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Рeculiarities of control commands generation for oculographic interfaces under the conditions of vestibular impacts

© 2023 Ya. A. Turovsky, V. Yu. Alekseev, L. G. Muradova, A. P. Mironkin

Voronezh State University, 394018 Voronezh, Universitetskaya pl., 1, Russia
V. A. Trapeznikov Institute of Control Sciences of Russian Academy of Sciences, 117997 Moscow, Profsoyuznaya street, 65, Russia

Received 11 Jun 2022

The article presents the results of a study of the parameters of human eye movement when using an oculographic interface to control a self-propelled chassis. In the course of the experiment, it was shown that from race to race, the time spent by the subjects on one race was reduced, the number of errors and the number of subjects who did not successfully complete their races decreased. On the basis of cluster analysis, individual typological features of the reaction of eye movement to the movement of the user’s head during the execution of the main commands for controlling the self-propelled chassis were revealed. It is shown that when the selfpropelled chassis is moving, the generation of the “forward” and “backward” commands by the optical-oculographic interface is generally carried out according to the scenario common for users, and does not require correction when controlling the self-propelled chassis. At the same time, the generation of turn commands is a more individual process, which is associated both with the calibration of the device and with the individual position of the user’s head and eyes and, therefore, requires more careful control when using oculographic interfaces.

Key words: oculography, oculographic interface, human-computer interface

DOI: 10.31857/S0235009223010080  EDN: AUFZKR

Cite: Ya. A. Turovsky, Alekseev V. Yu., Muradova L. G., Mironkin A. P. Osobennosti generatsii komand dlya okulograficheskikh interfeisov v usloviyakh vestibulyarnykh vozdeistvii [Рeculiarities of control commands generation for oculographic interfaces under the conditions of vestibular impacts]. Sensornye sistemy [Sensory systems]. 2023. V. 37(1). P. 49–59 (in Russian). doi: 10.31857/S0235009223010080

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