2002.09-2006.07 北京理工大学光电学院 测控技术与仪器专业 工学学士

2006.09-2011.06 北京理工大学光电学院 光学工程专业 工学博士

2009.09-2010.09 剑桥大学工程系 电子工程专业 联合培养博士

2011.07-2013.09 清华大学 精密仪器系 博士后

2013.09-2016.07 清华大学 精密仪器系 助理研究员

2016.07-2017.12 清华大学 精密仪器系 助理教授

2017.12-2024.07 清华大学 精密仪器系 副教授

2024.08-2025.12 中国光学工程学会 校企联合办主任

2026.01-至今    北京科技大学 自动化学院 教授

信息光学、全息与衍射光学、光场调控、激光精密制造、智能光子技术

专著

金国藩、张浩、苏萍、蒋强、曹良才，计算机制全息图，科学出版社，2020

代表性论文

[1]     S. Tian, J. Xiao, H. Zhang*, Qiaofeng Tan, Liqun Sun, “Computer holography in phase space: an analytical framework for wavefield evolution in space-frequency domain,” Opt. Laser Technol. 195, 114613 (2026)

[2]     S. Tian, J. Xiao, H. Zhang*, Qiaofeng Tan, Liqun Sun, “Noise Suppression Strategies in Computer Holography: Methods and Techniques,” Lights 1, 2 (2025)

[3]     N. Zhao, J. Xiao, R. Zhu, and H. Zhang*, “Gaze-Engineered 3D Augmented Reality,” Adv. Intell. Syst. 2500070 (2025)

[4]     R. Zhu, L. Chen, J. Xiao, H. Zhang*, “Three-dimensional computer holography with phase space tailoring,” PhotoniX 5, 34 (2024)

[5]     N. Zhao, J. Xiao, P. Weng, and H. Zhang*, “Tomographic waveguide-based augmented reality display,” Opt. Express 32, 18692-18699 (2024)

[6]     R. Zhu, L. Chen, and H. Zhang*, “Computer holography using deep neural network with Fourier basis,” Opt. Lett. 48, 2333-2336 (2023)

[7]     X. Wang, H. Zhang*, “Diffraction Characteristics of a Digital Micromirror Device for Computer Holography Based on an Accurate Three-Dimensional Phase Model,” Photonics, 10, 130 (2023)

[8]     J. Xiao, W. Zhang, and H. Zhang*, “Inverse diffraction in phase space,” J. Opt. Soc. Am. A 40, 175-184 (2023)

[9]     L. Chen, R. Zhu, and H. Zhang*, “Speckle-free compact holographic near-eye display using camera-in-the-loop optimization with phase constraint,” Opt. Express 30, 46649-46665 (2022)

[10]  S. Tian, L. Chen, and H. Zhang*, “Optimized Fresnel phase hologram for ringing artifacts removal in lensless holographic projection,” Appl. Opt. 61, B17-B24 (2022)

[11]  J. Xiao, W. Zhang, and H. Zhang*, “Sampling analysis for Fresnel diffraction fields based on phase space representation,” J. Opt. Soc. Am. A 39, A15-A28 (2022)

[12]  L. Chen, S. Tian, H. Zhang*, L. Cao*, and G. Jin, “Phase hologram optimization with bandwidth constraint strategy for speckle-free optical reconstruction,” Opt. Express 29, 11645-11663 (2021)

[13]  W. Zhang, H. Zhang*, K. Matsushima, and G. Jin, “Shifted band-extended angular spectrum method for off-axis diffraction calculation,” Opt. Express 29, 10089-10103 (2021)

[14]  W. Zhang, H. Zhang*, and G. Jin, “Single-Fourier transform based full-bandwidth Fresnel diffraction,” J. Opt. 23, 035604 (2021)

[15]  W. Zhang, H. Zhang*, and G. Jin, “Phase-space synthesized digital holography for high space-bandwidth product imaging,” Opt. Eng. 60(1), 013105 (2021)

[16]  W. Zhang, H. Zhang*, and G. Jin, “Frequency sampling strategy for numerical diffraction calculations,” Opt. Express 28, 39916-39932 (2020)

[17]  W. Zhang, H. Zhang*, C. J. R. Sheppard, and G. Jin, “Analysis of numerical diffraction calculation methods: from the perspective of phase space optics and the sampling theorem,” J. Opt. Soc. Am. A 37, 1748-1766 (2020)

[18]  L. Chen, H. Zhang*, Z. He, X. Wang, L. Cao*, and G. Jin, “Weighted constraint iterative algorithm for phase hologram generation,” Appl. Sci. 10(10), 3652 (2020)

[19]  W. Zhang, H. Zhang*, and G. Jin, “Resolution-enhanced digital in-line holography by extension of the computational bandwidth,” Opt. Commun. 472, 126038 (2020)

[20]  W. Zhang, H. Zhang*, and G. Jin, “Adaptive-sampling angular spectrum method with full utilization of space-bandwidth product,” Opt. Lett. 45, 4416-4419 (2020)

[21]  L. Chen, H. Zhang*, L. Cao*, and G. Jin, “Non-iterative phase hologram generation with optimized phase modulation,” Opt. Express 28, 11380-11392 (2020)

[22]  W. Zhang, H. Zhang*, and G. Jin, “Band-extended angular spectrum method for accurate diffraction calculation in a wide propagation range,” Opt. Lett. 45, 1543-1546 (2020)

[23]  W. Zhang, H. Zhang*, L. Cao, M. Gehm, Q. Jiang, D. Brady, and G. Jin “Resolution and sampling analysis in digital in-line holography with spherical wave illumination,” Optical Engineering 59, 102402 (2019)

[24]  H. Zhang*, L. Cao, and G. Jin, “Three-dimensional computer-generated hologram with Fourier domain segmentation,” Opt. Express 27, 11689-11697 (2019)

[25]  H. Zhang*, L. Cao, and G. Jin, “Scaling of Three-Dimensional Computer-Generated Holograms with Layer-Based Shifted Fresnel Diffraction,” Appl. Sci. 9, 2118 (2019)

[26]  X. Wang, H. Zhang*, L. Cao*, and G. Jin, “Generalized single-sideband three-dimensional computer-generated holography,” Opt. Express 27, 2612-2620 (2019)

[27]  H. Zhang*, L. Cao, and G. Jin, “Computer-generated hologram with occlusion effect using layer-based processing,” Appl. Opt. 56, F138-F143 (2017)

[28]  H. Zhang*, L. Cao, G. Jin, “Lighting effects rendering in three-dimensional computer-generated holographic display,” Opt. Commun., 370, 192-197 (2016)

[29]  H. Zhang*, Y. Zhao, L. Cao, and G. Jin, “Layered holographic stereogram based on inverse Fresnel diffraction,” Appl. Opt. 55, A154-A159 (2016)

[30]  H. Zhang*, Y. Zhao, L. Cao, and G. Jin, “Fully computed holographic stereogram based algorithm for computer-generated holograms with accurate depth cues,” Opt. Express 23, 3901-3913 (2015)

[31]  H. Zhang*, Y. Zhao, L. Cao, and G. Jin, “Three-dimensional display technologies in wave and ray optics: a review (Invited Paper),” Chin. Opt. Lett. 12, 060002- (2014)

[32]  H. Zhang*, Q. Tan, and G. Jin, “Holographic display system of a three-dimensional image with distortion-free magnification and zero-order elimination,” Opt. Eng. 51(7), 075801 (2012)

[33]  H. Zhang*, N. Collings, J. Chen, B. Crossland, D. Chu, and J. Xie, “Full parallax three-dimensional display with occlusion effect using computer generated hologram,” Opt. Eng. 50, 074003 (2011)

[34]  H. Zhang, J. Xie, J. Liu*, and Y. Wang*, “Optical reconstruction of 3D images by use of pure-phase computer-generated holograms,” Chin. Opt. Lett. 7, 1101-1103 (2009)

[35]  H. Zhang, J. Xie, J. Liu*, and Y. Wang, “Elimination of a zero-order beam induced by a pixelated spatial light modulator for holographic projection,” Appl. Opt. 48, 5834-5841 (2009)

智能光子技术（本科生）

[1]     国家自然科学基金重点项目，动态高分辨率计算全息显示新理论与关键技术，2020.01-2025.12，子任务负责人。

[2]     国家重点研发计划，临场真实感近眼三维显示技术与装置，2021.12-2024.12，子课题负责人。

[3]     国家自然科学基金面上项目，基于高精度波前变换的近眼计算全息三维显示技术研究，2019.01-2022.12，项目负责人。

[4]     国家重点实验室自主研究课题，基于相位信息优化的高精度计算全息三维重建方法研究，2020.01-2022.12，项目负责人。

[5]     国家自然科学基金青年科学基金，基于波前动态扫描系统的计算全息三维显示技术研究，2016.01-2018.12，项目负责人。

2024年，清华大学招生工作十年年功奖

2023年，北京高校优秀本科毕业设计指导教师

2023年，北京市挑战杯一等奖作品指导教师

2023年，清华大学校级工会积极分子

2023年，清华大学优秀招生教师

2023年，清华大学优秀学生科协指导教师

2022年，清华大学校级工会积极分子

2022年，清华大学优秀学生科协指导教师

2021年，北京高校第十二届青年教师教学基本功比赛三等奖

2020年，清华大学学生实验室建设贡献一等奖

2020年，清华大学实验室技术成果三等奖

2020年，清华大学第九届青年教师教学大赛工科组一等奖

2019年，清华大学校级工会积极分子

2016年，中国仪器仪表学会金国藩青年学子奖

2016年，清华大学实验室技术成果二等奖

[1]     眼动追踪光场3D显示方法、装置、电子设备及存储介质，ZL202410406680.0，授权。

[2]     一种用于增强现实的三维场景实现方法及系统，ZL202310377980.6，授权。

[3]     一种用于增强现实的二值层析三维场景实现方法及系统，ZL202310449369.X，授权。

[4]     一种用于光场三维显示量化标定的方法，ZL201710135853.X，授权。

[5]     准共光路多角度照明数字全息成像系统及方法，ZL201711163260.0，授权。

[6]     紧凑型无透镜准共光路离轴数字全息成像系统及方法，ZL201711121349.0，授权。

[7]     紧凑型准共光路相移数字全息成像系统及方法，ZL201711121140.4，授权。

[8]     一种基于衍射光栅的数字全息成像方法、系统，ZL201710676415.4，授权。