Definition
Spatial visualization was defined by McGee (1979) as “the ability to mentally rotate, manipulate, and twist two- and three-dimensional stimulus objects” (p. 896). Although, better visualization skills can be achieved through childhood education and skill training, researches show it is still possible to train spatial visualization skills with various types of exercises in adults. It is not a new idea to use educational games and computer software in the education and teaching of spatial skills (Wells 2003; Uttal et al. 2013; Anderson et al. 2003; Kaufmann et al. 2000). Researches show it is possible to use VR/AR platforms to improve visualization skills. VR/AR platforms are a part of digital media, and special applications which focuses on the instruction of the visualizations skills can be developed with the support of the features and attributes of this media. Current best practices...
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References
Anderson, L., Esser, J., Interrante, V.: Virtual environment for conceptual design in architecture. In: Proceedings of the Workshop on Virtual Environments 2003 (EGVE '03), pp. 57–63. ACM, New York (2003). https://doi.org/10.1145/769953.769960
AWE Visual Spatial Skills Overview.: Retrieved from http://www.engr.psu.edu/awe/misc/arps/visualspatialweb%2003_22_05.pdf (2005) Accessed 22 Mar 2018
Balkaya, B., Catak, G.: Why games are fun? The reward system in the human brain. In: Bostan, B. (ed.) Gamer Psychology and Behavior International Series on Computer Entertainment and Media Technology, pp. 21–38. Springer International Publishing, Switzerland (2016)
Cherney, I.D., Coaller, M.: Sex differences in line judgement: relation to mathematics preparation and strategy use. Percept. Mot. Skills. 100, 615–627 (2005)
Cherney, I.D., London, K.L.: Gender – linked differences in the toys, television shows, computer games and outdoor activities of 5-to 13-year-old children. Sex Roles. 54, 717–726 (2006)
Clark, R.E.: Media will never influence learning. Educ. Technol. Res. Dev. 42(2), 21–29 (1994)
Edutrends http://observatory.itesm.mx/edu-trends-augmented-and-virtual-reality (2018) Accessed 17 May 2018
French, J.W., Ekstrom, R.B., Price, L.A.: Kit of Reference Tests for Cognitive Factors. Educational Testing Service, Princeton (1963)
González, R.C., Gutierrez, J.M., Dominguez, M.G., Carrodeguas, M.C.M.: Virtual technologies to develop visual-spatial ability in engineering students. EURASIA J. Math. Sci. Technol. Educ. 13(2), 441–468 (2017)
Guay, R.: Purdue Spatial Visualization Test. West Lafayette, Purdue Research Foundation (1976)
Gutiérrez, J.M., Dominguez, M.G., González, C.R., Corredeguas, M.C.M.: Using different methodologies and technologies to training spatial skill in engineering graphic subjects. In: 2013 I.E. Frontiers in Education Conference (FIE), Oklahoma City, OK. pp. 362–368. (2013). https://doi.org/10.1109/FIE.2013.6684848
Hegarty, M., Montello, D.R., Richardson A.E. et al. Spatial abilities at different scales: individual differences in aptitude-test performance and spatial-layout learning. Intelligence. 34(2), 151–176 (2006)
Hyde, J.S.: Women in science: gender similarities in abilities and sociocultural forces. In: Ceci, S.J., Williams, W.M. (eds.) Why Aren’t More Women in Science?: Top Researchers Debate the Evidence, pp. 131–145. American Psychological Association, Washington DC (2007)
Kaufmann, H., Schmalstieg, D., Wagner, M.: Construct 3D: a virtual reality application for mathematics and geometry education. Educ. Inf. Technol. 5(4), 263–276 (2000). https://doi.org/10.1023/A:1012049406877
Kosslyn, S.M.: Mental imagery. In: Kosslyn, S.M., Osherson, D.N. (eds.) Visual Cognition: an Invitation to Cognitive Science, vol. 2, pp. 267–296. MIT Press, Cambridge, MA (1995)
Kyllonen, P.C., Lohman, D.F., Snow, R.E.: Effects of aptitudes, strategy training and task facets on spatial task performance. J. Educ. Psychol. 76(1), 130–145 (1984)
Linn, M.C., Petersen, A.C.: Emergence and characterization of sex differences in spatial ability: a meta-analysis. Child Dev. 56(6), 1479–1498 (1985)
Maeda, Y., Yoon, S.Y., Kim-Kang, G., Imbrie, P.K.: Psychometric properties of the revised PSVT: R for measuring first year engineering students' spatial ability. Int. J. Eng. Educ. 29(3), 763–776 (2013)
Mayer, R.E.: Multimedia learning. Psychol. Learn. Motiv. 41, 85–139 (2002)
McGee, M.G.: Human spatial abilities: psychometric studies and environmental, genetic, hormonal and neurological influences. Psychol. Bull. 86(5), 899–918 (1979)
Mental Imagery and Human-Computer Interaction Lab of National University of Singapore, Department of Psychology. Retrieved from http://www.nmr.mgh.harvard.edu/mkozhevnlab/ Accessed 22 Mar 2018
Metzler, J., Shepard, R.N.: Transformational studies of the internal representation of three-dimensional objects. In: Theories in Cognitive Psychology: the Loyola Symposium, pp. 147–201. Hillsdale, NJ, Erlbaum (1974)
Meyer, M., Koehler, M.S.: Internal influences on gender differences in mathematics. In: Fennema, E., Leder, G.C. (eds.) Mathematics and Gender, pp. 60–95. Teachers College Press, New York (1990)
Neubauer, A.C., Bergner, S., Schatz, M.: Two- vs. three-dimensional presentation of mental rotation tasks: sex differences and effects of training on performance and brain activation. Intelligence. 38(5), 529–539 (2010)
Peters, M., Laeng, B., Latham, K., Jackson, M., Zaiyouna, R., Richardson, C.: A redrawn Vandenberg and Kuse mental rotations test: different versions and factors that affect performance. Brain Cogn. 28(1), 39–58 (1995)
Rafi, A., Samsudin, K.A., Said, C.S.: Training in spatial visualization: The effects of training method and gender. Educ. Technol. Soc. 11(3), 127–140 (2008)
Rakic, P., Arellano, J., Breunig, J.: Development of the primate cerebral cortex. In: Gazzaniga, M. (ed.) The Cognitive Neurosciences, pp. 7–28. The MIT Press, London (2009)
Roblyer, M.D., Doering, A.H.: Integrating Educational Technology into Teaching, 5th edn. Allyn & Bacon, Boston (2010)
Schnabel, M.A., Kvan, T.: Spatial understanding in immersive virtual environments. Int. J. Archit. Comput. 1(4), 435–448 (2003)
Shepard, R., Metzler, J.: Mental rotation of three dimensional objects. Science. 171(3972), 701–703 (1971)
Sorby, S.A.: Educational research in developing 3-D spatial skills for engineering students. Int. J. Sci. Educ. 31(3), 459–480 (2009)
Sorby, S.A., Leopold, C., Gorska, R.: Cross-cultural comparisons of gender differences in the spatial skills of engineering students. J. Women Minorities Sci. Eng. 5, 279–291 (1999)
Tsutsumi, E.: A mental cutting test using drawings of intersections. J. Geometry Graphics. 8, 117–126 (2004)
Uttal, D.H., Meadow, N.G., et al.: The malleability of spatial skills: a meta-analysis of training studies. Psychol. Bull. 139(2), 352–402 (2013)
Vandenberg, S.G., Kuse, A.R.: Mental rotations, a group test of three-dimensional spatial visualization. Percept. Mot. Skills. 47(2), 599–604 (1978)
Wells, M.A.: Critique of virtual reality in the architectural design process. Tehnical report R-94-3. In: Human Interface Technology Laboratory FJ-15. University of Washington, Seattle (2003)
Witkin, H.A., Moore, C.A., Goodenough, D.R., Cox, P.W.: Field- dependent and field- independent cognitive styles and their educational implications. Rev. Educ. Res. 47(1), 1–64 (1977)
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Tuker, C. (2024). Training Spatial Skills with Virtual Reality and Augmented Reality. In: Lee, N. (eds) Encyclopedia of Computer Graphics and Games. Springer, Cham. https://doi.org/10.1007/978-3-031-23161-2_173
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