Abstract
Robots instead of humans work in unstructured environments, expanding the scope of human work. The interactions between humans and robots are indirect through operating terminals. The mental workloads of human increase with the lack of direct perception to the real scenes. Thus, mental workload assessment is important, which could effectively avoid serious accidents caused by mental overloading. In this paper, the operating object is a dual-arm robot. The classification of operator’s mental workload is studied by using the heart rate variability (HRV) signal. First, two kinds of electrocardiogram (ECG) signals are collected from six subjects who performed tasks or maintained a relaxed state. Then, HRV data is obtained from ECG signals and 20 kinds of HRV features are extracted. Last, six different classifications are used for mental workload classification. Using each subject’s HRV signal to train the model, the subject’s mental workload is classified. Average classification accuracy of 98.77% is obtained using the K-Nearest Neighbor (KNN) method. By using the HRV signal of five subjects for training and that of one subject for testing with the Gentle Boost (GB) method, the highest average classification accuracy (80.56%) is obtained. This study has implications for the analysis of HRV signals characteristic of mental workload in different subjects, which could improve operators’ well-being and safety in the human-robot interaction process.
Highlights
Robots replace humans to perform some complex tasks, which expends the scope of human work [1,2]
A human remote-controlled robot performs complex or dangerous tasks in unstructured environments, which expends the scope of human work
In the process of completing the tasks, the mental workload of the operator will change based on the different tasks of the robot
Summary
Robots replace humans to perform some complex tasks, which expends the scope of human work [1,2]. Studies based on dual-arm robots have always moved towards the operation of humanization. A dual-arm robot is studied as the operating object, which is controlled by a wearable exoskeleton controller in master-slave mode. It is crucial to monitor the mental workload of the operator. On this basis, the human-robot task assignment could be dynamically adjusted based on the mental workload. The human-robot task assignment could be dynamically adjusted based on the mental workload This kind of research improves human-robot system performance and safety and refine the subjective experience of operators. It is of Electronics 2020, 9, 2174; doi:10.3390/electronics9122174 www.mdpi.com/journal/electronics
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