Low-Memory-Footprint CNN-Based Biomedical Signal Processing for Wearable Devices

Low-Memory-Footprint CNN-Based Biomedical Signal Processing for Wearable Devices

The rise of wearable devices has enabled real-time processing of sensor data for critical health monitoring applications, such as human activity recognition (HAR) and cardiac disorder classification (CDC). However, the limited computational and memory resources of wearables necessitate lightweight y...

Full description

Saved in:
Bibliographic Details
Main Authors: Zahra Kokhazad, Dimitrios Gkountelos, Milad Kokhazadeh, Charalampos Bournas, Georgios Keramidas, Vasilios Kelefouras
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:IoT
Subjects:
biomedical applications
human activity recognition
cardiac disorder classification
filter-based pruning
low-rank factorization
quantization
Online Access:https://www.mdpi.com/2624-831X/6/2/29
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The rise of wearable devices has enabled real-time processing of sensor data for critical health monitoring applications, such as human activity recognition (HAR) and cardiac disorder classification (CDC). However, the limited computational and memory resources of wearables necessitate lightweight yet accurate classification models. While deep neural networks (DNNs), including convolutional neural networks (CNNs) and long short-term memory networks, have shown high accuracy for HAR and CDC, their large parameter sizes hinder deployment on edge devices. On the other hand, various DNN compression techniques have been proposed, but exploiting the combination of various compression techniques with the aim of achieving memory efficient DNN models for HAR and CDC tasks remains under-investigated. This work studies the impact of CNN architecture parameters, focusing on the convolutional and dense layers, to identify configurations that balance accuracy and efficiency. We derive two versions of each model—lean and fat—based on their memory characteristics. Subsequently, we apply three complementary compression techniques: filter-based pruning, low-rank factorization, and dynamic range quantization. Experiments across three diverse DNNs demonstrate that this multi-faceted compression approach can significantly reduce memory and computational requirements while maintaining validation accuracy, leading to DNN models suitable for intelligent health monitoring on resource-constrained wearable devices.
ISSN:2624-831X

Similar Items