Deep learning empowered sensor fusion boosts infant movement classification

TL;DR

This study demonstrates that combining pressure, inertial, and visual sensors using deep learning significantly improves the accuracy of infant movement classification, aiding early neurodevelopmental assessment.

Contribution

It introduces a multi-sensor fusion approach with CNNs for infant movement analysis, outperforming single sensor methods and advancing automated early detection of neurodevelopmental issues.

Findings

Sensor fusion achieved 94.5% accuracy in classifying infant movements.

Multi-sensor system outperformed individual sensor modalities.

Fusion approach enhances automated early neurodevelopmental assessment.

Abstract

To assess the integrity of the developing nervous system, the Prechtl general movement assessment (GMA) is recognized for its clinical value in diagnosing neurological impairments in early infancy. GMA has been increasingly augmented through machine learning approaches intending to scale-up its application, circumvent costs in the training of human assessors and further standardize classification of spontaneous motor patterns. Available deep learning tools, all of which are based on single sensor modalities, are however still considerably inferior to that of well-trained human assessors. These approaches are hardly comparable as all models are designed, trained and evaluated on proprietary/silo-data sets. With this study we propose a sensor fusion approach for assessing fidgety movements (FMs). FMs were recorded from 51 typically developing participants. We compared three different sensor modalities (pressure, inertial, and visual sensors). Various combinations and two sensor fusion approaches (late and early fusion) for infant movement classification were tested to evaluate whether a multi-sensor system outperforms single modality assessments. Convolutional neural network (CNN) architectures were used to classify movement patterns. The performance of the three-sensor fusion (classification accuracy of 94.5%) was significantly higher than that of any single modality evaluated. We show that the sensor fusion approach is a promising avenue for automated classification of infant motor patterns. The development of a robust sensor fusion system may significantly enhance AI-based early recognition of neurofunctions, ultimately facilitating automated early detection of neurodevelopmental conditions.