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Education and Research Directions

Tarek M. Sobh School of Engineering University of Bridgeport Bridgeport, CT 06604. Education and Research Directions. Outline. Central issues in education and research New directions Engineering Problems and a plan Making the “Right” Engineer / Scientist

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Education and Research Directions

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  1. Tarek M. Sobh School of Engineering University of Bridgeport Bridgeport, CT 06604 Education and Research Directions

  2. Outline • Central issues in education and research • New directions • Engineering Problems and a plan • Making the “Right” Engineer / Scientist • New disciplines / challenges and our signature areas • Mechanisms for supporting research • Research strategies and techniques • Projects

  3. Central Issues In Education / Research Some Thoughts from the Late Eighties • Manufacturingand linkages withDesign: • Concurrent Engineering and the ProductRealization Process • Growing Role of theComputer and Software Tools • Simulation, Visualization, Design • Growing Importance of Information Technologies in All Disciplines • Incipience ofMultidisciplinary Education • Comprehensive University / Industry Relations

  4. Central Issues in Education / Research The Twenty-First Century • Manufacturing and Design in Micro and Nano Scales: MEMS and NEMS • Growing importance of Biological Sciences • Increasing Pressure to Transcend Traditional Academic Boundaries: Multidisciplinary Education • Reduce rigidity of curriculum requirements and increase flexibility: Programs of study that meld previously disparate disciplines • Ever Expanding Impact of Information Technologies: The Internet and Wireless Communication Technologies • Asynchronous and Synchronous Distance Learning • The Virtual University • The Virtual Laboratory Experience • e-learning Courses

  5. Central Issues in Education / Research The Twenty-First Century (continued) • Socialization of Learning • Student Centered Learning Activities • Relations with Industry: An Alternative Model • Innovation and Entrepreneurship • The Research / Business Interface • Globalization • International Study and Work Experience

  6. Some New Directions • First-Year Courses onIntroduction to Systems • Multidisciplinary, Experiential and Contextual • Faculty participation from all disciplines • Projects involve analysis, design, buildandtestactivities that cross disciplinary boundaries and involve real applications • Interactive and Collaborative • Shift from faculty- and lecture-centered activities to student-centered activities • Numerous team-based activities

  7. New Directions (continued) A PrototypeLearning Center • Computer Clustersfor Collaborative Simulation and Design Activities • Prototype Fabricationand Test Equipment • Facilities for Conducting Experiments • Group Work and Study Spaces • Multimedia Presentation and Demonstration Area

  8. New Directions (continued) Learning Center in New Building

  9. The Problem(s) (and a Plan) • K-12 Science and Math Weakness • Curriculum / Research based (partially) on constituents’ feedback, needs, vision, aspirations, problems (local, regional, national and global) • Leading versus following ? • “Functional” body of knowledge for leading edge technology development and to produce competent and interdisciplinary engineers and scientists. • New programs (outcome-based) utilizing outstanding and unique human and technology resources (let’s not fall into the .com trap again).

  10. The Problem(s) and Plan (contd.) • Traditional degrees (what does that mean ?) versus new interdisciplinary goal-oriented programs that cater to new complex real-world 21st century areas of interest and potential U.S. dominance. • Global competition (in what ?) Should we be scared ? 500K jobs to India 2001-2003, is this a problem ? How to solve it ? • New programs and collaborations (degree / within degree) driven by our vision of what the future “should be like”, not by what is the current state of the art. NO LIMITS (time to completion, etc.), example: ABET is making it easy at the undergraduate level !.

  11. The Problem and Plan (Contd.) • Quasi-Reverse brain drain (politics / Economics) • Europe, Asia, Canada, Australia very serious competition for brain power. • Continuing to attract international talent (remember K-12 problem) and need for aggressive recruiting at all levels and international cooperation / programs. • Profession Respectability / licensure, lobbying issues.

  12. Making the RIGHT engineers/scientists • Future Engineers (Joe Bordogna, COO NSF): • Holistic designer • Astute maker • Trusted innovator • Harm avoider • Change agent • Master integrator • Enterprise enabler • Knowledge handler • Technology steward • Model for education suitable to the a new world in which change and complexity are the rule, a globally linked world that needs integration in many ways. • The Aftermath (Sam Florman, 2001), Prey (Crichton, 2002)

  13. New? “Engineering” Disciplines / Trends or our signature areas • “BIO”: Deliberate strategic response versus a natural evolutionary process (no definitive mandate ?) • Terascale: tera operations / compute power, terabyte storage, terabyte networking. Fascinating (for now) infrastructure. Applications: Communications, simulations / visualizations, real-time capabilities, etc. • Nanoscale: nano technologies / nano photonics, new materials / machines / living cells interface, precise control and manipulation at that scale [femto scale !] Also, MEMS and “smart dust” for agent detection, temperature, motion, vision sensing, etc.,

  14. New Trends / Challenge Areas • Cognition: above areas + neurosciences, perception, sensing, machine vision, agent-based systems, linguistics, psychologists, mathematics, robotics, automation, and many others interact. • Complexity, integration (traffic, weather, intelligent infrastructure and control systems, aerospace, aviation, large systems). • Advanced Materials and Manufacturing. • Information, communications and perception technologies (not only for defense, but many other applications) • Renewable energy and power systems. • We should not abandon all we know, but rather complement what we do with emerging paradigms

  15. New Directions (continued) Example : Bioengineering • A term with multiple meanings and implications • Medical Engineering • Prostheses • Diagnostic and Surgical Tools • Biotechnology • Bioinformatics • Biosensors • Tissue Engineering • Environmental Engineering/Science • Remediation of organic wastes • Biological destruction of carcinogens and toxic chemicals • Required molecular and cellular biology course for all engineering students • Departmental elective courses

  16. New Directions (continued) Integrated Research/Business Practice Courses Fundamentals:  The Corporation and it Financial Processes  Human Resources and Management Processes  Innovation Processes  Supply Chain Processes and Quality Advanced Topics:  e-Business, Globalization, Outsourcing  Entrepreneurship, Logistics  Business Plans and Business Simulations

  17. Mechanisms for Supporting Research • Periodic Graduate Programs Review • Periodic Research Review • SWOT Analysis • Identification of “Centers of Excellence” • Potential groups / individuals / student work. • Existing opportunities • Yearly / Periodic Goals (Change and Maintenance) • Faculty Development Funds, Seed grants • Making research embedded in the culture • Professional review • Develop Web, training/workshops, grant writ(ers)/(ing)

  18. Research Strategies • Sponsored Research: Industry, Federal, Foundations, State, Local • Multi-Disciplinary • Across departments, schools, campuses • SWOT again • Joint work / proposal writing: Partner with Industry Centers, Other Universities, School Districts, etc. • Identification / Listing of resources / agencies (project) • Recommendations regarding potential project resources

  19. Some Techniques • IAB role • Student Centered Activities • Startup co-ops, internships, GA’s, low overhead. • As a constituent, advise (and be advised) on emerging trends. • Relations with Industry / University Clients Model • Complete Involvement • Joint Work (research and curricular) • Interfacing: VC’s (connecting), Incubator(s) • Overhead % back to group / dept. / school. • Seed funding / ID of potential, extending resources.

  20. Interdisciplinary Project Examples: • Glove (Chiro, Eng and Business (law)) • Robotic Musicians (A&S, Music, Eng) • E-Assessment (Education, Eng) • ConnCap (Education, Eng) • Biometrics / Face ID (Bus, Eng, art (law)) • Tire changing (Bus, Eng) • Reverse Engineering in Dentistry, Film Making (Eng, Art, Health sciences) • Robotics prototyping based on task specification (R.E. of Maths, statics, dynamics, E.E) • Traffic Control (vision, GPS, wireless). • Across dept., school, campus, joint with Univ., school districts, industry, VC’s.

  21. Example Resources • Faculty Enhancement Programs • Instrumentation Grants for research in Computer and Information Science • Research Equipment Grant Program • CISE Directorate Educational Supplements • Instrumentation and Laboratory Improvement • Research in Undergraduate Institutions Program • Grant Opportunities for Academic Liason with Industry Programs • Institutional Infrastructure Programs. • Activities for Women and Minorities in Science Programs • Networking Infrastructure for Education Program. • DUE Undergraduate Education programs • Graduate Research Traineeships programs • Research Careers for Minority scholars program • CISE Computer and Computation Research Grants. • CISE Information, Robotics, and Intelligent Systems Grants (RMI). • CISE Cross-Disciplinary Activities in: o Educational Infrastructure o Institutional Infrastructure for Research o Special Projects • Academic Research Infrastructure (a cross-directorate program) • Research Opportunity Awards (a cross-directorate program) • Small grants for Exploratory Research Program. • Research and Education in Strategic Areas Programs • EHR Division of Undergraduate Education Programs. • EHR Division of Graduate Education and Research Development Programs. • International Directorate Grants. • DARPA, ONR, AFOSR, DoD, NASA, DOE, NIH. • State and local initiatives (centers of excellence programs, etc.) • Collaboration with research centers, industry, • Inter-school, inter-campuses, other Universities, school districts. • Student fellowships (federal / state /industry / foundation) (e.g, IEEE CSIDC, Sigma Xi, Microsoft, etc.)

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