Quadratic approximation of high order Bessel Gaussian beams propagation through non-Kolmogorov and marine atmosphere

The quadratic approximation of the high order Bessel Gaussian beams propagation through the non-Kolmogorov and the marine atmosphere is studied in this paper. Based on the extended Huygens–Fresnel principle, the intensity of the Bessel Gaussian beams propagation through the turbulence atmosphere is a quadruple integral, which could be simplified to a double integral when the spherical wave structure function is approximate to a quadratic function. And the intensity calculated by the Rytov method is a triple integral and studied as a comparison. In this paper, the accuracy of two methods is analyzed and the applicable condition is provided. The result of the Gaussian beam is also calculated to verify to presumption. And there will be a large bias between the extended Huygens–Fresnel principle with the quadratic approximation and the Rytov method when the inner scale of the turbulence is small and the Rytov method is better at this circumstance. This paper provides the theoretical basis for the application of the quadratic approximation.

[1]  E. Wolf,et al.  Mode analysis of spreading of partially coherent beams propagating through atmospheric turbulence. , 2003, Journal of the Optical Society of America. A, Optics, image science, and vision.

[2]  L. Andrews,et al.  Laser Beam Propagation Through Random Media , 1998 .

[3]  A. Martín-Ruiz,et al.  Generation of J(0) Bessel beams with controlled spatial coherence features. , 2010, Optics express.

[4]  H. Eyyuboğlu,et al.  Propagation of higher order Bessel–Gaussian beams in turbulence , 2007 .

[5]  Andrew Forbes,et al.  Entangled Bessel beams , 2012, Optics & Photonics - Optical Engineering + Applications.

[6]  Yun Zhu,et al.  Propagation of the OAM mode carried by partially coherent modified Bessel-Gaussian beams in an anisotropic non-Kolmogorov marine atmosphere. , 2016, Journal of the Optical Society of America. A, Optics, image science, and vision.

[7]  J J Miceli,et al.  Comparison of Bessel and Gaussian beams. , 1988, Optics letters.

[8]  Bai Lu,et al.  Propagation of Bessel Gaussian beams through non-Kolmogorov turbulence based on Rytov theory. , 2018, Optics express.

[9]  F. Gori,et al.  Bessel-Gauss beams , 1987 .

[10]  Joseph Lipka,et al.  A Table of Integrals , 2010 .

[11]  Pu Ji-xiong,et al.  Propagation of Gauss?Bessel beams in turbulent atmosphere , 2009 .

[12]  Wang Wan-Jun,et al.  Propagation of annular cos-Gaussian beams through turbulence. , 2018, Journal of the Optical Society of America. A, Optics, image science, and vision.

[13]  Andrew Forbes,et al.  Generating and measuring nondiffracting vector Bessel beams. , 2013, Optics letters.

[14]  C. Young,et al.  A marine atmospheric spectrum for laser propagation , 2008 .

[15]  NIABASI,et al.  Long distance Bessel beam propagation through Kolmogorov turbulence , 2019 .

[16]  Miles J. Padgett,et al.  Entangled Bessel beams , 2014, Optics & Photonics - Optical Engineering + Applications.

[17]  Miceli,et al.  Diffraction-free beams. , 1987, Physical review letters.

[18]  O. Korotkova,et al.  Intensity fluctuations in J-Bessel–Gaussian beams of all orders propagating in turbulent atmosphere , 2008 .

[19]  Italo Toselli,et al.  Free space optical system performance for laser beam propagation through non-Kolmogorov turbulence , 2007, SPIE LASE.

[20]  Yanhua Shih,et al.  Virtual ghost imaging through turbulence and obscurants using Bessel beam illumination , 2012 .