Top

Published in:

01-03-2017 | Research Article

The virtual reality head-mounted display Oculus Rift induces motion sickness and is sexist in its effects

Authors: Justin Munafo, Meg Diedrick, Thomas A. Stoffregen

Published in: Experimental Brain Research | Issue 3/2017

Abstract

Anecdotal reports suggest that motion sickness may occur among users of contemporary, consumer-oriented head-mounted display systems and that women may be at greater risk. We evaluated the nauseogenic properties of one such system, the Oculus Rift. The head-mounted unit included motion sensors that were sensitive to users’ head movements, such that head movements could be used as control inputs to the device. In two experiments, seated participants played one of two virtual reality games for up to 15 min. In Experiment 1, 22% of participants reported motion sickness, and the difference in incidence between men and women was not significant. In Experiment 2, motion sickness was reported by 56% of participants, and incidence among women (77.78%) was significantly greater than among men (33.33%). Before participants were exposed to the head-mounted display system, we recorded their standing body sway during the performance of simple visual tasks. In both experiments, patterns of pre-exposure body sway differed between participants who (later) reported motion sickness and those who did not. In Experiment 2, sex differences in susceptibility to motion sickness were preceded by sex differences in body sway. These postural effects confirm a prediction of the postural instability theory of motion sickness. The results indicate that users of contemporary head-mounted display systems are at significant risk of motion sickness and that in relation to motion sickness these systems may be sexist in their effects.

Allen B, Hanley T, Rokers B, Green CS (2016) Visual 3D motion acuity predicts discomfort in 3D stereoscopic environments. Entertain Comput 13:1–9CrossRef

Balasubramaniam R, Riley MA, Turvey MT (2000) Specificity of postural sway to the demands of a precision task. Gait Posture 11:12–24CrossRefPubMed

Bonnet CT, Faugloire EM, Riley MA, Bardy BG, Stoffregen TA (2006) Motion sickness preceded by unstable displacements of the center of pressure. Hum Move Sci 25:800–820CrossRef

Boyd D (2014). Is the Oculus Rift sexist? http://qz.com/192874/is-the-oculus-rift-designed-to-be-sexist/

Chang C-H, Pan W-W, Tseng L-Y, Stoffregen TA (2012) Postural activity and motion sickness during video game play in children and adults. Exp Brain Res 217:299–309CrossRefPubMed

Chen Y-C, Dong X, Chen F-C, Stoffregen TA (2012) Control of a virtual avatar influences postural activity and motion sickness. Ecol Psychol 24:279–299CrossRef

Chiari L, Rocchi L, Cappello A (2002) Stabilometric parameters are affected by anthropometry and foot placement. Clin Biomech 17:666–677CrossRef

Diels C (2014) Will autonomous vehicles make us sick? In: Sharples S, Shorrock S (eds) Contemporary ergonomics and human factors. CRC Press, Boca Raton, pp 301–307

Dong X, Yoshida K, Stoffregen TA (2011) Control of a virtual vehicle influences postural activity and motion sickness. J Exp Psychol Appl 17:128–138CrossRefPubMed

Draper MH, Virre ES, Furness TA, Gawron VJ (2001) Effects of image scale and system time delay on simulator sickness within head-coupled virtual environments. Hum Fact 43:129–146CrossRef

Drummond PD (2005) Triggers of motion sickness in migraine sufferers. Headache 45:653–656CrossRefPubMed

Era P, Sainio P, Koskinen S, Haavisto P, Vaara M, Aromaa A (2006) Postural balance in a random sample of 7979 subjects aged 40 years and over. Gerontology 52:204–213CrossRefPubMed

Giammarco EA, Schneider TJ, Carswell JJ, Knipe WS (2015) Video game preferences and their relation to career interests. Pers Individ Differ 73:98–104CrossRef

Golding JF (2006) Motion sickness susceptibility. Autonom Neurosci Basic Clin 129:67–76CrossRef

Grannell C (2013). Why iOS7 is making some users sick. http://www.theguardian.com/technology/2013/sep/27/ios-7-motion-sickness-nausea. Accessed June 23 2016

Ihlen EA (2012) Introduction to multifractal detrended fluctuation analysis in Matlab. Front Physiol 3:141CrossRefPubMedPubMedCentral

Ihlen EA, Vereijken B (2010) Interaction-dominant dynamics in human cognition: beyond 1/ƒ α fluctuation. J Exp Psychol Gen 139:436–463CrossRefPubMed

Ihlen EA, Skjaeret N, Vereijken B (2013) The influence of center-of-mass movements on the variation in the structure of human postural sway. J Biomech 46:484–490CrossRefPubMed

Kelty-Stephen DG, Palatinus K, Saltzman E, Dixon JA (2013) A tutorial on multifractality, cascades, and interactivity for empirical times series in ecological science. Ecol Psychol 25:1–62CrossRef

Kennedy RS, Lilienthal MG (1994) Measurement and control of motion sickness after-effects from immersion in virtual reality. In: Proceedings of “Virtual Reality and Medicine: the Cutting Edge”. New York: SIG-Advanced Applications, pp 111–119

Kennedy RS, Dunlap WP, Fowlkes JE (1990) Prediction of motion sickness susceptibility. In: Crampton GH (ed) Motion and space sickness. CRC Press, Boca Raton FL, pp 179–215

Kennedy RS, Lane NE, Berbaum KS, Lilienthal MG (1993) Simulator sickness questionnaire: an enhanced method for quantifying simulator sickness. Int J Aviat Psychol 3:203–220CrossRef

Kennedy RS, Drexler J, Kennedy RC (2010) Research in visually induced motion sickness. Appl Ergonom 41:494–503CrossRef

Kimura D (1997) Sex, sexual orientation and Sex hormones influence human cognitive functions. Biomed Rev 7:33–39CrossRef

Klosterfalfen S, Pan F, Kellerman S, Enck P (2006) Gender and race as determinants of nausea induced by circular vection. Gend Med 3:236–242CrossRef

Koslucher FC, Haaland E, Stoffregen TA (2014) Body load and the postural precursors of motion sickness. Gait Posture 39:606–610CrossRefPubMed

Koslucher FC, Haaland E, Malsch A, Webeler J, Stoffregen TA (2015) Sex differences in the incidence of motion sickness induced by linear visual oscillation. Aviat Med Hum Perform 86:787–793CrossRef

Koslucher FC, Haaland E, Stoffregen TA (2016a) Sex differences in visual performance and postural sway precede sex differences in visually induced motion sickness. Exp Brain Res 234:313–322. doi:10.1007/s00221-015-4462-y CrossRefPubMed

Koslucher FC, Munafo J, Stoffregen TA (2016b) Postural sway in men and women during nauseogenic motion of the illuminated environment. Exper Brain Res 234:2709–2720. doi:10.1007/s00221-016-4675-8 CrossRef

Lackner JR, DiZio P (2006) Space motion sickness. Exp Brain Res 175:377–399CrossRefPubMed

Lang DJ (2016) For virtual reality creators, motion sickness a real issue. http://phys.org/news/2016-03-virtual-reality-creators-motion-sickness.html. Accessed May 9 2016

Lawther A, Griffin MJ (1986) The motion of a ship at sea and the consequent motion sickness amongst passengers. Ergonomics 29:535–552CrossRefPubMed

Lawther A, Griffin MJ (1988) A survey of the occurrence of motion sickness amongst passengers at sea. Aviat Space Environ Med 59:399–406PubMed

Lewis T (2015) When will virtual-reality headsets stop making people sick? http://www.livescience.com/50129-virtual-reality-nausea-sickness.html. Accessed June 23 2016

Lin D, Seol H, Nussbaum MA, Madigan ML (2008) Reliability of COP-based postural sway measures and age-related differences. Gait Posture 28:337–342CrossRefPubMed

McConville KMV, Milosevic M (2014) Active video game head movement inputs. Pers Ubiq Comput 18:253–257CrossRef

Merhi O, Faugloire E, Flanagan M, Stoffregen TA (2007) Motion sickness, console video games, and head mounted displays. Hum Fact 49:920–934CrossRef

Munafo J, Curry C, Wade MG, Stoffregen TA (2016) The distance of visual targets affects the spatial magnitude and multifractal scaling of standing body sway in younger and older adults. Exp Brain Res 234:2721–2730CrossRefPubMed

Read JCA, Bohr I (2014) User experience while viewing stereoscopic 3D television. Ergonomics 57:1140–1153CrossRefPubMedPubMedCentral

Regan EC, Price KR (1994) The frequency of occurrence and severity of side-effects of immersion virtual reality. Aviat Space Environ Med 65:527–530PubMed

Riccio GE, Stoffregen TA (1991) An ecological theory of motion sickness and postural instability. Ecol Psychol 3:195–240CrossRef

Rolnick A, Lubow RE (1991) Why is the driver rarely motion sick? The role of controllability in motion sickness. Ergonomics 34:867–879CrossRefPubMed

Stanney K, Salvendy G, Deisinger J, DiZio P, Ellis S, Ellision J, Fogleman G, Gallimore J, Hettinger L, Kennedy R, Lackner J, Lawson B, Maida J, Mead A, Mon-Williams M, Newman D, Piantanida T, Reeves L, Riedel O, Singer M, Stoffregen T, Wann J, Welch R, Wilson J, Witmer R (1998) Aftereffects and sense of presence in virtual environments: formulation of a research and development agenda. Report sponsored by the Life Sciences Division at NASA headquarters. Int J Hum Comput Interact 10:135–187CrossRefPubMed

Stevens SC, Parsons MG (2002) Effects of motion at sea on crew performance: a survey. Mar Technol 39:29–47

Stoffregen TA (1985) Flow structure versus retinal location in the optical control of stance. J Exper Psychol: Human Percept Perf 11:554–565

Stoffregen TA, Smart LJ (1998) Postural instability precedes motion sickness. Brain Res Bull 47:437–448CrossRefPubMed

Stoffregen TA, Hettinger LJ, Haas MW, Roe M, Smart LJ (2000a) Postural instability and motion sickness in a fixed-base flight simulator. Hum Fact 42:458–469CrossRef

Stoffregen TA, Pagulayan RJ, Bardy BG, Hettinger LJ (2000b) Modulating postural control to facilitate visual performance. Hum Move Sci 19:203–220CrossRef

Stoffregen TA, Faugloire E, Yoshida K, Flanagan M, Merhi O (2008) Motion sickness and postural sway in console video games. Hum Fact 50:322–331CrossRef

Stoffregen TA, Yoshida K, Villard S, Scibora L, Bardy BG (2010) Stance width influences postural stability and motion sickness. Ecol Psychol 22:169–191CrossRef

Stoffregen TA, Chen F-C, Varlet M, Alcantara C, Bardy BG (2013) Getting your sea legs. PLOS ONE 8(6):e66949. doi:10.1371/journal.pone.0066949 CrossRefPubMedPubMedCentral

Stoffregen TA, Chen Y-C, Koslucher FC (2014) Motion control, motion sickness, and the postural dynamics of mobile devices. Exp Brain Res 232:1389–1397CrossRefPubMed

Turner M (1999) Motion sickness in public road transport: passenger behaviour and susceptibility. Ergonomics 42:444–461CrossRefPubMed

Turner M, Griffin MJ (1999) Motion sickness in public road transport: the relative importance of motion, vision, and individual differences. Br J Psychol 90:519–530CrossRefPubMed

Voyer D, Voyer S, Bryden MP (1995) Magnitude of sex differences in spatial abilities: a meta-analysis and consideration of critical variables. Psychol Bull 117:250–270CrossRefPubMed

Title: The virtual reality head-mounted display Oculus Rift induces motion sickness and is sexist in its effects
Authors: Justin Munafo
Meg Diedrick
Thomas A. Stoffregen
Publication date: 01-03-2017
Publisher: Springer Berlin Heidelberg
Published in: Experimental Brain Research / Issue 3/2017
Print ISSN: 0014-4819
Electronic ISSN: 1432-1106
DOI: https://doi.org/10.1007/s00221-016-4846-7

Keynote webinar | Spotlight on medication adherence

Springer Medicine

The virtual reality head-mounted display Oculus Rift induces motion sickness and is sexist in its effects

Abstract

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 3/2017

Initiation of forward gait with lateral occurrence of emotional stimuli: general findings and relevance for pedestrians crossing roads

Temporal prediction abilities are mediated by motor effector and rhythmic expertise

Investigating three types of continuous auditory feedback in visuo-manual tracking

Motor hysteresis in a sequential grasping and pointing task is absent in task-critical joints

Embodiment and the origin of interval timing: kinematic and electromyographic data

Aperture extent and stimulus speed affect the perception of visual acceleration