个人简历
2007年获南开大学光学工程专业工学博士学位,2014-2015年赴香港理工大学超精密加工技术国家重点实验室进行访问交流。主要从事光电成像技术、光学系统设计和光学信息处理技术领域的教学科研工作。
先后承担国家自然科学基金面上项目、天津市自然科学基金重点项目、中科院国防科技创新重点课题等多项国家和省部级项目,参与科技部973计划子课题、重点研发计划、载人航天有效载荷、国产工业软件研制等重大项目。获得发明专利授权十余项,在国内外高水平期刊发表文章近百篇。
获2014年度中国仪器仪表学会奖学金-金国藩青年学子奖,2015年度中国光学工程学会创新技术三等奖(第三完成人),2019年度和2021年度天津市科技进步一等奖,2021年度中国光学科技奖应用成果类一等奖,2024年度天津市科技进步二等奖。
个人主页:https://nankai.teacher.360eol.com/teacherBasic/preview?teacherId=9042
科研项目/成果/获奖/专利
基于像差场偏移量计算模型的自由曲面反射系统公差降敏设计方法研究(国家自然基金面上项目,2025-2028,负责人)
基于人眼像差精准解耦调控理论的近视激光矫正手术个性化角膜切削量的确定(南开大学眼科学研究院开放基金项目,2023-2026,负责人)
基于严格矢量像差理论的离轴自由曲面成像光学系统的优化设计(国家自然基金面上项目,2021-2024,负责人)
人眼像差耦合特性及其在近视眼激光矫正中的应用基础研究(天津市自然基金重点项目,2019-2022,负责人)
局域型光学自由曲面模型应用于大视场高像质光学成像系统设计的关键技术研究(国家自然基金面上项目,2017-2020,负责人)
微结构表面超精密加工新型光学在位检测技术基础研究-(天津市自然基金面上项目,2015-2018,负责人)
基于光场成像技术的超分辨信息获取与重建(国家自然基金面上项目,2015-2018,负责人)
自由曲面特征表征函数与建模研究(中科院创新基金重点项目子课题,2013-2015,负责人)
基于偶氮聚合物光场吸收调制的超分辨微加工技术基础研究(国家自然基金青年项目,2012-2014,负责人)
高灵敏度荧光探测系统研究(科技部重点研发计划课题,2018-2022,参与)
新型三维成像与三维微显示技术及器件基础研究(科技部973项目子课题,2010-2014,参与)
承担多项企事业单位委托合作项目。
在研项目合同经费200余万元。
论文/专著/教材
近年来发表的部分文章:
[1] Ya Wen, Xing Zhao, Zhixiang Jiang, Da Li*, High performance multimode fiber specklegram sensing with multi-layer convolutional neural network based on digital aperture filtering. Chinese Optics Letters, 2025, 23(5): 051201
[2] Kaiyi Zhang, Xing Zhao, Ya Wen, and Da Li, "PSLFM: a single-frame uncalibrated photometric stereoscopic light field measurement scheme based on dense convolutional neural networks," Opt. Express. 2025, 33(2): 3082-3100
[3] Ming Chen, Xing Zhao, Bin Wang, Da Li, Xiaoxuan Xu, Hongliang Liu, Siwen Ai & Lu Sun, Flower-like gap-enhanced Raman tags wrapped with polydopamine-functionalized MoS2 nanosheets for phototheranostic nanoplatform. J Mater Sci. 2025,60(4): 1873-1890.
[4] Jingfan Wang, Xing Zhao, Yan Wang, Da Li*, Color-multiplexed 3D differential phase contrast microscopy with optimal annular illumination. Opt. Express, 2024, 32(27): 49135-49152
[5] Zhang, S. Zhao, X. Li, D. Zhao, X*. Zhang, L*. Wang, Y. Introducing Aberrations into Human Eye Models with High Precision for Objective Visual Quality Evaluation. Photonics, 2024, 11(12): 1146.
[6] Jingfan Wang, Xing Zhao, Yan Wang, Da Li*. Transport-of intensity differential phase contrast imaging: defying weak object approximation and matched-illumination condition. Photonics Research, 2024, 12(11): 2712.
[7] Ya Wen, Xing Zhao, Zhixiang Jiang, Haoran Li, and Da Li*, "High performance few-mode fiber-based light field direction sensing system using deep convolutional neural network: fiber speckle demodulation network (FSDNET)," Opt. Express 2024, 32(12): 21629-21642
[8] Shuai Zhang, Xing Zhao*, Da Li, Hao Feng, Shangnan Zhao, Lingjie Wang, and Xin Zhang, High-precision analysis of aberration contribution of Zernike freeform surface terms for non-zero field of view, Opt. Express 2024, 32(3): 3167-3183
[9] Jingfan Wang, Xing Zhao, Yan Wang, and Da Li*, Quantitative real-time phase microscopy for extended depth-of-field imaging based on the 3D single-shot differential phase contrast (ssDPC) imaging method. Opt. Express 2024, 32(2), 2081-2096
[10] Ming Chen, Xing Zhao, Bin Wang*, Hongliang Liu, Zhixiang Chen, Lu Sun, Xiaoxuan Xu, Graphene-wrapped petal-like gap-enhanced Raman tags for enhancing photothermal conversion and Raman imaging, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2024,304:123306.
[11] Jingfan Wang, Ming Chen, Xing Zhao, Yan Wang, and Da Li*, Fourier Raman light field microscopy based on surface-enhanced Raman scattering, Opt. Lett. 2024, 49(16), 4693-4696,
[12] Zhixiang Jiang, Yongkang Zhang, Zhuoyuan Li, Ya Wen, Guowei Liu, Fan Feng, Da Li, Xing Zhao, Song Lipei*, Fourier single-pixel imaging based on sampling prediction from intermediate frequencies, Optics Communications, 2024, 570, 130930,
[13] Zhixiang Jiang, Ya Wen, Lipei Song*, Da Li, and Xing Zhao, "Optical fiber bundle differential compressive imaging," Opt. Lett. 2024, 49(4), 2297-2300
[14] Ming Chen, Jingfan Wang, Da Li*, Bin Wang*, Shuo Wang, Xing Zhao, Meng Meng; High-speed and wide-field 3D Raman imaging using flower-like gap-enhanced Raman tags. Appl. Phys. Lett. 2024, 124 (12): 123701
[15] Zhi Zhang, Nan Zhang, Yuezheng Wang, Bofu Xie, Yuyan Xiang, Jiewei Guo, Bingpeng Shang, Lanjun Guo, Xing Zhao, Maoqiang Xie, Lie Lin, and Weiwei Liu, "Detection of 1.4 μg/m3 Na+ in aerosol at a 30 m distance using 1 kHz femtosecond laser filamentation in air," Opt. Express 2023, 31(4), 6464-6474
[16] Jiasheng Yao, Zhixiang Jiang, Xuekun Lv, Qiang Peng, Xing Zhao, Lipei Song*, Adaptive Fourier single-pixel imaging based on directional energy continuity in high frequencies, Optics and Lasers in Engineering, 2023, 162(3):107406,
[17] Shishi Tao, Bofu Xie, Jiayun Xue, Zhi Zhang, Nan Zhang, Lanjun Guo, Lie Lin, Pengfei Qi*, Xing Zhao, and Weiwei Liu, "Giant enhancement of acoustic and fluorescence emission from an off-axis reflective femtosecond laser filamentation system," Opt. Express 2022, 30(21): 38745-38752
[18] Xinheng Zhao, Lin Zhang, Jiaonan Ma, Mengdi Li, Jiamei Zhang, Xing Zhao and Yan Wang, Comparison of Wavefront-Guided Femtosecond LASIK and Optimized SMILE for Correction of Moderate-to-High Astigmatism. J Refract Surg. 2021, 37(3):166-173.
[19] Jiang Zhixiang, Zhao Xing, Wen Ya, Peng Qiang, Li Da, Song Lipei*, Block-based compressed sensing for fast optic fiber bundle imaging with high spatial resolution, Optics Express, 2023. 31(11): p. 17235-17249
[20] Tao S, Xue J, Guo J, Zhao X*, Zhang Z, Lin L, Liu W. Investigation of Focusing Properties on Astigmatic Gaussian Beams in Nonlinear Medium. Sensors. 2022; 22(18):6981.
[21] Chen, M.; Wang, B.; Wang, J.; Liu, H.; Chen, Z.; Xu, X.*; Zhao, X*. Highly Stable, Graphene-Wrapped, Petal-Like, Gap-Enhanced Raman Tags. Nanomaterials. 2022, 12(10): 1626.
[22] Wang, J.; Zhao, X.; Li, D*.; Wen, Y.; Wang, W.; Wang, B.; Xu, X.; Bai, H.; Liu, W. Autostereoscopic-Raman Spectrometry-Based Three-Dimensional Metrology System for Measurements, Tracking and Identification in a Volume. Appl. Sci. 2022, 12(6): 3111.
[23] Wang Weihao, Zhao Xing*, Jiang Zhixiang, Wen Ya, Deep learning-based scattering removal of light field imaging, Chinese Optics Letters, 2022, 20(4): 41101
[24] Y. Wen, T. Liu, P. Chen, J. Wang, D. Xiao, X. Zhao*, Image quality improvements of diffuse optical tomography by using multiple polarization components, Results in Optics, 2022, Vol. 7, 100219.
[25] Shuai Zhang, Liuchang Xiao, Xing Zhao*, Lipei Song, Yongji Liu, Lingjie Wang, Guangwei Shi, and Weiwei Liu, "Optimization method using nodal aberration theory for coaxial imaging systems with radial basis functions based on surface slope," Appl. Opt. 2021, 60(9), 2722-2730
[26] Weihao Wang, Xing Zhao*, Xuewei Zhao, Lipei Song, Weiwei Liu, Yaoyao Wang, "On-machine measurement method for micro-structured surface by integral imaging with workpiece rotating technique," Opt. Eng. 60(5), 051210 (2021).
[27] Liuchang Xiao, Kainian Tong, Lipei Song, Lingjie Wang, Pengfei Wu, Weiwei Liu, Xing Zhao*, "Model of radial basis functions with slope-based shape factor and distribution for optical freeform surface," Opt. Eng. 59(12), 125101 (2020),
[28] Yaoyao Wang, Juan Zhang, Xuewei Zhao, Bo Zhang, Lipei Song, Xing Zhao*, "Hybrid pixel mapping reconstruction method of axially moving lenslet array in integral imaging with arbitrary moving gap," Opt. Eng. 57(6), 061620 (2018)
[29] Kainian Tong, Yi Zheng, Zan Zhang, Xing Zhao*, Bo Zhang, Lipei Song, Lingjie Wang, Chao Wang, and Pengfei Wu, "Model of radial basis functions based on surface slope for optical freeform surfaces," Opt. Express, 2018, 26(11): 14010-14023
[30] Yao-yao Wang (王尧尧),Juan Zhang (张娟), Xue-wei Zhao (赵雪微), Li-pei Song (宋丽培), Bo Zhang (张勃), Xing Zhao* (赵星), Depth extraction method with high accuracy in integral imaging based on moving array lenslet technique, Optoelectronics Letters, 2018, 14(2): 148–151
[31] Juan Zhang, Liqiu Zhou, Xiaoxue Jiao, Lei Zhang, Lipei Song, Bo Zhang, Yi Zheng, Zan Zhang, and Xing Zhao*, Statistics-based reconstruction method with high random-error tolerance for integral imaging, Appl. Opt. 2015, 54(28): E176-E180
[32] Liqiu Zhou, Xing Zhao*, Yong Yang, Xiaocong Yuan, Voxel model for evaluation of a three-dimensional display and reconstruction in integral imaging, Optics Letters, 39(7): 2032-2035 (2014)
[33] Qiang Li, Xing Zhao*, Bo Zhang, Yi Zheng, Liqiu Zhou, Lingjie Wang, Yanxiong Wu and Zhiliang Fang, Nanofocusing of longitudinally polarized light using absorbance modulation, Applied Physics Letters, 104(6): 061103 (2014)
[34] Fang Wang, Xing Zhao*, Yong Yang, Zhiliang Fang, Xiaocong Yuan, Performance analysis of three-dimensional integral imaging systems based on human vision, Optik, 124(2): 134-138 (2013)
[35] Xiaoxue Jiao, Xing Zhao*, Yong Yang, Zhiliang Fang, and Xiaocong Yuan, Dual-camera enabled real-time three-dimensional integral imaging pick-up and display. Optics. Express, 20(25): 27304-27311 (2012)
[36] 王芳,赵星*,杨勇 等 . 基于人眼视觉的集成成像三维显示分辨率的比较. 物理学报, 61(8): 084212. (2012)
[37] Da Li, Xing Zhao*, Yong Yang, Zhiliang Fang, and Xiaocong Yuan, Tunable viewing scope of three-dimensional integral imaging, Applied. Optics. 50(34), H230-H236 (2011)
[38] Xing Zhao, Yuyang Sun, Jing Bu, Siwei Zhu, and X.-C. Yuan, Microlens-array-enabled on-chip optical trapping and sorting. Applied. Optics. 50(3), 318-322 (2011)
[39] 解博夫, 张帅, 李浩然, 冯昊, 黎达, 赵星*. 矢量像差理论在成像系统像差补偿中的应用(特邀)[J]. 红外与激光工程, 2023, 52(7): 20230343. doi: 10.3788/IRLA20230343
[40] 解博夫, 赵星*, 陶诗诗, 张帅, 李浩然, 李渊博, 刘洪亮, 刘伟伟. 自由曲面补偿飞秒激光成丝系统像差的应用[J]. 光学学报, 2023, 43(8): 0822020.
[41] 李浩然, 张帅, 解博夫, 文雅, 徐绍伟, 陶宇亮, 赵星*, 刘伟伟. 用于光丝激光雷达收集系统的非球面环带菲涅耳透镜设计[J]. 中国激光, 2023, 50(7): 0708010.
[42] 文雅, 汪书勤, 李浩然, 徐绍伟, 陶宇亮, 赵星*, 刘伟伟. 大口径菲涅耳透镜远距离宽光谱聚光系统设计[J]. 中国激光, 2023, 50(7): 0708011.
[43] 胡俊波,张帅,解博夫,赵星*,刘伟伟. 基于同时多表面设计原理的非球面成像光学系统初始结构构造方法研究. 光电子激光,2022, 33(10):1009~1017
[44] 赵星*,刘桐君,陈平等.利用深度学习扩展非接触扩散光学层析成像系统中探测器的动态范围[J].光学精密工程,2021,29(11):2529-2538.
[45] 赵星*,肖流长,张赞,王灵杰,张效栋. 基于面形斜率的高斯径向基自由曲面优化设计及公差分析,光学精密工程,2019,27(12): 2499-2508
[46] 赵雪微,王尧尧,宋丽培,张勃,赵星*. 基于计算集成成像的水下目标成像[J]. 中国激光, 2018, 45(1): 0109001
[47] 张赞,赵星*,李强,郑义,张娟,席炜,武鹏飞. 涡旋光场的吸收调制效应及其在超分辨技术中的应用. 光电子激光,2017, 28(3):334-339
[48] 武鹏飞,张赞,郑义,张娟,王尧尧,赵星*,王灵杰,伍雁雄. 采样点分布对基于面形斜率径向基模型的自由曲面拟合精度的影响. 光学精密工程, 2016,24(7): 1564-1572.
[49] 张娟,周立秋,张勃,张赞,郑义,赵星*. 基于光线追迹的集成成像技术重建分辨率研究[J]. 中国激光, 2015, 42(11): 1108004
[50] 赵星, 郑义, 张赞,张娟,王灵杰,伍雁雄. 基于面形斜率的光学自由曲面表征[J]. 光学精密工程, 2015,23(7): 1957-1964.
讲授课程
工程光学——本科专业必修课
光电信息处理实验——本科专业实验
光学仪器原理与测试技术——研究生专业选修课
社会兼职
天津市光学学会理事;
中国新一代人工智能发展战略研究院办公室主任;
期刊审稿人:Optics Express、Applied Optics、JOSA.A、光学精密工程、光学学报、中国激光、红外与激光工程