Abstract
Standard feature engineering involves manually designing measurable descriptors based on some expert knowledge in the domain of application, followed by the selection of the best performing set of designed features for the subsequent optimisation of an inference model. Several studies have shown that this whole manual process can be efficiently replaced by deep learning approaches which are characterised by the integration of feature engineering, feature selection and inference model optimisation into a single learning process. In the following work, deep learning architectures are designed for the assessment of measurable physiological channels in order to perform an accurate classification of different levels of artificially induced nociceptive pain. In contrast to previous works, which rely on carefully designed sets of hand-crafted features, the current work aims at building competitive pain intensity inference models through autonomous feature learning, based on deep neural networks. The assessment of the designed deep learning architectures is based on the BioVid Heat Pain Database (Part A) and experimental validation demonstrates that the proposed uni-modal architecture for the electrodermal activity (EDA) and the deep fusion approaches significantly outperform previous methods reported in the literature, with respective average performances of and for the binary classification experiment consisting of the discrimination between the baseline and the pain tolerance level ( vs. ) in a Leave-One-Subject-Out (LOSO) cross-validation evaluation setting. Moreover, the experimental results clearly show the relevance of the proposed approaches, which also offer more flexibility in the case of transfer learning due to the modular nature of deep neural networks.
Highlights
Conventional machine learning approaches are built upon a set of carefully engineered representations, which consist of measurable parameters extracted from raw data
The weight corresponding to the aggregation layer (λ agg ) was set higher than the others to push the network to focus on the weighted combination of the single modality architectures’ outputs, and to evaluate an optimal set of the weighting parameters {α1 ( electrodermal activity (EDA)), α2 ( EMG ), α3 ( ECG )}
The implementation and evaluation of the described algorithms was done with the libraries Keras [52], Tensorflow [53] and Scikit-learn [54]
Summary
Conventional machine learning approaches are built upon a set of carefully engineered representations, which consist of measurable parameters extracted from raw data. Based on some expert knowledge in the domain of application, a feature extractor is designed and used to extract relevant information in the form of a feature vector from the preprocessed raw data This high level representation of the input data is subsequently used to optimise an inference model. Each processing layer is characterised by a set of parameters that are used to transform its input (which is the representation generated by the previous layer) into a new and more abstract representation This specific hierarchical combination of several non-linear transformations enables deep learning architectures to learn very complex functions as well as abstract descriptive (or discriminative) representations directly from raw data [2]. Similar performances have been achieved in the field of speech recognition [8,9] and natural language processing [10,11]
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