Defocused contrast sensitivity function in peripheral vision.

Ophthalmic & physiological optics : the journal of the British College of Ophthalmic Opticians (Optometrists) Pub Date : 2022-03-01 Epub Date: 2021-12-12 DOI:10.1111/opo.12932

Durgasri Jaisankar, Marwan Suheimat, Robert Rosén, David A Atchison

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引用次数: 1

Abstract

Purpose: Human peripheral detection performance is affected by optical factors such as defocus and higher order aberrations. From optical theory, we would expect defocus to produce local depressions (notches) in the contrast sensitivity function (CSF). However, such notches have not been observed in peripheral vision, and it is unknown whether human peripheral vision can detect local depressions (notches) in the CSF, such as those produced by monochromatic defocus when all monochromatic ocular aberrations are corrected. The purpose of the study was to identify such notches.

Methods: Participants were three adult emmetropes. Following full adaptive optics correction, on-axis and 20° nasal visual field detection CSFs in monochromatic light were measured for the right eye with a 7 mm diameter pupil, both without and with ±2 D defocus, and with separate determinations for horizontal and vertical gratings. Defocused CSFs were compared with predictions based on theoretical modulation transfer functions.

Results: Notches in the monochromatic defocused CSFs were identified for peripheral vision at optically predicted spatial frequencies with other monochromatic ocular aberrations corrected, provided that there was adequate spatial frequency sampling. The spatial frequencies of notches were similar to those predicted from optical theory, but their depths (0.3 to 0.9 log unit) were smaller than predicted.

Conclusion: With fine spatial frequency sampling, notches were identified in defocused monochromatic CSFs when all other monochromatic ocular aberrations were corrected, both on-axis and at 20° eccentricity. Unless recognised as such, notches may contribute to noise in through-focus detection measurements of peripheral visual performance.

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散焦对比灵敏度在周边视觉中的作用。

目的:人体周边检测性能受到光学因素如离焦和高阶像差的影响。从光学理论来看，我们预计散焦会在对比灵敏度函数(CSF)中产生局部凹陷(缺口)。然而，在周围视觉中没有观察到这样的缺口，并且人类周围视觉是否可以检测到脑脊液中的局部凹陷(缺口)是未知的，例如当所有单色眼像差被纠正时，单色离焦产生的凹陷。这项研究的目的是确定这样的缺口。方法:研究对象为3名成年女性。在完全自适应光学校正后，在单色光下测量右眼的轴向和20°鼻视野检测csf，瞳孔直径为7 mm，无和±2 D离焦，水平和垂直光栅分别测定。将散焦CSFs与基于理论调制传递函数的预测结果进行了比较。结果:在光学预测的空间频率下，在单色散焦的csf中发现了周围视觉的缺口，并校正了其他单色眼像差，前提是有足够的空间频率采样。缺口的空间频率与光学理论预测的相似，但其深度(0.3 ~ 0.9 log单位)比预测的要小。结论:通过精细的空间频率采样，在所有其他单色眼像差(轴向和偏心20°)校正后，在离焦单色csf中发现了缺口。除非被识别出来，否则缺口可能会在周边视觉性能的透焦检测测量中造成噪声。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Ophthalmic & physiological optics : the journal of the British College of Ophthalmic Opticians (Optometrists)

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