Title :
A generic and versatile architecture for inference of evolutionary trees under maximum likelihood
Author :
Alachiotis, Nikolaos ; Stamatakis, Alexandros
Author_Institution :
Exelixis Lab., Heidelberg Inst. for Theor. Studies, Heidelberg, Germany
Abstract :
Likelihood-based reconstruction of phylogenetic (evolutionary) trees from molecular sequence data exhibits extreme resource requirements because of the high computational cost of the phylogenetic likelihood function. We propose a dedicated computer architecture for the inference of phylogenies under the maximum likelihood criterion. Our design is sufficiently generic to support any possible input data type, that is, DNA, RNA secondary structure, or protein data. Furthermore, the architecture is able to calculate log-likelihood scores and perform numerical scaling to maintain numerical stability on large datasets. It can also optimize the branch lengths of tree topologies and calculate transition probability matrices. We used FPGA technology to verify the correctness of our architecture.
Keywords :
DNA; bioinformatics; computer architecture; coprocessors; evolutionary computation; field programmable gate arrays; inference mechanisms; matrix algebra; numerical stability; proteins; trees (mathematics); DNA data; FPGA technology; RNA secondary structure; bioinformatics; computer architecture; evolutionary trees; likelihood-based reconstruction; log-likelihood scores; maximum likelihood criterion; molecular sequence data; numerical scaling; numerical stability; phylogenetic coprocessor; phylogenetic likelihood function; phylogenetic trees; phylogenies inference; protein data; transition probability matrices; Computational modeling; Computer architecture; DNA; Field programmable gate arrays; Phylogeny; Probability; Proteins;
Conference_Titel :
Signals, Systems and Computers (ASILOMAR), 2010 Conference Record of the Forty Fourth Asilomar Conference on
Conference_Location :
Pacific Grove, CA
Print_ISBN :
978-1-4244-9722-5
DOI :
10.1109/ACSSC.2010.5757682
