[1] BEHERA S, JOSEPH J. Demonstration of multi-imaging and multi-focusing through planar motheye kind of gradient microlens multi-array[J]. Optics Communications, 459, 125061(2020).

[2] ZHANG L, WANG C, ZHANG C et al. High-throughput two-photon 3D printing enabled by holographic multi-foci high-speed scanning[J]. Nano Letters, 24, 2671-2679(2024).

[3] BAUER T, ORLOV S, PESCHEL U et al. Nanointerferometric amplitude and phase reconstruction of tightly focused vector beams[J]. Nature Photonics, 8, 23-27(2014).

[4] GU M, LIN H, LI X. Parallel multiphoton microscopy with cylindrically polarized multifocal arrays[J]. Optics Letters, 38, 3627-3630(2013).

[5] CHA J W, SINGH V R, KIM K H et al. Reassignment of scattered emission photons in multifocal multiphoton microscopy[J]. Scientific Reports, 4, 5153(2014).

[6] MA Y, RUI G, GU B et al. Trapping and manipulation of nanoparticles using multifocal optical vortex metalens[J]. Scientific Reports, 7, 14611(2017).

[7] JIA B, LIN H, GU M. Dynamic generation of Debye diffraction-limited multifocal arrays for direct laser printing nanofabrication[J]. Optics Letters, 36, 406(2011).

[8] ZHU L, YANG R, ZHANG D et al. Dynamic three-dimensional multifocal spots in high numerical-aperture objectives[J]. Optics Express, 25, 24756-24766(2017).

[9] REN H, LI X, GU M. Polarization-multiplexed multifocal arrays by a π-phase-step-modulated azimuthally polarized beam[J]. Optics Letters, 39, 6771-6774(2014).

[10] MARSHEL J H, KIM Y S, MACHADO T A et al. Cortical layer–specific critical dynamics triggering perception[J]. Science, 365, eaaw5202(2019).

[11] FAINI G, TANESE D, MOLINIER C et al. Ultrafast light targeting for high-throughput precise control of neuronal networks[J]. Nature Communications, 14, 1888(2023).

[12] RUAN H, BRAKE J, ROBINSON J E et al. Deep tissue optical focusing and optogenetic modulation with time-reversed ultrasonically encoded light[J]. Science Advances, 3, eaao5520(2017).

[13] KIM D, HERMERSCHMIDT A, DYACHENKO P et al. Inverse design and demonstration of high-performance wide-angle diffractive optical elements[J]. Optics Express, 28, 22321-22333(2020).

[14] CHEN Z, ZBEK A, REBLING J et al. Multifocal structured illumination optoacoustic microscopy[J]. Light: Science & Applications, 9, 152(2020).

[15] LEE J H, CHANG S, KIM M S et al. High-identical numerical aperture, multifocal microlens array through single-step multi-sized hole patterning photolithography[J]. Micromachines, 11, 1068(2020).

[16] JEONG K H, BAE S I, KIM K S et al. Multifocal microlens arrays using multilayer photolithography[J]. Optics Express, 28, 9082-9088(2020).

[17] MERENDA F, ROHNER J, FOURNIER J M et al. Miniaturized high-NA focusing-mirror multiple optical tweezers[J]. Optics Express, 15, 6075-6086(2007).

[18] SHAO Y, QU J, LI H et al. High-speed spectrally resolved multifocal multiphoton microscopy[J]. Applied Physics B, 99, 633-637(2010).

[19] ZHANG L, WANG C, ZHANG C et al. High-throughput two-photon 3D printing enabled by holographic multi-foci high-speed scanning[J]. Nano Letters, 24, 2671-2679(2024).

[20] YU J, ZHOU C, LU Y et al. Square lattices of quasi-perfect optical vortices generated by two-dimensional encoding continuous-phase gratings[J]. Optics Letters, 40, 2513-2516(2015).

[21] WEN J, FENG H, LIU S et al. Arbitrary continuous nano-marks generated by multifocal spot arrays for controllable laser printing[J]. Laser Physics, 27, 046201(2017).

[22] NOGRETTE F, LABUHN H, RAVETS S et al. Single-atom trapping in holographic 2D arrays of microtraps with arbitrary geometries[J]. Physical Review X, 4, 021034(2014).

[23] LEONARDO R D, IANNI F, RUOCCO G. Computer generation of optimal holograms for optical trap arrays[J]. Optics Express, 15, 1913-1922(2007).

[24] WANG R X, ZHU J Y, CHANG C et al. Interdigitated photoconductive antenna pumped by reconfigurable structured light for terahertz emission and modulation[J]. IEEE Transactions on Microwave Theory and Techniques, 71, 3661-3667(2023).

[25] MIKHAYLOV D, ZHOU B, KIEDROWSKI T et al. High accuracy beam splitting using spatial light modulator combined with machine learning algorithms[J]. Optics and Lasers in Engineering, 121, 227-235(2019).

[26] LI Z L, ZHENG H Y, TEH K M et al. Analysis of oxide formation induced by UV laser coloration of stainless steel[J]. Applied Surface Science, 256, 1582-1588(2009).

[27] IONIN A A, KUDRYASHOV S I, MAKAROV S V et al. Femtosecond laser color marking of metal and semiconductor surfaces[J]. Applied Physics A, 107, 301-305(2012).

[28] SUN F, ZHU L, WANG W et al. Three-dimensional dynamic optical trapping using non-iterative computer-generated holography[J]. Optics and Lasers in Engineering, 164, 107500(2023).

[29] ZHANG T, LI M, QIU J et al. Multiple foci modulation with controllable positions and intensity ratios through decomposed optimization[J]. Optics Letters, 44, 2354-2357(2019).

[30] LEUTENEGGER M, RAO R, LEITGEB R A et al. Fast focus field calculations[J]. Optics Express, 14, 11277-11291(2006).

[31] YOUNGWORTH K, BROWN T. Focusing of high numerical aperture cylindrical-vector beams[J]. Optics Express, 7, 77-87(2000).

[32] RICHARDS B, WOLF E. Electromagnetic diffraction in optical systems. II. structure of the image field in an aplanatic system[J]. Proceedings of the Royal Society of London, 253, 358-379(1959).

[33] WENG X, SONG Q, LI X et al. Free-space creation of ultralong anti-diffracting beam with multiple energy oscillations adjusted using optical pen[J]. Nature Communications, 9, 5035(2018).

[34] PERSSON M, ENGSTRÖM D, GOKSÖR M. Reducing the effect of pixel crosstalk in phase only spatial light modulators[J]. Optics Express, 20, 22334-22343(2012).

[35] ENGSTRÖM D, MILEWSKI G, BENGTSSON J. Diffraction-based determination of the phase modulation for general spatial light modulators[J]. Applied Optics, 45, 7195-7204(2006).

[36] CHEN H, WANG N, HUANG Y et al. Generation of multi-focus shaping with high uniformity based on an improved Gerchberg-Saxton algorithm[J]. Applied Optics, 63, 3283-3289(2024).