Scintillation analysis of truncated Bessel beams via numerical turbulence propagation simulation

Scintillation aspects of truncated Bessel beams propagated through atmospheric turbulence are investigated using a numerical wave optics random phase screen simulation method. On-axis, aperture averaged scintillation and scintillation relative to a classical Gaussian beam of equal source power and s...

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Veröffentlicht in:	Applied optics (2004) 2013-11, Vol.52 (33), p.8032-8039
Hauptverfasser:	Eyyuboğlu, Halil T, Voelz, David, Xiao, Xifeng
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Sprache:	eng
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container_end_page	8039
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container_title	Applied optics (2004)
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creator	Eyyuboğlu, Halil T Voelz, David Xiao, Xifeng
description	Scintillation aspects of truncated Bessel beams propagated through atmospheric turbulence are investigated using a numerical wave optics random phase screen simulation method. On-axis, aperture averaged scintillation and scintillation relative to a classical Gaussian beam of equal source power and scintillation per unit received power are evaluated. It is found that in almost all circumstances studied, the zeroth-order Bessel beam will deliver the lowest scintillation. Low aperture averaged scintillation levels are also observed for the fourth-order Bessel beam truncated by a narrower source window. When assessed relative to the scintillation of a Gaussian beam of equal source power, Bessel beams generally have less scintillation, particularly at small receiver aperture sizes and small beam orders. Upon including in this relative performance measure the criteria of per unit received power, this advantageous position of Bessel beams mostly disappears, but zeroth- and first-order Bessel beams continue to offer some advantage for relatively smaller aperture sizes, larger source powers, larger source plane dimensions, and intermediate propagation lengths.
doi_str_mv	10.1364/AO.52.008032
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title	Scintillation analysis of truncated Bessel beams via numerical turbulence propagation simulation
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