Matt Fago 
15 Washington Avenue 
Manitou Springs, CO 80829
(719) 481-3933
(626) 827-8616 (cell)
fago@earthlink.net

                                EDUCATION 

California Institute of Technology, Pasadena CA, 4.0 / 4.0 grade point
  PhD in Aeronautics, minor in Materials Science, June, 2004
  Master of Science in Aeronautics, June, 1999 
  Field of study: computational solid mechanics
  Advisor: Michael Ortiz
  Thesis: "Constrained Sequential Lamination: 
           Nonconvex Optimization and Material Microstructure"
  Experience includes:
   * C/C++/Java/Fortran, Linux/Unix, massively parallel computing, 
     computer graphics, meshing
   * Optimization, nonlinear finite elements, multiscale material modeling, 
     computational physics

University of Michigan, Ann Arbor, MI, 3.96 / 4.0 grade point 
  Aerospace Engineering BSE, August 1995 
  Mechanical Engineering BSE, December, 1995 
  Research and design experience includes: 
   * Conducted independent research of shell vibration and composite
     failure using holography 
   * Contributed to the preliminary design of a Neptune Orbiter
     spacecraft
   * Completed projects in Mechanical Design, Structural Mechanics and
     Aerospace Laboratory 


                           INDUSTRY EXPERIENCE 
                           
Northrop Grumman Space Technology, Redondo Beach, CA 10/2003 - 4/2005
 * Analyzed the dynamics of a space telescope prototype for the SVMV 
   R&D program
 * Development of parallel C++ spectral element code for efficient 
   frequency response analysis
 * Active SSBI/SCI clearance

Lawrence Livermore National Labs, Livermore, CA Guest 7/2002 - 10/2002
 * Modeled void growth in thin Copper films using molecular dynamics
 * Developed molecular dynamics model of thin film bending stiffness 

Lockheed Martin Astronautics, Denver, CO 1/1996 - 9/1998 
 * Developed system level finite element model of Mars 2001 Orbiter 
 * Developed Phase A spacecraft configuration model of Mars 2001
   Orbiter 
 * Conducted detailed structural analysis in support of design trades 
 * Designed and analyzed spacecraft structural components and
   assemblies, Mars Surveyor 98 
 * Obtained in-depth experience with SDRC I-Deas and MSC Nastran
 * Interfaced with composites lab, prototyping shop and precision
   alignment lab 

Nicolet Instruments, Madison, WI Summer Intern 1990 - 1994 
 * Designed mechanical components of three products as project
   mechanical engineer 
 * Designed and constructed operational prototypes of mechanical and
   optical components 
 * Created and implemented tests to qualify performance of optical
   components 
 * Resolved design problems and redesigned components for cost
   reduction 


                                 HONORS
 
 * DOE Computational Science Graduate Fellowship 
 * Lockheed Martin Employee Commendation for Phase A work on Mars 2001 
 * Edward A. Stalker Undergraduate Research Fellowship, summer 1995 
 * Nicolet Instruments Hi-Step scholar: internship and scholarship 
 * Branstrom Prize for top 5% of freshman in 1991, Angell Scholar and
   Deans Honor list 


                           RESEARCH INTERESTS

 * Computational solid mechanics
 * Structural analysis and design
 * Computational geometry and computer graphics
 * Multiscale modeling with wavelets and subdivision surfaces
 * Application of ab-initio material models to structural analysis
 * MEMS analysis and design tools
 * Optimization


                            RESEARCH SUMMARY 

Sequential lamination of martensitic materials
  Implemented a model to simulate martensitic phase transformations at 
  the subgrid level of a finite element simulation. Sequential 
  lamination is used to construct the partial relaxation of a multiwell 
  energy density, and provides microstructures that are in static and 
  configurational equilibrium.  The laminate topology evolves during 
  deformation through branching and pruning operations, while a 
  continuity constraint provides a simple model of metastability and 
  hysteresis.
  
Local-Quasicontinuum Density Functional Theory
  Co-developed a material model that utilizes ab initio material
  properties computed in real-time during a finite element
  calculation. The material behavior is modeled, through the
  Cauchy-Born assumption, as individual non-interacting unit-cells
  at each mesh integration point. Density Functional Theory is
  used to compute the stresses and energies, with the global
  solution fields obtained through energy minimization. This
  approach allows for the prediction of phase changes and the
  effects of alloy composition, and simulation under large ranges
  of stresses.
  
Finite temperature quasicontinuum method
  Extending the quasicontinuum method to finite temperatures. The
  quasicontinuum method is a multiscale generalization of
  molecular dynamics that uses representative atoms to model
  regions where fields vary slowly, while seamlessly transitioning
  to atomistic resolution where required. Finite temperature
  effects are included by using a Langevin thermostat to provide a
  first approximation to the thermal motion of the atoms.
  
NiTi phase transformation under dynamic loading
  Kolsky bar experiments investigating the phase transformation
  behavior of a superelastic Nickel Titanium shape memory alloy
  under dynamic loading.
  
Edge delamination in laminated composites
  Experimental investigation of void growth in laminated composite
  panels using holographic interferometry.


                              PUBLICATIONS

Prediction of dislocation nucleation during nanoindentation by the 
orbital free Density Functional Theory based local quasicontinuum 
method. R.L. Hayes, M. Fago, M. Ortiz and E.A. Carter. Multiscale
Modeling and Simulation, 4(2):359-389, 2005.
      
Density functional theory based local quasicontinuum method: 
Prediction of dislocation nucleation. M. Fago, R.L. Hayes, E.A. 
Carter, and M. Ortiz. Physical Review B, 70:100102, 2004.
      
A constrained sequential-lamination algorithm for the simulation of
sub-grid microstructure in martensitic materials. S. Aubry, M. Fago,
M. Ortiz. Computer Methods in Applied Mechanics and Engineering, 
192(26-27):2823-2843, 2003.

Experimental investigation of the behavior of edge delaminations using
holographic interferometry. M.J. Fago and A.M. Waas. Optical
Engineering, 37:1420-1428, 1998.


                      CONFERENCES AND PRESENTATIONS

Local quasicontinuum density functional theory. M. Fago, R.L. Hayes, 
E.A. Carter, M. Ortiz. 7th US National Congress on Computational 
Mechanics, 2003.

A constrained sequential-lamination algorithm with applications to
plasticity and shape memory alloys. M. Ortiz, S. Aubry,
M. Fago. COMPLAS 2003. 

Simulation of laminated microstructures in martensitic
materials. S. Aubry, M. Fago, M. Ortiz. ASCI review poster
presentation, October 2002. 

Density functional theory as a finite element constitutive
model. M. Fago, M. Ortiz, R.L. Hayes, E.A. Carter. CSGF conference
poster session 2002. 

Finite element simulation of laminated microstructures in shape memory
materials. M. Fago, S. Aubry, M. Ortiz. CSGF conference poster session
2001.