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Virtual Reality serving Mathematics Education: Dynamical Visualization of Multivariable Functions. Yehuda Badihi 1, David Zeitoun 2 Th. Dana Picard 1 1.Jerusalem College of Technology 2. Orot College of Education. 1 Supported by the Israel Science Foundation, research
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Virtual Reality serving Mathematics Education: Dynamical Visualization of Multivariable Functions Yehuda Badihi 1, David Zeitoun 2 Th. Dana Picard 1 1.Jerusalem College of Technology 2. Orot College of Education 1 Supported by the Israel Science Foundation, research grant number 1340/05 2 Supported by a Meital R&D grant
Representations of a mathematical object • Multiple representations of the same objects • The given representation may be static, despite the dynamical nature of the rule being taught • Transfers between different representations • Complete mastering requires a permanent transfer from one kind of representation to another kind. MEITAL 2010
Strange 3D plots: treatment of discontinuities MEITAL 2010
Strange 3D plots: Mathematical Differences MEITAL 2010
Visualisation of the plots: Polar Coordinates MEITAL 2010
Incomplete is better than false MEITAL 2010
Right coordinates are not a panacea MEITAL 2010
Why to look for another technology? • Conventional representations: Use a global viewing and zooming . • It does not change the nature of the representation We wish: • A dynamic viewing based on flying through given path: • dynamical change of the values of the parameters. • Permanent recalculation of “positions”. MEITAL 2010
Virtual Reality – what’s that? Basic notions • Synthetic physical computer-based environment. • 3D and Stereoscopic Imaging of the environment as close as possible to real world perception • The viewing and interaction with the environment is represented as in the reality (by head and eye movements etc.). • Audio surrounded representation of the objects. VR requires advanced technology (hardware and software). MEITAL 2010
“Virtual Reality” Technology and Mathematical Imaging The Main principle In order for the Student to experience a “world picture” of the function, it is necessary for him/her to be placed and exposed to the best representation of the function, including its problematic characteristics (discontinuities, singular points etc.). MEITAL 2010
Virtual reality and Immersion The VR technology provides a feeling of being inside the picture by effective presence, orientation and temporarydetachment from the surroundings outside the scenario. MEITAL 2010
Path Lines for the visualization of the Discontinuities MEITAL 2010 12
Properties/skills and derivatives Presence • Being located as an integral part of the virtual environment • In other words: sensual interaction, both active and passive, with the environment MEITAL 2010
Properties/skills and derivatives Orientation • Possibility to “feel” a world image • Personal place inside the world • Absolute and relative positioning of objects • Depth perception (3D) • Within the range of eye catching • High resolution => separation of relevant details MEITAL 2010
Properties/skills and derivatives Immersion: live experience • Reactions to stimuli in virtual world similar to their real world counterpart • Disconnection from the stimuli in the real environment The more deeply lively experienced the learning process the more internalized its results (Ausburn and Ausburn, 2004; Barnett et al, 2005). Have "a physical model that you can feel in your hands“ (JCT student, 2008). MEITAL 2010
Among the principles for virtual imaging of mathematical functions • VR perception will enhance the physical meaning of the function • The VR imaging provides to the learner tools for a precise, sensual distinction without in-between, of changes in the function behavior • VR imaging will faithfully show all the points of the graph of the function’ including those which are hard to visualize with more classical technical means (CAS, plotters, etc.) MEITAL 2010
Among the principles for virtual imaging of mathematical functions 4. Audio Modality: • complements visual effects 5. The color resolution has a low level of influence on the confidence • Possible exception: if color perception and understanding is an integral part of the requested skills MEITAL 2010
Among the principles for virtual imaging of mathematical functions • Presence of an external observer • Part of the virtual environment • “hidden” communication 7. The added value of a stereophonic experience is greater than the stereoscopic visual experience • Sound added to the dynamical presentation of movement 8. The usage of VR should slow down the extinction of the learnt material MEITAL 2010
Basic configuration: presentation, presence and orientation MEITAL 2010
Where are we currently? • Double development • Interactive views from outside: not yet VR, GUI driven • VR system • Future tasks: • Sound addition • Permanent maintenance • Write the support material MEITAL 2010
A few references • A. Arcavi (2003). The role of visualization in the learning of Mathematics, Educ. St. in Math. 52. • C. Sik-Lanyi, Z. Lanyi,A. Tilinger (2003), Using Virtual reality to Improve Space and Depth Perception, J. of Information Technology Education 2. • L. Ausburn, F. Ausburn (2004). Desktop Virtual Reality: A Powerful New Technology for Teaching and Research in Industrial Teacher. J. of Industrial Teacher Educ. 41. • Dana-Picard Th. (2007). Motivating constraints of a pedagogy-embedded Computer Algebra System, Int. J. of Sc. and Math. Educ. 5 (2) MEITAL 2010