Affiliation:
1. Experimental Psychology I Institute of Psychology, Osnabrück University Osnabrück Germany
2. Department of Psychology Norwegian University of Science and Technology Trondheim Norway
Abstract
AbstractHuman face perception is a specialized visual process with inherent social significance. The neural mechanisms reflecting this intricate cognitive process have evolved in spatially complex and emotionally rich environments. Previous research using VR to transfer an established face perception paradigm to realistic conditions has shown that the functional properties of face‐sensitive neural correlates typically observed in the laboratory are attenuated outside the original modality. The present study builds on these results by comparing the perception of persons and objects under conventional laboratory (PC) and realistic conditions in VR. Adhering to established paradigms, the PC‐ and VR modalities both featured images of persons and cars alongside standard control images. To investigate the individual stages of realistic face processing, response times, the typical face‐sensitive N170 component, and relevant subsequent components (L1, L2; pre‐, post‐response) were analyzed within and between modalities. The between‐modality comparison of response times and component latencies revealed generally faster processing under realistic conditions. However, the obtained N170 latency and amplitude differences showed reduced discriminative capacity under realistic conditions during this early stage. These findings suggest that the effects commonly observed in the lab are specific to monitor‐based presentations. Analyses of later and response‐locked components showed specific neural mechanisms for identification and evaluation are employed when perceiving the stimuli under realistic conditions, reflected in discernible amplitude differences in response to faces and objects beyond the basic perceptual features. Conversely, the results do not provide evidence for comparable stimulus‐specific perceptual processing pathways when viewing pictures of the stimuli under conventional laboratory conditions.