[1] [1] Lee LP, Szema R. Inspirations from biological, optics for advanced phtonic systems. Science. 2005;310:1148–50. .10.1126/science.1115248

[2] [2] Sarkar, M., Theuwissen, A. in A Biologically Inspired CMOS Image Sensor Vol. 461 Studies in Computational Intelligence 1-11 (Springer-Verlag Berlin, 2013).

[3] [3] Toates FM. Accommodation function of Human eye. Physiol Rev. 1972;52:828–000. .10.1152/physrev.1972.52.4.828

[4] [4] Jagger WS. The optics of the spherical fish Lens. Vision Res. 1992;32:1271–84. .10.1016/0042-6989(92)90222-5

[5] [5] Easter SS, Hitchcock PF. The myopic eye of the black moor goldfish. Vision Res. 1986;26:1831–000. .10.1016/0042-6989(86)90135-5

[6] [6] Rossel S. Binocular stereopsis in an insect. Nature. 1983;302:821–2. .10.1038/302821a0

[7] [7] Sarkar, M. & Theuwissen, A. in A Biologically Inspired CMOS Image Sensor Vol. 461 Studies in Computational Intelligence 13-48 (Springer-Verlag Berlin, 2013).

[8] [8] Land MF, Nilsson DE, Land MF, Nilsson DE. Apposition compound eyes. New York: Oxford Univ Press; 2012.

[9] [9] Song YM, et al. Digital cameras with designs inspired by the arthropod eye. Nature. 2013;497:95–9. .10.1038/nature12083

[10] [10] Keum D, et al. Xenos peckii vision inspires an ultrathin digital camera. Light-Science & Applications. 2018;7:7. .10.1038/s41377-018-0081-2

[11] [11] Kim K, Jang KW, Ryu JK, Jeong KH. Biologically inspired ultrathin arrayed camera for high-contrast and high-resolution imaging. Light-Science & Applications. 2020;9:7. .10.1038/s41377-020-0261-8

[12] [12] Kogos LC, et al. Plasmonic ommatidia for lensless compound-eye vision. Nature Communications. 2020;11:9. .10.1038/s41467-020-15460-0

[13] [13] Zhu, L Z., Y. L. Sun, H B. Miniaturising artificial compound eyes based on advanced micronanofabrication techniques. Light Advanced Manufacturing.2021;(2):84-100

[14] [14] Floreano D, et al. Miniature curved artificial compound eyes. Proc Natl Acad Sci U S A. 2013;110:9267–72. .10.1073/pnas.1219068110

[15] [15] Shi CY, et al. SCECam: a spherical compound eye camera for fast location and recognition of objects at a large field of view. Optics Express. 2017;25:32333–45. .10.1364/oe.25.032333

[16] [16] Zheng YL, Song L, Huang JX, Zhang HY, Fang FZ. Detection of the three-dimensional trajectory of an object based on a curved bionic compound eye. Opt Lett. 2019;44:4143–6. .10.1364/ol.44.004143

[17] [17] Ma MC, et al. Target orientation detection based on a neural network with a bionic bee-like compound eye. Optics Express. 2020;28:10794–805. .10.1364/oe.388125

[18] [18] Dai B, et al. Biomimetic apposition compound eye fabricated using microfluidic-assisted 3D printing. Nature Communications. 2021;12:11. .10.1038/s41467-021-26606-z

[19] [19] Feng X, et al. A Meniscus Multifocusing Compound Eye Camera Based on Negative Pressure Forming Technology. Micromachines. 2023;14:12. .10.3390/mi14020420

[20] [20] Hu ZY, et al. Miniature optoelectronic compound eye camera. Nat Commun. 2022;13:5634. .10.1038/s41467-022-33072-8

[21] [21] Zhang H, et al. Development of a low cost high precision three-layer 3D artificial compound eye. Optics Express. 2013;21:22232–45. .10.1364/oe.21.022232

[22] [22] Chung-You, L., Jun-Fu, C., Ting-Chieh, Y., Wang, K. Use bionic microlens array and CMOS image sensor for three-dimensional motion detection. 2012 7th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS). 2021;388-391 .

[23] [23] Chen AH, He BW, Gao CH. In: 3rd International Conference on Mechatronics and Control Engineering (ICMCE). Switzerland: Trans Tech Publications Ltd; 2014. p 290–4.

[24] [24] Frost SA, Gorospe GE, Teubert C. Compound eye sensor for real-time aircraft wing deflection measurement. AIAA Guidance Navigation and Control Conference. 2016;9–9. .

[25] [25] Xian, D., Su, Q., Fengwen, M. & Weiqi, J. Development of a 3x3-channel bionic compound eyes imaging system for target positioning. Proc. SPIE (USA) 11885, 118850V (118810 pp.)-118850V (118810 pp.), (2021).

[26] [26] Ma MC, Guo F, Cao ZL, Wang KY. Development of an artificial compound eye system for three-dimensional object detection. Applied Optics. 2014;53:1166–72. .10.1364/ao.53.001166

[27] [27] Jian HJ, He JZ, Jin XY, Chen XC, Wang KY. Automatic geometric calibration and three-dimensional detecting with an artificial compound eye. Applied Optics. 2017;56:1296–301. .10.1364/ao.56.001296

[28] [28] Pang K, Fang FZ, Song L, Zhang Y, Zhang HY. Bionic compound eye for 3D motion detection using an optical freeform surface. J Opt Soc Am B-Opt Phys. 2017;34:B28–35. .10.1364/josab.34.000b28

[29] [29] Li L, Hao YP, Xu JL, Liu FL, Lu J. The Design and Positioning Method of a Flexible Zoom Artificial Compound Eye. Micromachines. 2018;9:14. .10.3390/mi9070319

[30] [30] Kral K, Poteser M. Motion parallax as a source of distance information in locusts and mantids. J Insect Behav. 1997;10:145–63. .10.1007/bf02765480

[31] [31] Kapustjansky A, Chittka L, Spaethe J. Bees use three-dimensional information to improve target detection. Naturwissenschaften. 2010;97:229–33. .10.1007/s00114-009-0627-5

[32] [32] Zhang L, Zhan HY, Liu XY, Xing F, You Z. A wide-field and high-resolution lensless compound eye microsystem for real-time target motion perception. Microsyst Nanoeng. 2022;8:9. .10.1038/s41378-022-00388-w

[33] [33] Zhan H, et al. Analyzing the Effect of the Intra-Pixel Position of Small PSFs for Optimizing the PL of Optical Subpixel Localization. Engineering. 2023. .10.1016/j.eng.2023.03.009

[34] [34] Braddick O. VISUAL HYPERACUITY. Nature. 1984;308:228–9. .10.1038/308228a0

[35] [35] Liu B, He Z. Genetic Algorithm based MIMO Radar Polyphase Code Design. Journal of Electronic Measurement and Instrument. 2008;22:62–6.

[36] [36] Asim B. Advances in Theory and Applications of Stereo Vision. Croatia: INTECH d.o.o.; 2011. p 39–43.

[37] [37] Okutomi M, Kanade T. A MULTIPLE-BASE-LINE STEREO. IEEE Trans Pattern Anal Mach Intell. 1993;15:353–63. .10.1109/34.206955

[38] [38] Wang DK, Watkins C, Xie HK. MEMS Mirrors for LiDAR: A Review. Micromachines. 2020;11:24. .10.3390/mi11050456

[39] [39] Zhang, X. S., Kwon, K., Henriksson, J., Luo, J. H. & Wu, M. C. A large-scale microelectromechanical-systems-based silicon photonics LiDAR. Nature 603, 253-+, (2022).

[40] [40] Muralikrishnan B, Phillips S, Sawyer D. Laser trackers for large-scale dimensional metrology: A review. Precis Eng-J Int Soc Precis Eng Nanotechnol. 2016;44:13–28. .10.1016/j.precisioneng.2015.12.001

[41] [41] Vikas & Sahu, R. K. A review on application of laser tracker in precision positioning metrology of particle accelerators. Precis. Eng.-J. Int. Soc. Precis. Eng. Nanotechnol. 2021;71, 232-249, .

[42] [42] Katoch S, Chauhan SS, Kumar V. A review on genetic algorithm: past, present, and future. Multimed Tools Appl. 2021;80:8091–126. .10.1007/s11042-020-10139-6

[43] [43] Zhang, Y. F. et al. Conceptual design of the optical system of the 6.5m wide field multiplexed survey telescope with excellent image quality. PhotoniX. 2023;4:25,