Difference between revisions of "Computability and Complexity in Self-Assembly"
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|authors=James I. Lathrop, Jack H. Lutz, Matthew J. Patitz, and Scott M. Summers | |authors=James I. Lathrop, Jack H. Lutz, Matthew J. Patitz, and Scott M. Summers | ||
|date=2010/04/20 | |date=2010/04/20 | ||
| − | |file=[[media:CCSA journal.pdf]] | + | |file=[[media:CCSA journal.pdf | Computability and Complexity in Self-Assembly.pdf]] |
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Revision as of 12:02, 22 June 2021
Published on: 2010/04/20
Abstract
This paper explores the impact of geometry on computability and complexity in Winfree’s model of nanoscale self-assembly. We work in the two-dimensional tile assembly model, i.e., in the discrete Euclidean plane \(\mathbb{Z} \times \mathbb{Z}\). Our first main theorem says that there is a roughly quadratic function \(f\) such that a set \(A \subseteq \mathbb{Z}^+\) is computably enumerable if and only if the set \(X_A = \{(f(n), 0)
Authors
James I. Lathrop, Jack H. Lutz, Matthew J. Patitz, and Scott M. Summers
