Park, Min-KyuPark, Chul-SoonHwang, Yong SeokKim, Eun-SooChoi, Duk-YongLee, Sang-Shin2022-10-122195-1071http://hdl.handle.net/1885/274471The light-field (LF) imaging technique can obtain the light intensity and directional ray distribution information by utilizing a microlens array (MLA). Based on the recoded 3D information, full-parallax or depth-slice images can be reconstructed. Due to the limited ray sampling rate of the MLA, however, conventional LF imaging schemes are fatally susceptible to a trade-off between the spatial and angular resolution. To mitigate this issue, a virtual-moving metalens array (VMMA) based on a multifunctional dielectric metasurface is proposed, which can laterally shift the sampling position without physical movement, by simply tailoring the polarization of incident beam. Thanks to the polarization-tailored VMMA, the LF imaging scheme is successfully realized to provide a fourfold enhanced spatial resolution without sacrificing the angular resolution.This research was supported by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education (no. 2018R1A6A1A03025242).application/pdfen-AU© 2020 Wiley-VCH GmbHlight-field imagingmetasurface lens arraymultifunctional metasurfacepolarization-dependent movable lens arrayresolution improvement202010.1002/adom.2020008202021-11-28