[1] ALLEN L, BEIJERSBERGEN M W, SPREEUW R J C et al. Orbital angular momentum of light and the transformation of Laguerre-Gaussian laser modes[J]. Physical Review A, 45, 8185-8189(1992).

[2] LOU Y, CHEN CH Y, ZHAO Y W. Characteristics of Gaussian vortex beam in atmospheric turbulence transmission[J]. Chinese Optics, 10, 768-776(2017).

[3] LIU J, CHEN SH, WANG H Y et al. Amplifying orbital angular momentum modes in ring-core erbium-doped fiber[J]. Research, 2020, 7623751(2020).

[4] [4] LIU J Y, ZHANG J X, LIU J, et al. 1Pbps bital angular momentum fibreoptic transmission[J]. Light: Science & Applications, 2022, 11(1): 202.

[5] LIU Z Q, ZHANG H K, LIU K G et al. Data transmission under high scattering based on OAM-basis transmission matrix[J]. Optics Letters, 47, 4580-4583(2022).

[6] KONG A R, LEI T, WANG D W et al. Extending orbital angular momentum multiplexing to radially high orders for massive mode channels in fiber transmission[J]. Optics Letters, 48, 3717-3720(2023).

[7] LAMPERSKA W, MASAJADA J, DROBCZYŃSKI S et al. Optical vortex torque measured with optically trapped microbarbells[J]. Applied Optics, 59, 4703-4707(2020).

[8] STUHLMÜLLER N C X, FISCHER T M, DE LAS HERAS D. Colloidal transport in twisted lattices of optical tweezers[J]. Physical Review E, 106, 034601(2022).

[9] ZENG K, PU J J, XU X M et al. Gradient torque and its effect on rotational dynamics of optically trapped non-spherical particles in the elliptic Gaussian beam[J]. Optics Express, 31, 16582-16592(2023).

[10] WANG J Y, LI F F, KANG G G. Multiwavelength achromatic super-resolution focusing via a metasurface-empowered controlled generation of focused cylindrically polarized vortex beams[J]. Optics Express, 30, 30811-30821(2022).

[11] ZHAO D E, LI N L, MA Y Y. Characteristics of double-vortex optical interferogram based on shearing interference[J]. Laser & Optoelectronics Progress, 58, 1108001(2021).

[12] LIU Z L, LI M Y, LU X Y. On-machine detection technology and application progress of high dynamic range fringe structured light[J]. Chinese Optics, 17, 1-18(2024).

[13] MA J B, LI P, ZHOU Z H et al. Characteristics of fork-shaped fringes formed by off-axis interference of two vortex beams[J]. Journal of the Optical Society of America A, 38, 115-123(2021).

[14] COX M A, CELIK T, GENGA Y et al. Interferometric orbital angular momentum mode detection in turbulence with deep learning[J]. Applied Optics, 61, D1-D6(2022).

[15] QIN H, FU Q, TAN W et al. Highly accurate OAM mode detection network for ring Airy Gaussian vortex beams disturbed by atmospheric turbulence based on interferometry[J]. Journal of the Optical Society of America A, 40, 1319-1326(2023).

[16] SILVA J G, JESUS-SILVA A J, ALENCAR M A R C et al. Unveiling Square and triangular optical lattices: a comparative study[J]. Optics Letters, 39, 949-952(2014).

[17] LAN B, LIU CH, RUI D M et al. The topological charge measurement of the vortex beam based on dislocation self-reference interferometry[J]. Physica Scripta, 94, 055502(2019).

[18] CHEN T CH, LU X Y, ZENG J et al. Young's double-slit experiment with a partially coherent vortex beam[J]. Optics Express, 28, 38106-38114(2020).

[19] MELO L A, JESUS-SILVA A J, CHÁVEZ-CERDA S et al. Direct measurement of the topological charge in elliptical beams using diffraction by a triangular aperture[J]. Scientific Reports, 8, 6370(2018).

[20] ZHUANG J Q, XIONG H, YU T CH. Orbital angular momentum detection of vortex beam based on soft-edge aperture[J]. Optics and Precision Engineering, 30, 1394-1405(2022).

[21] WANG J Q, FU SH Y, SHANG Z J et al. Adjusted EfficientNet for the diagnostic of orbital angular momentum spectrum[J]. Optics Letters, 47, 1419-1422(2022).

[22] LI X J, SUN L M, HUANG J M et al. Research on orbital angular momentum recognition technology based on a convolutional neural network[J]. Sensors, 23, 971(2023).

[23] CHEN J, KE X ZH, YANG Y M. Laguerre-Gaussian beam diffraction and dispersion of the orbital angular momentum[J]. Acta Optica Sinica, 34, 0427001(2014).