Larry C. Andrews scite author profile

Overview: The purpose of this chapter is to introduce the basic features of a Gaussian-beam wave in both the plane of the transmitter and the plane of the receiver. Our main concentration of study involves the lowest-order mode or TEM 00 beam, but we also briefly introduce Hermite-Gaussian and LaguerreGaussian beams as higher-order modes, or additional solutions, of the paraxial wave equation. Each of these higher-order modes produces a pattern of multiple spots in the receiver plane as opposed to a single (circular) spot from a lowest-order beam wave. Consequently, the analysis of such beams is more complex than that of the TEM 00 beam. One advantage in working with the TEM 00 Gaussian-beam wave model is that it also includes the limiting classical cases of an infinite plane wave and a spherical wave.We facilitate the free-space analysis of Gaussian-beam waves by introducing two sets of nondimensional beam parameters-one set that characterizes the beam in the plane of the transmitter and another set that does the same in the plane of the receiver. The beam spot radius and phase front radius of curvature, as well as other beam properties, are readily determined from either set of beam parameters. For example, we use the beam parameters to identify the size and location of the beam waist and the geometric focus. The consistent use of these beam parameters in all the remaining chapters of the text facilitates the analysis of Gaussian-beam waves propagating through random media.When optical elements such as aperture stops and lenses exist at various locations along the propagation path, the method of ABCD ray matrices can be used to characterize these elements (including the free-space propagation between elements). By cascading the matrices in sequence, the entire optical path between the input and output planes can be represented by a single 2Â2 matrix. The use of these ray matrices, which is based on the paraxial approximation, greatly simplifies the treatment of propagation through several such optical elements. In later chapters we will extend this technique to propagation paths that also include atmospheric turbulence along portions of the path.

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Laser Beam Scintillation with Applications

Andrews

2001

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Mathematical model for the irradiance probability density function of a laser beam propagating through turbulent media

2001

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We develop a model for the probability density function (pdf) of the irradiance fluctuations of an optical wave propagating through a turbulent medium. The model is a two-parameter distribution that is based on a doubly stochastic theory of scintillation that assumes that small-scale irradiance fluctuations are modulated by large-scale irradiance fluctuations of the propagating wave, both governed by independent gamma distributions. The resulting irradiance pdf takes the form of a generalized K distribution that we term the gamma-gamma distribution. The two parameters of the gamma-gamma pdf are determined using a recently published theory of scintillation, using only values of the refractive-index structure parameter C n 2 (or Rytov variance) and inner scale l 0 provided with the simulation data. This enables us to directly calculate various log-irradiance moments that are necessary in the scaled plots. We make a number of comparisons with published plane wave and spherical wave simulation data over a wide range of turbulence conditions (weak to strong) that includes inner scale effects. The gamma-gamma pdf is found to generally provide a good fit to the simulation data in nearly all cases tested. © 2001 Society of Photo-Optical Instrumentation Engineers.

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Special Functions of Mathematics for Engineers

Andrews¹

1997

323

245

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Theory of optical scintillation

et al. 1999

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Larry C. Andrews

Laser Beam Propagation through Random Media

Laser Beam Scintillation with Applications

Mathematical model for the irradiance probability density function of a laser beam propagating through turbulent media

Special Functions of Mathematics for Engineers

Theory of optical scintillation

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