[1] CAI Z W, CHEN J W, PEDRINI G C et al. Lensless light-field imaging through diffuser encoding[J]. Light: Science & Applications, 9, 143(2020).

[2] WU G X, NG S W L, ZHOU Y et al. Dynamic nano-imaging via a microsphere compound lens integrated microfluidic device with a 10× objective lens[J]. Lab on a Chip, 23, 3070-3079(2023).

[3] ZHONG Y, YU H, WEN Y et al. Novel optofluidic imaging system integrated with tunable microlens arrays[J]. ACS Applied Materials & Interfaces, 15, 11994-12004(2023).

[4] YUAN R Y, MA X L, CHU F et al. Optofluidic lenticular lens array for a 2D/3D switchable display[J]. Optics Express, 29, 37418-37428(2021).

[5] ZHOU X T, PENG Y Y, PENG R et al. Fabrication of large-scale microlens arrays based on screen printing for integral imaging 3D display[J]. ACS Applied Materials & Interfaces, 8, 24248-24255(2016).

[6] ZHANG L, ZHOU L Y, ZHOU W C et al. Design, fabrication and testing of a compact large-field-of-view infrared compound eye imaging system by precision glass molding[J]. Precision Engineering, 66, 87-98(2020).

[7] ELSHERIF M, MOREDDU R, HASSAN M U et al. Real-time optical fiber sensors based on light diffusing microlens arrays[J]. Lab on a Chip, 19, 2060-2070(2019).

[8] CHEN X, ZHANG G, WANG M Y et al. A thin format vision-based tactile sensor with a Microlens Array (MLA)[J]. IEEE Sensors Journal, 22, 22069-22076(2022).

[9] LIANG Y, ZHU T F, DU X L et al. Fabrication of a microlens array on diamond for Shack-Hartmann sensor[J]. Diamond and Related Materials, 121, 108783(2022).

[10] HU Y L, RAO S L, WU S Z et al. All‐glass 3D optofluidic microchip with built‐in tunable microlens fabricated by femtosecond laser‐assisted etching[J]. Advanced Optical Materials, 6, 1701299(2018).

[11] LIU X Q, YU L, YANG S N et al. Optical nanofabrication of concave microlens arrays[J]. Laser & Photonics Reviews, 13, 1800272(2019).

[12] LIU F, BIAN H, ZHANG F et al. IR artificial compound eye[J]. Advanced Optical Materials, 8, 1901767(2019).

[13] LI M J, YANG T Z, YANG Q et al. Bioinspired anti‐fogging and anti‐fouling artificial compound eyes[J]. Advanced Optical Materials, 10, 2200861(2022).

[14] LIU X Q, YANG S N, YU L et al. Rapid engraving of artificial compound eyes from curved sapphire substrate[J]. Advanced Functional Materials, 29, 1900037(2019).

[15] JIN H N, GAO X Y, REN K L et al. Review on piezoelectric actuators based on high-performance piezoelectric materials[J]. IEEE Transactions on Ultrasonics, 69, 3057-3069(2022).

[16] MENG Q H, HU J L. A review of shape memory polymer composites and blends[J]. Composites Part A: Applied Science and Manufacturing, 40, 1661-1672(2009).

[17] CAO J J, HOU Z S, TIAN Z N et al. Bioinspired zoom compound eyes enable variable-focus imaging[J]. ACS Applied Materials & Interfaces, 12, 10107-10117(2020).

[18] ZHANG Dawei. Styrene shape-memory polymer and its study of optical and magnetic actuation[D], 3-20(2011).

[19] XIE T, ROUSSEAU I A. Facile tailoring of thermal transition temperatures of epoxy shape memory polymers[J]. Polymer, 50, 1852-1856(2009).

[20] XIA Y L, HE Y, ZHANY F H et al. A review of shape memory polymers and composites: mechanisms, materials, and applications[J]. Advanced Materials, 33, 2000713(2021).

[21] ZHU Guangming[M]. Shape memory polymers and their applications, 28-40(2002).

[22] LIANG L, HU X J, SHI Y et al. Tunable and dynamic optofluidic microlens arrays based on droplets[J]. Analytical Chemistry, 94, 14938-14946(2022).

[23] DAI H T, LIU Y J, SUN X W et al. A negative-positive tunable liquid-crystal microlens array by printing[J]. Optics Express, 17, 4317-4323(2009).

[24] LI Y, LIU Y J, LUO D. A photo-switchable and photo-tunable microlens based on chiral liquid crystals[J]. Journal of Materials Chemistry C, 7, 15166-15170(2019).