[1] IGA K, KINOSHITA S, KOYAMA F. Microcavity GalaAs/GaAs surface-emitting laser with Ith=6 mA[J]. Electronics Letters, 23, 134-136(2007).

[2] LARSSON A. Advances in VCSELs for communication and sensing[J]. IEEE Journal of Selected Topics in Quantum Electronics, 17, 1552-1567(2011).

[3] MOENCH H, CARPAIJ M, GERLACH P et al. VCSEL-based sensors for distance and velocity[C], 9766, 97660A(2016).

[4] LIU A, WOLF P, LOTT J A et al. Vertical-cavity surface-emitting lasers for data communication and sensing[J]. Photonics Research, 7, 121-136(2019).

[5] LIN C K, TANDON A, DJORDJEV K et al. High-speed 985 nm bottom-emitting VCSEL arrays for chip-to-chip parallel optical interconnects[J]. IEEE Journal of Selected Topics in Quantum Electronics, 13, 1332-1339(2007).

[6] SAFAISINI R, JOSEPH J R, DANG G et al. Scalable high-power, high-speed CW VCSEL arrays[J]. Electronics Letters, 45, 414-415(2009).

[7] LIM Y L, NIKOLIC M, BERTLING K et al. Self-mixing imaging sensor using a monolithic VCSEL array with parallel readout[J]. Optics Express, 17, 5517-5525(2009).

[8] SAFAISINI R, JOSEPH J R, LEAR K L. Scalable high-CW-power high-speed 980-nm VCSEL arrays[J]. IEEE Journal of Quantum Electronics, 46, 1590-1596(2010).

[9] LIVERMAN S, BIALEK H, NATARAJAN A et al. VCSEL array-based gigabit free-space optical femtocell communication[J]. Journal of Lightwave Technology, 38, 1659-1667(2019).

[10] SEURIN J F, ZHOU D, XU G et al. High-efficiency VCSEL arrays for illumination and sensing in consumer applications[C], 9766, 97660D(2016).

[11] CHEN B, CLAUS D, RUSS D et al. Generation of a high-resolution 3D-printed freeform collimator for VCSEL-based 3D-depth sensing[J]. Optics Letters, 45, 5583-5586(2020).

[12] CHILLA J L A, BENWARE B, WATSON M E et al. Coherence of VCSEL's for holographic interconnects[J]. IEEE Photonics Technology Letters, 7, 449-451(1995).

[13] VERSCHAFFELT G, VANDER S G. Spatial coherence properties of pulsed red VCSELs[J]. IEEE Photonics Technology Letters, 28, 1026-1029(2016).

[14] VERSCHAFFELT G, CRAGGS G, PEETERS M L F et al. Spatially resolved characterization of the coherence area in the incoherent emission regime of a broad-area vertical-cavity surface-emitting laser[J]. IEEE Journal of Quantum Electronics, 45, 249-255(2009).

[15] PEETERS M, VERSCHAFFELT G, THIENPONT H et al. Spatial decoherence of pulsed broad-area vertical-cavity surface-emitting lasers[J]. Optics Express, 13, 9337-9345(2005).

[16] KNITTER S, LIU C, REDDING B et al. Coherence switching of a degenerate VECSEL for multimodality imaging[J]. Optica, 3, 403-406(2016).

[17] BIRKBECK A L, FLYNN R A, OZKAN M et al. VCSEL arrays as micromanipulators in chip-based biosystems[J]. Biomedical Microdevices, 5, 47-54(2003).

[18] REDDING B, BROMBERG Y, CHOMA M A et al. Full-field interferometric confocal microscopy using a VCSEL array[J]. Optics Letters, 39, 4446-4449(2014).

[19] CHEN Y, CAI Y, EYYUBOGLUH T et al. Scintillation properties of dark hollow beams in a weak turbulent atmosphere[J]. Applied Physics B, 90, 87-92(2008).

[20] CAI Y, CHEN Y, EYYUBOGLUH T et al. Scintillation index of elliptical Gaussian beam in turbulent atmosphere[J]. Optics Letters, 32, 2405-2407(2007).

[21] EYYUBOGLUH T, BAYKAL Y, SERMUTLU E et al. Scintillation advantages of lowest order Bessel–Gaussian beams[J]. Applied Physics B, 92, 229-235(2008).

[22] SHIRAI T, DOGARIU A, WOLF E. Mode analysis of spreading of partially coherent beams propagating through atmospheric turbulence[J]. Journal of the Optical Society of America A, 20, 1094-1102(2003).

[23] GBUR G, WOLF E. Spreading of partially coherent beams in random media[J]. Journal of the Optical Society of America A, 19, 1592-1598(2002).