Abstract
The design of human–robot interactions is a key challenge to optimize operational performance. A promising approach is to consider mixed-initiative interactions in which the tasks and authority of each human and artificial agents are dynamically defined according to their current abilities. An important issue for the implementation of mixed-initiative systems is to monitor human performance to dynamically drive task allocation between human and artificial agents (i.e., robots). We, therefore, designed an experimental scenario involving missions whereby participants had to cooperate with a robot to fight fires while facing hazards. Two levels of robot automation (manual vs. autonomous) were randomly manipulated to assess their impact on the participants’ performance across missions. Cardiac activity, eye-tracking, and participants’ actions on the user interface were collected. The participants performed differently to an extent that we could identify high and low score mission groups that also exhibited different behavioral, cardiac and ocular patterns. More specifically, our findings indicated that the higher level of automation could be beneficial to low-scoring participants but detrimental to high-scoring ones, and vice versa. In addition, inter-subject single-trial classification results showed that the studied behavioral and physiological features were relevant to predict mission performance. The highest average balanced accuracy (74%) was reached using the features extracted from all input devices. These results suggest that an adaptive HRI driving system, that would aim at maximizing performance, would be capable of analyzing such physiological and behavior markers online to further change the level of automation when it is relevant for the mission purpose.
Highlights
In the near future, human and artificial agents will be deployed to handle several missions in different contexts working as teammates
As we study the impact of the robot automation level, a random change of the automation level is the best choice to avoid to create a bias related to a mode change policy; 10-s time windows were chosen as data collected during pilot experiments, as well as previous study [29], demonstrated to compute Heart Rate (HR) and Heart-Rate Variability (HRV) metrics in a robust manner for online purpose
Only trends were observed between HRVnorm (W ) and mission score (ρ = −0.24, p = 0.07), and between HRnorm (W ) and mission score (ρ = 0.27, p = 0.06)
Summary
Human and artificial agents will be deployed to handle several missions in different contexts working as teammates. Robots can operate in hostile environments, can quickly compute actions, and reduce mission costs while maximizing production. The human operator may experience high workload [6] and cognitive fatigue [7,8] that in turn can impair their attentional [9] and executive abilities [10]. In this cybernetic system context, several challenges have arisen such as the implementation of human–robots monitoring
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