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邢妍
2023-04-10 19:25  

邢妍 北京航空航天大学仪器科学与光电工程学院 副教授

研究方向:3D显示技术

联系邮箱:yanxing@buaa.edu.cn



工作经历

2023.02—至今 北京航空航天大学 仪器科学与光电工程学院 副教授

2019.7-2023.02  北京航空航天大学 仪器科学与光电工程学院 博士后

教育经历

2014.09-2019.06  四川大学   电子信息学院      光学工程     博士研究生

2010.09-2014.06  四川大学   电子信息学院   光信息科学与技术    本科

获奖及荣誉

2024 第一届光显示大会“学术新星”

2022年 参加项目“集成光场3D显示关键技术及应用”荣获教育部技术发明一等奖(3/6

2017年 “SID 2017 Student Travel Grant Award”(SID :国际信息显示学会)


科研项目

[1]国家自然科学基金面上项目“实时光场3D获取与显示技术”(62575011),2026~2029年(项目负责人)

[2]国家自然科学基金面上项目“宽视角大景深集成成像3D显示技术”(62375009),2024~2027年(项目负责人)

[3]国家自然科学基金青年科学基金项目(C类)“基于环形摄像机阵列的集成成像桌面3D拍摄技术”(62105014),2022~2024年(项目负责人)

[4]国家重点研发计划项目“3D显示关键共性技术与架构”(2021YFB2802300),2022~2025(项目主研)

[5]国家自然科学基金联合重点基金项目“面向目标监视的复眼阵列相机智能探测感知技术研究”(U21B2034),2022~2025(项目主研)

科研成果

在3D显示技术方面取得了以下代表成果:

[1]在理论方面,建立了针对桌面显示的集成成像光场采样与重构新模型,为宽视角桌面集成成像3D拍摄和显示技术提供了理论支撑;提出了集成成像环形微图像阵列编码方法,相比传统方法简化了系统硬件复杂度。相关研究成果发表在光学工程领域重要期刊 Opto-Electronic Advances 上,入选为期刊封底文章,并受到科学新闻网 EurekAlert、 Sciencex等多方国内外媒体网站的关注和宣传报道。

[2]在系统方面,研制了15.6英寸-32英寸的多种高性能裸眼光场3D显示器,实现了横、竖、斜、远、近观看皆逼真舒适的效果,图像清晰度高、立体感强。研制的高性能裸眼光场3D显示器参与了国际显示技术大会I-Zone创新区等重要展览,获I-Zone“创新先锋奖”等荣誉,并获得了与会专家的肯定与好评。

论文与专利

发表SCI收录论文30余篇,其中第一作者/通讯作者发表SCI收录论文19篇,授权中国发明专利25件,申请国际发明专利3件。

代表论文

[1]Xiao-Shuai Hu, Xing-Yu Lin, Yi-Jian Liu, Min-Hao Xiang, Yu-Qiang Guo, Yan Xing*, and Qiong-Hua Wang*, Culling-based real-time rendering with accurate ray sampling for high-resolution light field 3D display, IEEE Transactions on Visualization and Computer Graphics, 2025, 31(9), 6385-6397.

[2]Yan Xing, Xing-Yu Lin, Lin-Bo Zhang, Yun-Peng Xia, Han-Le Zhang, Hong-Yu Cui, Shuang Li, Tong-Yu Wang, Hui Ren, Di Wang, Huan Deng, and Qiong-Hua Wang*, Integral imaging-based tabletop light field 3D display with large viewing angle, Opto-Electronic Advances, 2023, 6, 220178.

[3]Yuan-Yi Huang†, Yan Xing†, Xue-Rui Wen, Min-Yang He, Fan Chu*, and Qiong-Hua Wang*, Dual-plane augmented reality integral imaging 3D display system based on reflective polarizer and holographic optical element, Optics & Laser Technology, 2025, 190, 113173.

[4]Lin-Bo Zhang, Wei-Ze Li, Yi-Jian Liu, Yi-Hang Li, Xing-Yu Lin, Qiong-Hua Wang, and Yan Xing*, Wide-viewing-angle and crosstalk-free integral imaging 3D display using time-division multiplexing and polarizer arrays, Optics Express, 2025, 33, 42557-42571.

[5]Wei-Ze Li, Lin-Bo Zhang, Yi-Jian Liu, Xue-Rui Wen, Fan Chu, Yan Xing*, and Qiong-Hua Wang*, Square-LFRF: High-speed light field 3D source generation using anti-aliasing virtual views synthesis based on neural radiance fields, Optics Express, 2025, 33(13), 28884-28897.

[6]Han-Le Zhang*, Yi-Jian Liu, Xue-Rui Wen, Wei-Ze Li, and Yan Xing*, Floating depth and viewing angle enhanced integral imaging display system based on a transmissive mirror device, Optics Express, 2024, 32(13), 22052-22066.

[7]Han-Le Zhang, Xiao-Li Ma, Xing-Yu Lin, Yan Xing*, and Qiong-Hua Wang*, System to eliminate the graininess of an integral imaging 3D display by using a transmissive mirror device, Optics Letters, 2022, 47(18), 4628-4631.

[8]Yan Xing, Yun-Peng Xia, Shuang Li, Hui Ren, and Qiong-Hua Wang*, Annular sector elemental image array generation method for tabletop integral imaging 3D display with smooth motion parallax, Optics Express, 2020, 28(23), 34706-34716.

其他论文

[9]Min-Yang He, Cheng-Bo Zhao, Xue-Rui Wen, Yi-Jian Liu, Qiong-Hua Wang, and Yan Xing*, Tabletop 3D display with large radial viewing angle based on panoramic annular lens array, Photonics, 2025, 12(5), 515.

[10]Cheng-Bo Zhao, Yi-Jian Liu, Yuan-Yi Huang, Xiao-Tian Zhang, Yan Xing*, and Qiong-Hua Wang*, Photonics Breakthroughs 2024: Large-viewing-angle light field 3D display based on high-precision beam directionality, IEEE Photonics Journal, 2025, 17(3), 1-7.

[11]Hongran Zeng, Guohang Wu, Chongyang Zhang, Shouxin Liu, Junfeng Guo, Seok-Tae Kim, Yan Xing, and Xiaowei Li*, Secure scattering 3D integral imaging through optical single-pixel sensing, Optics Letters, 2025, 50(21), 6449-6452.

[12]Hongran Zeng, Yan Xing, Seok-Tae Kim, and Xiaowei Li*, Dualmodal and multifunctional steganography of three-dimensional integral imaging for the Internet of Medical Things, Signal Processing, 2025, 110217.

[13]Hong-Ran Zeng, Chong-Yang Zhang, Xiao-Wei Li*, Shou-Xin Liu, Jun-Feng Guo, Yan Xing, Seok Kim, Da-Hai Li, and Yi-Guang Liu, Chosen plaintext attack on single pixel imaging encryption via neural differential cryptanalysis, Laser & Photonics Reviews, 2025, 19(3), 2401056.

[14]Yi-Jian Liu, Xue-Rui Wen, Xiao-Shuai Hu, Wei-Ze Li, Yan Xing, Chao Liu, Han-Le Zhang*, and Qiong-Hua Wang*, High-resolution integral imaging display using targeted optimized compound lens array for voxel aliasing elimination, Laser & Photonics Reviews, 2024, 18(7), 202400182.

[15]Xue-Rui Wen, Yi-Jian Liu, Wei-Ze Li, Yan Xing, Han-Le Zhang*, and Qiong-Hua Wang*, Large viewing angle integral imaging 3D display system based on a symmetrical compound lens array, Optics Express, 2024, 32, 5705-5717.

[16]Lin-Bo Zhang, Yi-Jian Liu, Wei-Ze Li, Fan Chu, Han-Le Zhang*, Yan Xing, and Qiong-Hua Wang*, A 2D/3D convertible integral imaging display with enhanced depth of field, Optics and Lasers in Engineering, 2024, 181, 108393.

[17]Chao Liu, Yi Zheng, Rong-Ying Yuan, Zhao Jiang, Jin-Bo Xu, You-Ran Zhao, Xin Wang, Xiao-Wei Li, Yan Xing, and Qiong-Hua Wang*, Tunable liquid lenses: emerging technologies and future perspectives, Laser & Photonics Reviews, 2023, 17(11), 2300274.

[18]Hongran Zeng, Yan Xing, Seok-Tae Kim, and Xiaowei Li*, Designing real-time 3D image security with CA-based random mode decomposition, Signal Processing, 2022, 197, 108554.

[19]Xiao-Li Ma, Rong-Ying Yuan, Lin-Bo Zhang, Min-Yang He, Han-Le Zhang, Yan Xing*, and Qiong-Hua Wang*, Augmented reality autostereoscopic 3D display based on sparse reflection array, Optics Communications, 2022, 510, 127913.

[20]Xiao-Li Ma, Han-Le Zhang*, Rong-Ying Yuan, Tong-Yu Wang, Min-Yang He, Yan Xing, and Qiong-Hua Wang*, Depth of field and resolution-enhanced integral imaging display system, Optics Express, 2022, 30(25), 44580-44593.

[21]Tian-Hao Wang, Huan Deng*, Yan Xing, Cui-Ni Yang, Fei-Yan Zhong, and Zhao-Da Guo, High-resolution integral imaging display with precise light control unit and error compensation, Optics Communications, 2022, 518, 128363.

[22]Sen-Lin Pang, Tian-Hao Wang, Fei-Yan Zhong, Lin-Bo Zhang, Huan Deng, and Yan Xing*, Tabletop integral imaging 3D display system based on annular point light source, Displays, 2021, 69, 102029.

[23]Yun-Peng Xia, Shuang Li, Hui Ren, Huan Deng, and Yan Xing*, High-efficient rendering to generate annular sector elemental image array for tabletop integral imaging three-dimensional display, Journal of the Society for Information Display, 2021, 29, 632-641.

[24]Xiao-Ming Ma, Yan Xing*, Jia-Chen Zheng, Xiao-Wei Li, and Qiong-Hua Wang*, A real-time interactive rendering method for 360° tabletop integral imaging 3D display, Journal of the Society for Information Display, 2021, 29, 679-688.

[25]Min-Yang He, Di Wang, Yan Xing*, Yi-Wei Zheng, Han-Le Zhang, Xiao-Li Ma, Rong-Ying Yuan, and Qiong-Hua Wang*, Compact and lightweight optical see-through holographic near-eye display based on holographic lens, Displays, 2021, 70, 102104.

[26]Shuang Li, Qiong-Hua Wang*, Yun-Peng Xia, Yan Xing, Hui Ren, and Huan Deng, Integral imaging 3D display system with improved depth of field using a colloidal scattering layer, Optics Communications, 2021, 484, 126680.

[27]Di Wang, Chao Liu, Chuan Shen, Yan Xing, and Qiong-Hua Wang*, Holographic capture and projection system of real object based on tunable zoom lens, PhotoniX, 2020, 1, 6.

[28]Han-Le Zhang, Huan Deng, Hui Ren, Xin Yang, Yan Xing, Da-Hai Li, and Qiong-Hua Wang*, Method to eliminate pseudoscopic issue in integral imaging 3D display by using transmissive mirror device and light filter, Optics Letters, 2020, 45(2), 351-354.

[29]Chao Liu, Di Wang, Qiong-Hua Wang*, and Yan Xing, Multifunctional optofluidic lens with beam steering, Optics Express, 2020, 28(5), 7734-7745.

[30]Huan Deng, Sai Li, Lei Wang, Yan Xing, and Qiong-Hua Wang, Dual-view integral imaging system with wide viewing angle and high spatial resolution, IEEE Photonics Journal, 2020, 12(3), 1-11.

[31]Yan Xing, Qiong-Hua Wang*, Ling Luo, Hui Ren, and Huan Deng, High-performance dual-view 3D display system based on integral imaging, IEEE Photonics Journal, 2019, 11(1), 1-12.

[32]Yan Xing, Qiong-Hua Wang*, Hui Ren, Ling Luo, Huan Deng, and Da-Hai Li, Optical arbitrary-depth refocusing for large-depth scene in integral imaging display based on reprojected parallax image, Optics Communications, 2019, 433, 209-214.

[33]Yan Xing, Qiong-Hua Wang*, Zhao-Long Xiong, and Huan Deng, Encrypting three-dimensional information system based on integral imaging and multiple chaotic maps, Optical Engineering, 2016, 55(2), 023107-023107.

[34]Yan Xing, Qiong-Hua Wang, Cheng-Gao Luo, Huan Deng, and Da-Hai Li, Depth-enhanced integral imaging system based on spatial filtering, Journal of Information Display, 2015, 16(2), 85-88.


授权发明专利

[1]邢妍,王琼华,李爽,任慧,夏云鹏,一种集成成像环扇形微图像阵列生成方法,专利号:ZL202010113447.5

[2]邢妍,王琼华,任慧,马孝铭,庞森林,夏云鹏,一种裸眼3D视觉伪装系统,专利号:ZL202010433170.4

[3]邢妍,王琼华,马晓莉,何岷阳,郑家琛,张林博,一种2D/3D兼容视觉伪装系统,专利号:ZL202010433165.3

[4]王琼华,邢妍,夏云鹏,李爽,任慧,一种集成成像桌面3D显示的360°视差图像校正方法,专利号:ZL201911322712.4

[5]王琼华,邢妍,罗令,赵敏,一种集成成像三维重聚焦再现图像黑边的消除方法,专利号:ZL201710829635.6

[6]王琼华,邢妍,罗令,任慧,邓欢,一种基于棋盘格标定板的会聚式集成成像拍摄方法,专利号:ZL 201810170032.4

[7]王琼华,邢妍,熊召龙,邓欢,一种基于傅里叶谱的被遮挡三维物体显示方法,专利号:ZL 201710025183.6

[8]王琼华,邢妍,熊召龙,邓欢,一种基于集成成像和多混沌系统的三维信息加密方法,专利号:ZL 201510712155.2

[9]王琼华,邢妍,熊召龙,邓欢,一种基于重映射的集成成像微图像阵列快速生成方法,专利号:ZL 201610388732.1

[10]王琼华,任慧,邢妍,李爽,夏云鹏,一种3D显示装置,专利号:ZL 202010215696.5

[11]王琼华,罗令,邢妍,任慧,邓欢,陈聪,一种集成成像桌面3D显示的自适应微图像阵列生成方法,专利号:ZL 201810876059.5

[12]王琼华,任慧,邢妍,一种大尺寸无缝拼接的集成成像桌面3D显示装置,专利号:ZL 202010391804.4

[13]王琼华,熊召龙,邢妍,邓欢,张汉乐,一种基于深度数据的集成成像微图阵列方向性映射法,专利号:ZL 201610000695.2

[14]王琼华,熊召龙,邢妍,邓欢,张汉乐,一种基于单应性变换的集成成像摄像机阵列标定方法,专利号:ZL 201510457190.4

[15]王琼华,熊召龙,邢妍,邓欢,张汉乐,一种集成成像三维显示中心深度平面的调节方法,专利号:ZL 201510347993.4

[16]王琼华,熊召龙,邢妍,邓欢,李大海,一种基于计算成像的光学不可视场景三维信息获取方法,专利号:ZL 201710049708.X

[17]王琼华,熊召龙,邢妍,董衍煜,罗令,邓欢,一种基于随机森林的高精度三维信息快速获取方法,专利号:ZL 201611037639.2

[18]王琼华,熊召龙,邢妍,陈军,邓欢,一种基于投影变换的自由立体显示深度数据校正方法,专利号:ZL 201510323021.1

[19]王琼华,熊召龙,邢妍,邓欢,李大海,一种集成成像超大三维场景拍摄图像校正方法,专利号:ZL 201710240040.7

[20]王琼华,熊召龙,邢妍,邓欢,赵敏,一种基于集成成像摄像机阵列的隐藏物体成像方法,专利号:ZL 201710315492.7

[21]王琼华,夏云鹏,李爽,邢妍,邓欢,一种基于光线跟踪的集成成像环扇形微图像阵列生成方法,专利号:ZL202010324656.4

[22]邓欢,王琼华,刘尧,邢妍,基于偏振针孔阵列的穿透式集成成像3D显示装置,专利号:ZL201510006938.9

[23]王琼华,罗令,熊召龙,邢妍,董衍煜,邓欢,一种基于CPU多线程的集成成像3D片源快速生成方法,专利号:ZL201611245985.X

[24]王琼华,任慧,罗令,邢妍,一种针对真实三维场景的交互式自由立体显示方法,川大,专利号:ZL 201810078152.1

[25]王琼华,肖飞,熊召龙,邢妍,邓欢,一种自由立体显示中的虚拟视点图像生成方法,专利号:ZL 201710226879.5

申请国际发明专利

[26]Yan Xing, Qiong-Hua Wang, Xing-Yu Lin, Cheng-Bo Zhao, Fan Chu, Min-Hao Xiang, and Ke-Feng Tu, Light field 3D display apparatus and light field 3D display method, U.S. Patent, 2025, 申请号:19/268, 136

[27]Qiong-Hua Wang, Xue-Rui Wen, Fan Chu, Yan Xing, Xing-Yu Lin, Yi-Jian Liu, and Tian-Zi Shen, Light field 3D display device based on time-sequentially switched liquid crystal lens arrays, U.S. Patent, 2025, 申请号:19/313, 507

[28]Qiong-Hua Wang, Shuang Li, Yun-Peng Xia, Yan Xing, Hui Ren, and Huan Deng, Integrated imaging 3D display device based on liquid scattering layer, 2020, 国际申请号:PCT/CN2020/139336

软件著作权

[1]王琼华,李伟泽,林星雨,刘一健,邢妍,张汉乐,集成成像裸眼光场3D片源渲染软件V1.0,原创软件,登记号:2023SR0540629

学术任职

[1]中国图象图形学学会三维成像与显示专委会秘书长

[2]中国光学工程学会光显示专委会委员

[3]中国光学学会全息与光信息专委会委员

[4]中国人工智能学会元宇宙技术专委会委员

[5]北京图象图形学学会女科技工作者委员会委员

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