Your search keyword '"Open Science Grid"' showing total 14 results

1. An open science grid implementation of the steady state genetic algorithm for crystal structure prediction.

Author

Varela, Kristal N., Pagola, Gabriel I., Lund, Albert M., Ferraro, Marta B., Orendt, Anita M., and Facelli, Julio C.

Subjects

OPEN scholarship, GENETIC algorithms, CRYSTAL structure, SPACE groups, DENSITY functional theory

Abstract

In this paper we report the implementation and testing of algorithmic changes that have been implemented in MGAC, a crystal structure prediction system, to make it scalable and amenable to take advantage of such significant distributed resources as the Open Science Grid (OSG). The changes include the adoption of a steady state Genetic Algorithm (GA) and the adoption of a more general definition of the GA genome that eliminates the need of searching individually for each of the 230 possible space groups and the use of the Density Functional Theory with dispersion correction (DFT-D) as implemented in Quantum Espresso (QE) to calculate crystal energies. The performance of this implementation of MGAC, which in the following we label as MGAC-QE-OSG, is demonstrated for two test cases methanol and ethanol. In both cases the MGAC-QE-OSG can find the experimental structures of these compounds. • We describe the implementation of the Steady State Genetic Algorithm (SSGA). • SSGA is crystal structure prediction system that uses the Open Science Grid (OSG). • The performance of SSGA is demonstrated for two test cases methanol and ethanol. • SSGA can find the experimental structures of methanol and ethanol. [ABSTRACT FROM AUTHOR]

Published

2024

2. Langston University - High Energy Physics (LU-HEP)

Author

Snow, Dr., Joel [Langston Univ., OK (United States)]

Published

2012

3. Rosen Center for Advanced Computing: Facilities, Equipment, and Resources

Author

Song, X Carol and Purdue University Office of Research

Subjects

data storage, Open Science Grid, boilerplate, cyberinfrastructure, ITaP, high-performance computing, clusters, grant, HUBzero, visualization

Abstract

Overview of RCAC as the research computing arm of Information Technology at Purdue. Describes technical support services as well as collaboration resources in software development, integration, and hosting.

Published

2023

4. Sustainable Science in the Green Cloud via Environmentally Opportunistic Computing

Author

Suh, In-Saeng, Brenner, Paul R., Kim, Jae H., editor, and Lee, Myung J., editor

Published

2011

5. The PacCAF Grid portal for the CDF experiment

Author

Hou, Suen, Lin, Simon C., editor, and Yen, Eric, editor

Published

2010

6. The Deployment and Maintenance of a Condor-Based Campus Grid

Author

Sepulveda, Dru, Goasguen, Sebastien, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Nierstrasz, Oscar, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Sudan, Madhu, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Vardi, Moshe Y., Series editor, Weikum, Gerhard, Series editor, Abdennadher, Nabil, editor, and Petcu, Dana, editor

Published

2009

7. ReSS: A Resource Selection Service for the Open Science Grid

Author

Garzoglio, Gabriele, Levshina, Tanya, Mhashilkar, Parag, Timm, Steve, Lin, Simon C., editor, and Yen, Eric, editor

Published

2009

8. Image Harvest: an open-source platform for high-throughput plant image processing and analysis.

Author

Knecht, Avi C., Campbell, Malachy T., Caprez, Adam, Swanson, David R., and Walia, Harkamal

Subjects

*IMAGE processing, *PLANT genes, *PLANT phenology, *RICE, *BOTANISTS

Abstract

High-throughput plant phenotyping is an effective approach to bridge the genotype-to-phenotype gap in crops. Phenomics experiments typically result in large-scale image datasets, which are not amenable for processing on desktop computers, thus creating a bottleneck in the image-analysis pipeline. Here, we present an open-source, flexible image-analysis framework, called Image Harvest (IH), for processing images originating from high-throughput plant phenotyping platforms. Image Harvest is developed to perform parallel processing on computing grids and provides an integrated feature for metadata extraction from large-scale file organization. Moreover, the integration of IH with the Open Science Grid provides academic researchers with the computational resources required for processing large image datasets at no cost. Image Harvest also offers functionalities to extract digital traits from images to interpret plant architecture-related characteristics. To demonstrate the applications of these digital traits, a rice (Oryza sativa) diversity panel was phenotyped and genome-wide association mapping was performed using digital traits that are used to describe different plant ideotypes. Three major quantitative trait loci were identified on rice chromosomes 4 and 6, which co-localize with quantitative trait loci known to regulate agronomically important traits in rice. Image Harvest is an open-source software for high-throughput image processing that requires a minimal learning curve for plant biologists to analyzephenomics datasets. [ABSTRACT FROM AUTHOR]

Published

2016

9. OSG-GEM: Gene Expression Matrix Construction Using the Open Science Grid.

Author

Poehlman, William L., Rynge, Mats, Branton, Chris, Balamurugan, D., and Feltus, Frank A.

Subjects

*GENE expression, *NUCLEOTIDE sequencing, *GENE mapping, *BIOINFORMATICS, *RNA sequencing

Abstract

High-throughput DNA sequencing technology has revolutionized the study of gene expression while introducing significant computational challenges for biologists. These computational challenges include access to sufficient computer hardware and functional data processing workflows. Both these challenges are addressed with our scalable, open-source Pegasus workflow for processing high-throughput DNA sequence datasets into a gene expression matrix (GEM) using computational resources available to U.S.-based researchers on the Open Science Grid (OSG). We describe the usage of the workflow (OSG-GEM), discuss workflow design, inspect performance data, and assess accuracy in mapping paired-end sequencing reads to a reference genome. A target OSG-GEM user is proficient with the Linux command line and possesses basic bioinformatics experience. The user may run this workflow directly on the OSG or adapt it to novel computing environments. [ABSTRACT FROM AUTHOR]

Published

2016

10. A Distributed Workflow Management System with Case Study of Real-life Scientific Applications on Grids.

Author

Wu, Qishi, Zhu, Mengxia, Gu, Yi, Brown, Patrick, Lu, Xukang, Lin, Wuyin, and Liu, Yangang

Abstract

Next-generation scientific applications feature complex workflows comprised of many computing modules with intricate inter-module dependencies. Supporting such scientific workflows in wide-area networks especially Grids and optimizing their performance are crucial to the success of collaborative scientific discovery. We develop a Scientific Workflow Automation and Management Platform (SWAMP), which enables scientists to conveniently assemble, execute, monitor, control, and steer computing workflows in distributed environments via a unified web-based user interface. The SWAMP architecture is built entirely on a seamless composition of web services: the functionalities of its own are provided and its interactions with other tools or systems are enabled through web services for easy access over standard Internet protocols while being independent of different platforms and programming languages. SWAMP also incorporates a class of efficient workflow mapping schemes to achieve optimal end-to-end performance based on rigorous performance modeling and algorithm design. The performance superiority of SWAMP over existing workflow mapping schemes is justified by extensive simulations, and the system efficacy is illustrated by large-scale experiments on real-life scientific workflows for climate modeling through effective system implementation, deployment, and testing on the Open Science Grid. [ABSTRACT FROM AUTHOR]

Published

2012

11. OSG-GEM: Gene Expression Matrix Construction Using the Open Science Grid

Author

William L. Poehlman, Mats Rynge, Frank Alex Feltus, Chris Branton, and D. Balamurugan

Subjects

0301 basic medicine, Open science, Biology, Biochemistry, Workflow engine, Workflow technology, 03 medical and health sciences, distributed computing, 0302 clinical medicine, Open Science Grid, Molecular Biology, lcsh:QH301-705.5, DNA sequence analysis, Applied Mathematics, Grid, RNAseq, Data science, Pegasus, Computer Science Applications, Computational Mathematics, 030104 developmental biology, Workflow, Computer architecture, Technical Advance, lcsh:Biology (General), Scalability, 030217 neurology & neurosurgery, Workflow management system, Reference genome

Abstract

High-throughput DNA sequencing technology has revolutionized the study of gene expression while introducing significant computational challenges for biologists. These computational challenges include access to sufficient computer hardware and functional data processing workflows. Both these challenges are addressed with our scalable, open-source Pegasus workflow for processing high-throughput DNA sequence datasets into a gene expression matrix (GEM) using computational resources available to U.S.-based researchers on the Open Science Grid (OSG). We describe the usage of the workflow (OSG-GEM), discuss workflow design, inspect performance data, and assess accuracy in mapping paired-end sequencing reads to a reference genome. A target OSG-GEM user is proficient with the Linux command line and possesses basic bioinformatics experience. The user may run this workflow directly on the OSG or adapt it to novel computing environments.

Published

2016

12. Image Harvest: an open-source platform for high-throughput plant image processing and analysis

Author

David Swanson, Malachy T. Campbell, Harkamal Walia, Avi C. Knecht, and Adam Caprez

Subjects

Crops, Agricultural, 0106 biological sciences, 0301 basic medicine, Physiology, Computer science, open-source software, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Image processing, Plant Science, large-scale biology, Bioinformatics, computer.software_genre, 01 natural sciences, Bottleneck, 03 medical and health sciences, Phenomics, image analysis, Open Science Grid, Image Processing, Computer-Assisted, OpenCV, High-throughput computing, 2. Zero hunger, Electronic Data Processing, High throughput computing, Oryza, Pipeline (software), image processing, Metadata, Phenotype, 030104 developmental biology, Parallel processing (DSP implementation), phenomics, Feature (computer vision), Data mining, computer, Software, Genome-Wide Association Study, Research Paper, 010606 plant biology & botany

Abstract

Highlight Image Harvest is an open-source software for high-throughput image processing and analysis that is integrated with the Open Science Grid and provides computational resources to process large image datasets., High-throughput plant phenotyping is an effective approach to bridge the genotype-to-phenotype gap in crops. Phenomics experiments typically result in large-scale image datasets, which are not amenable for processing on desktop computers, thus creating a bottleneck in the image-analysis pipeline. Here, we present an open-source, flexible image-analysis framework, called Image Harvest (IH), for processing images originating from high-throughput plant phenotyping platforms. Image Harvest is developed to perform parallel processing on computing grids and provides an integrated feature for metadata extraction from large-scale file organization. Moreover, the integration of IH with the Open Science Grid provides academic researchers with the computational resources required for processing large image datasets at no cost. Image Harvest also offers functionalities to extract digital traits from images to interpret plant architecture-related characteristics. To demonstrate the applications of these digital traits, a rice (Oryza sativa) diversity panel was phenotyped and genome-wide association mapping was performed using digital traits that are used to describe different plant ideotypes. Three major quantitative trait loci were identified on rice chromosomes 4 and 6, which co-localize with quantitative trait loci known to regulate agronomically important traits in rice. Image Harvest is an open-source software for high-throughput image processing that requires a minimal learning curve for plant biologists to analyzephenomics datasets.

Published

2016

13. Adaptive Co-Scheduler for Highly Dynamic Resources

Author

Vedalaveni, Kartik

Subjects

Adaptive, co-scheduler, condor, grid computing, globus, open science grid, flocking, job router, Computational Engineering, Other Computer Engineering

Abstract

There are many kinds of scientific applications that run on high throughput computational (HTC) grids. HTC may utilize clusters opportunistically, only running on a given cluster when it is otherwise idle. These widely dispersed HTC clusters are heterogeneous in terms of capability and availability, but can provide significant computing power in aggregate. The scientific algorithms run on them also vary greatly. Some scientific algorithms might use high rates of disk I/O and some might need large amounts of RAM. Most schedulers only consider cpu availability, but unchecked demand on these associated resources that aren’t managed by resource managers may give rise to several issues on the cluster. On the grid there could be different schedulers on different sites and we cannot rely upon features of one kind of scheduler to characterize the nature and features of every job. Most state of the art schedulers do not take into account resources like RAM, Disk I/O or Network I/O. This is as true for the local schedulers as much it is for the grid. Often there is a need to extend these schedulers to solve situations arising from new and/or complex use cases either by writing a plugin for existing schedulers or by CoScheduling. A key issue is when resources like RAM, Disk I/O or Network I/O are used in an unchecked manner and performance degrades as a result of it. Further scheduling jobs that claim the degraded resources could overwhelm the resource to an extent that the resource will finally stop responding or theWe solve system will crash. We schedule based on minimum turnaround time of the sites which will help increase the throughput of the overall workload for the Co-Scheduler, which also is a good load- balancer in itself. The Co-Scheduler is driven by the fact that turnaround time increases when concurrent jobs accessing these resources reach a threshold value which in-turn causes degradation and this is the basis for this work. With an increase in the number of entities concurrently using the resource, there is a need to monitor and schedule concurrent and unmanaged access to any given resource to prevent degradation. These issues that we encounter in real life at the Holland Computing Center are the basis and motivation for tackling this problem and for developing an adaptive approach for scheduling. This co-scheduler must be aware of multi-resource degradation, balance load across multiple sites and run clusters at high efficiency and share resources fluidly. An initial implementation tested at HCC will be evaluated and presented. Adviser: David Swanson

Published

2013

14. Deploying and Maintaining a Campus Grid at Clemson University

Author

Sepulveda, Dru

Subjects

BOINC, campus grid, Condor, cyberinfrastructure, Open Science Grid, Computer Sciences

Abstract

Many institutions have all the tools needed to create a local grid that aggregates commodity compute resources into an accessible grid service, while simultaneously maintaining user satisfaction and system security. In this thesis, the author presents a three-tiered strategy used at Clemson University to deploy and maintain a grid infrastructure by making resources available to both local and federated remote users for scientific research. Using this approach virtually no compute cycles are wasted. Usage trends and power consumption statistics collected from the Clemson campus grid are used as a reference for best-practices. The loosely-coupled components that comprise the campus grid work together to form a highly cohesive infrastructure that not only meets the computing needs of local users, but also helps to fill the needs of the scientific community at large. Experience gained from the deployment and management of this system may be adapted to other grid sites, allowing for the development of campus-wide, grid-connected cyberinfrastructures.

Published

2009