Evaluation of MSU CAVS Capabilities

1. Evaluation of MSU CAVS Capabilities

2. MSU Capability Match-Up • Contents • Tree Structure of CAVS Organization • Significant Accomplishments for FY2004 • Major Goals for FY2006-2010 • Employee Matrix • Department Structure • Department Projects • Department Faculty

3. MSU Capability Match-Up Mississippi State University Center for Advanced Vehicular Systems Mission To research and develop manufacturing and design means and methods for producing vehicles of superior quality with advanced features and functions at reduced costs and shorter product development times, exploiting the underlying technologies for broader industrial use. • Alternative Power Systems • Power Electronic Systems • Advanced Power Systems • Computational Manufacturing and Design • Theoretical Modeling • Experimentation • Large Scale Parallel Computational Simulation • Human and Systems Engineering Research Focus Areas

4. Significant Accomplishments for FY2004 • Completed and opened two CAVS facilities, $23M total by June 2005 • Assembled strong leadership & over 150 total staff: professionals, academic & students • $790K in MS funded service expenditures • $2.48 M in external research expenditures • 35 external awards for $8.8 M • 43 external proposals for $23.6 M • 89 publications (23 journal articles) • Developed Computational Training System (beta) and established collaboration with community colleges regarding work force development & training • Demonstrated full vehicle crashworthiness optimization within 36 hour cycle MSU Capability Match-Up

5. Major Goals for FY2006-2010 • R&D Structural Component Modeling and Simulation Analysis System utilizing multi-scale material modeling, validated through experiments and appropriate for a variety of materials (e.g., lightweight alloys, composites, bio-materials) and a variety of manufacturing processes (e.g., stamping, forging, casting). • R&D Computational Manufacturing and Design System for optimizing the design of structural component product and manufacturing process, building on unique MSU multi-scale material modeling. • R&D Full Vehicle and Road-side Barrier Crashworthiness Design Optimization System for safe lightweight construction and advanced transportation systems. • R&D Integrated, Distributed Information System, utilizing intelligent, secure wireless ad hoc communication and networking, intelligent sensing, web-accessibility and transparent computational resources, and decision support data mining. • R&D Advanced Human Engineering Design System for optimizing the workplace environment for enhanced worker safety and productivity. • R&D Computational Training System for adaptive e-learning, utilizing advanced 3-D engineering tools. • R&D Advanced Power Electronics Technologies and Design System for optimizing the design of power electronics sub-systems, including support for hierarchical design, multi-level modeling and simulation, thermal management, design synthesis, knowledge capture, multi-objective design optimization, and rapid prototyping. • R&D Advanced Power Train Design System, utilizing rapid prototyping of modular, configurable electrical power components (e.g., switching, control, motors). • R&D Advanced Power Technologies with modeling and simulation for efficient, clean operation from renewable fuels (e.g., bio-diesel hybrid, fuel-cell). • Develop a Manufacturing Solutions Information System with decision support, which incorporates advanced manufacturing processes and materials with economic modeling, best practices, and software tools. • Develop efficient means to provide Extension, Engineering Education, and Workforce Training services in support of Mississippi industry, focusing on advanced engineering methods and technology transfer from research. • Plan, develop, and manage programs relevant to Transportation Safety and Security. MSU Capability Match-Up

6. MSU Capability Match-Up

7. MSU Capability Match-Up

8. MSU Capability Match-Up

9. MSU Capability Match-Up Break Down of Alternative Power Systems Department Fuel Cell Modeling and Simulation Power Electronics Power Train Development

10. MSU Capability Match-Up Break Down of Computational Manufacturing and Design Department Computational Manufacturing Crashworthiness Optimization Model Development Structural Cast Magnesium Development Project (SCMD).

11. MSU Capability Match-Up Break Down of Human and Systems Engineering Department Human Factors Enterprise Systems Computational Training System Telematics and Autonomous Vehicle Control Human Motion Capture and Data Interoperability and Hardware Development Intelligent Electronic Systems Institute for Signal and Information Processing (ISIP) Telecommunications and Information Technology Laboratory (TITL)

12. MSU Capability Match-Up Alternative Power Systems Projects Fuel Cell Modeling and Simulation - Advance Measurements and Validation of PEM Fuel Cell Models Fuel Cell Stack System Simulation Model Hydrogen - Future Energy Source Integrating Multi Resolution Fuel Cell Simulation Modeling of PEMFC Cathode Catalyst Particle Transient Fuel Cell Modeling Power Electronics Silicon Carbide Power Semiconductors for Application in Hybrid Electric Vehicles (HEVs) High Power Density Power Converter Design and Prototyping for On-Board Vehicle Power (OBVP) Power Train Design PSAT/ADIVSOR Modeling Tools for Power Train Analysis Fuel Cell Power Train Modeling Simulation and Test Bed Intelligent design and engineering reuse software overlay for power train Analysis Challenge X (US Dept. of Energy and General Motors)

13. MSU Capability Match-Up Alternative Power Systems Projects Initiated with Input by Nissan • Fuel Cell Simulation • Goals: • Develop a fuel cell simulation framework based on Loci framework to integrate all essential component models for seamless and dynamic fuel cell simulations. • Develop multi-fidelity simulation strategies for efficient and accurate fuel cell simulations targeting the design, optimization, and diagnostics of fuel cell systems. • Develop and validate essential fuel cell component models and integrated models through both bulk and distribution measurements. • Develop advanced material characterization and measurement techniques for model validation and fuel cell operation monitoring and diagnostics. • Experimental Fuel Cells • Goals: • To obtain the kinetic parameters of the ORR as a function of temperature between –20 to 30°C at a polycrystalline Pt surface in acid/water or acid/salt/water solutions • To characterize Nafion PEMFC proton-conducting membranes by SANS and proton conductivity studies after exposure to: (1) low temperature operation; (2) high temperature operation; (3) CO and SO2 during operation; and (4) operation at high current density. The characterization will involve SANS/USANS studies of changes in the domain structure versus that of the virgin membrane (before operation). Proton conductivity measurements will also be used to attempt correlation of proton conductivity to phase domain structure

14. MSU Capability Match-Up Computational Manufacturing and Design Projects Multi-Pass Reverse Hot Rolling Process Simulation Damage and Failure Modeling Dodge Neon Crash Simulation Spring-back in Stamped Aluminum Alloy Sheets for Auto-Body Panels Computational Modeling of Fatigue, Fracture, and Ductile Failure Mechanisms at Atomic and Micro-structural Scales in Metals Corvette Engine Cradle Design Multi-Objective Optimization of Roadside Safety Barrier Design Multi-scale Modeling of Metal Casting Cadillac Control Arm Lightweight Design Chemo-mechanical Material Damage Modeling Experimentally Quantified Microstructure-Property Relations for Modeling Vibration Study of Components and White-Body Structures

15. MSU Capability Match-Up Human and Systems Engineering Projects Human Factors Enterprise Systems Computational Training System Telematics and Autonomous Vehicle Control Human Motion Caption and Data Interoperability and Hardware Development Intelligent Electronic Systems

16. MSU Capability Match-Up Intelligent Electronic Systems Projects Campus Bus Networking In-Vehicle Dialog Systems IP Version 6 Routing Spoken-Language Information Retrieval Nonlinear Statistical Modeling of Speech Powertrain Design Tools Internet-Accessible Speech Recognition Technology Cognitive Assessment Using Voice Analysis Active Projects Aurora Evaluation Of Speech Recognition Front Ends Bulldog Stock Exchange A Japanese Command and Control Word Database Automatic Pronunciation Generation Robust Low Perplexity Voice Interfaces Southern-Accented Speech Switchboard Resegmentation A Digital Telephone Interface For Sun Workstations Scenic Beauty Estimation of Forestry Images Inactive Projects

17. MSU Capability Match-Up Alternative Power Systems Faculty David Gao, Assistant Research Professor, Center for Advanced Vehicular Systems Michael Mazzola, Professor, Electrical and Computer Engineering G. Marshall Molen, Distinguished Professor, Electrical and Computer Engineering J. Charlie Wu, Assistant Research Professor, Center for Advanced Vehicular Systems

18. MSU Capability Match-Up Computational Manufacturing and Design Research Faculty and Staff Howie Fang, Assistant Research Professor, Center for Advanced Vehicular Systems Mark Horstemeyer, Professor and CAVS Chair, Mechanical Engineering Wenlong Li, Associate Professor, Mechanical Engineering David Oglesby, Research Associate II, Center for Advanced Vehicular Systems Paul Wang, Manager, Comp Mfg & Des Thrust, Center for Advanced Vehicular Systems

19. MSU Capability Match-Up Human and Systems Engineering Faculty and Staff Julie Baca, Assistant Research Professor, Center for Advanced Vehicular Systems Kim Ball, Research Associate II, Center for Advanced Vehicular Systems Debbie Brown, Research Associate III, Ctr for Educational Training Tech Scott Calhoun, Senior Research Associate, Center for Advanced Vehicular Systems Vincent Duffy, Associate Professor, Industrial Engineering David Goa, Assistant Research Professor, Center for Advanced Vehicular Systems Tomasz Haupt, Associate Research Professor, Center for Advanced Vehicular Systems Greg Henley, Research Associate III, Center for Advanced Vehicular Systems Georgios Lazarou, Assistant Professor, Electrical and Computer Engineering Neil Littell, Product Life Cycle Mgmt Coord., Center for Advanced Vehicular Systems John McGinley, Research Associate II, Center for Advanced Vehicular Systems Joe Picone, Professor, Electrical and Computer Engineering Zach Rowland, Research Associate III, Center for Advanced Vehicular Systems