Using Tactile Cueing to Enhance Spatial Awareness under Degraded Visual Environment

Abstract

Spatial orientation is critical for air operations. Perception of orientation is continuously maintained by accurate information from the visual, vestibular, and somatosensory systems in daily terrestrial activities. The various contributions of these senses can be significantly altered in variable gravitoinertial environments, or when one of the sensory cues is markedly reduced. The visual orientation system can be compromised during low visibility, or as a result of sudden loss of visual cues during `brownout' while flying/landing in the desert or during `whiteout' while flying/landing in snowy terrains. Current desert operations have led to an unacceptable number of terminal area aborts, mishaps and fatalities involving rotary wing aircraft throughout NATO due to "brownout". The use of a tactile interface as a "more natural" approach to convey position and motion perception was proposed some years ago [1]. Proof of concept studies has been conducted [2]. However, it is known that human perception of motion in 3 dimensional space involves roll, pitch, yaw, heave, sway and surge. Specifically, our ability to detect roll, pitch and heave are less sensitive. This study is to investigate if tactile cueing can enhance the detection and/or correction of roll, pitch and heave movements in degraded visual environments. A six degrees-of-freedom motion platform (MOOG 6DOF2000E) was used to generate the requisite motion in roll, pitch and heave separately. The tactile display system consists of a torso vest with a 3 rows by 8 columns array of tactors (EAI Inc C2 model), and tactors on two shoulder and two thighs straps respectively. Based on tactile cueing, blind-folded subject were to 1) indicate motion perception when devoid of all visual, auditory and artificial tactile cues, 2) return to vertical from an offset, 3) maintain straight and level while the platform is continuously in motion. The first study examines the effects of tactile cues along the spinal axis (heave mo

Document Details

Document Type

Technical Report

Publication Date

Oct 01, 2009

Accession Number

ADA567922

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