Piece-wise Matching Layer in Representation Learning for ECG Classification

TL;DR

This paper introduces a novel piece-wise matching layer for ECG classification that enhances representation learning by capturing local features and dynamics, improving accuracy without requiring extensive expert knowledge or large datasets.

Contribution

The paper proposes a new piece-wise matching layer that operates on multiple levels to improve ECG classification, addressing challenges of complexity, generality, and data requirements in existing methods.

Findings

Improves classification accuracy by around 4-7% on PhysioNet datasets.

Does not rely on prior knowledge of classes or arrhythmia locations.

Demonstrates effectiveness across various processing scenarios.

Abstract

This paper proposes piece-wise matching layer as a novel layer in representation learning methods for electrocardiogram (ECG) classification. Despite the remarkable performance of representation learning methods in the analysis of time series, there are still several challenges associated with these methods ranging from the complex structures of methods, the lack of generality of solutions, the need for expert knowledge, and large-scale training datasets. We introduce the piece-wise matching layer that works based on two levels to address some of the aforementioned challenges. At the first level, a set of morphological, statistical, and frequency features and comparative forms of them are computed based on each periodic part and its neighbors. At the second level, these features are modified by predefined transformation functions based on a receptive field scenario. Several scenarios of offline processing, incremental processing, fixed sliding receptive field, and event-based triggering receptive field can be implemented based on the choice of length and mechanism of indicating the receptive field. We propose dynamic time wrapping as a mechanism that indicates a receptive field based on event triggering tactics. To evaluate the performance of this method in time series analysis, we applied the proposed layer in two publicly available datasets of PhysioNet competitions in 2015 and 2017 where the input data is ECG signal. We compared the performance of our method against a variety of known tuned methods from expert knowledge, machine learning, deep learning methods, and the combination of them. The proposed approach improves the state of the art in two known completions 2015 and 2017 around 4% and 7% correspondingly while it does not rely on in advance knowledge of the classes or the possible places of arrhythmia.