Chinese Journal of Mechanical Engineering >

2018 , Vol. 31 >Issue 1: 16 - 16

DOI: https://doi.org/10.1186/s10033-018-0204-y

Review

Fabrication of Microlens Array and Its Application: A Review

  • Wei Yuan ,
  • Li-Hua Li ,
  • Wing-Bun Lee ,
  • Chang-Yuen Chan
Expand
  • 1. State Key Laboratory of Ultra-precision Machining Technology, Partner Laboratory in the Hong Kong Polytechnic University, Hong Kong 999077, China;
    2. Shenzhen Branch of State Key Laboratory of Ultra-precision Machining Technology, PolyU Shenzhen Research Institute, Shenzhen 518000, China

Received date: 2016-10-19

  Online published: 2019-07-23

Fold

Abstract

Microlens arrays are the key component in the next generation of 3D imaging system, for it exhibits some good optical properties such as extremely large feld of view angles, low aberration and distortion, high temporal resolution and infnite depth of feld. Although many fabrication methods or processes are proposed for manufacturing such precision component, however, those methods still need to be improved. In this review, those fabrication methods are categorized into direct and indirect method and compared in detail. Two main challenges in manufacturing microlens array are identifed:how to obtain a microlens array with good uniformity in a large area and how to produce the microlens array on a curved surface? In order to efectively achieve control of the geometry of a microlens, indirect methods involving the use of 3D molds and replication technologies are suggested. Further development of ultraprecision machining technology is needed to reduce the surface fuctuation by considering the dynamics of machine tool in tool path planning. Finally, the challenges and opportunities of manufacturing microlens array in industry and academic research are discussed and several principle conclusions are drawn.

Key words: Microlens array; Ultraprecision machining; 3D image system; MEMS

Cite this article

Wei Yuan , Li-Hua Li , Wing-Bun Lee , Chang-Yuen Chan . Fabrication of Microlens Array and Its Application: A Review[J]. Chinese Journal of Mechanical Engineering, 2018 , 31(1) : 16 -16 . DOI: 10.1186/s10033-018-0204-y

References

[1] M F Land, D-E Nilsson. Animal eyes. Oxford University Press, 2012.
[2] M F Land. The optics of animal eyes. Contemporary Physics, 1988, 29(5): 435-455.
[3] G A Horridge. The separation of visual axes in apposition compound eyes. Philosophical Transactions of the Royal Society of London B: Biological Sciences, 1978, 285(1003): 1-59.
[4] M F Land. Variations in the structure and design of compound. Facets of Vision, 1989, 3: 30-73.
[5] Y Xu, S Yan, C Zhou, et al. Advances in bionic study on insects' compound eyes. Optical Technique, 2006, 32: 10-12.
[6] J Duparré, F Wippermann. Micro-optical artificial compound eyes. Bioinspiration & Biomimetics, 2006, 1(1): R1.
[7] J Tanida, R Shogenji, Y Kitamura, et al. Color imaging with an integrated compound imaging system. Optics Express, 2003, 11(18): 2109-2117.
[8] R Shogenji, Y Kitamura, K Yamada, et al. Bimodal fingerprint capturing system based on compound-eye imaging module. Applied Optics, 2004, 43(6): 1355-1359.
[9] R Horisaki, S Irie, Y Ogura, et al. Three-dimensional information acquisition using a compound imaging system. Optical Review, 2007, 14(5): 347-350.
[10] M Oikawa, K Iga, T Sanada, et al. Array of distributed-index planar microlenses prepared from ion exchange technique. Japanese Journal of Applied Physics, 1981, 20(4): L296.
[11] N F Borrelli, D L Morse, R H Bellman, et al. Photolytic technique for producing microlenses in photosensitive glass. Applied Optics, 1985, 24(16): 2520-2525.
[12] Z D Popovic, R A Sprague, G N Connell. Technique for monolithic fabrication of microlens arrays. Applied Optics, 1988, 27(7): 1281-1284.
[13] M Kubo, M Hanabusa. Fabrication of microlenses by laser chemical vapor deposition. Applied Optics, 1990, 29(18): 2755-2759.
[14] D M Hartmann, O Kibar, S Esener. Polymer microlens arrays fabricated using the hydrophobic effect. Proc. SPIE, 2000: 496-507.
[15] Y Fu, B K A Ngoi. Investigation of diffractive-refractive microlens array fabricated by focused ion beam technology. Optical Engineering, 2001, 40(4): 511-516.
[16] N Ong, Y Koh, Y Q Fu. Microlens array produced using hot embossing process. Microelectronic Engineering, 2002, 60(3): 365-379.
[17] P Merz, H J Quenzer, H Bernt, et al. A novel micromachining technology for structuring borosilicate glass substrates. TRANSDUCERS, Solid-State Sensors, Actuators and Microsystems, 12th International Conference on, 2003: 258-261.
[18] X Zhang, F Fang, L Yu, et al. Slow slide servo turning of compound eye lens. Optical Engineering, 2013, 52(2): 023401-023401.
[19] F Fang, X Zhang, X Hu. Cylindrical coordinate machining of optical freeform surfaces. Optics Express, 2008, 16(10): 7323-7329.
[20] X Liu, X Zhang, F Fang, et al. Influence of machining errors on form errors of microlens arrays in ultra-precision turning. International Journal of Machine Tools and Manufacture, 2015, 96: 80-93.
[21] D P Yu, G S Hong, Y San Wong. Profile error compensation in fast tool servo diamond turning of micro-structured surfaces. International Journal of Machine Tools and Manufacture, 2012, 52(1): 13-23.
[22] D Floreano, R Pericet-Camara, S Viollet, et al. Miniature curved artificial compound eyes. Proceedings of the National Academy of Sciences, 2013, 110(23): 9267-9272.
[23] Y M Song, Y Xie, V Malyarchuk, et al. Digital cameras with designs inspired by the arthropod eye. Nature, 2013, 497(7447): 95-99.
[24] M K Park, H J Lee, J S Park, et al. Design and fabrication of multi-focusing microlens array with different numerical apertures by using thermal reflow method. Journal of the Optical Society of Korea, 2014, 18(1): 71-77.
[25] M Levoy, R Ng, A Adams, et al. Light field microscopy. ACM Transactions on Graphics (TOG), 2006, 25(3): 924-934.
[26] R Stevens, T Miyashita. Review of standards for microlenses and microlens arrays. The Imaging Science Journal, 2010, 58(4): 202-212.
[27] R R Syms, E M Yeatman, V M Bright, et al. Surface tension-powered selfassembly of microstructures-the state-of-the-art. Journal of Microelectro-mechanical systems, 2003, 12(4): 387-417.
[28] H Yang, C K Chao, M K Wei, et al. High fill-factor microlens array mold insert fabrication using a thermal reflow process. Journal of Micromechanics and Microengineering, 2004, 14(8): 1197.
[29] S Moore, J Gomez, D Lek, et al. Experimental study of polymer microlens fabrication using partial-filling hot embossing technique. Microelectronic Engineering, 2016, 162: 57-62.
[30] S Di, H Lin, R Du. An artificial compound eyes imaging system based on mems technology. Robotics and Biomimetics (ROBIO), 2009 IEEE International Conference, 2009: 13-18.
[31] D Daly, R Stevens, M Hutley, et al. The manufacture of microlenses by melting photoresist. Measurement Science and Technology, 1990, 1(8): 759.
[32] S Haselbeck, H Schreiber, J Schwider, et al. Microlenses fabricated by melting a photoresist on a base layer. Optical Engineering-BellinghamInternational Society for Optical Engineering, 1993, 32: 1322-1322.
[33] T R Jay, M B Stern. Preshaping photoresist for refractive microlens fabrication. Opt. Eng., 1994, 33(11): 3552-3555.
[34] S Audran, B Faure, B Mortini, et al. Study of dynamical formation and shape of microlenses formed by the reflow method. Proc. SPIE, 2006: 61534D.
[35] C Y Chang, S Y Yang, L S Huang, et al. Fabrication of polymer microlens arrays using capillary forming with a soft mold of micro-holes array and UV-curable polymer. Optics Express, 2006, 14(13): 6253-6258.
[36] C Pan, T Wu, M Chen, et al. Hot embossing of micro-lens array on bulk metallic glass. Sensors and Actuators A: Physical, 2008, 141(2): 422-431.
[37] D Yao, P Nagarajan, L Li, et al. A two-station embossing process for rapid fabrication of surface microstructures on thermoplastic polymers. Polymer Engineering & Science, 2007, 47(4): 530-539.
[38] Y Ishii, S Koike, Y Arai, et al. Ink-jet fabrication of polymer microlens for optical-I/O chip packaging. Japanese Journal of Applied Physics, 2000, 39(3S): 1490.
[39] Y Luo, L Wang, Y Ding, et al. Direct fabrication of microlens arrays with high numerical aperture by ink-jetting on nanotextured surface. Applied Surface Science, 2013, 279: 36-40.
[40] J Y Kim, N B Brauer, V Fakhfouri, et al. Hybrid polymer microlens arrays with high numerical apertures fabricated using simple ink-jet printing technique. Optical Materials Express, 2011, 1(2): 259-269.
[41] J Y Kim, K Pfeiffer, A Voigt, et al. Directly fabricated multi-scale microlens arrays on a hydrophobic flat surface by a simple ink-jet printing technique. Journal of Materials Chemistry, 2012, 22(7): 3053-3058.
[42] X Zhu, L Zhu, H Chen, et al. Fabrication of high numerical aperture microlens array based on drop-on-demand generating of water-based molds.Optics & Laser Technology, 2015, 68: 23-27.
[43] J Albero, L Nieradko, C Gorecki, et al. Fabrication of spherical microlenses by a combination of isotropic wet etching of silicon and molding techniques. Optics Express, 2009, 17(8): 6283-6292.
[44] R Bitterli, T Scharf, H-P Herzig, et al. Fabrication and characterization of linear diffusers based on concave micro lens arrays. Optics Express, 2010, 18(13): 14251-14261.
[45] G Du, Q Yang, F Chen, et al. Direct fabrication of seamless roller molds with gapless and shaped-controlled concave microlens arrays. Optics Letters, 2012, 37(21): 4404-4406.
[46] X Meng, F Chen, Q Yang, et al. Simple fabrication of closed-packed IR microlens arrays on silicon by femtosecond laser wet etching. Applied Physics A, 2015, 121(1): 157-162.
[47] X J Yi, X Y Zhang, Y Li, et al. Microlens arrays formed by melting photoresist and ion beam milling. Proc. SPIE, 1998: 249-253.
[48] L Harriott, R Scotti, K Cummings, et al. Micromachining of integrated optical structures. Applied Physics Letters, 1986, 48(25): 1704-1706.
[49] E B Kley, T Possner, R Göring. Realization of micro-optic and integrated optic components by electron-beam-lithographic surface profiling and ion exchange in glass. International Journal of Optoelectronnics, 1993, 8: 513-513.
[50] T Fujita, H Nishihara, J Koyama. Fabrication of micro lenses using electronbeam lithography. Optics Letters, 1981, 6(12): 613-615.
[51] A Brückner, J Duparré, P Dannberg, et al. Artificial neural superposition eye. Optics Express, 2007, 15(19): 11922-11933.
[52] K H Jeong, J Kim, L P Lee. Biologically inspired artificial compound eyes. Science, 2006, 312(5773): 557-561.
[53] H Yu, G Zhou, F S Chau, et al. Fabrication and characterization of PDMS microlenses based on elastomeric molding technology. Optics Letters, 2009, 34(21): 3454-3456.
[54] K Wei, H Zeng, Y Zhao. Insect–Human Hybrid Eye (IHHE): an adaptive optofluidic lens combining the structural characteristics of insect and human eyes. Lab on a Chip, 2014, 14(18): 3594-3602.
[55] M Wang, T Wang, H Shen, et al. Subtle control on hierarchic reflow for the simple and massive fabrication of biomimetic compound eye arrays in polymers for imaging at a large field of view. Journal of Materials Chemistry C, 2016, 4(1): 108-112.
[56] E Brinksmeier, L Autschbach. Ball-end milling of free-form surfaces for optical mold inserts. Proceedings of 19th Annual Meeting of American Society for Precision Engineering (ASPE), 2004: 88-91.
[57] J Yan, Z Zhang, T Kuriyagawa, et al. Fabricating micro-structured surface by using single-crystalline diamond endmill. The International Journal of Advanced Manufacturing Technology, 2010, 51(9): 957-964.
[58] A Yi and L Li. Design and fabrication of a microlens array by use of a slow tool servo. Optics Letters, 2005, 30(13): 1707-1709.
[59] J Zhou, L Li, N Naples, et al. Fabrication of continuous diffractive optical elements using a fast tool servo diamond turning process. Journal of Micromechanics and Microengineering, 2013, 23(7): 075010.
[60] F Z Chen, C H Chen, C H Wu, et al. Development of a double-sided micro lens array for micro laser projector application. Optical Review, 2012, 19(4): 238-241.
[61] C Y Chan, L H Li, W B Lee, et al. Research on light field imaging based on compound eye ultra-precision machining. Journal of Mechanical Engineering, 2016, 52(17): 50-57.
[62] Z W Zhu, S To, W L Zhu, et al. Feasibility study of the novel quasi-elliptical tool servo for vibration suppression in the turning of micro-lens arrays. International Journal of Machine Tools and Manufacture, 2017, 122: 98-105.
[63] L Li, Y Y Allen. Development of a 3D artificial compound eye. Optics Express, 2010, 18(17): 18125-18137.
[64] L Li, Y Y Allen. Microfabrication on a curved surface using 3D microlens array projection. Journal of Micromechanics and Microengineering, 2009, 19(10): 105010.
[65] M Levoy, P Hanrahan. Light field rendering. Proceedings of the 23rd Annual Conference on Computer Graphics and Interactive Techniques, 1996: 31-42.
[66] E H Adelson, J Y Wang. Single lens stereo with a plenoptic camera. IEEE Transactions on Pattern Analysis and Machine Intelligence, 1992, 14(2): 99-106.
[67] B Wilburn, M Smulski, H-H K Lee, et al. The light field video camera.Media Processors 2002, 2002, 4674: 29-36.
[68] B Wilburn, N Joshi, V Vaish, et al. High performance imaging using large camera arrays. ACM Transactions on Graphics (TOG), 2005: 765-776.
[69] T Georgiev, C Intwala. Light field camera design for integral view photography. Adobe Technical Report, 2006.
[70] R Ng, M Levoy, M Brédif, et al. Light field photography with a hand-held plenoptic camera. Computer Science Technical Report CSTR, 2005, 2(11): 1-11.
[71] M W Tao, S Hadap, J Malik, et al. Depth from combining defocus and correspondence using light-field cameras. Proceedings of the IEEE International Conference on Computer Vision, 2013: 673-680.
[72] R Ueno, K Suzuki, M Kobayashi, et al. Compound-eye camera module as small as 8.5$times$8.5$times $6.0 mm for 26 k-Resolution Depth Map and 2-Mpix 2D Imaging. IEEE Photonics Journal, 2013, 5(4): 6801212-6801212.
Options
Outlines

/

  Copyright © Chinese Journal of Mechanical Engineering, All Rights Reserved.
Powered by Beijing Magtech Co. Ltd,.