发表论文
[1] 张佳锋, 杨震, 马晓珊, 彭晓东, 刘河山, 唐文林, 赵梦园, 高辰, 强丽娥, 韩晓晴, 刘彬彬. Inter-spacecraft offset frequency setting strategy in the Taiji program. Applied Optics[J]. 2022, 61(3): 837-843, [2] 雷雪林, 马晓珊, 彭晓东, 杨震, 狄荣育, 祁航. Dynamic scattering media imaging based on combined modulation. Spienull. 2022, 12166: 1586-1592, [3] 张佳锋, 杨震, 马晓珊, 彭晓东, 刘河山, 唐文林, 赵梦园, 高辰, 强丽娥, 韩晓晴, 刘彬彬. Inter-spacecraft offset frequency setting strategy in the Taiji program. Applied Optics[J]. 2022, 61(3): 837-843, [4] 雷雪林, 马晓珊, 彭晓东, 杨震, 狄荣育, 祁航. Dynamic scattering media imaging based on combined modulation. Spienull. 2022, 12166: 1586-1592, [5] 张佳锋, 杨震, 马晓珊, 彭晓东, 刘河山, 唐文林, 赵梦园, 高辰, 强丽娥, 韩晓晴, 刘彬彬. Inter-spacecraft offset frequency setting strategy in the Taiji program. Applied Optics[J]. 2022, 61(3): 837-843, [6] 雷雪林, 马晓珊, 彭晓东, 杨震, 狄荣育, 祁航. Dynamic scattering media imaging based on combined modulation. Spienull. 2022, 12166: 1586-1592, [7] 牛文龙, 樊铭瑞, 李运, 彭晓东, 谢文明. 人机共融的远程态势智能感知系统. 国防科技大学学报[J]. 2021, [8] 王嘉璇, 李大林, 彭晓东, 孙天然. 基于对抗神经网络有限角度的磁层边界CT重构技术. 空间科学学报[J]. 2021, 41(4): 546-554, http://lib.cqvip.com/Qikan/Article/Detail?id=7105375942.[9] Peng, Xiaodong, Jin, Hongbo, Xu, Peng, Wang, Zhi, Luo, Ziren, Ma, Xiaoshan, Qiang, LiE, Tang, Wenlin, Ma, Xin, Zhang, Yuzhu, Wang, Zuolei, Wu, Pengzhan, Deng, Xiaoqin, Li, Haosi, Wu, Liming, Wang, Juan, Wei, Yuxiao, Lin, Zhiyong, Gao, Chen, Zhao, Mengyuan. System modeling in data processing of Taiji-1 mission. INTERNATIONAL JOURNAL OF MODERN PHYSICS A[J]. 2021, 36(11N12): http://dx.doi.org/10.1142/S0217751X21400261.[10] Wu, YueLiang, Luo, ZiRen, Wang, JianYu, Bai, Meng, Bian, Wei, Cai, HaiWen, Cai, RongGen, Cai, ZhiMing, Cao, Jin, Chen, Bin, Chen, DiJun, Chen, GuangFeng, Chen, Kun, Chen, Ling, Chen, LiSheng, Chen, MingWei, Chen, WeiBiao, Chen, Yan, Chen, ZeYi, Chi, YiXing, Cong, LinXiao, Deng, JianFeng, Deng, XiaoQin, Dong, XiaoLong, Duan, Li, Fan, Da, Fan, SenQuan, Fan, ShouShan, Fang, Chao, Fang, Yuan, Feng, Ke, Feng, JianChao, Feng, Pan, Feng, Zhun, Gao, Chen, Gao, RuiHong, Gao, RunLian, Guo, Bin, Guo, Tong, Guo, XiaoLiang, Guo, Xu, Guo, ZongKuan, He, JianWu, He, JiBo, Hou, Xia, Hu, Liang, Hu, WenRui, Hu, ZhiQiang, Huang, MinJie, Jia, JianJun, Jiang, KaiLi, Jin, Gang, Jin, HongBo, Kang, BaoPeng, Kang, Qi, Kong, FengLian, Lei, JunGang, Li, BoQuan, Li, CunHui, Li, DongJing, Li, Fan, Li, HaoSi, Li, HuaDong, Li, HuaWang, Li, Jiang, Li, LiuFeng, Li, Wei, Li, XiaoKang, Li, YingMin, Li, YongGui, Li, YunPeng, Li, YuPeng, Li, Zhao, Li, Zhe, Liang, Hong, Lin, Huang, Lin, ZhiYong, Liu, Chang, Liu, DongBin, Liu, HeShan, Liu, Hong, Liu, Peng, Liu, YuRong, Lu, ZongYu, Luo, HongWei, Luo, Jun, Ma, FuLi, Ma, LongFei, Ma, XiaoShan, Ma, Xin, Man, YiChuan, Mao, JunCheng, Min, Jian, Niu, Yu, Peng, JianKang, Peng, XiaoDong, Qi, KeQi, Qiang, LiE, Qiao, CongFeng, Qu, YeXi, Ruan, WenHong, Sha, Wei, Shen, Jia, Shi, XingJian, Shu, Rong, Su, Ju, Su, Peng, Sui, YanLin, Sun, GuangWei, Tan, HePing, Tang, WenLin, Tao, HongJiang, Tao, WenZe, Tian, Zheng, Wan, LingFeng, Wang, ChenYu, Wang, Jia, Wang, Juan, Wang, JunBiao, Wang, LinLin, Wang, PengCheng, Wang, ShaoXin, Wang, XiaoPeng, Wang, YanFeng, Wang, YuKun, Wang, Zhi, Wang, ZuoLei, Wei, YongQiang, Wei, YuXiao, Wu, Di, Wu, LiMing, Wu, PengZhan, Wu, ZhiHua, Xi, DongXue, Xie, YiFang, Xin, GuoFeng, Xu, HengTong, Xu, LuXiang, Xu, Peng, Xu, ShuYan, Xu, Yu, Xue, Bing, Xue, DaTong, Xue, SenWen, Xue, ZhangBin, Yang, Chao, Yang, Ran, Yang, ShiJia, Yang, Shuang, Yang, Yong, Yang, ZhongGuo, Yin, YongLi, Yu, DuLi, Yu, JinPei, Yu, Tao, Zhang, AiBing, Zhang, Bing, Zhang, Chu, Zhang, Min, Zhang, Jing, Zhang, RuiJun, Zhang, XiaoFeng, Zhang, XiaoQing, Zhang, XueQuan, Zhang, YongHe, Zhang, YuZhu, Zhang, YuanZhong, Zhao, MengYuan, Zhao, Jian, Zhao, WeiWei, Zhao, Ya, Zheng, JianHua, Zhou, CuiYun, Zhou, Ying, Zhu, Ren, Zhu, XiaoCheng, Zhu, XiaoYi, Zhu, ZhenCai, Zou, XiaoBo, Zou, ZiMing, Taiji Sci Collaboration. Taiji program in space for gravitational universe with the first run key technologies test in Taiji-1. INTERNATIONAL JOURNAL OF MODERN PHYSICS A[J]. 2021, 36(11N12): http://dx.doi.org/10.1142/S0217751X21020024.[11] 雷雪林, 马晓珊, 杨震, 彭晓东, 李运, 赵梦园, 樊铭瑞. Improving Compressed Sensing Image Reconstruction Based on Atmospheric Modulation Using the Distributed Cumulative Synthesis Method. IEEE PHOTONICS JOURNAL[J]. 2021, 13(5): http://dx.doi.org/10.1109/JPHOT.2021.3108194.[12] 王鹤群, 彭晓东, 周武根. 基于深度相机的边缘融合直接位姿估计方法. 传感器与微系统[J]. 2021, 40(10): 118-120, http://lib.cqvip.com/Qikan/Article/Detail?id=7105727755.[13] The Taiji Scientific Collaboration. China's first step towards probing the expanding universe and the nature of gravity using a space borne gravitational wave antenna. COMMUNICATIONS PHYSICS[J]. 2021, 4(1): https://doaj.org/article/a51ad5ea0a16417dbc672b81bc75fd08.[14] 牛文龙, 樊铭瑞, 李运, 彭晓东, 谢文明. 人机共融的远程态势智能感知系统. 国防科技大学学报[J]. 2021, [15] 王嘉璇, 李大林, 彭晓东, 孙天然. 基于对抗神经网络有限角度的磁层边界CT重构技术. 空间科学学报[J]. 2021, 41(4): 546-554, http://lib.cqvip.com/Qikan/Article/Detail?id=7105375942.[16] Peng, Xiaodong, Jin, Hongbo, Xu, Peng, Wang, Zhi, Luo, Ziren, Ma, Xiaoshan, Qiang, LiE, Tang, Wenlin, Ma, Xin, Zhang, Yuzhu, Wang, Zuolei, Wu, Pengzhan, Deng, Xiaoqin, Li, Haosi, Wu, Liming, Wang, Juan, Wei, Yuxiao, Lin, Zhiyong, Gao, Chen, Zhao, Mengyuan. System modeling in data processing of Taiji-1 mission. INTERNATIONAL JOURNAL OF MODERN PHYSICS A[J]. 2021, 36(11N12): http://dx.doi.org/10.1142/S0217751X21400261.[17] Wu, YueLiang, Luo, ZiRen, Wang, JianYu, Bai, Meng, Bian, Wei, Cai, HaiWen, Cai, RongGen, Cai, ZhiMing, Cao, Jin, Chen, Bin, Chen, DiJun, Chen, GuangFeng, Chen, Kun, Chen, Ling, Chen, LiSheng, Chen, MingWei, Chen, WeiBiao, Chen, Yan, Chen, ZeYi, Chi, YiXing, Cong, LinXiao, Deng, JianFeng, Deng, XiaoQin, Dong, XiaoLong, Duan, Li, Fan, Da, Fan, SenQuan, Fan, ShouShan, Fang, Chao, Fang, Yuan, Feng, Ke, Feng, JianChao, Feng, Pan, Feng, Zhun, Gao, Chen, Gao, RuiHong, Gao, RunLian, Guo, Bin, Guo, Tong, Guo, XiaoLiang, Guo, Xu, Guo, ZongKuan, He, JianWu, He, JiBo, Hou, Xia, Hu, Liang, Hu, WenRui, Hu, ZhiQiang, Huang, MinJie, Jia, JianJun, Jiang, KaiLi, Jin, Gang, Jin, HongBo, Kang, BaoPeng, Kang, Qi, Kong, FengLian, Lei, JunGang, Li, BoQuan, Li, CunHui, Li, DongJing, Li, Fan, Li, HaoSi, Li, HuaDong, Li, HuaWang, Li, Jiang, Li, LiuFeng, Li, Wei, Li, XiaoKang, Li, YingMin, Li, YongGui, Li, YunPeng, Li, YuPeng, Li, Zhao, Li, Zhe, Liang, Hong, Lin, Huang, Lin, ZhiYong, Liu, Chang, Liu, DongBin, Liu, HeShan, Liu, Hong, Liu, Peng, Liu, YuRong, Lu, ZongYu, Luo, HongWei, Luo, Jun, Ma, FuLi, Ma, LongFei, Ma, XiaoShan, Ma, Xin, Man, YiChuan, Mao, JunCheng, Min, Jian, Niu, Yu, Peng, JianKang, Peng, XiaoDong, Qi, KeQi, Qiang, LiE, Qiao, CongFeng, Qu, YeXi, Ruan, WenHong, Sha, Wei, Shen, Jia, Shi, XingJian, Shu, Rong, Su, Ju, Su, Peng, Sui, YanLin, Sun, GuangWei, Tan, HePing, Tang, WenLin, Tao, HongJiang, Tao, WenZe, Tian, Zheng, Wan, LingFeng, Wang, ChenYu, Wang, Jia, Wang, Juan, Wang, JunBiao, Wang, LinLin, Wang, PengCheng, Wang, ShaoXin, Wang, XiaoPeng, Wang, YanFeng, Wang, YuKun, Wang, Zhi, Wang, ZuoLei, Wei, YongQiang, Wei, YuXiao, Wu, Di, Wu, LiMing, Wu, PengZhan, Wu, ZhiHua, Xi, DongXue, Xie, YiFang, Xin, GuoFeng, Xu, HengTong, Xu, LuXiang, Xu, Peng, Xu, ShuYan, Xu, Yu, Xue, Bing, Xue, DaTong, Xue, SenWen, Xue, ZhangBin, Yang, Chao, Yang, Ran, Yang, ShiJia, Yang, Shuang, Yang, Yong, Yang, ZhongGuo, Yin, YongLi, Yu, DuLi, Yu, JinPei, Yu, Tao, Zhang, AiBing, Zhang, Bing, Zhang, Chu, Zhang, Min, Zhang, Jing, Zhang, RuiJun, Zhang, XiaoFeng, Zhang, XiaoQing, Zhang, XueQuan, Zhang, YongHe, Zhang, YuZhu, Zhang, YuanZhong, Zhao, MengYuan, Zhao, Jian, Zhao, WeiWei, Zhao, Ya, Zheng, JianHua, Zhou, CuiYun, Zhou, Ying, Zhu, Ren, Zhu, XiaoCheng, Zhu, XiaoYi, Zhu, ZhenCai, Zou, XiaoBo, Zou, ZiMing, Taiji Sci Collaboration. Taiji program in space for gravitational universe with the first run key technologies test in Taiji-1. INTERNATIONAL JOURNAL OF MODERN PHYSICS A[J]. 2021, 36(11N12): http://dx.doi.org/10.1142/S0217751X21020024.[18] 雷雪林, 马晓珊, 杨震, 彭晓东, 李运, 赵梦园, 樊铭瑞. Improving Compressed Sensing Image Reconstruction Based on Atmospheric Modulation Using the Distributed Cumulative Synthesis Method. IEEE PHOTONICS JOURNAL[J]. 2021, 13(5): http://dx.doi.org/10.1109/JPHOT.2021.3108194.[19] 王鹤群, 彭晓东, 周武根. 基于深度相机的边缘融合直接位姿估计方法. 传感器与微系统[J]. 2021, 40(10): 118-120, http://lib.cqvip.com/Qikan/Article/Detail?id=7105727755.[20] The Taiji Scientific Collaboration. China's first step towards probing the expanding universe and the nature of gravity using a space borne gravitational wave antenna. COMMUNICATIONS PHYSICS[J]. 2021, 4(1): https://doaj.org/article/a51ad5ea0a16417dbc672b81bc75fd08.[21] 牛文龙, 樊铭瑞, 李运, 彭晓东, 谢文明. 人机共融的远程态势智能感知系统. 国防科技大学学报[J]. 2021, [22] 王嘉璇, 李大林, 彭晓东, 孙天然. 基于对抗神经网络有限角度的磁层边界CT重构技术. 空间科学学报[J]. 2021, 41(4): 546-554, http://lib.cqvip.com/Qikan/Article/Detail?id=7105375942.[23] Peng, Xiaodong, Jin, Hongbo, Xu, Peng, Wang, Zhi, Luo, Ziren, Ma, Xiaoshan, Qiang, LiE, Tang, Wenlin, Ma, Xin, Zhang, Yuzhu, Wang, Zuolei, Wu, Pengzhan, Deng, Xiaoqin, Li, Haosi, Wu, Liming, Wang, Juan, Wei, Yuxiao, Lin, Zhiyong, Gao, Chen, Zhao, Mengyuan. System modeling in data processing of Taiji-1 mission. 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Taiji program in space for gravitational universe with the first run key technologies test in Taiji-1. INTERNATIONAL JOURNAL OF MODERN PHYSICS A[J]. 2021, 36(11N12): http://dx.doi.org/10.1142/S0217751X21020024.[25] 雷雪林, 马晓珊, 杨震, 彭晓东, 李运, 赵梦园, 樊铭瑞. Improving Compressed Sensing Image Reconstruction Based on Atmospheric Modulation Using the Distributed Cumulative Synthesis Method. IEEE PHOTONICS JOURNAL[J]. 2021, 13(5): http://dx.doi.org/10.1109/JPHOT.2021.3108194.[26] 王鹤群, 彭晓东, 周武根. 基于深度相机的边缘融合直接位姿估计方法. 传感器与微系统[J]. 2021, 40(10): 118-120, http://lib.cqvip.com/Qikan/Article/Detail?id=7105727755.[27] The Taiji Scientific Collaboration. China's first step towards probing the expanding universe and the nature of gravity using a space borne gravitational wave antenna. 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Compressive Sensing Imaging Based on Modulation of Atmospheric Scattering Medium. APPLIED SCIENCES-BASEL[J]. 2020, 10(13): https://www.webofscience.com/wos/woscc/full-record/WOS:000550412300001.[33] Xie, Jingyi, Peng, Xiaodong, Wang, Haijiao, Niu, Wenlong, Zheng, Xiao. UAV Autonomous Tracking and Landing Based on Deep Reinforcement Learning Strategy. SENSORS[J]. 2020, 20(19): https://doaj.org/article/0a850fb5812e4bb69f648c8d5d0bc574.[34] 李媛, 彭晓东, 周武根, 李运, 谢文明. 小行星场景下基于循环卷积网络的位姿估计方法. 传感器与微系统[J]. 2020, 39(8): 55-57+61, http://lib.cqvip.com/Qikan/Article/Detail?id=7102584184.[35] Lei, Xuelin, Ma, Xiaoshan, Yang, Zhen, Peng, Xiaodong, Li, Yun, Ni, Wei. Compressive Sensing Imaging Based on Modulation of Atmospheric Scattering Medium. APPLIED SCIENCES-BASEL[J]. 2020, 10(13): https://www.webofscience.com/wos/woscc/full-record/WOS:000550412300001.[36] Xie, Jingyi, Peng, Xiaodong, Wang, Haijiao, Niu, Wenlong, Zheng, Xiao. 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