Schmidtmann, G., Jennings, B. J., Sandra, D. A., Pollock, J., & Gold, I. (2019). The McGill Face Database: validation and insights into the recognition of facial expressions of complex mental states. BioRxiv, 586453. https://doi.org/10.1101/586453 [PDF]

The McGill Face Database: validation and insights into the recognition of facial expressions of complex mental states

Current databases of facial expressions of mental states typically represent only a small subset of expressions, usually covering the basic emotions (fear, disgust, surprise, happiness, sadness, and anger). To overcome these limitations, we introduce a new database of pictures of facial expressions reflecting the richness of mental states. 93 expressions of mental states were interpreted by two professional actors and high-quality pictures were taken under controlled conditions in front and side view. The database was validated with two different experiments (N=65). First, a four-alternative forced choice paradigm was employed to test the ability of participants to correctly select a term associated with each expression. In a second experiment, we employed a paradigm that did not rely on any semantic information. The task was to locate each face within a two-dimensional space of valence and arousal (mental state - space) employing a "point-and-click" paradigm. Results from both experiments demonstrate that subjects can reliably recognize a great diversity of emotional states from facial expressions. Interestingly, while subjects' performance was better for front view images, the advantage over the side view was not dramatic. To our knowledge, this is the first demonstration of the high degree of accuracy human viewers exhibit when identifying complex mental states from only partially visible facial features. The McGill Face Database provides a wide range of facial expressions that can be linked to mental state terms and can be accurately characterized in terms of arousal and valence.

Ingo Fruend (York University, Toronto) and I demonstrate that only a small fraction of biologically relevant shapes can be represented by Radial Frequency (RF) pattern-based shapes and that this small fraction is perceptually distinct from the general class of all possible planar shapes. In this paper we derive a general method to compute the distance of a given shape's outline from the set of RF patterns, allowing us to scan large numbers of object outlines automatically. This analysis shows that only 1 to 6% of naturally smooth outlines can be exactly represented by RF patterns. In addition, we present results from visual search experiments, which revealed that searching RF patterns among non-RF patterns is efficient, whereas searching an RF pattern among other RF patterns is inefficient (and vice versa).

Our results suggest that RF patterns represent only a small and restricted subset of possible planar shapes and that results obtained with this special class of stimuli can not simply be expected to generalise to any arbitrary planar shape and shape representation in general.

Schmidtmann, G., & Fruend, I. (2019). Radial frequency patterns describe a small and perceptually distinct subset of all possible planar shapes. Vision Research, 154, 122–130.  [PDF]

Ania Zolubak, PhD candidate in Dr Garcia-Suarez’ Lab, presented a poster at the European Conference on Visual Perception in Trieste.

Scale-invariance for radial frequency patterns in peripheral vision.

Zolubak, A. B., Schmidtmann, G., Garcia-Suarez, L. 

Radial frequency (RF) patterns are sinusoidally modulated contours. Previous studies have shown that RF shape discrimination (RF vs circle) is scale-invariant, i.e. performance is independent of radius size when presented centrally.
This study aims to investigate scale-invariance in peripheral vision (0-20° nasal visual field, radius 1°, RF=6, SF=1 or 5cpd) by scaling radii according to the Cortical Magnification Factor (CMF) and its fractions (MF1=½, MF2=¼, MF3=1/8).
Results show that performance remains constant with eccentricity for CMF, MF1, MF2 and for two observers (N=4) for MF3. However, the average performance for MF2 was twice and for MF3 four times worse compared to CMF and MF1.
The scale-invariance found for larger stimuli indicates the involvement of global shape processing in the periphery. The higher, yet constant thresholds for smaller patterns suggest that the resolvability of the contours limits peripheral performance and may elicit processing by low-level mechanisms.

New/Old Equipment 

The McGill Face Database: validation and insights into the recognition of complex facial expressions of mental states

Gunnar Schmidtmann, Ben J. Jennings, Dasha A. Sandra, Ian Gold

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Gunnar Schmidtmann, Alexandre Desjardins, Frederick A.A. Kingdom

The influence of face identity noise on face recognition in healthy subjects and patients with mild traumatic brain injury - an equivalent noise approach.

Schmidtmann, G., Wehbé, F., Sandra, D.A., Farivar, R.

McGill Vision Research, Department of Ophthalmology, McGill University

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Schmidtmann, G., Desjardins, A., Kingdom, F.A.A., RF shape channels: The processing of compound Radial Frequency patterns. VSS, 2017 [POSTER]

Radial Frequency (RF) patterns are quasi-circular contours that are frequently used to investigate intermediate stages of shape processing. Combinations of RF patterns have been used to construct more complex shapes such as head contours. Previous studies have suggested that complex shapes may be encoded by multiple, narrowly-tuned RF shape channels. The aim of this study was to test the hypothesis that complex shape processing may be based on multiple, independent RF channels and to demonstrate the limitations such shape descriptors. Thresholds were determined for detection (circle vs. RF compound) and discrimination (RF compound vs. RF compound) of various weighted combinations (symmetrical and asymmetrical) of two RF components (RF3&RF5; RF3&RF8; RF4&RF7).  If both RF components were processed by a common broadband channel, one would expect a substantial increase in sensitivity as the information from both components would be summed within the same channel (additive summation: AS). If the two components were processed independently by separate channels, one would expect only a slight increase in sensitivity for the compound compared to the components (probability summation: PS).  The data were analyzed by a model for probability (PS) and additive summation (AS) under Signal Detection Theory (Kingdom, Baldwin & Schmidtmann, Journal of Vision, 15(5):1).  Results show that summation of information from different RF components is consistent with AS.  This suggest that the shapes tested here are processed by a broadly tuned mechanism. In addition, we demonstrate the mathematical limitations of RF patterns which make them an unlikely candidate for universal shape descriptors.