Lynn Schmittwilken , Felix A. Wichmann , Marianne Maertens
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It is less studied how well these mechanisms account for sensitivity to more behaviourally relevant stimuli such as sharp edges at high contrast (i.e. object boundaries) which abound in the natural environment and have broader SF spectra. Here, we probe sensitivity to edges (2-AFC, edge localization) in the presence of broadband and narrowband noises. We use Cornsweet luminance profiles with peak frequencies at 0.5, 3 and 9 cpd as edge stimuli. To test how well mechanisms underlying sinusoidal contrast sensitivity can account for edge sensitivity, we implement a single- and a multi-scale model building upon standard spatial vision model components. Both models account for most of the data but also systematically deviate in their predictions, particularly in the presence of pink noise and for the lowest SF edge. These deviations might indicate a transition from contrast- to luminance-based detection at low SFs. 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Here, we probe sensitivity to edges (2-AFC, edge localization) in the presence of broadband and narrowband noises. We use Cornsweet luminance profiles with peak frequencies at 0.5, 3 and 9 cpd as edge stimuli. To test how well mechanisms underlying sinusoidal contrast sensitivity can account for edge sensitivity, we implement a single- and a multi-scale model building upon standard spatial vision model components. Both models account for most of the data but also systematically deviate in their predictions, particularly in the presence of pink noise and for the lowest SF edge. These deviations might indicate a transition from contrast- to luminance-based detection at low SFs. 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引用次数: 0
摘要
早期视觉处理的一个公认特征是对比敏感度函数(CSF),它描述了敏感度如何随视觉输入的空间频率(SF)内容而变化。对比敏感度函数促使人们开发出了现在的空间视觉标准模型。该模型通过方位和空间频率选择性通道中的活动来表示视觉输入,这些通道通过非线性重组来预测知觉决策。标准空间视觉模型已在低对比度的正弦光栅下进行了广泛测试,因为其狭窄的自旋光谱可以隔离潜在的自旋选择机制。至于这些机制如何解释对高对比度尖锐边缘(即物体边界)等行为相关刺激的敏感性,目前研究较少。在这里,我们探究了在宽带和窄带噪声存在的情况下对边缘的敏感性(2-AFC,边缘定位)。我们使用峰值频率为 0.5、3 和 9 cpd 的 Cornsweet 亮度曲线作为边缘刺激。为了测试正弦对比敏感性的基本机制如何解释边缘敏感性,我们在标准空间视觉模型组件的基础上建立了一个单尺度和多尺度模型。这两种模型都能解释大部分数据,但在预测方面也存在系统性偏差,尤其是在存在粉红噪声和最低 SF 边缘时。这些偏差可能表明,在低 SF 条件下,基于对比度的检测已过渡到基于亮度的检测。另外,它们也可能表明目前的空间视觉模型中存在缺失的部分。
Standard models of spatial vision mispredict edge sensitivity at low spatial frequencies
One well-established characteristic of early visual processing is the contrast sensitivity function (CSF) which describes how sensitivity varies with the spatial frequency (SF) content of the visual input. The CSF prompted the development of a now standard model of spatial vision. It represents the visual input by activity in orientation- and SF selective channels which are nonlinearly recombined to predict a perceptual decision. The standard spatial vision model has been extensively tested with sinusoidal gratings at low contrast because their narrow SF spectra isolate the underlying SF selective mechanisms. It is less studied how well these mechanisms account for sensitivity to more behaviourally relevant stimuli such as sharp edges at high contrast (i.e. object boundaries) which abound in the natural environment and have broader SF spectra. Here, we probe sensitivity to edges (2-AFC, edge localization) in the presence of broadband and narrowband noises. We use Cornsweet luminance profiles with peak frequencies at 0.5, 3 and 9 cpd as edge stimuli. To test how well mechanisms underlying sinusoidal contrast sensitivity can account for edge sensitivity, we implement a single- and a multi-scale model building upon standard spatial vision model components. Both models account for most of the data but also systematically deviate in their predictions, particularly in the presence of pink noise and for the lowest SF edge. These deviations might indicate a transition from contrast- to luminance-based detection at low SFs. Alternatively, they might point to a missing component in current spatial vision models.
期刊介绍:
Vision Research is a journal devoted to the functional aspects of human, vertebrate and invertebrate vision and publishes experimental and observational studies, reviews, and theoretical and computational analyses. Vision Research also publishes clinical studies relevant to normal visual function and basic research relevant to visual dysfunction or its clinical investigation. Functional aspects of vision is interpreted broadly, ranging from molecular and cellular function to perception and behavior. Detailed descriptions are encouraged but enough introductory background should be included for non-specialists. Theoretical and computational papers should give a sense of order to the facts or point to new verifiable observations. Papers dealing with questions in the history of vision science should stress the development of ideas in the field.