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Main Authors: Sadhukhan, Shouvik, Narayanamurthy, C. S.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.07058
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author Sadhukhan, Shouvik
Narayanamurthy, C. S.
author_facet Sadhukhan, Shouvik
Narayanamurthy, C. S.
contents We present a unified theoretical framework linking second and fourth order statistical correlations of stochastic electromagnetic beams to the scintillation index observed after propagation through Kolmogorov atmospheric turbulence. We derive the beam coherence polarization matrix and its propagation law in a random medium. An algebraic connection is established between the second order polarization matrix J, its fourth order Gram counterpart obtained from the square of J, the classical degree of polarization P, the fourth order degree of polarization, and the scintillation index of the beam intensity. A key result is a closed form purity relation connecting the trace of the squared polarization matrix to the square of its trace, which shows that unpolarized natural beams exhibit a large scintillation index. The analysis demonstrates that scintillation can be reduced by polarizing the beam using suitable polarizer sets. This reduction occurs independently of the atmospheric turbulence strength parameter. Experimental results further show that simultaneous control of coherence and polarization, achievable using a pseudo random phase plate, provides a practical approach for minimizing scintillation in free space optical communication links.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07058
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Spatio-Temporal Scintillation Mitigation via Polarizations Coupled Higher-Order Correlation
Sadhukhan, Shouvik
Narayanamurthy, C. S.
Optics
We present a unified theoretical framework linking second and fourth order statistical correlations of stochastic electromagnetic beams to the scintillation index observed after propagation through Kolmogorov atmospheric turbulence. We derive the beam coherence polarization matrix and its propagation law in a random medium. An algebraic connection is established between the second order polarization matrix J, its fourth order Gram counterpart obtained from the square of J, the classical degree of polarization P, the fourth order degree of polarization, and the scintillation index of the beam intensity. A key result is a closed form purity relation connecting the trace of the squared polarization matrix to the square of its trace, which shows that unpolarized natural beams exhibit a large scintillation index. The analysis demonstrates that scintillation can be reduced by polarizing the beam using suitable polarizer sets. This reduction occurs independently of the atmospheric turbulence strength parameter. Experimental results further show that simultaneous control of coherence and polarization, achievable using a pseudo random phase plate, provides a practical approach for minimizing scintillation in free space optical communication links.
title Spatio-Temporal Scintillation Mitigation via Polarizations Coupled Higher-Order Correlation
topic Optics
url https://arxiv.org/abs/2603.07058