Result 1 to 20 of 22 total
Component-based matching for multiple interacting RNA sequences. (English)
Chen, Jianer (ed.) et al., Bioinformatics research and applications. 7th international symposium, ISBRA 2011, Changsha, China, May 27‒29, 2011. Proceedings. Berlin: Springer (ISBN 978-3-642-21259-8/pbk). Lecture Notes in Computer Science 6674. Lecture Notes in Bioinformatics, 73-86 (2011).
1
Component-based matching for multiple interacting RNA sequences (English)
ISBRA, 73-86 (2011).
2
Annotation concept synthesis and enrichment analysis. (English)
Farzindar, Atefeh (ed.) et al., Advances in artificial intelligence. 23rd Canadian conference on artificial intelligence, Canadian AI 2010, Ottawa, Canada, May 31 ‒ June 2, 2010. Proceedings. Berlin: Springer (ISBN 978-3-642-13058-8/pbk). Lecture Notes in Computer Science 6085. Lecture Notes in Artificial Intelligence, 304-308 (2010).
3
Annotation concept synthesis and enrichment analysis (English)
Canadian Conference on AI, 304-308 (2010).
4
Parallel multiprocessor approaches to the RNA folding problem. (English)
Wyrzykowski, Roman (ed.) et al., Parallel processing and applied mathematics. 7th international conference, PPAM 2007, Gdansk, Poland, September 9‒12, 2007. Revised selected papers. Berlin: Springer (ISBN 978-3-540-68105-2/pbk). Lecture Notes in Computer Science 4967, 1230-1239 (2008).
5
Detecting localized interspersed motifs in genomic sequences (English)
IEEE T. Instrumentation and Measurement 56, No. 5, 1770-1775 (2007).
6
Parallel multiprocessor approaches to the RNA folding problem (English)
PPAM, 1230-1239 (2007).
7
Identification of consensus RNA secondary structures using suffix arrays. (English)
BMC Bioinform. 7, No. 1, 244 (2006).
8
An approach to selecting putative RNA motifs using MDL principle (English)
BIOCOMP, 560-569 (2006).
9
Evaluation of RNA secondary structure motifs using regression analysis (English)
CCECE, 1747-1752 (2006).
10
Simultaneous alignment and structure prediction of three RNA sequences. (English)
Int. J. Bioinform. Res. Appl. 1, No. 2, 230-245 (2005).
11
Simultaneous alignment and structure prediction of RNAs. Are three input sequences better than two? (English)
Sunderam, Vaidy S. (ed.) et al., Computational science ‒ ICCS 2005. 5th international conference, Atlanta, GA, USA, May 22‒25, 2005. Proceedings, Part II. Berlin: Springer (ISBN 3-540-26043-9/pbk). Lecture Notes in Computer Science 3515, 936-943 (2005).
12
Simultaneous alignment and structure prediction of rnas (English)
International Conference on Computational Science (2), 936-943 (2005).
13
Air cargo operations evaluation and analysis through simulation (English)
Winter Simulation Conference, 1790- (2004).
14
Generating protein three-dimensional fold signatures using inductive logic programming (English)
Computers & Chemistry 26, No. 1, 57-64 (2002).
15
The effect of relational background knowledge on learning of protein three-dimensional fold signatures. (English)
Mach. Learn. 43, No.1-2, 81-95 (2001).
16
Use of inductive logic programming to learn principles of protein structure (English)
Electron. Trans. Artif. Intell. 4, No. B, 119-124 (2000).
17
Impact of connection bank redesign on airport gate assignment (English)
Winter Simulation Conference, 1378-1382 (1999).
18
Application of inductive logic programming to discover rules governing the three-dimensional topology of protein structure (English)
ILP, 53-64 (1998).
19
Exploring the conformations of nucleic acids. (English)
J. Funct. Program. 5, No. 3, 443-460 (1995).
20
Result 1 to 20 of 22 total
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