Cyril de Bodt scite author profile

Thermosensation is crucial for humans to probe the environment and detect threats arising from noxious heat or cold. Over the last years, EEG frequency-tagging using long-lasting periodic radiant heat stimulation has been proposed as a means to study the cortical processes underlying tonic heat perception. This approach is based on the notion that periodic modulation of a sustained stimulus can elicit synchronized periodic activity in the neuronal populations responding to the stimulus, known as a steady-state response (SSR). In this paper, we extend this approach using a contact thermode to generate both heat-and coldevoked SSRs. Furthermore, we characterize the temporal dynamics of the elicited responses, relate these dynamics to perception, and assess the effects of displacing the stimulated skin surface to gain insight on the heat-and cold-sensitive afferents conveying these responses. Two experiments were conducted in healthy volunteers. In both experiments, noxious heat and innocuous cool stimuli were applied during 75 seconds to the forearm using a Peltier-based contact thermode, with intensities varying sinusoidally at 0.2 Hz. Displacement of the thermal stimulation on the skin surface was achieved by independently controlling the Peltier elements of the thermal probe. Continuous intensity ratings to sustained heat and cold stimulation were obtained in the first experiment with 14 subjects, and the EEG was recorded in the second experiment on 15 subjects. Both contact heat and cool stimulation elicited periodic EEG responses and percepts. Compared to heat stimulation, the responses to cool stimulation had a lower magnitude and shorter latency. All responses tended to habituate along time, and this response attenuation was most pronounced for cool compared to warm stimulation, and for stimulation delivered using a fixed surface compared to a variable surface.

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Nonlinear Dimensionality Reduction With Missing Data Using Parametric Multiple Imputations

Bodt

Mulders

Verleysen

et al. 2019

IEEE Trans. Neural Netw. Learning Syst.

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Fast Multiscale Neighbor Embedding

Bodt

Mulders

Verleysen

et al. 2022

IEEE Trans. Neural Netw. Learning Syst.

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Inference of node attributes from social network assortativity

Mulders

Bodt

Bjelland

et al. 2019

Neural Comput & Applic

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Social networks are known to be assortative with respect to many attributes, such as age, weight, wealth, level of education, ethnicity and gender: similar people according to these attributes tend to be more connected. This can be explained by influences and homophilies. Independently of its origin, this assortativity gives us information about each node given its neighbors. Assortativity can thus be used to improve individual predictions in a broad range of situations, when data are missing or inaccurate. This paper presents a general framework based on probabilistic graphical models to exploit social network structures for improving individual predictions of node attributes. Using this framework, we quantify the assortativity range leading to an accuracy gain in several situations, with various individual prediction profiles. We finally show how specific characteristics of the network can enhance performances further. For instance, the gender assortativity in real-world mobile phone data drastically changes according to some communication attributes. In this case, using the network topology indeed improves local predictions of node labels, and moreover enables inferring missing node labels based on a subset of known vertices. In both cases, the performances of the proposed method

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Stochastic quartet approach for fast multidimensional scaling

Lambert¹,

Bodt²,

Verleysen³

et al. 2021

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Multidimensional scaling is a statistical process that aims to embed high-dimensional data into a lower-dimensional, more manageable space. Common MDS algorithms tend to have some limitations when facing large data sets due to their high time and spatial complexities. This paper attempts to tackle the problem by using a stochastic approach to MDS which uses gradient descent to optimise a loss function defined on randomly designated quartets of points. This method mitigates the quadratic memory usage by computing distances on the fly, and has iterations in O(N ) time complexity, with N samples. Experiments show that the proposed method provides competitive results in reasonable time. Public codes are available at https://github.com/PierreLambert3/SQuaD-MDS.git. Multidimensional scaling and its limitationsDimensionality reduction (DR) is the process of mapping high-dimensional (HD) observations into a lower-dimensional (LD) space such that the LD embedding is a faithful representation of the HD data. The main DR uses are in machine learning, to curb the curse of dimensionality, and in visualisation. Mapped data can reveal structures that would lay hidden from the human perception if left in HD. Typically, some information is lost by the DR and, therefore, each DR method has a take on what kind of information should be preserved and what can be lost. Used frequently in visualisation, t-SNE [1] aims at retaining the neighbourhood of each point according to a distance metric and a perplexity, which reflects the size of the neighbourhood to preserve. While t-SNE excels at retaining local structures, sufficiently remote points tend to be considered equally distant by the algorithm and, therefore, the larger-scale structures can be distorted. Such distortions can lead to erroneous conclusions by the human user, who might overestimate the dissimilarity between two clusters that are distant in the LD embedding. For this reason, using multiple DR paradigms in conjunction is a good practice in visualisation: another embedding that preserves distances instead of neighbourhoods would have prevented this erroneous conclusion.This paper considers metric multidimensional scaling (MDS): a DR technique that produces a LD embedding such that the pairwise distances in LD reflect those in HD. MDS minimises a cost function which, in its simplest form, is the sum of the squared differences between distances in HD and the Euclidean distances in LD. A common strategy to optimize this cost function is based on 417

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Cyril de Bodt

Dynamics of the perception and EEG signals triggered by tonic warm and cool stimulation

Nonlinear Dimensionality Reduction With Missing Data Using Parametric Multiple Imputations

Fast Multiscale Neighbor Embedding

Inference of node attributes from social network assortativity

Stochastic quartet approach for fast multidimensional scaling

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