This document surveys the computational strategies followed to parallelize the most used software in the bioinformatics arena. The studied algorithms are computationally expensive and their computational patterns range from regular, such as database searching applications, to very irregularly structured patterns (phylogenetic trees). Fine- and coarse-grained parallel strategies are discussed for these very diverse sets of applications. This overview outlines computational issues related to parallelism, physical machine models, parallel programming approaches, and scheduling strategies for a broad range of computer architectures. In particular, it deals with shared, distributed, and shared/distributed memory architectures
The revolution in next-generation DNA sequencing technologies is leading to explosive data growth in...
Supplementary data associated with this article can be found, in the online version, at http://dx.do...
Bioinformatics and computational biology are driven by growing volumes of data in biological systems...
This monograph presents examples of best practices when combining bioinspired algorithms with parall...
Abstract — Nowadays, multicore processor and GPUs have entered the mainstream of microprocessor dev...
Certain bioinformatics research, such as sequence alignment, alternative splicing, protein function/...
In the last years the fast growth of bioinformatics field has atracted the attention of computer sci...
The exponential growth of databases that contains biological information (such as protein and DNA da...
Genomic data analysis in evolutionary biology is becoming so computationally intensive that analysis...
Abstract — In recent years our society has witnessed an unprecedented growth in computing power avai...
The exponential growth in bioinformatics data generation and the stagnation of processor frequencies...
In this paper, we will explore the need of parallelizing bioinformatics algorithms. More specificall...
This article describes research in progress at the Yale University School of Medicine on the use of ...
The study of biological and genetic information, mostly DNA data, is an extremely important subject ...
Exponential growth in biological sequence data combined with the computationally intensive nature of...
The revolution in next-generation DNA sequencing technologies is leading to explosive data growth in...
Supplementary data associated with this article can be found, in the online version, at http://dx.do...
Bioinformatics and computational biology are driven by growing volumes of data in biological systems...
This monograph presents examples of best practices when combining bioinspired algorithms with parall...
Abstract — Nowadays, multicore processor and GPUs have entered the mainstream of microprocessor dev...
Certain bioinformatics research, such as sequence alignment, alternative splicing, protein function/...
In the last years the fast growth of bioinformatics field has atracted the attention of computer sci...
The exponential growth of databases that contains biological information (such as protein and DNA da...
Genomic data analysis in evolutionary biology is becoming so computationally intensive that analysis...
Abstract — In recent years our society has witnessed an unprecedented growth in computing power avai...
The exponential growth in bioinformatics data generation and the stagnation of processor frequencies...
In this paper, we will explore the need of parallelizing bioinformatics algorithms. More specificall...
This article describes research in progress at the Yale University School of Medicine on the use of ...
The study of biological and genetic information, mostly DNA data, is an extremely important subject ...
Exponential growth in biological sequence data combined with the computationally intensive nature of...
The revolution in next-generation DNA sequencing technologies is leading to explosive data growth in...
Supplementary data associated with this article can be found, in the online version, at http://dx.do...
Bioinformatics and computational biology are driven by growing volumes of data in biological systems...