Inferring path average C^2_n values in the marine environment

Vetelino, Frida Strömqvist; Grayshan, Katelyn; Young, Cynthia

doi:10.1364/josaa.24.003198

Cited by 27 publications

(8 citation statements)

References 15 publications

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“…Several experimental data and measurements indicate that the turbulence in the upper troposphere and stratosphere, or along nonhomogeneous path, deviates from predictions of the Kolmogorov model [2][3][4][5][6]. Other experiments showed that atmospheric turbulence in maritime environments can assume a different statistical behavior with respect to Kolmogorov [7][8][9][10][11][12][13]. In addition, anisotropy in stratospheric turbulent inhomogeneities has been experimentally investigated [14][15][16][17], and laboratory results have shown that turbulence can be anisotropic.…”

Section: Introductionmentioning

confidence: 99%

Light propagation through anisotropic turbulence

Toselli

Agrawal

Restaino³

2011

J. Opt. Soc. Am. A

134

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A wealth of experimental data has shown that atmospheric turbulence can be anisotropic; in this case, a Kolmogorov spectrum does not describe well the atmospheric turbulence statistics. In this paper, we show a quantitative analysis of anisotropic turbulence by using a non-Kolmogorov power spectrum with an anisotropic coefficient. The spectrum we use does not include the inner and outer scales, it is valid only inside the inertial subrange, and it has a power-law slope that can be different from a Kolmogorov one. Using this power spectrum, in the weak turbulence condition, we analyze the impact of the power-law variations α on the long-term beam spread and scintillation index for several anisotropic coefficient values ς. We consider only horizontal propagation across the turbulence cells, assuming circular symmetry is maintained on the orthogonal plane to the propagation direction. We conclude that the anisotropic coefficient influences both the long-term beam spread and the scintillation index by the factor ς 2−α .

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Section: Introductionmentioning

confidence: 99%

Light propagation through anisotropic turbulence

Toselli

Agrawal

Restaino³

2011

J. Opt. Soc. Am. A

134

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“…The traditional Kolmogorov spectrum is primarily used in theoretical studies due to its simplicity but is valid only in the inertial subrange. Recently the marine atmospheric refractivity spectrum that presents a multiplicative factor able to describe the aforementioned characteristic bump was proposed and takes the form [12] …”

Section: Marine Atmospheric Refractivity Spectral Modelmentioning

confidence: 99%

“…The effects of humidity over water make the optical waves' propagation more complicated [9,10], and the interaction between the humidity and temperature fluctuations in the marine atmosphere needs to be considered. Based on experimental data taken over the Salton Sea [10], recently a new analytic marine atmospheric refractivity spectrum has been developed [11,12], and it revealed a significant amplification of the characteristic bump compared with the terrestrial refractivity spectrum. The pronounced bump in the refractivity spectrum derived from the Salton Sea data is believed to generally represent the marine atmosphere [10].…”

Section: Introductionmentioning

confidence: 99%

“…The pronounced bump in the refractivity spectrum derived from the Salton Sea data is believed to generally represent the marine atmosphere [10]. Even though more experiments are necessary for its validation, this spectrum is a good candidate to describe atmospheric turbulence in a general marine environment [12]. It has been applied to investigate the optical waves' propagation through marine atmospheric turbulence [11,13,14].…”

Section: Introductionmentioning

confidence: 99%

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Temporal power spectra of irradiance scintillation for infrared optical waves’ propagation through marine atmospheric turbulence

Cui

2014

J. Opt. Soc. Am. A

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Current theoretical temporal power spectra models of an optical wave have been developed for terrestrial environments. The interactions between humidity and temperature fluctuations in the marine atmospheric environments make the marine atmospheric turbulence particularly challenging, and the optical waves' propagation through marine turbulence exhibits a different behavior with respect to terrestrial propagation. In this paper, the temporal power spectra of irradiance scintillation under weak marine atmospheric turbulence, which is one of the key temporal statistics to describe the correlation of irradiance fluctuations at different time instances, is investigated in detail both analytically and numerically. Closed-form expressions for the temporal power spectra of irradiance scintillation are derived for infrared plane and spherical waves under weak marine atmospheric turbulence, and they consider physically the influences of finite turbulence inner and outer scales. The final results indicate that the marine atmospheric turbulence brings more effects on the irradiance scintillation than the terrestrial atmospheric turbulence.

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“…Considering the effect of the inner-scale of turbulence, researchers [3] developed the irradiance fluctuation expressions of plane and spherical waves on the basis of the new maritime spectrum in weak optical turbulence. In maritime environments, Vetelino et al [4] proposed theoretical scintillation expressions under moderate-to-strong Kolmogorov turbulence. In weak non-Kolmogorov maritime atmospheric turbulence channels, scintillation and aperture averaging of Gaussian beams were investigated [5].…”

Section: Introductionmentioning

confidence: 99%

Spiral spectrum of Airy beams propagation through moderate-to-strong turbulence of maritime atmosphere

Zhu

Zhang

2016

Opt. Express

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The spatial coherence radius in moderate-to-strong maritime turbulence is derived on the basis of the modified Rytov approximation. Models are developed to simulate the spiral spectrum of Airy beams propagating through moderate-to-strong maritime turbulence. In the moderate-to-strong irradiance fluctuation region, we analyze the effects of maritime turbulence on the spread of the spiral spectrum of Airy beams in a horizontal propagation path. Results indicate that the increment in the inner-scale significantly increases the received power. By contrast, the outer-scale elicits a negligible effect on the received power if the ratio of the inner-scale to the outer-scale is less than 0.01. The outer-scale affects the received power only if the ratio is greater than 0.01. The performance of a light source is essential for the received power of Airy beams carrying orbital angular momentum (OAM) through moderate-to-strong maritime turbulence. Airy beams with longer wavelengths, smaller OAM numbers, larger radii of the main ring, and smaller diameters of the circular aperture are less affected by maritime turbulence. Autofocusing of Airy beams is beneficial for the propagation of the spiral spectrum in a certain propagation distance. These results contribute to the design of optical communication systems with OAM encoding for moderate-to-strong maritime turbulence.

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Inferring path average C^2_n values in the marine environment

Cited by 27 publications

References 15 publications

Light propagation through anisotropic turbulence

Light propagation through anisotropic turbulence

Temporal power spectra of irradiance scintillation for infrared optical waves’ propagation through marine atmospheric turbulence

Spiral spectrum of Airy beams propagation through moderate-to-strong turbulence of maritime atmosphere

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