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Augmented topological maps for three-dimensional navigation

Published online by Cambridge University Press:  08 October 2013

Herbert Peremans
Affiliation:
Active Perception Lab, FTEW-MTT, Universiteit Antwerpen, 2000 Antwerpen, Belgium. herbert.peremans@ua.ac.behttp://www.ua.ac.be/main.aspx?c=herbert.peremansDieter.Vanderelst@ua.ac.behttp://bitsofbats.weebly.com/
Dieter Vanderelst
Affiliation:
Active Perception Lab, FTEW-MTT, Universiteit Antwerpen, 2000 Antwerpen, Belgium. herbert.peremans@ua.ac.behttp://www.ua.ac.be/main.aspx?c=herbert.peremansDieter.Vanderelst@ua.ac.behttp://bitsofbats.weebly.com/

Abstract

We describe an augmented topological map as an alternative for the proposed bicoded map. Inverting causality, the special nature of the vertical dimension is then no longer fixed a priori and the cause of specific navigation behavior, but a consequence of the combination of the specific geometry of the experimental environment and the motor capabilities of the experimental animals.

Type
Open Peer Commentary
Copyright
Copyright © Cambridge University Press 2013 

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References

Kuipers, B., Browning, R., Gribble, B., Hewett, M. & Remolina, E. (2000) The spatial semantic hierarchy. Artificial Intelligence 119:191233.Google Scholar
Thiele, H. & Winter, Y. (2005) Hierarchical strategy for relocation of food targets in flower bats: Spatial memory versus cue-directed search. Animal Behaviour 69:315–27.Google Scholar
Veelaert, P. & Peremans, H. (1999) Flexibility maps: A formalisation of navigation behaviours. Robotics and Autonomous Systems 27:151–69.CrossRefGoogle Scholar
Winter, Y. & Stich, K. P. (2005) Foraging in a complex naturalistic environment: Capacity of spatial working memory in flower bats. Journal of Experimental Biology 208:539–48.Google Scholar
Winter, Y., von Merten, S. & Kleindienst, H.-U. (2004) Visual landmark orientation by flying bats at a large-scale touch and walk screen for bats, birds, and rodents. Journal of Neuroscience Methods 141:283–90.Google Scholar
Wyeth, G. & Milford, M. J. (2009) Spatial cognition for robots: Robot navigation from biological inspiration. IEEE Robotics and Automation Magazine 16(3):2432.Google Scholar