Abstract

Human observers can rapidly perceive complex real-world scenes. Grouping visual elements into meaningful units is an integral part of this process. Yet, so far, the neural underpinnings of perceptual grouping have only been studied with simple lab stimuli. We here uncover the neural mechanisms of one important perceptual grouping cue, local parallelism. Using a new, image-computable algorithm for detecting local symmetry in line drawings and photographs, we manipulated the local parallelism content of real-world scenes. We decoded scene categories from patterns of brain activity obtained via functional magnetic resonance imaging (fMRI) in 38 human observers while they viewed the manipulated scenes. Decoding was significantly more accurate for scenes containing strong local parallelism compared to weak local parallelism in the parahippocampal place area (PPA), indicating a central role of parallelism in scene perception. To investigate the origin of the parallelism signal we performed a model-based fMRI analysis of the public BOLD5000 dataset, looking for voxels whose activation time course matches that of the locally parallel content of the 4916 photographs viewed by the participants in the experiment. We found a strong relationship with average local symmetry in visual areas V1-4, PPA, and retrosplenial cortex (RSC). Notably, the parallelism-related signal peaked first in V4, suggesting V4 as the site for extracting paralleism from the visual input. We conclude that local parallelism is a perceptual grouping cue that influences neuronal activity throughout the visual hierarchy, presumably starting at V4. Parallelism plays a key role in the representation of scene categories in PPA.

Highlights

  • Upon opening their eyes, humans experience a rich, cohesive world, composed of many objects and surfaces

  • In all regions of interest (ROIs), BOLD activity was lowest for intact line drawings

  • Participants saw photographs, and we investigate how the local parallelism measure from line drawings extracted from these photographs is reflected in the time course of BOLD activity in a linear model-based analysis

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Summary

Introduction

Humans experience a rich, cohesive world, composed of many objects and surfaces. We can understand the identity of images presented in a rapid visual stream [1], quickly find objects in noisy real-world environments [2], and even detect shapes composed of smaller elements such as edge segments or Gabor patches [3, 4]. The specific roles of these authors are articulated in the ‘author contributions’ section

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