Anaphylactoid Purpura in Children (Schönlein-Henoch Syndrome)

Epilepsy and psychogenic non-epileptic seizures (PNES) often show over-lap in symptoms, especially at an early disease stage. During a PNES, the electrical activity of the brain remains normal but in case of an epileptic seizure the brain will show epileptiform discharges on the electroencephalogram (EEG). In many cases an accurate diagnosis can only be achieved after a long-term video monitoring combined with EEG recording which is quite expensive and time-consuming. In this paper using short-term EEG data, the classification of epilepsy and PNES subjects is analyzed based on signal, functional network and EEG microstate features. Our results showed that the beta-band is the most useful EEG frequency sub-band as it performs best for classifying subjects. Also the results depicted that when the coverage feature of the EEG microstate analysis is calculated in beta-band, the classification shows fairly high accuracy and precision. Hence, the beta-band and the coverage are the most important features for classification of epilepsy and PNES patients.

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Twitter rumour detection in the health domain

Sicilia

Giudice

Pei

et al. 2018

Expert Systems with Applications

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Sparse evolutionary deep learning with over one million artificial neurons on commodity hardware

Liu

Mocanu

Matavalam

et al. 2020

Neural Comput & Applic

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Artificial neural networks (ANNs) have emerged as hot topics in the research community. Despite the success of ANNs, it is challenging to train and deploy modern ANNs on commodity hardware due to the ever-increasing model size and the unprecedented growth in the data volumes. Particularly for microarray data, the very high dimensionality and the small number of samples make it difficult for machine learning techniques to handle. Furthermore, specialized hardware such as graphics processing unit (GPU) is expensive. Sparse neural networks are the leading approaches to address these challenges. However, off-the-shelf sparsity-inducing techniques either operate from a pretrained model or enforce the sparse structure via binary masks. The training efficiency of sparse neural networks cannot be obtained practically. In this paper, we introduce a technique allowing us to train truly sparse neural networks with fixed parameter count throughout training. Our experimental results demonstrate that our method can be applied directly to handle high-dimensional data, while achieving higher accuracy than the traditional two-phase approaches. Moreover, we have been able to create truly sparse multilayer perceptron models with over one million neurons and to train them on a typical laptop without GPU (https:// github.com/dcmocanu/sparse-evolutionary-artificial-neural-networks/tree/master/SET-MLP-Sparse-Python-Data-Struc tures), this being way beyond what is possible with any state-of-the-art technique.

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DHNE: Network Representation Learning Method for Dynamic Heterogeneous Networks

Yin

Zhang

et al. 2019

IEEE Access

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Analyzing the rich information behind heterogeneous networks through network representation learning methods is signifcant for many application tasks such as link prediction, node classifcation and similarity research. As the networks evolve over times, the interactions among the nodes in networks make heterogeneous networks exhibit dynamic characteristics. However, almost all the existing heterogeneous network representation learning methods focus on static networks which ignore dynamic characteristics. In this paper, we propose a novel approach DHNE to learn the representations of nodes in dynamic heterogeneous networks. The key idea of our approach is to construct comprehensive historical-current networks based on subgraphs of snapshots in time step to capture both the historical and current information in the dynamic heterogeneous network. And then under the guidance of meta paths, DHNE performs random walks on the constructed historical-current graphs to capture semantic information. After getting the node sequences through random walks, we propose the dynamic heterogeneous skip-gram model to learn the embeddings. Experiments on large-scale real-world networks demonstrate that the embeddings learned by the proposed DHNE model achieve better performances than state-of-the-art methods in various downstream tasks including node classifcation and visualization. INDEX TERMS Dynamic heterogeneous networks, network representation learning, random walk, skip-gram model.

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Flywheel energy storage systems for power systems application

Pei

Cavagnino

Vaschetto

et al. 2017

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ResGCN: attention-based deep residual modeling for anomaly detection on attributed networks

Pei

Huang

Ipenburg³

et al. 2021

Mach Learn

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Effectively detecting anomalous nodes in attributed networks is crucial for the success of many real-world applications such as fraud and intrusion detection. Existing approaches have difficulties with three major issues: sparsity and nonlinearity capturing, residual modeling, and network smoothing. We propose Residual Graph Convolutional Network (ResGCN), an attention-based deep residual modeling approach that can tackle these issues: modeling the attributed networks with GCN allows to capture the sparsity and nonlinearity, utilizing a deep neural network allows direct residual ing from the input, and a residual-based attention mechanism reduces the adverse effect from anomalous nodes and prevents over-smoothing. Extensive experiments on several real-world attributed networks demonstrate the effectiveness of ResGCN in detecting anomalies.

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Effect of linear mixing in EEG on synchronization and complex network measures studied using the Kuramoto model

Ahmadi

Pei

Pechenizkiy

2019

Physica A: Statistical Mechanics and its Applications

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Health-related rumour detection on Twitter

Sicilia

Giudice²,

Pei

et al. 2017

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Yulong Pei

EEG-based classification of epilepsy and PNES: EEG microstate and functional brain network features

Twitter rumour detection in the health domain

Sparse evolutionary deep learning with over one million artificial neurons on commodity hardware

DHNE: Network Representation Learning Method for Dynamic Heterogeneous Networks

Flywheel energy storage systems for power systems application

ResGCN: attention-based deep residual modeling for anomaly detection on attributed networks

Effect of linear mixing in EEG on synchronization and complex network measures studied using the Kuramoto model

Health-related rumour detection on Twitter

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