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Introduction to the program of the summer school

Introduction to the program of the summer school. Peter Kacsuk MTA SZTAKI kacsuk@sztaki.hu. 1. SCI-BUS is supported by the FP7 Capacities Programme under contract nr RI-283481. Who are the members of an e-science community?. End -u se rs (e-scientists) (50.000-500.000)

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Introduction to the program of the summer school

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  1. Introduction to the program of the summer school Peter Kacsuk MTA SZTAKI kacsuk@sztaki.hu 1 SCI-BUS is supported by the FP7 Capacities Programme under contract nr RI-283481

  2. Who are the members of an e-science community? • End-users (e-scientists) (50.000-500.000) • Execute the published WF applications with custom input parameters by creating application instances using the published WF applications as templates • Science Gateway (SG) Framework Developers (5-10) • Develop genericSG framework • SG Instance Developers (50-100) • Develop application domain specific SG instance • WF Application Developers (500-1.000) • Develop WF applications • Publish the completed WF applications for end-users

  3. Using a SG frameworkto develop applications and share them with others Supercomputer based SGs (DEISA, TeraGrid) Access to a large set of ready-to-run scientific WF applications • Accessing a large set of various DCIs to make these WF applications run WF App. Repository Science Gateway (SG) framework Cluster based service grids (SGs) (EGEE, OSG, etc.) Desktop grids (DGs) (BOINC, Condor, etc.) Grid systems Local clusters Supercomputers Distributed Computing Infrastructure (DCI) What do WF developers need? Clouds

  4. Supercomputer based SGs (DEISA, TeraGrid) Science Gateway (SG)instance App. Repository Cluster based service grids (SGs) (EGEE, OSG, etc.) Desktop grids (DGs) (BOINC, Condor, etc.) Grid systems Local clusters Supercomputers What do e-scientists need? E-scientists • Sharing ready-to-use appls via the repository • Joint run appls via the gateway in the hidden e-science infrastructure Clouds Distributed Computing Infrastructure (DCI)

  5. What do we want to achieve? Cyberspace er Workflows Bio Physics Chemist Kepler Taverna Galaxy WF systems Cloud Grid BOINC Infrastructures Users should be able to access and use any WF and any infrastructure in an interoperable way no matter which is their home WF system

  6. Cyberspace access via gateway Science Gateway er Workflows Bio Physics Chemist Kepler Taverna Galaxy Cyberspace WF systems Cloud Grid BOINC Infrastructures

  7. Projects and school program Science Gateway SCI-BUS (Day 3-5) Cyberspace er Workflows Bio Physics Chemist SHIWA and ER-Flow (day 6) Kepler Taverna Galaxy WF systems Cloud SZTAKI Cloud (day 1 and 2) Grid BOINC Infrastructures

  8. Summary Taverna WF Kepler WF gUSE WF Engine OpenNebulaCloud gUSE gateway gUSE gateway The 4 projects have created a technology that enables to combine many different WFs, WF systems and DCIs in many different ways with a gateway access It is like a puzzle where you can put together the required pieces to create the final picture

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