Measuring the Drag Latency of Touchscreen Displays for Human-in-the-Loop Simulator Experiments

Vrouwenvelder, Simon; Postema, F. N.; Pool, Daan M.

doi:10.2514/6.2021-0896

AIAA Scitech 2021 Forum 2021

DOI: 10.2514/6.2021-0896

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Measuring the Drag Latency of Touchscreen Displays for Human-in-the-Loop Simulator Experiments

Simon Vrouwenvelder

F. N. Postema

Daan M. Pool

Abstract: This paper presents a novel methodology for measuring the drag latency of touchscreens. Drag latency is a characteristic of touch hardware that can affect key metrics of human performance as typically collected in human-in-the-loop (simulator) experiments. The proposed methodology uses a laser and laser sensor to obtain an external measurement of stylus position that is compared, in time, with the digitally measured touch event data. The drag latency is estimated as the time shift required to align the locatio… Show more

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Mitigation of Biodynamic Feedthrough for Touchscreens on the Flight Deck

Khoshnewiszadeh

Pool

2021

International Journal of Human–Computer Interaction

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Biodynamic feedthrough (BDFT) is a key issue for touchscreen operations on the future flight deck, as cockpit accelerations due to turbulence leave pilots vulnerable to erroneous touches that disrupt task performance. This research focuses on the implementation of a software-based cancellation approach to mitigate the adverse effects of BDFT in touchscreen dragging tasks. A flight-simulator experiment with 18 participants was performed to estimate models of BDFT dynamics for horizontal and vertical touchinputs on a primary flight display. The averaged BDFT models were used to cancel BDFT in the same continuous dragging task used for model identification and a discrete point-to-point dragging task. While for the continuous task the cancellation enabled 63% mitigation in BDFT, the same cancellation was ineffective for the discrete task, due to reduced BDFT susceptibility. Overall, the results show that while model-based BDFT cancellation can be highly effective, a key technical challenge will be ensuring it is sufficiently task-adaptive.

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Mitigation of Biodynamic Feedthrough for Touchscreens on the Flight Deck

Khoshnewiszadeh

Pool

2021

International Journal of Human–Computer Interaction

Self Cite

View full text Add to dashboard Cite

show abstract

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Measuring the Drag Latency of Touchscreen Displays for Human-in-the-Loop Simulator Experiments

Cited by 1 publication

References 18 publications

Mitigation of Biodynamic Feedthrough for Touchscreens on the Flight Deck

Mitigation of Biodynamic Feedthrough for Touchscreens on the Flight Deck

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