Abstract
Human activity recognition (HAR) based on the wearable device has attracted more attention from researchers with sensor technology development in recent years. However, personalized HAR requires high accuracy of recognition, while maintaining the model’s generalization capability is a major challenge in this field. This paper designed a compact wireless wearable sensor node, which combines an air pressure sensor and inertial measurement unit (IMU) to provide multi-modal information for HAR model training. To solve personalized recognition of user activities, we propose a new transfer learning algorithm, which is a joint probability domain adaptive method with improved pseudo-labels (IPL-JPDA). This method adds the improved pseudo-label strategy to the JPDA algorithm to avoid cumulative errors due to inaccurate initial pseudo-labels. In order to verify our equipment and method, we use the newly designed sensor node to collect seven daily activities of 7 subjects. Nine different HAR models are trained by traditional machine learning and transfer learning methods. The experimental results show that the multi-modal data improve the accuracy of the HAR system. The IPL-JPDA algorithm proposed in this paper has the best performance among five HAR models, and the average recognition accuracy of different subjects is 93.2%.
Highlights
We can clearly find that the performance of the Human activity recognition (HAR) model trained with air pressure data is better than the model trained without air pressure data on the mean accuracy value
We propose a compact wireless wearable sensor node that combines an air pressure sensor and an inertial measurement unit (IMU) sensor
The results show that the HAR model trained with air pressure data is better in recognition performance than the model trained without air pressure data
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Human activity recognition (HAR) is an important research field in the world [1]. It has a broad range of application scenarios in industrial automation [2], sports [3], medical [4], security [5], smart city [6], and smart home [7]. HAR system plays an essential role in human-centered applications, such as health detection [8], driver behavior monitoring [9], gait detection [10], fall detection [11], and other personalized services
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