Unconventional Computation: 9th International Conference, UC 2010 Tokyo, Japan, June 21-25, 2010, Proceedings Contributor(s): Calude, Christian S. (Editor), Hagiya, Masami (Editor), Morita, Kenichi (Editor) |
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ISBN: 3642135226 ISBN-13: 9783642135224 Publisher: Springer OUR PRICE: $52.24 Product Type: Paperback - Other Formats Published: June 2010 |
Additional Information |
BISAC Categories: - Computers | Computer Science - Computers | Logic Design - Mathematics | Logic |
Dewey: 006.3 |
Series: Lecture Notes in Computer Science |
Physical Information: 0.5" H x 6.1" W x 9.2" (0.70 lbs) 195 pages |
Descriptions, Reviews, Etc. |
Publisher Description: The 9th International Conference on Unconventional Computation, UC 2010, was organized under the auspices of EATCS and Academia Europaea, by the University of Tokyo (Tokyo, Japan), and the Center for Discrete Mathematics and Theoretical Computer Science (Auckland, New Zealand). It was held in Tokyoduring June 21-25,2010(seehttp: //arn.local.frs.riken.jp/UC10/). The venue was the Sanjo (Hilltop) Conference Hall at Hongo Campus of the University of Tokyo. Hongo Campus was formerly the residence of the Maeda family, one of the richest feudal lords in the Edo period of Japan. The Japanese garden in the residence is partially preserved, including the pond and the hill on which the conference hall is located. Within walking distance from Hongo Campus are Ueno park with many museums, the Akihabara area, which is now the center of Japanesepop culture, and the Korakuenamusement park/baseball stadium. The International Conference on Unconventional Computation (UC) series (seehttp: //www.cs.auckland.ac.nz/CDMTCS/conferences/uc/)isdevotedto all aspects of unconventional computation -- theory as well as experiments and applications. Typical, but not exclusive, topics are: natural computing including quantum, cellular, molecular, membrane, neural, and evolutionary computing, as well as chaos and dynamical system-based computing, and various proposals for computational mechanisms that go beyond the Turing model. |