计算生物学中的加速硬件

A. Ivanov
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引用次数: 0

摘要

欢迎来到2014年!继2013年12月关于ic和系统的变异性和老化减缓效应的年终特刊之后,我们将带您进入一个完全不同的空间。在本期中,我们将重点关注与分子生物学研究相关的日益增长的计算挑战。生物数据的生成正在以前所未有的速度发生,而处理速度却没有真正跟上。这种处理通常是在标准桌面计算平台上的软件中进行的,但这种情况正在发生变化。本期探讨了这些变化,并重点介绍了一些基于硬件的方法和相应的算法,这些方法和算法已被开发出来,以实现高度期望的生物数据处理加速。我们的第一篇文章由Majumder等人撰写,深入探讨了分子生物学研究中高速数据生成的具体情况。本文将新兴硬件平台的性能与计算生物学领域的其他应用进行了比较。其次,Aluru和Jammula的一篇文章提供了更广泛的调查,介绍了生物序列分析中的FPGA和GPU硬件加速器,以及检查高通量测序和应用程序所产生的加速研究。我们的第三篇论文由Liu和Schmidt撰写,提出了支持cuda的gpu的两种关键计算技术,这些技术允许快速比对来加速CUSHAW2算法,并支持模拟和真实读取到人类基因组的比对。接下来,Schlachter等人研究了分子动力学模拟中的资源利用问题。他们专注于非专用的高端集群,并提出了额外的模块来补充现有的工作流和资源管理器。他们报告了两个分子模拟,并验证了他们提出的方法带来的性能优势。在此之后,作者Savran, Gao和Bakos讨论了对内存使用和GPU内核性能的改进,该内核执行大规模短序列数据对明智对齐。作者已经建立了一个可能的大规模排列的新记录。为了结束对计算生物学加速的讨论,Chrysos等人的一篇文章提出了许多信息丰富的案例研究,这些案例研究举例说明了基于fpga的可重构计算平台的现代混合系统如何能够提供生物信息学算法的大幅加速和节省。我们的最后三篇专题文章涉及更普遍的话题。第一篇是由Yilmaz、Nassery和Ozev撰写的文章,概述并确认了使用QAM调制并避免高DFT开销的内置EVM测量技术的准确性。在此之后,Jenihhin等人提出了一种将VHDL代码项的统计分析与静态切片相结合的设计错误定位方法。作者通过一组真实的bug案例和原始的功能测试,证明了他们的方法在工业处理器(ROBSY)上的有效性。我们的最后一篇文章是来自奥胡斯加州大学圣巴巴拉分校的作者们的合作
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A look at accelerated hardware in computational biology
Welcome to 2014! h FOLLOWING DECEMBER 2013’S special year end issue on the slowing effects of variability and aging in ICs and systems, to start this new volume of D&T we bring you to a completely different space. In this issue, we take a focused look into the growing computational challenges associated with molecular biology research. The generation of biological data is now happening at unprecedented rates, and processing rates have not really kept pace. Such processing has typically been carried out in software on standard desktop computing platforms, but this situation is changing. This issue explores such changes and highlights some of the hardware-based approaches and corresponding algorithms that have been developed to enable highly desired biological data processing acceleration. Our first article, by Majumder et al., dives into the specifics of high-speed rates of data generation in molecular biology research. The article compares the performance of emerging hardware platforms with other applications across the field of computational biology. Second, an article by Aluru and Jammula provides a wider scope investigation by presenting surveys on FPGA and GPU hardware accelerators in biological sequence analysis, as well as research on acceleration resulting from examining high-throughput sequencing and applications. Our third submission, authored by Liu and Schmidt, presents two critical computing techniques for CUDA-enabled GPUs that allow fast alignments to accelerate the CUSHAW2 algorithm, supported by the alignments of simulated and real reads to the human genome. Next, Schlachter et al. investigate the problem of resource utilization in molecular dynamics simulations. They focus on non-dedicated high-end clusters and propose additional modules to supplement existing workflow and resource managers. They report on two molecular simulations and validate the performance benefits that their proposed approaches bring. Following this, authors Savran, Gao, and Bakos discuss improvements to the memory usage and performance of their GPU kernel, which performs large-scale short sequence dataset pair wise alignments. The authors have established a possible new record in large-scale alignments. To conclude this discussion of computational biology acceleration, an article by Chrysos et al. presents a number of informative case studies that exemplify how modern hybrid systems with FPGAbased reconfigurable computing platforms can offer large speed-ups and savings in bioinformatics algorithms. Our last three feature articles touch on more general interest topics. The first is an article by Yilmaz, Nassery, and Ozev that outlines and confirms the accuracy of built-in EVM measurement techniques that use QAM modulation and avoid high DFT overheads. Following this, Jenihhin et. al present an approach to design error localization that combines statistical analysis of VHDL code items with static slicing. The authors demonstrate the efficiency of their approach on an industrial processor (ROBSY) using a set of real bug cases and the original functional test. Our last article, a collaboration by authors from the University of California at Santa Barbara, Aarhus
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IEEE Design & Test of Computers
IEEE Design & Test of Computers 工程技术-工程:电子与电气
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