An innovative reconfigurable supercomputing platform -XD1000 is being developed by XtremeData to exploit the rapid progress of FPGA technology and the high-performance of Hyper-Transport interconnection. In this paper, we present implementations of the Smith-Waterman algorithm for both DNA and protein sequences on the platform. The main features include: (1) we bring forward a multistage PE (processing element) design which significantly reduces the FPGA resource usage and hence allows more parallelism to be exploited; (2) our design features a pipelined control mechanism with uneven stage latencies -a key to minimize the overall PE pipeline cycle time; (3) we also present a compressed substitution matrix storage structure, resulting in substantial decrease of the on-chip SRAM usage. Finally, we implement a 384-PE systolic array running at 66.7MHz, which can achieve 25.6GCUPS peak performance. Compared with the 2.2GHz AMD Opteron host processor, the FPGA coprocessor results in speedup of 185 and 250 respectively.
Scanning bio-sequence database and finding similarities among DNA and protein sequences is basic and important work in bioinformatics field. To solve this problem, Needleman-Wunschh (NW) algorithm is a classical and precise tool, and Smith-Waterman (SW) algorithm is more practical for its capability to find similarities between subsequences. Such algorithms have computational complexity proportional to the length product of both involved sequences, hence processing time becomes insufferable due to exponential growth speed and great amount of bio-sequence database. To alleviate this serious problem, a reconfigurable accelerator for SW algorithm is presented. In the accelerator, a modified equation is proposed to improve mapping efficiency of a processing element (PE), and a special floor plan is applied to a fine-grain parallel PE array and interface components to cut down their routing delay. Basing on the two techniques, the proposed accelerator can reach at 82-MHz frequency in an Altera EP1S30 device. Experiments demonstrate the accelerator provides more than 330 speedup as compared to a standard desktop platform with a 2.8-GHz Xeon processor and 4-GB memory and has 50% improvement on the peak performance of a transferred traditional implementation without using the two special techniques. Our implementation is also about 9% faster than the fastest implementation in a most recent family of SW algorithm accelerators.Index Terms-Bioinformatics, computational complexity, field-programmable gate array (FPGA), reconfigurable accelerator, Smith-Waterman (SW) algorithm.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.