Sage Journals: Discover world-class research

Abstract

This pilot study integrates immersive virtual reality (VR) and physiological measures to develop an improved measure of spatial ability (SpA) and situation awareness (SA) in U.S. Naval Aviation. Existing static measures often suffer from limitations such as obtrusiveness, ceiling/floor effects, and being disconnected from operational contexts, even though both SpA and SA are critical to U.S. Naval Aviation. Therefore, we developed Assessing Spatial Abilities in Naval Aviation (ASANA), a custom simulated environment where participants aerially navigate to waypoints using a reference map that rotates across multiple headings, providing a dynamic, realistic task to evaluate SpA. Additionally, the physiological signals of heart rate variability, skin conductance, pupillometry, and eye tracking were recorded to explore their potential as real-time SA indicators. Participants from U.S. Naval Aviation schoolhouses completed both established SpA assessments and a mission in ASANA. Preliminary findings show that navigation performance aligns with traditional SpA and SA metrics, and that physiological markers such as heart rate variability and skin conductance correlate with performance outcomes. Future work will assess larger samples and event-based analyses to better understand these constructs and inform training and selection protocols for U.S. Naval Aviation.

Keywords

virtual reality situation awareness spatial ability physiological signals aviation

Get full access to this article

View all access options for this article.

References

Bayro

McGarry

NeSmith

Coyne

J. T.

Jeong

(2025, March). ASANA: A VR-based simulation for assessing spatial ability and situational awareness in Naval aviation. In 2025 IEEE Conference on Virtual Reality and 3D User Interfaces Abstracts and Workshops (VRW) (pp. 1095–1100). IEEE.

Coyne

J. T.

Draheim

Sibley

C. S.

Armendariz

Melick

Foroughi

Burgoyne

A. P.

Engle

R. W.

(2024). Evaluation of new measures of spatial ability and attention control for selection of naval flight students In: Human Factors in Design, Engineering, and Computing. AHFE (2024) International Conference (159) AHFE International.

D’Oliveira

T. C.

(2004). Dynamic spatial ability: An exploratory analysis and a confirmatory study. International Journal of Aviation Psychology, 14(1), 19–38.

Endsley

M. R.

(1995). Toward a theory of situation awareness in dynamic systems. Human Factors, 37(1), 32–64.

Lochhead

Hedley

Çöltekin

Fisher

(2022). The immersive mental rotations test: Evaluating spatial ability in virtual reality. Frontiers in Virtual Reality, 3, 1–19.

Nguyen

Lim

C. P.

Nguyen

N. D.

Gordon-Brown

Nahavandi

(2018). A review of situation awareness assessment approaches in aviation environments. IEEE Systems Journal, 13, 3590–3603.

Salehi

Razavi

Smith

Dixit

(2024). Integrated eye-tracking and EEG data collection and synchronization for virtual reality-based spatial ability assessments. Intelligent human systems integration (IHSI 2024): Integrating people and intelligent systems (119). AHFE International.

Smith

Clark

Endsley

(2024). Multimodal physiological models of situation awareness. Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 68(1), 367–372.

Yang

Zhang

(2009). The impact of spatial ability on air traffic controller situation awareness and mental workload. In: Proceedings of the 9th International Conference of Chinese Transportation Professionals (ICCTP) (pp. 4460–4467).

10.

Zhang

Yang

Liang

Pitts

B. J.

Prakah-Asante

Curry

Duerstock

Wachs

J. P.

(2023). Physiological measurements of situation awareness: A systematic review. Human Factors, 65, 737–758.

Immersive VR for Evaluating Spatial Ability,Situation Awareness,and Psychophysiological Responses in Naval Aviation: A Preliminary Study

Abstract

Keywords

Get full access to this article

References