Color Space Geometry Uncovered with Magnetoencephalography

Rosenthal, Isabelle; Singh, Shridhar; Hermann, Katherine L.; Pantazis, Dimitrios; Conway, Bevil R.

doi:10.1016/j.cub.2020.10.062

Cited by 23 publications

(45 citation statements)

References 75 publications

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“…While the results show that representations of hue and luminance contrast are somewhat decoupled, they also confirm prior work showing the existence of representations that combine hue and luminance contrast (Rosenthal et al, 2020b): decoding performance for the identity problems, in which classifiers were trained using responses to stimuli that were distinguished by a combination of luminance contrast and hue, was always better than decoding performance for the generalization problems, in which classifiers were trained using responses to stimuli that were only distinguishable by one dimension, invariant to the other ( Figure 2 ). These results are therefore consistent with the idea that in addition to separate representations of hue and luminance contrast, the visual system has representations that combine hue and luminance contrast, perhaps reflecting the joint selectivity for hue and luminance contrast evident in some neural populations in the LGN(Wiesel and Hubel, 1966) and V1(Gegenfurtner, 2003; Johnson et al, 2008; Horwitz and Hass, 2012).…”

Section: Discussionsupporting

confidence: 86%

“…Note that decoding using pupil diameter and eye position cannot account for decoding of color (Rosenthal et al, 2020b).…”

Section: Methodsmentioning

confidence: 99%

“…Color can be decoded from MEG activity(Hermann et al, 2015; Rosenthal et al, 2017; Sandhaeger et al, 2019; Teichmann et al, 2019; Hajonides et al, 2020; Hermann et al, 2020; Rosenthal et al, 2020a). We have previously shown that MEG data elicited by colors provide evidence of joint coding of hue and luminance contrast that reflect color-naming patterns and can be used to construct a geometry of the neural representation of color (Rosenthal et al, 2020b). In the present work, we use multivariate analyses of the same large dataset to take up two unresolved issues: first, we test the extent to which hue and luminance contrast are encoded independently and whether these representations generalize across time; and second, we exploit the exquisite temporal resolution of MEG to tease apart the time course of the representations for hue and luminance contrast (the dataset is available here: https://doi.org/10.18112/openneuro.ds003352.v1.0.0; and here: https://neicommons.nei.nih.gov/#/).…”

mentioning

confidence: 99%

“…Here we explore a new approach to address the neural mechanisms for encoding hue and luminance contrast, using magnetoencephalography (MEG) in humans, coupled with multivariate analysis 44–48 ( Figure 1 ). Color can be decoded from MEG activity 49–56 . In the present work, we exploit the exquisite temporal resolution of MEG to tease apart the neural mechanisms for hue and luminance contrast.…”

mentioning

confidence: 99%

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Temporal dynamics of the neural representation of hue and luminance polarity

Hermann

Rosenthal

Singh

et al. 2020

Preprint

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Hue and luminance contrast are the most basic visual computations, and are reflected in the earliest layers of convolutional neural networks, yet the extent to which they are extracted by the same or separate circuits in the brain, and the timing of these neural computations, is unknown. Here we answer these questions using multivariate analyses of human brain responses measured with magnetoencephalography. We report three discoveries. First, hue and luminance contrast could be decoded independently, indicating these computations are somewhat separable. Hue was computed about 15-24ms after luminance contrast. Second, representations of hue showed relatively greater generalization across time and were more sustained, providing the first neural correlate of the perceptual preeminence of hue over luminance contrast in grouping objects. Finally, luminance contrast could be decoded less well for hues associated with daylight (orange and blue), suggesting that colorconstancy mechanisms are adapted to natural lighting.

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Section: Discussionsupporting

confidence: 86%

“…Note that decoding using pupil diameter and eye position cannot account for decoding of color (Rosenthal et al, 2020b).…”

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Temporal dynamics of the neural representation of hue and luminance polarity

Hermann

Rosenthal

Singh

et al. 2020

Preprint

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“…To achieve this, we chose unique and non-unique hues that were maximally distant in a perceptual space -red and green, orange and turquoise (see details of the stimulus set in Methods). As already reported by Rosenthal et al (2021) and Hermann et al (2021), inter-hue differences in decoding efficiency manifest even between such evenly spaced colours. To better understand the non-uniformity of this neurometric colour space, in our next experiment we aimed to investigate the structure of the decoding manifold by introducing proximal neighbours, clockwise and counterclockwise to each hue.…”

Section: Interim Discussionsupporting

confidence: 77%

Decoding of EEG signals reveals non-uniformities in the neural geometry of colour

Chauhan

Jakovljev

Thompson

et al. 2021

Preprint

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The idea of colour opponency maintains that colour vision arises through the comparison of two chromatic mechanisms, red versus green (RG) and yellow versus blue (YB). The four unique hues, red, green, blue, and yellow, are assumed to appear at the null points of these the two chromatic systems. However, whether unique hues have a distinct signature that can be reliably discerned in neural activity is still an open question. Here we hypothesise that, if unique hues represent a tractable cortical state, they should elicit more robust activity compared to non-unique hues. We use a spatiotemporal decoding approach to reconstruct an activation space for a set of unique and intermediate hues across a range of luminance values. We show that electroencephalographic (EEG) responses carry robust information about isoluminant unique hues within a 100-300 ms window from stimulus onset. Decoding is possible in both passive and active viewing tasks, but is compromised when concurrent high luminance contrast is added to the colour signals. The efficiency of hue decoding is not entirely predicted by their mutual distance in a nominally uniform colour space. Instead, the encoding space shows pivotal non-uniformities which suggest that anisotropies in neurometric hue-spaces are likely to represent perceptual unique hues. Furthermore, the neural code for hue temporally coincides with the neural code for luminance contrast, thus explaining why potential neural correlates of unique hues have remained so elusive until now.

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Toward more efficient and effective color quality control for the large‐scale offset printing process

Dziki,

Pieszczek,

Daszykowski

2024

Journal of Chemometrics

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This study illustrates at‐line application of hyperspectral imaging in the visible range for quality control of large‐scale offset printing. In particular, the measurement stability of a competitive device is assessed and compared to traditional handheld and desktop spectrophotometers. The performance of the commercially available instruments was assessed based on collected spectra and their corresponding L*, a*, and b* values. The printing process was described by hyperspectral images (in visible range) of selected regions from template color fields acquired at 17 sampling occasions. Spectra constituting hyperspectral images were visualized and evaluated in the space of significant principal components obtained from the principal component analysis. Furthermore, confidence ellipses were constructed for each set of spectra characterizing a specific moment of the printing process. Comparing their mutual locations, shapes, orientations, and sizes enabled effective visualization of process variability and was more comprehensive regarding the classic approach based on information provided by desktop and handheld spectrometers.

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Color Space Geometry Uncovered with Magnetoencephalography

Cited by 23 publications

References 75 publications

Temporal dynamics of the neural representation of hue and luminance polarity

Temporal dynamics of the neural representation of hue and luminance polarity

Decoding of EEG signals reveals non-uniformities in the neural geometry of colour

Toward more efficient and effective color quality control for the large‐scale offset printing process

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