Neural correlates of the uncanny valley effect for robots and hyper-realistic masks

Shona Fitzpatrick; Ailish K Byrne; Alex Headley; Jet G Sanders; Helen Petrie; Rob Jenkins; Daniel H Baker

doi:10.1371/journal.pone.0311714

Neural correlates of the uncanny valley effect for robots and hyper-realistic masks

Shona Fitzpatrick, Ailish K Byrne, Alex Headley, Jet G Sanders, Helen Petrie, Rob Jenkins, Daniel H Baker

Research output: Contribution to journal › Article › peer-review

Abstract

Viewing artificial objects and images that are designed to appear human can elicit a sense of unease, referred to as the 'uncanny valley' effect. Here we investigate neural correlates of the uncanny valley, using still images of androids (robots designed to look human), and humans wearing hyper-realistic silicone masks, as well as still images of real humans, in two experiments. In both experiments, human-like stimuli were harder to distinguish from real human faces than stimuli that were clearly not designed to mimic humans but contain facial features (mechanical robots and Halloween masks). Stimulus evoked potentials (electromagnetic brain responses) did not show convincing differences between faces and either androids or realistic masks when using traditional univariate statistical tests. However, a more sensitive multivariate analysis identified two regions of above-chance decoding, indicating neural differences in the response between human faces and androids/realistic masks. The first time window was around 100-200 ms post stimulus onset, and most likely corresponds to low-level image differences between conditions. The second time window was around 600 ms post stimulus onset, and may reflect top-down processing, and may correspond to the subjective sense of unease characteristic of the uncanny valley effect. Objective neural components might be used in future to rapidly train generative artificial intelligence systems to produce more realistic images that are perceived as natural by human observers.

Original language	English
Article number	e0311714
Number of pages	15
Journal	PLOS ONE
Volume	20
Issue number	3
DOIs	https://doi.org/10.1371/journal.pone.0311714
Publication status	Published - 18 Mar 2025

Bibliographical note

Keywords

Humans
Male
Female
Adult
Robotics
Masks
Young Adult
Brain/physiology
Photic Stimulation
Face/physiology
Electroencephalography
Evoked Potentials/physiology
Pattern Recognition, Visual/physiology

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10.1371/journal.pone.0311714Licence: CC BY

Neural correlates of the uncanny valley effect for robots and hyper-realistic masks
© 2025 Fitzpatrick et al.
Final published version, 3.97 MBLicence: CC BY

Cite this

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title = "Neural correlates of the uncanny valley effect for robots and hyper-realistic masks",

abstract = "Viewing artificial objects and images that are designed to appear human can elicit a sense of unease, referred to as the 'uncanny valley' effect. Here we investigate neural correlates of the uncanny valley, using still images of androids (robots designed to look human), and humans wearing hyper-realistic silicone masks, as well as still images of real humans, in two experiments. In both experiments, human-like stimuli were harder to distinguish from real human faces than stimuli that were clearly not designed to mimic humans but contain facial features (mechanical robots and Halloween masks). Stimulus evoked potentials (electromagnetic brain responses) did not show convincing differences between faces and either androids or realistic masks when using traditional univariate statistical tests. However, a more sensitive multivariate analysis identified two regions of above-chance decoding, indicating neural differences in the response between human faces and androids/realistic masks. The first time window was around 100-200 ms post stimulus onset, and most likely corresponds to low-level image differences between conditions. The second time window was around 600 ms post stimulus onset, and may reflect top-down processing, and may correspond to the subjective sense of unease characteristic of the uncanny valley effect. Objective neural components might be used in future to rapidly train generative artificial intelligence systems to produce more realistic images that are perceived as natural by human observers.",

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