Abstract
There is a growing interest in studying biological systems in natural settings, in which experimental stimuli are less artificial and behavior is less controlled. In primate vision research, free viewing of complex images has elucidated novel neural responses, and free viewing in humans has helped discover attentional and behavioral impairments in patients with neurological disorders. In order to fully interpret data collected from free viewing of complex scenes, it is critical to better understand what aspects of the stimuli guide viewing behavior. To this end, we have developed a novel viewing behavior model called a Biased Correlated Random Walk (BCRW) to describe free viewing behavior during the exploration of complex scenes in monkeys. The BCRW can predict fixation locations better than bottom-up salience. Additionally, we show that the BCRW can be used to test hypotheses regarding specific attentional mechanisms. For example, we used the BCRW to examine the source of the central bias in fixation locations. Our analyses suggest that the central bias may be caused by a natural tendency to reorient the eyes toward the center of the stimulus, rather than a photographer's bias to center salient items in a scene. Taken together these data suggest that the BCRW can be used to further our understanding of viewing behavior and attention, and could be useful in optimizing stimulus and task design.
Highlights
There has been a growing interest in studying biological systems in natural settings, in which experimental stimuli are less artificial and behavior is less controlled (Felsen and Dan, 2005; Hayhoe and Ballard, 2005; Meister and Buffalo, 2015)
We propose a novel model of viewing behavior for complex scenes called a Biased Correlated Random Walk (BCRW)
Because the BCRW relies heavily on salience, we first determined whether observed fixation locations occurred at more salient locations than expected by chance (Figure 4)
Summary
There has been a growing interest in studying biological systems in natural settings, in which experimental stimuli are less artificial and behavior is less controlled (Felsen and Dan, 2005; Hayhoe and Ballard, 2005; Meister and Buffalo, 2015). In order to fully interpret these data, it is critical to better understand what aspects of the stimuli guide viewing behavior. To this end, Modeling Visual Exploration in Monkeys we have developed a novel foraging model to describe free viewing behavior during the exploration of complex scenes in monkeys. This model allows us to predict where the monkeys will fixate
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