journal of Remote Sensing, 2016, 37(8): 1826-1844. [18]Tong X, Xu X, Plaza A, et al. A new genetic method for subpixel mapping using hyperspectral images[J]. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2016, 9(9): 4480-4491. [19]Feng R, Zhong Y, Xu X, et al. Adaptive sparse subpixel mapping with a total variation model for remote sensing imagery[J]. IEEE Transactions on Geoscience and Remote Sensing, 2016, 54(5): 2855-2872. [20]Zhong Y, Wu Y, Xu X, et al. An adaptive subpixel mapping method based on MAP model and class determination strategy for hyperspectral remote sensing imagery[J]. IEEE Transactions on Geoscience and Remote Sensing, 2014, 53(3): 1411-1426. [21]Xu X, Zhong Y, Zhang L. A sub-pixel mapping method based on an attraction model for multiple shifted remotely sensed images[J]. Neurocomputing, 2014, 134: 79-91. [22]Tong X, Li X, Xu X, et al. A two-phase classification of urban vegetation using airborne LiDAR data and aerial photography[J]. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2014, 7(10): 4153-4166. [23]Xu X, Tong X, Zhang L, et al. Unsupervised classification strategy utilizing an endmember extraction technique for airborne hyperspectral remotely sensed imagery[J]. Journal of Applied Remote Sensing, 2014, 8(1): 085090-085090. [24]Xie H, Luo X, Xu X, et al. New hyperspectral difference water index for the extraction of urban water bodies by the use of airborne hyperspectral images[J]. Journal of Applied Remote Sensing, 2014, 8(1): 085098-085098. [25]Xu X, Zhong Y, Zhang L. Adaptive subpixel mapping based on a multiagent system for remote-sensing imagery[J]. IEEE Transactions on Geoscience and Remote sensing, 2013, 52(2): 787-804. 部分发明专利 [1]一种面向火星巡视器行走能力测试的火星地面模拟场,授权号:CN112213132B [2]一种基于空地影像匹配的火星巡视器空间定位方法及系统,申请号:CN202310916060.7 [3]一种基于加权可变形卷积目标检测方法和装置,申请号:CN202211319155.2 [4]一种用于多源Landsat影像的长时序城市热岛效应分级方法,申请号:CN202210289094.3 [5]一种遥感影像目标样本增强方法,申请号:CN202210288788.5 [6]一种基于长短期记忆神经网络的滑坡位移预测方法,申请号:CN202210289093.9 [7]一种基于区域一致性分析的Landsat影像地表温度反演优选方法,申请号:CN202110131800.7 [8]一种用于疫情的返校大数据联动管理方法,申请号:CN202010841017.5 |