default search action
DIMACS Workshop: DNA Based Computers 1996
- Laura F. Landweber, Eric B. Baum:
DNA Based Computers, Proceedings of a DIMACS Workshop, Princeton, New Jersey, USA, June 10-12, 1996. DIMACS Series in Discrete Mathematics and Theoretical Computer Science 44, DIMACS/AMS 1999, ISBN 978-0-8218-0756-9 - Foreword. DNA Based Computers 1996: vii-
- Introduction. DNA Based Computers 1996: ix-
- Acknowledgements. DNA Based Computers 1996: xi-
- Sam T. Roweis, Erik Winfree
, Richard Burgoyne, Nickolas V. Chelyapov, Myron F. Goodman, Paul W. K. Rothemund, Leonard M. Adleman:
A sticker based model for DNA computation. 1-29 - Leonard M. Adleman, Paul W. K. Rothemund, Sam T. Roweis, Erik Winfree
On applying molecular computation to the data encryption standard. 31-44 - Thomas H. Leete, Matthew D. Schwartz, Robert M. Williams, David Harlan Wood, Jerome S. Salem, Harvey Rubin:
Massively parallel DNA computation: Expansion of symbolic determinants. 45-58 - Gheorghe Paun:
Universal DNA computing models based on the splicing operation. 59-75 - Eric B. Baum, Dan Boneh:
Running dynamic programming algorithms on a DNA computer. 77-85 - Natasa Jonoska, Stephen A. Karl:
A molecular computation of the road coloring problem. 87-96 - Peter D. Kaplan, Guillermo A. Cecchi, Albert Libchaber:
DNA based molecular computation: Template-template interactions in PCR. 97-104 - Frank Guarnieri, F. Carter Bancroft:
Use of a horizontal chain reaction for DNA-based addition. 105-111 - John S. Oliver:
Computation with DNA: Matrix multiplication. 113-122 - Qinghua Liu, Zhen Guo, Zhengdong Fei, Anne Condon, Robert M. Corn, Max G. Lagally, Lloyd M. Smith:
A surface-based approach to DNA computation. 123-132 - John-Thones Amenyo:
Mesoscopic computer engineering: Automating DNA-based molecular computing via traditional practices of parallel computer architecture design. 133-150 - Martyn Amos, Alan Gibbons, David A. Hodgson:
Error-resistant implementation of DNA computations. 151-161 - Dan Boneh, Christopher Dunworth, Richard J. Lipton, Jirí Sgall:
Making DNA computers error resistant. 163-170 - Stuart A. Kurtz, Stephen R. Mahaney, James S. Royer, Janos Simon:
Active transport in biological computing. 171-179 - Laura F. Landweber:
RNA based computing: Some examples from RNA catalysis and RNA editing. 181-189 - Erik Winfree
Universal computation via self-assembly of DNA: Some theory and experiments. 191-213 - Stephen C. Seeman, Hui Wang, Bing Liu, Jing Qi, Xiaojun Li, Xiaoping Yang, Furong Liu, Weiqiong Sun, Zhiyong Shen, Ruojie Sha, Chengde Mao, Yinli Wang, Siwei Zhang, Tsu-Ju Fu, Shouming Du, John E. Mueller, Yuwen Zhang, Junghuei Chen:
The perils of polynucleotides: The experimental gap between the design and assembly of unusual DNA structures. 215-233 - Eric B. Baum:
DNA sequences useful for computation. 235-241 - Kalim U. Mir:
A restricted genetic alphabet for DNA computing. 243-246 - Russell J. Deaton, R. C. Murphy, Max H. Garzon, Donald R. Franceschetti, Stanley Edward Stevens Jr.:
Good encodings for DNA-based solutions to combinatorial problems. 247-258 - Richard J. Lipton:
DNA computations can have global memory. 259-265 - Robert M. Williams, David Harlan Wood:
Exascale computer algebra problems interconnect with molecular reactions and complexity theory. 267-275
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
last updated on 2025-01-03 23:15 CET by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint
dblp was originally created in 1993 at:
since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by: