Discrete Human Activity Recognition and Fall Detection by Combining FMCW RADAR Data of Heterogeneous Environments for Independent Assistive Living

Umer Saeed,Akram Alomainy,Qammer H Abbasi,Syed Yaseen Shah,Syed Aziz Shah,Turke Althobaiti,Jawad Ahmad,Naeem Ramzan,Abdullah Alhumaidi Alotaibi

doi:10.3390/electronics10182237

Abstract

Human activity monitoring is essential for a variety of applications in many fields, particularly healthcare. The goal of this research work is to develop a system that can effectively detect fall/collapse and classify other discrete daily living activities such as sitting, standing, walking, drinking, and bending. For this paper, a publicly accessible dataset is employed, which is captured at various geographical locations using a 5.8 GHz Frequency-Modulated Continuous-Wave (FMCW) RADAR. A total of ninety-nine participants, including young and elderly individuals, took part in the experimental campaign. During data acquisition, each aforementioned activity was recorded for 5–10 s. Through the obtained data, we generated the micro-doppler signatures using short-time Fourier transform by exploiting MATLAB tools. Subsequently, the micro-doppler signatures are validated, trained, and tested using a state-of-the-art deep learning algorithm called Residual Neural Network or ResNet. The ResNet classifier is developed in Python, which is utilised to classify six distinct human activities in this study. Furthermore, the metrics used to analyse the trained model’s performance are precision, recall, F1-score, classification accuracy, and confusion matrix. To test the resilience of the proposed method, two separate experiments are carried out. The trained ResNet models are put to the test by subject-independent scenarios and unseen data of the above-mentioned human activities at diverse geographical spaces. The experimental results showed that ResNet detected the falling and rest of the daily living human activities with decent accuracy.

Highlights

Radio Detection and Ranging (RADAR)-based technologies are often associated with military and defence applications, including detecting and tracking of planes and ships
The Residual Neural Network (ResNet) method utilised in this study to classify six various human activities was developed in Python, with the TensorFlow and NumPy libraries being used extensively
We presented preliminary findings for a scheme that utilises the Frequency-Modulated Continuous-Wave (FMCW) RADAR to recognise several human activities, including falling, sitting, standing, walking, drinking, and bending

Summary

Introduction

Radio Detection and Ranging (RADAR)-based technologies are often associated with military and defence applications, including detecting and tracking of planes and ships. In recent years, RADAR-based technology has attracted the attention of a wide range of disciplines outside of military and air traffic control [2]. RADAR-based technology has been proposed in the healthcare field to track everyday living activities at home and to monitor patients’ vital signs, including breathing rate and heart rate [6,7,8]. RADAR technology is used in the human gesture recognition system to monitor and identify complex movements made by individuals to interact with objects without pressing buttons or touching screens [9,10,11]

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