Model for Predicting the Effects of Laser Exposures and Eye Protection on Vision

Abstract

Laser safety standards and eye protection (filters) are designed to limit ocular exposures to prevent retinal lesions, yet 'eyesafe' laser exposures can disrupt vision by causing glare and flashblindness. Protective filters can have opposing effects on vision function. They reduce laser exposures but also reduce task luminance and contrast. Filters alone may interfere with vision and consequently reduce work safety and performance. It is therefore important to be able to predict the effects of both laser exposures and protective filters to assess trade-offs between protection and visual function. This paper briefly reviews the methods, concepts, and experimental database used in our laboratory to predict laser, filter, and laser-plus-filter effects on tasks involving visual detection. The modeling approach uses estimates of the spatial distribution of light in the retinal image of the laser source to predict glare, flashblindness, and retinal lesions. It also considers the non-uniformity of visual abilities across the retina in predicting the impact of a laser exposure of a given size and retinal location. The proposed modeling approach provides a general framework for the interpretation, integration, and application of data from various studies. It has the potential to assess the effects of lasers and eye-protection devices on vision, and to guide visual simulations of the appearance of displays and scenes after laser exposures. The model is far from complete and is complicated by the number of variables affecting laser exposures, vision, and the role of vision in occupational tasks. Keywords: Vision; Vision models; Lasers; Glare; Adaptation flashblindness; Scotoma; Eye protection.

Document Details

Document Type

Technical Report

Publication Date

Jan 01, 1990

Accession Number

ADA219697

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