https://orcid.org/0000-0002-4310-5473
References
- Ren Y, Xie G, Huang H, et al. Adaptive optics compensation of multiple orbital angular momentum beams propagating through emulated atmospheric turbulence. Opt Lett. 2014;39:2845–2848.
- Wang WB, Gozali R, Shi L, et al. Deep transmission of Laguerre-Gaussian vortex beams through turbid scattering media. Opt Lett. 2016;41:2069–2072.
- Huang H, Milione G, Lavery MPJ, et al. Mode division multiplexing using an orbital angular momentum mode sorter and MIMO-DSP over a graded-index few-mode optical fibre. Sci Rep. 2015;5:14931.
- Pors B-J, Monken CH, Eliel ER, et al. Transport of orbital-angular-momentum entanglement through a turbulent atmosphere. Opt Express. 2011;19:6671–6683.
- He H, Heckenberg NR, Rubinsztein-Dunlop H. Optical particle trapping with higher-order doughnut beams produced using high efficiency computer generated holograms. J Modern Opt. 1995;42:217–223.
- O'neil AT, Courtial J. Mode transformations in terms of the constituent Hermite-Gaussian or Laguerre-Gaussian modes and the variable-phase mode converter. Opt Commun. 2000;181:35–45.
- O'neil AT, Courtial J. An experiment to observe the intensity and phase structure of Laguerre-Gaussian laser modes. Am J Phys. 2000;64:77–82.
- Bekshaev A, Orlinska O, Vasnetsov M. Optical vortex generation with a ‘fork'hologram under conditions of high-angle diffraction. Opt Commun. 2010;283:2006–2016.
- Kotlyar VV, Kovalev AA, Porfirev AP. Astigmatic transforms of an optical vortex for measurement of its topological charge. Appl Opt. 2017;56:4095–4104.
- Courtial J, Padgett MJ. Performance of a cylindrical lens mode converter for producing Laguerre-Gaussian laser modes. Opt Commun. 1998;159:13–18.
- Reddy SG, Prabhakar S, Aadhi A, et al. Propagation of an arbitrary vortex pair through an astigmatic optical system and determination of its topological charge. J Opt Soc Am A. 2014;31:1295–1302.
- Mamani S, Bendau E, Secor J, et al. Hybrid generation and analysis of vector vortex beams. Appl Opt. 2017;56:2171–2175.
- Beijersbergen MW, Allen L, van der Veen HELO, et al. Astigmatic laser mode converters and transfer of orbital angular momentum. Opt Commun. 1993;96:123–132.
- Anguita J, Neifeld M, Vasic B. Turbulence induced channel crosstalk in an orbital angular momentum multiplexed free space optical link. Appl Opt. 2008;47:2414–2429.
- Funes G, Vial M, Anguita J. Orbital-angular-momentum crosstalk and temporal fading in a terrestrial laser link using single-mode fiber coupling. Opt Express. 2015;23:23133–23142.
- Funes G, Anguita J. On the cancellation of OAM beams propagating through convective turbulence. Opt Lett. 2017;42:1836–1839.
- Andrews C, Phillips RL. Laser beam propagation through random media. Bellingham: SPIE; 1998.
- Lane RG, Glindemann A, Dainty JC. Simulation of a Kolmogorov phase screen. Waves Random Media. 1992;2:1836–1839.
- Johansson EM, Gavel DT. Simulation of stellar speckle imaging. In Proceedings of SPIE. Vol. 2200. Amplitude and Intensity Spatial Interferometry II; 1994.
- Schmidt JD. Numerical simulation of optical wave propagation. Bellingham: SPIE; 2010.
- Olivares F, Funes G, Prez DG. Turbulence-induced power drops as extreme events. Opt Laser Eng. 2019;116:111–115.
- Tatarski VI. Wave propagation in a turbulent medium. Garden City (NY): Dover Publications; 1961, reissue (2016).
- Fried DL. Statistics of a geometric representation of wavefront distortion. J Opt Soc Am. 1965;55:1427–1435.
- Noll RJ. Zernike polynomials and atmospheric turbulence. J Opt Soc Am. 1976;66:207–211.
- Zernike Matlab program created by Paul Fricker (last version 2012). Zernike decomposition program created by Christopher Wilcox and Freddie Santiago (Last version 2010), adapted by Carlos Pirela (2018)
- Tyson R. Principles of adaptive optics. 4th ed. Boca Raton (FL): CRC Press; 2015.
- Roddier NA. Atmospheric wavefront simulation using Zernike polynomials. Opt Eng. 1990;29:1174–1180.