Design of interconnection-free biomolecular computing system

Takafumi Aoki; Michitaka Kameyama; Tatsuo Higuchi

Design of interconnection-free biomolecular computing system

Takafumi Aoki, Michitaka Kameyama, Tatsuo Higuchi

Leadership

Tohoku University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

10 Citations (Scopus)

Abstract

A systematic design method for an interconnection-free biomolecular computing system based on parallel distribution of logical information represented by varieties of molecules and parallel selection using specificity of enzymes is presented. A model of a biomolecular switching device is introduced as a universal building block, and the systematic synthesis of biodevice networks is discussed using a set-valued switching algebra. The main advantage is the maximum parallelism based on interconnection-free logic operations. It is possible to exploit the inherent parallelism of given algorithm through biodevice networks by converting the dataflow specification into parallel distribution and selection function.

Original language	English
Title of host publication	Proceedings of The International Symposium on Multiple-Valued Logic
Publisher	Publ by IEEE
Pages	173-180
Number of pages	8
ISBN (Print)	0818621451
Publication status	Published - 1991 May
Event	Proceedings of the 21st International Symposium on Multiple-Valued Logic - Victoria, BC, Can Duration: 1991 May 26 → 1991 May 29

Publication series

Name	Proceedings of The International Symposium on Multiple-Valued Logic
ISSN (Print)	0195-623X

Conference

Conference	Proceedings of the 21st International Symposium on Multiple-Valued Logic
City	Victoria, BC, Can
Period	91/5/26 → 91/5/29

Cite this

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title = "Design of interconnection-free biomolecular computing system",

abstract = "A systematic design method for an interconnection-free biomolecular computing system based on parallel distribution of logical information represented by varieties of molecules and parallel selection using specificity of enzymes is presented. A model of a biomolecular switching device is introduced as a universal building block, and the systematic synthesis of biodevice networks is discussed using a set-valued switching algebra. The main advantage is the maximum parallelism based on interconnection-free logic operations. It is possible to exploit the inherent parallelism of given algorithm through biodevice networks by converting the dataflow specification into parallel distribution and selection function.",

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Aoki, T, Kameyama, M & Higuchi, T 1991, Design of interconnection-free biomolecular computing system. in Proceedings of The International Symposium on Multiple-Valued Logic. Proceedings of The International Symposium on Multiple-Valued Logic, Publ by IEEE, pp. 173-180, Proceedings of the 21st International Symposium on Multiple-Valued Logic, Victoria, BC, Can, 91/5/26.

Design of interconnection-free biomolecular computing system. / Aoki, Takafumi; Kameyama, Michitaka; Higuchi, Tatsuo.
Proceedings of The International Symposium on Multiple-Valued Logic. Publ by IEEE, 1991. p. 173-180 (Proceedings of The International Symposium on Multiple-Valued Logic).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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N2 - A systematic design method for an interconnection-free biomolecular computing system based on parallel distribution of logical information represented by varieties of molecules and parallel selection using specificity of enzymes is presented. A model of a biomolecular switching device is introduced as a universal building block, and the systematic synthesis of biodevice networks is discussed using a set-valued switching algebra. The main advantage is the maximum parallelism based on interconnection-free logic operations. It is possible to exploit the inherent parallelism of given algorithm through biodevice networks by converting the dataflow specification into parallel distribution and selection function.

AB - A systematic design method for an interconnection-free biomolecular computing system based on parallel distribution of logical information represented by varieties of molecules and parallel selection using specificity of enzymes is presented. A model of a biomolecular switching device is introduced as a universal building block, and the systematic synthesis of biodevice networks is discussed using a set-valued switching algebra. The main advantage is the maximum parallelism based on interconnection-free logic operations. It is possible to exploit the inherent parallelism of given algorithm through biodevice networks by converting the dataflow specification into parallel distribution and selection function.

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Y2 - 26 May 1991 through 29 May 1991

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Design of interconnection-free biomolecular computing system

Abstract

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