Abstract
This paper proposes an approach to detecting affinities between perceptual objects contained in perceptual granules such as images with tolerance near preclasses. A perceptual object is something perceptible to the senses or knowable by the mind. Perceptual objects that have similar appearance are considered perceptually near each other, i.e., perceived objects that have perceived affinities or, at least, similar descriptions.A perceptual granule is a finite, non-empty set containing sample perceptual objects with common descriptions. Perceptual granules originate from observations of the objects in the physical world. Similarities between perceptual granules are measured within the context of what is known as a tolerance near space. This form of tolerance space is inspired by C.E. Zeeman’s work on visual perception and Henri Poincaré’s work on the contrast between mathematical continua and the physical continua in a pragmatic philosophy of science that laid the foundations for tolerance spaces. The perception of nearness or closeness that underlies tolerance near relations is rooted in Maurice Merleau-Ponty’s work on the phenomenology of perception during the mid-1940s, and, especially, philosophical reflections on description of perceived objects and the perception of nearness. Pairs of perceptual granules such as images are considered near each other to the extent that tolerance near preclasses of sufficient magnitude can be found. The contribution of this paper is the introduction of L 2 norm-based tolerance near preclasses in detecting affinities between images.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
Similar content being viewed by others
References
Bartol, W., Miró, J., Pióro, K., Rosselló, F.: On the coverings by tolerance classes. Information Sciences 166(1-4), 193–211 (2004)
Cyran, K.A., Mrózek, A.: Rough sets in hybrid methods for pattern recognition. International Journal of Intelligent Systems 16, 149–168 (2001)
Gerasin, S.N., Shlyakhov, V.V., Yakovlev, S.V.: Set coverings and tolerance relations. Cybernetics and Systems Analysis 44(3), 333–340 (2008)
Hassanien, A.E., Abraham, A., Peters, J.F., Schaefer, G., Henry, C.: Rough sets and near sets in medical imaging: A review. IEEE Transactions on Information Technology in Biomedicine (in press, 2009)
Henry, C.: Image nearness measurement system (2009), http://wren.ee.umanitoba.ca
Henry, C., Peters, J.F.: Image pattern recognition using approximation spaces and near sets. In: An, A., Stefanowski, J., Ramanna, S., Butz, C.J., Pedrycz, W., Wang, G. (eds.) RSFDGrC 2007. LNCS (LNAI), vol. 4482, pp. 475–482. Springer, Heidelberg (2007)
Henry, C., Peters, J.F.: Near set index in an objective image segmentation evaluation framework. In: GEOgraphic Object Based Image Analysis: Pixels, Objects, Intelligence, pp. 1–6. University of Calgary, Alberta (2008)
Henry, C., Peters, J.F.: Perception-based image analysis. International Journal of Bio-Inspired Computation 2(2) (to appear, 2009)
Jänich, K.: Topology. Springer, Berlin (1984)
Orłowska, E.: Semantics of vague concepts. Applications of rough sets. Tech. Rep. 469, Institute for Computer Science, Polish Academy of Sciences (1982)
Orłowska, E.: Semantics of vague concepts. In: Dorn, G., Weingartner, P. (eds.) Foundations of Logic and Linguistics. Problems and Solutions, pp. 465–482. Plenum Pres, London (1985)
Pawlak, Z., Peters, J.F.: Jak blisko (how near). Systemy Wspomagania Decyzji I 57, 109 (2002)
Peters, J.F.: Near sets. General theory about nearness of objects. Applied Mathematical Sciences 1(53), 2609–2629 (2007)
Peters, J.F.: Near sets. Special theory about nearness of objects. Fundamenta Informaticae 76, 1–27 (2007)
Peters, J.F.: Discovery of perceptually near information granules. In: Yao, J.T. (ed.) Novel Developements in Granular Computing: Applications of Advanced Human Reasoning and Soft Computation. Information Science Reference, Hersey (in press, 2009)
Peters, J.F.: Tolerance near sets and image correspondence. International Journal of Bio-Inspired Computation 1(4), 239–245 (2009)
Peters, J.F., Ramanna, S.: Affinities between perceptual granules: Foundations and perspectives. In: Bargiela, A., Pedrycz, W. (eds.) Human-Centric Information Processing Through Granular Modelling SCI 182, pp. 49–66. Springer, Heidelberg (2009)
Peters, J.F., Wasilewski, P.: Foundations of near sets. Information Sciences. An International Journal (in press, 2009)
Poincaré, H.: The topology of the brain and the visual perception. In: Fort, K.M. (ed.) Topology of 3-manifolds and Selected Topics, pp. 240–256. Prentice Hall, New Jersey (1965)
Schroeder, M., Wright, M.: Tolerance and weak tolerance relations. Journal of Combinatorial Mathematics and Combinatorial Computing 11, 123–160 (1992)
Shreider, Y.A.: Tolerance spaces. Cybernetics and Systems Analysis 6(12), 153–758 (1970)
Skowron, A., Stepaniuk, J.: Tolerance approximation spaces. Fundamenta Informaticae 27(2-3), 245–253 (1996)
Sossinsky, A.B.: Tolerance space theory and some applications. Acta Applicandae Mathematicae: An International Survey. Journal on Applying Mathematics and Mathematical Applications 5(2), 137–167 (1986)
Street, A.P., Wallis, W.D.: Combinatorics: A first course. The Charles Babbage Research Centre, Winnipeg (1982)
Zeeman, E.C.: The topology of the brain and the visual perception. In: Fort, K.M. (ed.) Topology of 3-manifolds and Selected Topics, pp. 240–256. Prentice Hall, New Jersey (1965)
Zheng, Z., Hu, H., Shi, Z.: Tolerance relation based granular space. In: Ślęzak, D., Wang, G., Szczuka, M.S., Düntsch, I., Yao, Y. (eds.) RSFDGrC 2005. LNCS, vol. 3641, pp. 682–691. Springer, Heidelberg (2005)
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2009 Springer-Verlag Berlin Heidelberg
About this paper
Cite this paper
Peters, J.F. (2009). Discovering Affinities between Perceptual Granules. In: Cyran, K.A., Kozielski, S., Peters, J.F., Stańczyk, U., Wakulicz-Deja, A. (eds) Man-Machine Interactions. Advances in Intelligent and Soft Computing, vol 59. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-00563-3_4
Download citation
DOI: https://doi.org/10.1007/978-3-642-00563-3_4
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-00562-6
Online ISBN: 978-3-642-00563-3
eBook Packages: EngineeringEngineering (R0)