Simultaneous modulation of beam intensity and wavefront with freeform surfaces on the off-axis target plane (invited)

Fanqi Shen; Yuqin Chen; Lin Yang; Jun She; Kai Chen; Jianming Huang; Rengmao Wu

doi:10.3788/IRLA20230323

[1] J Reimers, A Bauer, K P Thompson, et al. Freeform spectrometer enabling increased compactness. Light: Science & Applications, 6, e17026(2017).

[2] P Ge, Y Li, Z Chen, et al. LED high-beam headlamp based on free-form microlenses. Applied Optics, 53, 5570-5575(2014).

[3] Z Zhu, S Wei, R Liu, et al. Freeform surface design for high-efficient LED low-beam headlamp lens. Optics Communi-cations, 477, 126269(2020).

[4] P Ge, K Zhang, L Mao, et al. An off-axis, reflective system for uniform near-field illumination in optical microscopy. Ligh-ting Research & Technology, 50, 787-795(2018).

[5] Taege Y, Schulz S L, Messerscht B, et al. A miniaturized illumination unit f airy lightsheet microscopy using 3Dprinted freefm optics[C]Imaging Systems Applications, 2022. US: Optica Publishing Group, 2022: IW3C.1.

[6] L Yang, Y Liu, Z Ding, et al. Design of freeform lenses for illuminating hard-to-reach areas through a light-guiding system. Optics Express, 28, 38155-38168(2020).

[7] Y Jin, A Hassan, Y Jiang. Freeform microlens array homogenizer for excimer laser beam shaping. Optics Express, 24, 24846-24858(2016).

[8] Z Feng, B D Froese, R Liang, et al. Simplified freeform optics design for complicated laser beam shaping. Applied Optics, 56, 9308-9314(2017).

[9] X Mao, J Li, F Wang, et al. Fast design method of the smooth freeform lens with an arbitrary aperture for collimated beam shaping. Applied Optics, 58, 2512-2521(2019).

[10] T Yang, Y Wang, D Ni, et al. Design of off-axis reflective imaging systems based on freeform holographic elements. Optics Express, 30, 20117-20134(2022).

[11] Y Wang, T Yang, D Ni, et al. Design of an off-axis near-eye AR display system based on a full-color freeform holographic optical element. Optics Letters, 48, 1288-1291(2023).

[12] Z Feng, L Huang, M Gong, et al. Beam shaping system design using double freeform optical surfaces. Optics Express, 21, 14728-14735(2013).

[13] Z Feng, L Huang, G Jin, et al. Designing double freeform optical surfaces for controlling both irradiance and wavefront. Optics Express, 21, 28693-28701(2013).

[14] Y Zhang, R Wu, P Liu, et al. Double freeform surfaces design for laser beam shaping with Monge-Ampère equation method. Optics Communications, 331, 297-305(2014).

[15] S Wei, Z Zhu, Z Fan, et al. Double freeform surfaces design for beam shaping with non-planar wavefront using an integrable ray mapping method. Optics Express, 27, 26757-26771(2019).

[16] L L Doskolovich, M A Moiseev, E A Bezus, et al. On the use of the supporting quadric method in the problem of the light field eikonal calculation. Optics Express, 23, 19605-19617(2015).

[17] D A Bykov, L L Doskolovich, E V Byzov, et al. Supporting quadric method for designing refractive optical elements generating prescribed irradiance distributions and wavefronts. Optics Express, 29, 26304-26318(2021).

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