Abstract
As robots are becoming more accessible in our daily lives, the interest in physical human–robot interaction (HRI) is rapidly increasing. An electric bicycle (E-bike) is one of the best examples of HRI, because a rider simultaneously actuates the rear wheel of the E-bike in close proximity. Most commercially available E-bikes employ a control methodology known as a power assistant system (PAS). However, this type of system cannot offer fully efficient power assistance for E-bikes since it does not account for the biomechanics of riders. In order to address this issue, we propose a control algorithm to increase the efficiency and enhance the riding experience of E-bikes by implementing the control parameters acquired from analyses of human leg kinematics and muscular dynamics. To validate the proposed algorithm, we have evaluated and compared the performance of E-bikes in three different conditions: (1) without power assistance, (2) assistance with a PAS algorithm, and (3) assistance with the proposed algorithm. Our algorithm required 5.09% less human energy consumption than the PAS algorithm and 11.01% less energy consumption than a bicycle operated without power assistance. Our algorithm also increased velocity stability by 11.89% and acceleration stability by 27.28%, and decreased jerk by 12.36% in comparison to the PAS algorithm.
Highlights
Robots are becoming more prevalent in our society, not just in industrial fields and in our daily lives [1]
human–robot interaction (HRI) can be classified into two categories: remote interaction and proximate interaction [6]
Proximate interaction is closely related to human–robot safety, which is emphasized in transportation on roads, as with electric bicycles (E-bikes), autonomous cars, electric kickboards, etc
Summary
Robots are becoming more prevalent in our society, not just in industrial fields and in our daily lives [1]. Due to increasing demands for physical interaction between human and robots, the importance of human–robot interaction (HRI) technology has been gaining attention [2,3,4,5]. HRI can be classified into two categories: remote interaction and proximate interaction [6]. Remote interaction is that in which the human and robot are separated spatially or even temporally, and proximate interaction is that in which the human and robot are co-located. Proximate interaction is closely related to human–robot safety, which is emphasized in transportation on roads, as with electric bicycles (E-bikes), autonomous cars, electric kickboards, etc. An E-bike is a system that requires close interaction between a human and a motor. An E-bike is an environmentally friendly and healthy alternative to automobiles, making it a promising candidate for HRI transportation technology [7,8,9,10]
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