Philip B. Chapple scite author profile

The Z-scan technique is a popular method for measuring degenerate (single frequency) optical nonlinearities using a single laser beam. In order to perform reliable measurements, it is necessary to carefully characterize and control a number of experimental parameters, such as the beam quality, the power and temporal characteristics of the laser, the collection aperture size and position, the sample reflectivity, sample thickness and imperfections in the sample. Failure to control these parameters leads to inaccurate determinations of the nonlinearities. In this paper, we review the theory of Z-scan and examine each of these issues from experimental and theoretical viewpoints. This work will be of interest to anyone who performs Z-scan experiments and to those interested in optical power limiting and nonlinear optical propagation.

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Z-scan studies in the thin- and the thick-sample limits

Chapple

Staromlynska

McDuff

1994

J. Opt. Soc. Am. B

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Beam waist and M2 measurement using a finite slit

Chapple

1994

Opt. Eng

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Stochastic model-based processing for detection of small targets in non-Gaussian natural imagery

Chapple

Bertilone²,

Caprari³

et al. 2001

IEEE Trans. on Image Process.

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Stochastic background models incorporating spatial correlations can be used to enhance the detection of targets in natural terrain imagery, but are generally difficult to apply when the statistics are non-Gaussian. Chapple and Bertilone (see Opt. Commun., vol.150, p.71-76, 1998) proposed a simple stochastic model for images of natural backgrounds based on the pointwise nonlinear transformation of Gaussian random fields, and demonstrated its effectiveness and computational efficiency in modeling the textures found in natural terrain imagery acquired from airborne IR sensors. In this paper, we show how this model can be used to design algorithms that detect small targets (up to several pixels in size) in natural imagery by identifying anomalous regions of the image where the statistics differ significantly from the rest of the background. All of the model-based algorithms described here involve nonlinear spatial processing prior to the final decision threshold. Monte Carlo testing reveals that the model-based algorithms generally perform better than both the adaptive threshold filter and the generalized matched filter for detecting low-contrast targets, despite the fact that they do not require the target statistics needed for constructing the matched filter.

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<title>Platinum ethynyl compound for optical limiting</title>

Staromlynska

Chapple

Davy

et al. 1994

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Philip B. Chapple

Single-Beam Z-Scan: Measurement Techniques and Analysis

Z-scan studies in the thin- and the thick-sample limits

Beam waist and M2 measurement using a finite slit

Stochastic model-based processing for detection of small targets in non-Gaussian natural imagery

<title>Platinum ethynyl compound for optical limiting</title>

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