TY - JOUR
T1 - Temporal encoding of spatial information during active visual fixation
AU - Kuang, Xutao
AU - Poletti, Martina
AU - Victor, Jonathan D.
AU - Rucci, Michele
N1 - Funding Information:
This work was supported by National Institutes of Health (NIH) grants EY07977 and EY09314 to J.D.V. and NIH grant EY18363 and National Science Foundation grants BCS-0719849, BCS-1127216, and IOS-0843304 to M.R. The authors thank Antonino Casile and Eric Schwartz for helpful comments.
PY - 2012/3/20
Y1 - 2012/3/20
N2 - Humans and other species continually perform microscopic eye movements, even when attending to a single point [1-3]. These movements, which include drifts and microsaccades, are under oculomotor control [2, 4, 5], elicit strong neural responses [6-11], and have been thought to serve important functions [12-16]. The influence of these fixational eye movements on the acquisition and neural processing of visual information remains unclear. Here, we show that during viewing of natural scenes, microscopic eye movements carry out a crucial information-processing step: they remove predictable correlations in natural scenes by equalizing the spatial power of the retinal image within the frequency range of ganglion cells' peak sensitivity. This transformation, which had been attributed to center-surround receptive field organization [17-19], occurs prior to any neural processing and reveals a form of matching between the statistics of natural images and those of normal eye movements. We further show that the combined effect of microscopic eye movements and retinal receptive field organization is to convert spatial luminance discontinuities into synchronous firing events, beginning the process of edge detection. Thus, microscopic eye movements are fundamental to two goals of early visual processing: redundancy reduction [20, 21] and feature extraction.
AB - Humans and other species continually perform microscopic eye movements, even when attending to a single point [1-3]. These movements, which include drifts and microsaccades, are under oculomotor control [2, 4, 5], elicit strong neural responses [6-11], and have been thought to serve important functions [12-16]. The influence of these fixational eye movements on the acquisition and neural processing of visual information remains unclear. Here, we show that during viewing of natural scenes, microscopic eye movements carry out a crucial information-processing step: they remove predictable correlations in natural scenes by equalizing the spatial power of the retinal image within the frequency range of ganglion cells' peak sensitivity. This transformation, which had been attributed to center-surround receptive field organization [17-19], occurs prior to any neural processing and reveals a form of matching between the statistics of natural images and those of normal eye movements. We further show that the combined effect of microscopic eye movements and retinal receptive field organization is to convert spatial luminance discontinuities into synchronous firing events, beginning the process of edge detection. Thus, microscopic eye movements are fundamental to two goals of early visual processing: redundancy reduction [20, 21] and feature extraction.
UR - http://www.scopus.com/inward/record.url?scp=84858631860&partnerID=8YFLogxK
U2 - 10.1016/j.cub.2012.01.050
DO - 10.1016/j.cub.2012.01.050
M3 - Article
C2 - 22342751
AN - SCOPUS:84858631860
SN - 0960-9822
VL - 22
SP - 510
EP - 514
JO - Current Biology
JF - Current Biology
IS - 6
ER -