263 research outputs found
High performance reconfigurable architectures for biological sequence alignment
Bioinformatics and computational biology (BCB) is a rapidly developing
multidisciplinary field which encompasses a wide range of domains, including genomic
sequence alignments. It is a fundamental tool in molecular biology in searching for
homology between sequences. Sequence alignments are currently gaining close attention due
to their great impact on the quality aspects of life such as facilitating early disease diagnosis,
identifying the characteristics of a newly discovered sequence, and drug engineering. With
the vast growth of genomic data, searching for a sequence homology over huge databases
(often measured in gigabytes) is unable to produce results within a realistic time, hence the
need for acceleration. Since the exponential increase of biological databases as a result of the
human genome project (HGP), supercomputers and other parallel architectures such as the
special purpose Very Large Scale Integration (VLSI) chip, Graphic Processing Unit (GPUs)
and Field Programmable Gate Arrays (FPGAs) have become popular acceleration platforms.
Nevertheless, there are always trade-off between area, speed, power, cost, development time
and reusability when selecting an acceleration platform. FPGAs generally offer more
flexibility, higher performance and lower overheads. However, they suffer from a relatively
low level programming model as compared with off-the-shelf microprocessors such as
standard microprocessors and GPUs. Due to the aforementioned limitations, the need has
arisen for optimized FPGA core implementations which are crucial for this technology to
become viable in high performance computing (HPC).
This research proposes the use of state-of-the-art reprogrammable system-on-chip
technology on FPGAs to accelerate three widely-used sequence alignment algorithms; the
Smith-Waterman with affine gap penalty algorithm, the profile hidden Markov model
(HMM) algorithm and the Basic Local Alignment Search Tool (BLAST) algorithm. The
three novel aspects of this research are firstly that the algorithms are designed and
implemented in hardware, with each core achieving the highest performance compared to the
state-of-the-art. Secondly, an efficient scheduling strategy based on the double buffering
technique is adopted into the hardware architectures. Here, when the alignment matrix
computation task is overlapped with the PE configuration in a folded systolic array, the
overall throughput of the core is significantly increased. This is due to the bound PE
configuration time and the parallel PE configuration approach irrespective of the number of
PEs in a systolic array. In addition, the use of only two configuration elements in the PE optimizes hardware resources and enables the scalability of PE systolic arrays without
relying on restricted onboard memory resources. Finally, a new performance metric is
devised, which facilitates the effective comparison of design performance between different
FPGA devices and families. The normalized performance indicator (speed-up per area per
process technology) takes out advantages of the area and lithography technology of any
FPGA resulting in fairer comparisons.
The cores have been designed using Verilog HDL and prototyped on the Alpha Data
ADM-XRC-5LX card with the Virtex-5 XC5VLX110-3FF1153 FPGA. The implementation
results show that the proposed architectures achieved giga cell updates per second (GCUPS)
performances of 26.8, 29.5 and 24.2 respectively for the acceleration of the Smith-Waterman
with affine gap penalty algorithm, the profile HMM algorithm and the BLAST algorithm. In
terms of speed-up improvements, comparisons were made on performance of the designed
cores against their corresponding software and the reported FPGA implementations. In the
case of comparison with equivalent software execution, acceleration of the optimal
alignment algorithm in hardware yielded an average speed-up of 269x as compared to the
SSEARCH 35 software. For the profile HMM-based sequence alignment, the designed core
achieved speed-up of 103x and 8.3x against the HMMER 2.0 and the latest version of
HMMER (version 3.0) respectively. On the other hand, the implementation of the gapped
BLAST with the two-hit method in hardware achieved a greater than tenfold speed-up
compared to the latest NCBI BLAST software. In terms of comparison against other reported
FPGA implementations, the proposed normalized performance indicator was used to
evaluate the designed architectures fairly. The results showed that the first architecture
achieved more than 50 percent improvement, while acceleration of the profile HMM
sequence alignment in hardware gained a normalized speed-up of 1.34. In the case of the
gapped BLAST with the two-hit method, the designed core achieved 11x speed-up after
taking out advantages of the Virtex-5 FPGA. In addition, further analysis was conducted in
terms of cost and power performances; it was noted that, the core achieved 0.46 MCUPS per
dollar spent and 958.1 MCUPS per watt. This shows that FPGAs can be an attractive
platform for high performance computation with advantages of smaller area footprint as well
as represent economic ‘green’ solution compared to the other acceleration platforms. Higher
throughput can be achieved by redeploying the cores on newer, bigger and faster FPGAs
with minimal design effort
FPGA acceleration of sequence analysis tools in bioinformatics
Thesis (Ph.D.)--Boston UniversityWith advances in biotechnology and computing power, biological data are being produced at an exceptional rate. The purpose of this study is to analyze the application of FPGAs to accelerate high impact production biosequence analysis tools. Compared with other alternatives, FPGAs offer huge compute power, lower power consumption, and reasonable flexibility.
BLAST has become the de facto standard in bioinformatic approximate string matching and so its acceleration is of fundamental importance. It is a complex highly-optimized system, consisting of tens of thousands of lines of code and a large number of heuristics. Our idea is to emulate the main phases of its algorithm on FPGA. Utilizing our FPGA engine, we quickly reduce the size of the database to a small fraction, and then use the original code to process the query. Using a standard FPGA-based system, we achieved 12x speedup over a highly optimized multithread reference code.
Multiple Sequence Alignment (MSA)--the extension of pairwise Sequence Alignment to multiple Sequences--is critical to solve many biological problems. Previous attempts to accelerate Clustal-W, the most commonly used MSA code, have directly mapped a portion of the code to the FPGA. We use a new approach: we apply prefiltering of the kind commonly used in BLAST to perform the initial all-pairs alignments. This results in a speedup of from 8Ox to 190x over the CPU code (8 cores). The quality is comparable to the original according to a commonly used benchmark suite evaluated with respect to multiple distance metrics.
The challenge in FPGA-based acceleration is finding a suitable application mapping. Unfortunately many software heuristics do not fall into this category and so other methods must be applied. One is restructuring: an entirely new algorithm is applied. Another is to analyze application utilization and develop accuracy/performance tradeoffs. Using our prefiltering approach and novel FPGA programming models we have achieved significant speedup over reference programs. We have applied approximation, seeding, and filtering to this end. The bulk of this study is to introduce the pros and cons of these acceleration models for biosequence analysis tools
A study on the effect of stroop test on the formation of students discipline by using the Heart Rate Variability (HRV) technique
Discipline refers to self-control and individual behaviour. Other than that, discipline is an important element in the formation of integrity level. The objective of the study is to assess the effects of using the Stroop test of biofeedback protocol in order to evaluate individual level of discipline. A clinical study has been conducted on 50 participants which is the participants is a undergraduate student from Universiti Malaysia Pahang, who were divided into two groups. First group is students get high achiever and second group is students get low achierver in academic. The Heart Rate Variability (HRV) technique has been used in the assessment of this protocol. The findings show that there was a positive relationship between the Stroop test and the students discipline that those who excelled managed to get higher score of LF spectrum as compared to HF and VLF, while the students with lower achievement showed higher score of VLF and HF spectrum than LF. In conclusion, this test is one of the tests that can be used in increasing the level of individual discipline
Accelerating BLAST Computation on an FPGA-enhanced PC Cluster
This paper introduces an FPGA-based scheme to accelerate mpiBLAST, which is a parallel sequence alignment algorithm for computational biology. Recent rapidly growing biological databases for sequence alignment require highthroughput storage and network rather than computing speed. Our scheme utilizes a specialized hardware configured on an FPGA-board which connects flash storage and other FPGAboards directly. The specialized hardware configured on the FPGAs, we call a Data Stream Processing Engine (DSPE), take a role for preprocessing to adjust data for high-performance multi- and many- core processors simultaneously with offloading system-calls for storage access and networking. DSPE along the datapath achieves in-datapath computing which applies operations for data streams passing through the FPGA. Two functions in mpiBLAST are implemented using DSPE to offload operations along the datapath. The first function is database partitioning, which distributes the biological database to multiple computing nodes before commencing the BLAST processes. Using DSPE, we observe a 20-fold improvement in computation time for the database partitioning operation. The second function is an early part of the BLAST process that determines the positions of sequences for more detailed computations. We implement IDP-BLAST (In-datapath BLAST), which annotates positions in data streams from solid-state drives. We show that IDP-BLAST accelerates the computation time of the preprocess of BLAST by a factor of three hundred by offloading heavy operations to the introduced special hardware
Reconfigurable acceleration of genetic sequence alignment: A survey of two decades of efforts
Genetic sequence alignment has always been a computational challenge in bioinformatics. Depending on the problem size, software-based aligners can take multiple CPU-days to process the sequence data, creating a bottleneck point in bioinformatic analysis flow. Reconfigurable accelerator can achieve high performance for such computation by providing massive parallelism, but at the expense of programming flexibility and thus has not been commensurately used by practitioners. Therefore, this paper aims to provide a thorough survey of the proposed accelerators by giving a qualitative categorization based on their algorithms and speedup. A comprehensive comparison between work is also presented so as to guide selection for biologist, and to provide insight on future research direction for FPGA scientists
FPGAs in Bioinformatics: Implementation and Evaluation of Common Bioinformatics Algorithms in Reconfigurable Logic
Life. Much effort is taken to grant humanity a little insight in this fascinating and complex but fundamental topic. In order to understand the relations and to derive consequences humans have begun to sequence their genomes, i.e. to determine their DNA sequences to infer information, e.g. related to genetic diseases. The process of DNA sequencing as well as subsequent analysis presents a computational challenge for recent computing systems due to the large amounts of data alone. Runtimes of more than one day for analysis of simple datasets are common, even if the process is already run on a CPU cluster. This thesis shows how this general problem in the area of bioinformatics can be tackled with reconfigurable hardware, especially FPGAs. Three compute intensive problems are highlighted: sequence alignment, SNP interaction analysis and genotype imputation. In the area of sequence alignment the software BLASTp for protein database searches is exemplarily presented, implemented and evaluated.SNP interaction analysis is presented with three applications performing an exhaustive search for interactions including the corresponding statistical tests: BOOST, iLOCi and the mutual information measurement. All applications are implemented in FPGA-hardware and evaluated, resulting in an impressive speedup of more than in three orders of magnitude when compared to standard computers. The last topic of genotype imputation presents a two-step process composed of the phasing step and the actual imputation step. The focus lies on the phasing step which is targeted by the SHAPEIT2 application. SHAPEIT2 is discussed with its underlying mathematical methods in detail, and finally implemented and evaluated. A remarkable speedup of 46 is reached here as well
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