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  • Cited by 2
Publisher:
Cambridge University Press
Online publication date:
June 2011
Print publication year:
2011
Online ISBN:
9780511974960

Book description

Intended for researchers and graduate students in theoretical computer science and mathematical logic, this volume contains accessible surveys by leading researchers from areas of current work in logical aspects of computer science, where both finite and infinite model-theoretic methods play an important role. Notably, the articles in this collection emphasize points of contact and connections between finite and infinite model theory in computer science that may suggest new directions for interaction. Among the topics discussed are: algorithmic model theory, descriptive complexity theory, finite model theory, finite variable logic, model checking, model theory for restricted classes of finite structures, and spatial databases. The chapters all include extensive bibliographies facilitating deeper exploration of the literature and further research.

Reviews

"Researchers will find the book useful for referring to theorems on finite model theory. For building models of complicated problems, the book provides a good foundation."
Maulik A. Dave, Computing Reviews

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Contents

Bibliography
Bibliography
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[24] Grädel, E., and Walukiewicz, I. 1999. Guarded fixed point logic. Pages 45–54 of: Proceedings of 14th Annual IEEE Symposium on Logic in Computer Science LICS'99.
[25] Grädel, E., Hirsch, C., and Otto, M. 2002. Back and forth between guarded and modal logics. ACM Transactions on Computational Logics, 3, 418–463.
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[32] Hoogland, E., Marx, M., and Otto, M. 1999. Beth definability for the guarded fragment. In: Gebrandy, J., Marx, M., de Rijke, M., and Venema, Y. (eds), JFAK – Essays Dedicated to Johan van Benthem on the Occasion of his 50th Birthday. Amsterdam University Press. CD-ROM.
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[43] Otto, M. 2010a. Highly acyclic groups, hypergraph covers and the guarded fragment. Pages 12–21 of: Proceedings of 25th Annual IEEE Symposium on Logic in Computer Science LICS'10.
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[49] Vardi, M. 1997. Why is modal logic so robustly decidable? Pages 149–184 of: Immerman, N., and Kolaitis, P. (eds), Descriptive Complexity and Finite Models. DIMACS Series in Discrete Mathematics and Theoretical Computer Science, vol. 31. AMS.
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[51] Weinstein, S. 2007. Unifying themes in finite model theory. Pages 1–25 of: Finite Model Theory and Its Applications. Springer.

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