Abstract
We examine depth perception in images of real scenes with naturalistic variation in pictorial depth cues, simulated dioptric blur and binocular disparity. Light field photographs of natural scenes were taken with a Lytro plenoptic camera that simultaneously captures images at up to 12 focal planes. When accommodation at any given plane was simulated, the corresponding defocus blur at other depth planes was extracted from the stack of focal plane images. Depth information from pictorial cues, relative blur and stereoscopic disparity was separately introduced into the images. In 2AFC tasks, observers were required to indicate which of two patches extracted from these images was farther. Depth discrimination sensitivity was highest when geometric and stereoscopic disparity cues were both present. Blur cues impaired sensitivity by reducing the contrast of geometric information at high spatial frequencies. While simulated generic blur may not assist depth perception, it remains possible that dioptric blur from the optics of an observer’s own eyes may be used to recover depth information on an individual basis. The implications of our findings for virtual reality rendering technology are discussed.
Highlights
Many vertebrate and invertebrate visual systems have evolved multiple mechanisms that, in principle, allow them to estimate depth information from natural scenes
With the same technology employed in the current study, that the distribution of blur arising from light field photographs of natural images can be employed to facilitate binocular fusion and modify eye movement behavior [23]
When disparity cues were introduced alongside pictorial cues, discrimination improved significantly (d’ = 2.14, 95% confidence intervals [1.91 2.40], p = 10−7)
Summary
Many vertebrate and invertebrate visual systems have evolved multiple mechanisms that, in principle, allow them to estimate depth information from natural scenes. Organisms with overlapping binocular visual fields can use stereoscopic disparity to reliably estimate depth. Organisms with a narrow depth of field and adequate spatial resolution can use differences in optical blur between image regions to estimate their relative depths, the direction of depth difference requires the ability estimate differences in the phase as well as amplitude spectrum of formed images. Visually cognitive organisms that can employ top-down processing and memory, may encode static pictorial cues, dynamic optic flow cues and use knowledge about the relative sizes of identified objects to estimate their relative depths. Blakemore [1] was the first to extensively study the range of depth discrimination due PLOS ONE | DOI:10.1371/journal.pone.0140230. Blakemore [1] was the first to extensively study the range of depth discrimination due PLOS ONE | DOI:10.1371/journal.pone.0140230 October 8, 2015
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