光场显示研发进展

彭玉颜; 康家欣; 周雄图; 张永爱; 郭太良; 吴朝兴

doi:10.3981/j.issn.1000-7857.2024.03.01109

科技导报 >

2025 , Vol. 43 >Issue 2: 34 - 41

DOI: https://doi.org/10.3981/j.issn.1000-7857.2024.03.01109

特色专题：新型显示科学与技术专题

光场显示研发进展

彭玉颜 ^,¹ ,
康家欣 ¹ ,
周雄图 ^,¹^,²^,* ,
张永爱 ¹^,² ,
郭太良 ¹^,² ,
吴朝兴 ¹^,²

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1. 福州大学物理与信息工程学院, 福州 350108
2. 中国福建光电信息科学与技术创新实验室, 福州 350108

周雄图（通信作者），教授，研究方向为信息显示技术，电子信箱：xtzhou@fzu.edu.cn

彭玉颜，博士研究生，研究方向为3D显示，电子信箱：yuyan_peng@sina.com

收稿日期: 2024-03-12

网络出版日期: 2025-02-19

基金资助

国家重点研发计划项目(2022YFB3606603)

福建省光电子信息科技创新实验室项目(2021ZZ130)

福建省自然科学基金项目(2021J01577)

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Research progress of light field display and development suggestions

Yuyan PENG ^,¹ ,
Jiaxin KANG ¹ ,
Xiongtu ZHOU ^,¹^,²^,* ,
Yongai ZHANG ¹^,² ,
Tailiang GUO ¹^,² ,
Chaoxing WU ¹^,²

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1. College of Physics and Information Engineering of Fuzhou University, Fuzhou 350108, China
2. Fujian Science & Technology Innovation Laboratory for Optoelectronic Information of China, Fuzhou 350108, China

Received date: 2024-03-12

Online published: 2025-02-19

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摘要

光场显示具有数据量小、结构简单、易于集成化等优点，使其在军事、医学、教育、娱乐等领域具有巨大的应用潜力。然而，全彩色、大视角、高分辨率、大景深的光场显示受限于高分辨率显示器、光调制器、智能算法、超高速计算机等技术的发展。近年来，人们致力于探索新的设计策略、新的器件结构和潜在的应用。综述了三维（3D）显示技术的发展与分类以凸显出光场显示的优势；阐述了光场显示的概念与意义；介绍了光场显示中的集成成像光场显示、投影光场显示和层光场显示的发展及主要技术挑战。强调了在新形势下对光场显示的新要求，并提出对中国发展光场显示的建议，即加强技术创新平台建设，推动光场显示与其他前沿技术的融合，重点攻克关键技术和产业链瓶颈，促进产学研合作，以确保在全球高科技领域的竞争力。

关键词： 3D显示; 光场显示; 集成成像光场显示; 投影光场显示; 层光场显示

本文引用格式

彭玉颜 , 康家欣 , 周雄图 , 张永爱 , 郭太良 , 吴朝兴 . 光场显示研发进展[J]. 科技导报, 2025 , 43(2) : 34 -41 . DOI: 10.3981/j.issn.1000-7857.2024.03.01109

参考文献

原文顺序 | 文献年度倒序 | 文中引用次数倒序

1	Kim G , Kim Y , Yun J , et al. Metasurface-driven full-space structured light for three-dimensional imaging[J]. Nature Communications, 2022, 13 (1): 5920. DOI

2	Sun Q L , Wang C L , Fu Q , et al. End-to-end complex lens design with differentiate ray tracing[J]. ACM Transactions on Graphics, 2021, 40 (4): 1- 13.

3	王琼华. 3D显示技术与器件[M]. 北京: 科学出版社, 2011.

4	康家欣, 王文雯, 彭玉颜, 等. 光场显示技术的研究现状与发展趋势[J]. 光电子技术, 2023, 43 (2): 116- 128.

5	Liu Z S , Li D H , Deng H . Wide-viewing-angle integral imaging system with full-effective-pixels elemental image array[J]. Micromachines, 2023, 14 (1): 225. DOI

6	Downing E , Hesselink L , Ralston J , et al. A three-color, solid-state, three-dimensional display[J]. Science, 1996, 273 (5279): 1185- 1189. DOI

7	Hsu C H , Wu Y L , Cheng W H , et al. HoloTube: A lowcost portable 360-degree interactive autostereoscopic display[J]. Multimedia Tools and Applications, 2017, 76 (7): 9099- 9132. DOI

8	Xie X H , Yu X B , Fu B S , et al. High-quality reproduction method for three-dimensional light-field displays using parallax-view information synthesis and aberration precorrection[J]. Optics and Lasers in Engineering, 2024, 173: 107930. DOI

9	Gershun A . The light field[J]. Journal of Mathematics and Physics, 1939, 18 (1-4): 51- 151. DOI

10	Levoy M, Hanrahan P. Light field rendering[C] //Computer Graphics and Interactive Ttechniques. New York, USA: Association for Computing Machinery, 1996: 43-54.

11	Gortler J S, Grzeszczuk R, Szeliski R, et al. The lumigraph[C] //Computer Graphics and Interactive Techniques. New York, USA: Association for Computing Machinery, 1996: 31-42.

12	Lippmann G . Épreuves réversibles donnant la sensation du relief[J]. Journal de Physique Théorique et Appliquée, 1908, 7 (1): 821- 825. DOI

13	彭玉颜. 用于集成成像3D显示的微透镜阵列研制[D]. 福州: 福州大学, 2017.

14	Chao C H , Liu C L , Chen H H . Time-division multiplexing light field display with learned coded aperture[J]. IEEE Transactions on Image Processing, 2023, 32: 350- 363. DOI

15	Ma H W , Yao J H , Gao Y Q , et al. Parameter optimization method for light field 3D display[J]. Optics Express, 2023, 31 (25): 42206- 42217. DOI

16	Xing Y , Lin X Y , Zhang L B , et al. Integral imagingbased tabletop light field 3D display with large viewing angle[J]. Opto-Electronic Advances, 2023, 6 (6): 220178. DOI

17	Wang H , Deng H , Guo Z D , et al. Curved computer-generated integral imaging based on backward ray-tracing technique[J]. IEEE Photonics Journal, 2023, 15 (1): 1- 6.

18	Jiang L J , Lin J F , Rao F B , et al. Dual-mode optical seethrough integral imaging 3D display with large depth of field[J]. Optics and Lasers in Engineering, 2024, 175: 107986. DOI

19	Bae S I , Kim K , Jang K W , et al. High contrast ultrathin light-field camera using inverted microlens arrays with metal-insulator-metal optical absorber[J]. Advanced Optical Materials, 2021, 9 (6): 2001657. DOI

20	Wen J , Yan X P , Jiang X Y , et al. Comparative study on light modulation characteristic between hexagonal and rectangular arranged macro lens array for integral imaging based light field display[J]. Optics Communications, 2020, 466: 125613. DOI

21	Yang L , Shen J Q . Deep neural network-enabled resolution enhancement for the digital light field display based on holographic functional screen[J]. Optics Communications, 2024, 550: 130012. DOI

22	Yan X P , Yan Z , Jing T , et al. Enhancement of effective viewable information in integral imaging display systems with holographic diffuser: Quantitative characterization, analysis, and validation[J]. Optics and Laser Technology, 2023, 161: 109101. DOI

23	Yan Z , Yan X P , Jiang X Y , et al. Calibration of the lens' axial position error for microlens array based integral imaging display system[J]. Optics and Lasers in Engineering, 2021, 142: 106585. DOI

24	Cai Z W , Chen J W , Pedrini G , et al. Lensless light-field imaging through diffuser encoding[J]. Light, Science & Applications, 2020, 9: 143.

25	Wang W W , Chen G X , Weng Y L , et al. Large-scale microlens arrays on flexible substrate with improved numerical aperture for curved integral imaging 3D display[J]. Scientific Reports, 2020, 10 (1): 11741. DOI

26	Wang W W , Zhang Y A , Wu C X , et al. Enhanced depth of field of integral imaging display using bifocal microlens array fabricated by two-step lithography[J]. Journal of the Society for Information Display, 2023, 31 (7): 494- 503. DOI

27	Li Q , Zhong F Y , Deng H , et al. Depth-enhanced 2D/3D switchable integral imaging display by using n-layer focusing control units[J]. Liquid Crystals, 2022, 49 (10): 1367- 1375. DOI

28	Zhang Y A , Weng X Y , Liu P H , et al. Electrically highresistance liquid crystal micro-lens arrays with high performances for integral imaging 3D display[J]. Optics Communications, 2020, 462: 125299. DOI

29	Wang W W , Chen W D , Peng Y Y , et al. Low-voltage driving high-resistance liquid crystal micro-lens with electrically tunable depth of field for the light field imaging system[J]. Scientific Reports, 2022, 12 (1): 17442. DOI

30	Zhou R Y , Wei C X , Ma H W , et al. Depth of field expansion method for integral imaging based on diffractive optical element and CNN[J]. Optics Express, 2023, 31 (23): 38146- 38164. DOI

31	Yang L , Sang X Z , Yu X B , et al. Demonstration of an improved integral imaging system with large viewing angle using the micro-lens array mask[J]. Optik, 2019, 182: 1113- 1119. DOI

32	Gao X , Sang X Z , Xing S J , et al. Full-parallax 3D light field display with uniform view density along the horizontal and vertical direction[J]. Optics Communications, 2020, 467: 125765. DOI

33	Yan Z , Yan X P , Huang Y Q , et al. Characteristics of the holographic diffuser in integral imaging display systems: A quantitative beam analysis approach[J]. Optics and Lasers in Engineering, 2021, 139: 106484. DOI

34	Lv Z L , Li J N , Yang Y , et al. 3D head-up display with a multiple extended depth of field based on integral imaging and holographic optical elements[J]. Optics Express, 2023, 31 (2): 964- 975. DOI

35	Balogh T, Kovacs P T, Barsi A. Holovizio 3D display system[C] //Proceedings of 3DTV Conference. Piscataway, NJ: IEEE, 2007: 1-4.

36	Watanabe H , Okaichi N , Omura T , et al. Aktina Vision: Full-parallax three-dimensional display with 100 million light rays[J]. Scientific Reports, 2019, 9 (1): 17688. DOI

37	Yamauchi M , Yendo T . Light field display using wavelength division multiplexing[J]. ITE Transactions on Media Technology and Applications, 2023, 11 (2): 49- 55. DOI

38	Zhang H L , Deng H , Ren H , et al. See-through 2D/3D compatible integral imaging display system using lens-array holographic optical element and polymer dispersed liquid crystal[J]. Optics Communications, 2020, 456: 124615. DOI

39	Doronin O, Bregovic R, Gotchev A. Optimized 3D scene rendering on projection-based 3D displays[C] //Proceedings of 28th European Signal Processing Conference (EUSIPCO). Piscataway, NJ: IEEE, 2021: 580-584.

40	Wang P , Sang X Z , Chen D , et al. Computational superresolution full-parallax three-dimensional light field display based on dual-layer LCD modulation[J]. IEEE Access, 2020, 8: 81045- 81054. DOI

41	Zhu L M , Du G , Lv G Q , et al. Performance improvement for compressive light field display with multi-plane projection[J]. Optics and Lasers in Engineering, 2021, 142: 106609. DOI

42	Zhu L M , Chen Q Y , Chen T , et al. High-brightness hybrid compressive light field display with improved image quality[J]. Optics Letters, 2023, 48 (23): 6172- 6175. DOI

43	Li Y, Qiao W. Vector light field 3D display with multi-directional backlight[C] //Proceedings of International Conference on Precision Instruments and Optical Engineering (PIOE 2022). Guangzhou: SPIE, 2023: 120-125.

44	Zhou F B , Zhou F , Chen Y , et al. Vector light field display based on an intertwined flat lens with large depth of focus[J]. Optica, 2022, 9 (3): 288. DOI

45	Shi J C , Hua J Y , Zhou F B , et al. Augmented reality vector light field display with large viewing distance based on pixelated multilevel blazed gratings[J]. Photonics, 2021, 8 (8): 337. DOI

46	Hua J Y , Li Y , Ge P R , et al. Time-multiplexed vector light field display with intertwined views via metagrating matrix[J]. Optics and Lasers in Engineering, 2023, 164: 107527.

47	欧阳钟灿. 中国新型显示技术发展之路[J]. 科技导报, 2023, 41 (19): 92- 95. DOI

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