Table of Contents

• IntroductionDennis Gannon, Ewa Deelman, Matthew S. Shields, Ian J. Taylor. 1-8 [doi]
• Scientific versus Business WorkflowsRoger S. Barga, Dennis Gannon. 9-16 [doi]
• Generating Complex Astronomy WorkflowsG. Bruce Berriman, Ewa Deelman, John Good, Joseph C. Jacob, Daniel S. Katz, Anastasia C. Laity, Thomas A. Prince, Gurmeet Singh, Mei-Hui Su. 19-38 [doi]
• A Case Study on the Use of Workflow Technologies for Scientific Analysis: Gravitational Wave Data AnalysisDuncan A. Brown, Patrick R. Brady, Alexander Dietz, Junwei Cao, Ben Johnson, John McNabb. 39-59 [doi]
• Workflows in Pulsar AstronomyJohn Brooke, Stephen Pickles, Paul Carr, Michael Kramer. 60-79 [doi]
• Workflow and Biodiversity e-ScienceAndrew C. Jones. 80-90 [doi]
• Ecological Niche Modeling Using the Kepler Workflow SystemDeana D. Pennington, Dan Higgins, A. Townsend Peterson, Matthew B. Jones, Bertram Ludäscher, Shawn Bowers. 91-108 [doi]
• Case Studies on the Use of Workflow Technologies for Scientific Analysis: The Biomedical Informatics Research Network and the Telescience ProjectAbel W. Lin, Steven T. Peltier, Jeffrey S. Grethe, Mark H. Ellisman. 109-125 [doi]
• Dynamic, Adaptive Workflows for Mesoscale MeteorologyDennis Gannon, Beth Plale, Suresh Marru, Gopi Kandaswamy, Yogesh Simmhan, Satoshi Shirasuna. 126-142 [doi]
• SCEC CyberShake Workflows - Automating Probabilistic Seismic Hazard Analysis CalculationsPhilip Maechling, Ewa Deelman, Li Zhao, Robert Graves, Gaurang Mehta, Nitin Gupta, John Mehringer, Carl Kesselman, Scott Callaghan, David Okaya, Hunter Francoeur, Vipin Gupta, Yifeng Cui, Karan Vahi, Thomas H. Jordan, Edward Field. 143-163 [doi]
• Control- Versus Data-Driven WorkflowsMatthew S. Shields. 167-173 [doi]
• Component Architectures and Services: From Application Construction to Scientific WorkflowsDennis Gannon. 174-189 [doi]
• Petri NetsAndreas Hoheisel, Martin Alt. 190-207 [doi]
• Adapting BPEL to Scientific WorkflowsAleksander Slominski. 208-226 [doi]
• Protocol-Based Integration Using SSDL and π-CalculusSimon Woodman, Savas Parastatidis, Jim Webber. 227-243 [doi]
• Workflow Composition: Semantic Representations for Flexible AutomationYolanda Gil. 244-257 [doi]
• Virtual Data Language: A Typed Workflow Notation for Diversely Structured Scientific DataYong Zhao, Michael Wilde, Ian T. Foster. 258-275 [doi]
• Workflow-Level Parametric Study Support by MOTEUR and the P-GRADE PortalTristan Glatard, Gergely Sipos, Johan Montagnat, Zoltán Farkas, Péter Kacsuk. 279-299 [doi]
• myGrid: Aligning a Workflow System with the Life Sciences CommunityTom Oinn, Peter Li, Douglas B. Kell, Carole A. Goble, Antoon Goderis, R. Mark Greenwood, Duncan Hull, Robert Stevens 0001, Daniele Turi, Jun Zhao 0003. 300-319 [doi]
• The Triana Workflow Environment: Architecture and ApplicationsIan J. Taylor, Matthew S. Shields, Ian Wang, Andrew Harrison. 320-339 [doi]
• Java CoG Kit WorkflowGregor von Laszewski, Mihael Hategan, Deepti Kodeboyina. 340-356 [doi]
• Workflow Management in CondorPeter Couvares, Tevfik Kosar, Alain Roy, Jeff Weber, Kent Wenger. 357-375 [doi]
• Pegasus: Mapping Large-Scale Workflows to Distributed ResourcesEwa Deelman, Gaurang Mehta, Gurmeet Singh, Mei-Hui Su, Karan Vahi. 376-394 [doi]
• ICENIA. Stephen McGough, William Lee, Jeremy Cohen, Eleftheria Katsiri, John Darlington. 395-415 [doi]
• Expressing Workflow in the Cactus FrameworkTom Goodale. 416-427 [doi]
• Sedna: A BPEL-Based Environment for Visual Scientific Workflow ModelingBruno Wassermann, Wolfgang Emmerich, Ben Butchart, Nick Cameron, Liang Chen, Jignesh Patel. 428-449 [doi]
• ASKALON: A Development and Grid Computing Environment for Scientific WorkflowsThomas Fahringer, Radu Prodan, Rubing Duan, Jürgen Hofer, Farrukh Nadeem, Francesco Nerieri, Stefan Podlipnig, Jun Qin, Mumtaz Siddiqui, Hong Linh Truong, Alex Villazón, Marek Wieczorek. 450-471 [doi]
• Looking into the Future of Workflows: The Challenges AheadEwa Deelman. 475-481 [doi]