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Cyberinfrastructure Training, Education, Advancement, & Mentoring (CI-TEAM)

This program aims to develop a diverse cyberinfrastructure workforce and foster inclusion of underrepresented groups in cyberinfrastructure activities. It provides funding for demonstration and implementation projects that leverage multidisciplinary teams and partnerships to have a significant impact.

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Cyberinfrastructure Training, Education, Advancement, & Mentoring (CI-TEAM)

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  1. Cyberinfrastructure Training, Education, Advancement, & Mentoring (CI-TEAM) Miriam Heller National Science Foundation ACCI October 31, 2006 Office of CyberInfrastructure

  2. Cyberinfrastructure Revolution • “… the cyberinfrastructure layer… for the empowerment of specific communities of researchers to innovate and eventually revolutionize what they do, how they do it, and who participates.” • “must also… exploit the new opportunities that cyberinfrastructure brings for … people who, because of physical capabilities, location, or history, have been excluded from the frontiers of scientific and engineering research and education.” www.nsf.gov/od/oci/reports/toc.jsp Office of CyberInfrastructure

  3. Call to Action Vision • “NSF will play a leadership role in the development and support of a comprehensive cyberinfrastructure essential to 21st century advances in science and engineering research and education.” Mission • “Promote a CI that serves as an agent for broadening participation and strengthening the Nation’s workforce in all areas of science and engineering” Goals and Strategies • Support the development of the computing professionals, interdisciplinary teams and new organizational structures, such as virtual communities, ..., paying particular attention to the opportunities to broaden the participation of underrepresented groups” Office of CyberInfrastructure

  4. Cyberinfrastructure Training, Education, Advancement, and Mentoring for Our 21st Century Workforce (FY06 CI-TEAM) • Goals: • Develop a diverse cyberinfrastructure workforce • Foster inclusion in cyberinfrastructure activities of diverse groups • FY06 program funds ~ $10 M for two types of awards: • Demonstration Projects ≤ $250,000 • Implementation Projects ≤ $1,000,000 • Multidisciplinary teams • Significant impact from partnerships • Leveraged cyberinfrastructure • Replicable and (potentially) scalable • Open software standards where appropriate and possible • Management, collaboration and evaluation plans Office of CyberInfrastructure

  5. Community Mobilization, CI Awareness & Training New Curricula and Pedagogical Models Tool / Environment Development & Dissemination Authentic Research, Discovery-based Learning October 31, 2006 Office of CyberInfrastructure Office of CyberInfrastructure

  6. Learning and Our 21st Century CI WorkforceCI-TEAM: Demonstration Projects FY05 • Alvarez (FIU) – CyberBridges • Crasta (VaTech) – Project-Centric Bioinformatics • DiGiano (SRI) – Cybercollaboration Between Scientists and Software Developers • Figueiredo (UF) – MW enables Coastal & Estuarine Science CI Training • Fortson (Adler) – CI-Enabled 21st c. Astronomy Training for HS Science Teachers • Fox (IU) - Bringing Minority Serving Institution Faculty into CI & e-Science Communities • Gordon (OSU) – Leveraging CI to Scale-Up a Computational Science U/G Curriculum • Panoff (Shodor) – Pathways to CyberInfrastructure via Computational Science • Regli (Drexel) – CI for Creation and Use of Multi-Disciplinary Engineering Models • Simpson (PSU) – CI-Based Engineering Repositories for Undergraduates (CIBER-U) • Takai (SUNY) – Cyberinfrastructure via MARIACHI Office of CyberInfrastructure

  7. Learning and Our 21st Century CI WorkforceCI-TEAM: Demonstration Projects FY05 • Alvarez (FIU) – CyberBridges • Crasta (VaTech) – Project-Centric Bioinformatics • DiGiano (SRI) – Cybercollaboration Between Scientists and Software Developers • Figueiredo (UF) – MW enables Coastal & Estuarine Science CI Training • Fortson (Adler) – CI-Enabled 21st c. Astronomy Training for HS Science Teachers • Fox (IU) - Bringing Minority Serving Institution Faculty into CI & e-Science Communities • Gordon (OSU) – Leveraging CI to Scale-Up a Computational Science U/G Curriculum • Panoff (Shodor) – Pathways to CyberInfrastructure via Computational Science • Regli (Drexel) – CI for Creation and Use of Multi-Disciplinary Engineering Models • Simpson (PSU) – CI-Based Engineering Repositories for Undergraduates (CIBER-U) • Takai (SUNY) – Cyberinfrastructure via MARIACHI Office of CyberInfrastructure

  8. Learning and Our 21st Century CI WorkforceCI-TEAM: Demonstration Projects FY05 • Alvarez (FIU) – CyberBridges • Crasta (VaTech) – Project-Centric Bioinformatics • DiGiano (SRI) – Cybercollaboration Between Scientists and Software Developers • Figueiredo (UF) – MW enables Coastal & Estuarine Science CI Training • Fortson (Adler) – CI-Enabled 21st c. Astronomy Training for HS Science Teachers • Fox (IU) - Bringing Minority Serving Institution Faculty into CI & e-Science Communities • Gordon (OSU) – Leveraging CI to Scale-Up a Computational Science U/G Curriculum • Panoff (Shodor) – Pathways to CyberInfrastructure via Computational Science • Regli (Drexel) – CI for Creation and Use of Multi-Disciplinary Engineering Models • Simpson (PSU) – CI-Based Engineering Repositories for Undergraduates (CIBER-U) • Takai (SUNY) – Cyberinfrastructure via MARIACHI Office of CyberInfrastructure

  9. Learning and Our 21st Century CI WorkforceCI-TEAM: Demonstration Projects FY05 • Alvarez (FIU) – CyberBridges • Crasta (VaTech) – Project-Centric Bioinformatics • DiGiano (SRI) – Cybercollaboration Between Scientists and Software Developers • Figueiredo (UF) – MW enables Coastal & Estuarine Science CI Training • Fortson (Adler) – CI-Enabled 21st c. Astronomy Training for HS Science Teachers • Fox (IU) - Bringing Minority Serving Institution Faculty into CI & e-Science Communities • Gordon (OSU) – Leveraging CI to Scale-Up a Computational Science U/G Curriculum • Panoff (Shodor) – Pathways to CyberInfrastructure via Computational Science • Regli (Drexel) – CI for Creation and Use of Multi-Disciplinary Engineering Models • Simpson (PSU) – CI-Based Engineering Repositories for Undergraduates (CIBER-U) • Takai (SUNY) – Cyberinfrastructure via MARIACHI Office of CyberInfrastructure

  10. Middleware-enabledCoastal & Estuarine Science CI TrainingR. Figueiredo, J. R. Davis, J. A. B. Fortes, Y. P. Sheng (University of Florida) • Goals: • Educate and train the coastal and estuarine on use and development of CI. • Approach: • Create web portal with Grid-enabled simulators to model water quality at the Guana Tolomato Matanzas National Estuarine Research Reserve (NERR). • K-grey access to simulators at NERR and to water policy decision-makers. • Develop Grid middleware curriculum content. • Partners: • St. Johns River Water Management District • NERR • Leveraged Cyberinfrastructure: • NMI products: In-VIGO and Condor Office of CyberInfrastructure

  11. Learning and Our 21st Century CI WorkforceCI-TEAM: Demonstration Projects FY06 • Acevedo (U North Texas) Engaging Local Governments, Teachers and Students in CI for Environmental Monitoring and Modeling • Brodley (CRA) Multidisciplinary Opportunities for Women • Grimshaw (U VA) Towards a Culture of Computational Science • Neeman (U Oklahoma) Cyberinfrastructure Education for Bioinformatics and Beyond • O'Brien (UT Austin) Educating a Competitive, Cyberinfrastructure Savvy Engineering and Construction Workforce • Pennington (UNM) Advancing Cyberinfrastructure-based Science Through Education, Training, and Mentoring of Science Communities • Steckler (Oregon State U) Tsunami Shelter Challenge Office of CyberInfrastructure

  12. Learning and Our 21st Century CI WorkforceCI-TEAM: Implementation Projects FY06 • Alo (UH Downtown) Minority Serving Institutions (MSI)-Cyberinfrastructure Empowerment Coalition (MSI-CIEC) • Alvarez (FIU) Global CyberBridges (GCB): A Model Global Collaboration Infrastructure for e-Science for US / Int’l Partners • Finholt (U Mich) Cyberinfrastructure for Next Generation Civil Infrastructure • Hayden (Elizabeth City St U) Cyberinfrastructure for Remote Sensing of Ice Sheets • Jordan (USC) Advancement of Cyberinfrastructure Careers through Earthquake System Science (ACCESS) • Kalkhan (CO State) GODM Cyberinfrastructure for Citizen Scientists • Karniadakis (Brown U) Training Simulation Scientists in Advanced Cyberinfrastructure Tools and Concepts • Regli (Drexel) Cyber-Infrastructure for Engineering Informatics Education • Simpson (Penn State) A National Engineering Dissection Collaboratory • Takai (SUNY Stony Brook) Cyberinfrastructure via MARIACHI Office of CyberInfrastructure

  13. Tsunami Shelter ChallengeR. Steckler, M. Bailey, H. Yeh (Oregon State U) • Goals: • Build CI and computational skills in middle school teachers and students (low income, rural Hispanic & Native American). • Approach: • Design tsunami shelter with CAD tools. • Simulate & visualize effects of tsunami over CAD structures. • Document all with collaboration tools. • Test shelter mockups at Tsunami Wave Basin, with tele-presence, and compare with simulated results. • Partners: • IronCAD • International • Leveraged Cyberinfrastructure: • NEESgrid and repository and DLESE Office of CyberInfrastructure

  14. (MSI-CIEC): Minority Serving Institutions –CyberInfrastructure Empowerment CoalitionR.A. Aló (UH), G.C. Fox (IU), A.S. Kuslikis (AIHEC), A. Ramirez (HACU), S. Singleton (NAFEO) • Goals: • Provide a scalable, equitable mechanism for developing a CI-enabled science and engineering workforce inclusive of MSIs as full partners. • Approach: • Form a virtual organization supported by an MSI-CIEC portal and a CI Advisory Council. • Raise CI awareness of MSI students, faculty, ad-ministrators through education, curriculum, training. • Build CI-enabled MSI research capability. • Build institutional capacity in CI. • Leveraged Cyberinfrastructure: • TeraGrid, NCSA, SDSC, TACC, OSG. • Partners: • Eventually 335 MSIs Office of CyberInfrastructure

  15. Global CyberBridgesH. Alvarez, J. Ibarra, K. Kumar, C. Zhang (FIU) and P. Arzberger (UCSD) • Goals: • Create and transfer CI-enabled research knowledge and skills, increase scientists’ rates of discovery, and create a CI empowered global workforce. • Approach: • Engage graduate students as hubs in global, interdisciplinary faculty teams pursuing inquiry-based learning. • Develop socio-technical infrastructure to facilitate globally distributed R&D projects. • Launch CI scholastic certification program. • Leveraged Cyberinfrastructure: • WHREN-LILA; AMPATH • OptIPuter • Partners: • International (China, Hong Kong, Brazil) • PRAGMA Office of CyberInfrastructure

  16. Cyberinfrastructure for Simulation ScientistsG.E. Karniadakis (Brown U), S. Dong (Purdue U) and N. Karonis (Northern Illinois U) • Goals: • Advance simulation tools for TeraGrid. • Disseminate to wider scientific community. • Lower barriers to TeraGrid (TG) use. • Approach: • Mobilize and train new generation of biomechanics researchers. • Develop curriculum in grid computing, multiscale biological modeling, scientific visualization. • Leveraged Cyberinfrastructure: • Develop TG biomechanics gateway. • Develop web portal bioHUB. • Partners: • Community colleges (Chicago area) • High schools (Providence area) Office of CyberInfrastructure

  17. MARIACHI www.elmariachi-project.orgH. Takai, J. Hover, M. Marx (BNL), R.D. Bynum & M. Fernandez-Bugallo (SUNY SB) • Goals: • Build a state-of-the art educational program for distributed CI data collection & analysis and large-scale collaborative research projects. • Approach: • Exploit CI & distributed education facilities to detect ultra-high-energy cosmic rays. • Provide discovery-based and hands-on learning in physics, engineering, data management, and computer science. • Communicate with collaboration tools. • Partners: • LIGASE • High schools • Community colleges • International partners • Leveraged Cyberinfrastructure: • Implemented prototype detectors. • Open Science Grid for data collection and analysis. Office of CyberInfrastructure

  18. FY05 / FY06 CI-TEAM Summary • Two successful competitions. • 28 projects funded across all areas of science and engineering. • Geographical, organizational, gender, ethnic diversity. • Substantial impact expected through partnerships. • Working on the FY07 CI-TEAM solicitation with the NSF-wide management team. • Planning a CI-TEAM or CI-LWD grantees meeting. Office of CyberInfrastructure

  19. Backup Slides Office of CyberInfrastructure

  20. FY05 CI-TEAM Award Statistics Office of CyberInfrastructure

  21. FY06 CI-TEAMAward Statistics sciplines Office of CyberInfrastructure

  22. CI-Enabled 21st c. Astronomy Training for High School Science Teachers L. Fortson (Adler), C.R. Pennypacker (LBL), A Rahimi (Northwestern) • Goals: • Provide professional development to high school teachers to teach students how to carry out authentic astronomy research. • Approach: • Use research scenarios for training on START Collaboratory resources and tools to generate useful scientific results like professional astronomers. • Provide a model for network-based collaborative research to form a virtual community of practice. • Leveraged Cyberinfrastructure: • SDSS / NVO JHU. • START Collaboratory. • Partners: • Hands-On Universe, UC B Office of CyberInfrastructure

  23. CIBER-U’s CAD Model Creation/Sharing National Design Repository http://www.designrepository.org FY05 CI-TEAM: CIBER-U Demonstration Project Community Databases for Research & EducationSimpson (PSU), Regli (Drexel), Stone (UMo), Lewis (SUNY Buffalo) • Goals: • Attract and prepare students to work in distributed, technology-mediated environment, preferred by automotive and aerospace industries today. • Approach: • Implement CIBER-U in 7 U/G engineering design courses to teach access, storage, search, reuse of CAD models and data from NDR. • Enhance and use collaboration tools in NDR. • Expose over 1700 undergraduate students and 200 high school students to CIBER-U • Leveraged Cyberinfrastructure: • National Design Repository (NDR) • > 55,000 CAD models and assemblies • Used by > 1000 researchers per month • Partners: • Project Lead the Way high school state programs. Office of CyberInfrastructure

  24. FY05 CI-TEAM: Exploiting Cyber-Infrastructure for Creation and Use of Multi-Disciplinary Engineering ModelsRegli, Piasecki (Drexel), Gupta (UMd), Lin (UNC), Shapiro (U Wisc) • Snake-inspired robot systems • Semantic descriptions of robotic components, physics-based behavioral simulation, control and navigation software, tools for analysis and visualization, component surrogation and mission assessment. • Comprehensive engineering model for sharedin-silico prototyping • Multidisciplinary PI-developed courses taught at partner institutions, exploit tele-collaboration, distance- and e-Learning • Engineering Informatics • Partners to rapidly transition new knowledge representation, standards, and software interoperability: • NIST, DoE, ISO, W3C / Boeing, Honeywell, Kulicke and Soffa, EDS, S&K, Lockheed Martin and MSC Office of CyberInfrastructure

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