Benchmarking Reliability of Deep Learning Models for Pathological Gait Classification
- URL: http://arxiv.org/abs/2409.13643v1
- Date: Fri, 20 Sep 2024 16:47:45 GMT
- Title: Benchmarking Reliability of Deep Learning Models for Pathological Gait Classification
- Authors: Abhishek Jaiswal, Nisheeth Srivastava,
- Abstract summary: Researchers have recently sought to leverage advances in machine learning algorithms to detect symptoms of altered gait.
This paper analyzes existing approaches to identify gaps inhibiting translation.
We propose our strong baseline called Asynchronous Multi-Stream Graph Convolutional Network (AMS-GCN) that can reliably differentiate multiple categories of pathological gaits.
- Score: 2.1548132286330453
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Early detection of neurodegenerative disorders is an important open problem, since early diagnosis and treatment may yield a better prognosis. Researchers have recently sought to leverage advances in machine learning algorithms to detect symptoms of altered gait, possibly corresponding to the emergence of neurodegenerative etiologies. However, while several claims of positive and accurate detection have been made in the recent literature, using a variety of sensors and algorithms, solutions are far from being realized in practice. This paper analyzes existing approaches to identify gaps inhibiting translation. Using a set of experiments across three Kinect-simulated and one real Parkinson's patient datasets, we highlight possible sources of errors and generalization failures in these approaches. Based on these observations, we propose our strong baseline called Asynchronous Multi-Stream Graph Convolutional Network (AMS-GCN) that can reliably differentiate multiple categories of pathological gaits across datasets.
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