Levi D M, Klein S A
University of Houston, College of Optometry, TX 77004.
Vision Res. 1990;30(12):1971-93. doi: 10.1016/0042-6989(90)90016-e.
We used Gaussian blurred stimuli to explore the effect of blur on three tasks: (i) 2-line "resolution"; (ii) line detection; and (iii) spatial interval discrimination, in both central and peripheral vision. The results of our experiments can be summarized as follows. (i) 2-Line "resolution": thresholds for pairs of unblurred, low contrast, stimuli are approx. 0.5 min arc in the fovea. When the stimulus blur is small, it has little effect upon 2-line "resolution"; however, when the stimulus blur, sigma, exceeds 0.5 min, thresholds are degraded. We operationally define this transition point as the equivalent intrinsic blur or Bi. When the standard deviation of the stimulus blur, sigma, is greater than Bi, then the "resolution" threshold is approximately equal to sigma. Both the unblurred "resolution" threshold, and the equivalent intrinsic blur, Bi, vary with eccentricity in a manner consistent with the variation of cone separation within the central 10 deg. When the stimulus blur exceeds the equivalent intrinsic blur, "resolution" in the periphery is the same as in the fovea. (ii) Line detection: when the standard deviation of the stimulus blur, sigma, is less than Bi, then the line detection threshold is approximately inversely proportional to sigma (it is approximately TdBi/sigma) i.e. it obeys Ricco's law. When the standard deviation of the stimulus blur, sigma, is greater than Bi, then the "resolution" threshold is approximately equal to sigma and the detection threshold is approximately a fixed contrast (to be referred to as Td). According to (i) and (ii), the equivalent intrinsic blur, Bi, plays a dual role in determining both the "resolution" threshold and the detection threshold, Bi corresponds to the "Ricco's diameter" for spatial summation in a detection task, and it also corresponds to the "resolution" threshold for thin lines. This connection between detection and "resolution" is somewhat surprising. (iii) Spatial interval discrimination: thresholds are proportional to the separation of the lines (i.e. Weber's law). At the optimal separation, the thresholds represent a "hyperacuity" (i.e. they are smaller than the "resolution" threshold). For unblurred lines, the optimal separation is approximately 2-3 times the "resolution" limit at all eccentricities, so the optimal separation varies with eccentricity at the same rate as the equivalent intrinsic blur, Bi. However, the optimal spatial interval threshold falls off with eccentricity about 3-4 times more rapidly, consistent with the rate of decline of other position acuity tasks.(ABSTRACT TRUNCATED AT 400 WORDS)
(i)双线“分辨率”;(ii)线条检测;以及(iii)空间间隔辨别。我们实验的结果可总结如下。(i)双线“分辨率”:未模糊、低对比度刺激对的阈值在中央凹约为0.5分视角。当刺激模糊较小时,对双线“分辨率”影响不大;然而,当刺激模糊度σ超过0.5分时,阈值会降低。我们将这个转变点定义为等效固有模糊或Bi。当刺激模糊的标准差σ大于Bi时,“分辨率”阈值大约等于σ。未模糊的“分辨率”阈值和等效固有模糊Bi都随偏心率变化,其方式与中央10度内视锥细胞间距的变化一致。当刺激模糊超过等效固有模糊时,周边的“分辨率”与中央凹相同。(ii)线条检测:当刺激模糊的标准差σ小于Bi时,线条检测阈值大约与σ成反比(约为TdBi/σ),即它遵循里科定律。当刺激模糊的标准差σ大于Bi时,“分辨率”阈值大约等于σ,检测阈值大约为固定对比度(称为Td)。根据(i)和(ii),等效固有模糊Bi在确定“分辨率”阈值和检测阈值方面都起着双重作用,Bi对应于检测任务中空间总和的“里科直径”,它也对应于细线的“分辨率”阈值。检测与“分辨率”之间的这种联系有点令人惊讶。(iii)空间间隔辨别:阈值与线条间距成正比(即韦伯定律)。在最佳间距时,阈值代表一种“超敏锐度”(即它们小于“分辨率”阈值)。对于未模糊的线条,在所有偏心率下,最佳间距大约是“分辨率”极限的2 - 3倍,所以最佳间距与等效固有模糊Bi以相同速率随偏心率变化。然而,最佳空间间隔阈值随偏心率下降的速度大约快3 - 4倍,这与其他位置敏锐度任务的下降速率一致。(摘要截断于400字)
