Lee, Byung CheolPark, JangwoonJeong, HeejinPark, JaehyunLee, Byung CheolPark, JangwoonJeong, HeejinPark, Jaehyun2020-04-302020-04-302020-04-302020-04-302020-02-142020-02-142020-02-14Lee, B.C.; Park, J.; Jeong, H.; Park, J. Validation of Trade-Off in Human–Automation Interaction: An Empirical Study of Contrasting Office Automation Effects on Task Performance and Workload. Appl. Sci. 2020, 10, 1288.Lee, B.C.; Park, J.; Jeong, H.; Park, J. Validation of Trade-Off in Human–Automation Interaction: An Empirical Study of Contrasting Office Automation Effects on Task Performance and Workload. Appl. Sci. 2020, 10, 1288.https://hdl.handle.net/1969.6/87834https://hdl.handle.net/1969.6/87834https://hdl.handle.net/1969.6/87834https://hdl.handle.net/1969.6/87834Automation aims to improve the task performance and the safety of human operators. The success of automation can be facilitated with well-designed human–automation interaction (HAI), which includes the consideration of a trade-off between the benefits of reliable automation and the cost of Failed automation. This study evaluated four different types of HAIs in order to validate the automation trade-off, and HAI types were configured by the levels and the statuses of office automation. The levels of automation were determined by information amount (i.e., Low and High), and the statues were decided by automation function (i.e., Routine and Failed). Task performance including task completion time and accuracy and subjective workload of participants were measured in the evaluation of the HAIs. Relatively better task performance (short task completion time and high accuracy) were presented in the High level in Routine automation, while no significant effects of automation level were reported in Failed automation. The subjective workload by the National Aeronautics and Space Administration (NASA) Task Load Index (TLX) showed higher workload in High and Failed automation than Low and Failed automation. The type of sub-functions and the task classification can be estimated as major causes of automation trade-off, and dissimilar results between empirical and subjective measures need to be considered in the design of effective HAI.Automation aims to improve the task performance and the safety of human operators. The success of automation can be facilitated with well-designed human–automation interaction (HAI), which includes the consideration of a trade-off between the benefits of reliable automation and the cost of Failed automation. This study evaluated four different types of HAIs in order to validate the automation trade-off, and HAI types were configured by the levels and the statuses of office automation. The levels of automation were determined by information amount (i.e., Low and High), and the statues were decided by automation function (i.e., Routine and Failed). Task performance including task completion time and accuracy and subjective workload of participants were measured in the evaluation of the HAIs. Relatively better task performance (short task completion time and high accuracy) were presented in the High level in Routine automation, while no significant effects of automation level were reported in Failed automation. The subjective workload by the National Aeronautics and Space Administration (NASA) Task Load Index (TLX) showed higher workload in High and Failed automation than Low and Failed automation. The type of sub-functions and the task classification can be estimated as major causes of automation trade-off, and dissimilar results between empirical and subjective measures need to be considered in the design of effective HAI.en-USAttribution 3.0 United StatesAttribution 3.0 United Stateshttp://creativecommons.org/licenses/by/3.0/us/http://creativecommons.org/licenses/by/3.0/us/human-automation interactionuser experienceworkloadtask performancelevel and status of automationevaluationhuman-automation interactionuser experienceworkloadtask performancelevel and status of automationevaluationArticle10.3390/app1004128810.3390/app1004128810.3390/app1004128810.3390/app10041288