SCIENTIFIC COMPUTING AND VISUALIZATION (Fall 09)

Course Description
Particle and continuum simulations are used as a vehicle to learn basic elements of high performance scientific computing and visualization. Students will obtain hands-on experience in: 1) formulating a mathematical model to describe a physical phenomenon; 2) discretizing the model, which often consists of continuous differential or integral equations, into algebraic forms in order to allow numerical solution on computers; 3) designing/analyzing numerical algorithms to solve the algebraic equations efficiently on parallel computers; 4) translating the algorithms into a program; 5) performing a computer experiment by executing the program; 6) visualizing simulation data in an immersive and interactive virtual environment; and 7) managing/mining large datasets.

Visualization of 209 million-atom simulation of hypervelocity impact on a high-strength ceramic plate on a tiled display.

Syllabus

• Basic molecular dynamics (MD) algorithms
  • Integration of ordinary differential equations; periodic boundary condition; linked-list cells
• Parallel MD
  • Spatial decomposition (interprocessor caching and migration); load balancing; scalability analysis; asynchronous MD
  • Message passing interface (MPI) vs. shared memory (OpenMP) programming
  • Hybrid MPI+OpenMP programming
  • Build-it-yourself PC cluster
  • Multicore parallel programming (e.g., Cell, GPU)
• Scientific visualization
  • OpenGL programming
  • Virtual environment programming--CAVE Library, ImmersaDesk, tiled display
• Scientific data management/mining
  • Data compression for scalable I/O
  • Graph-based knowledge discovery
• Grid scientific computing
  • Computation steering on the Grid-integrated parallel computing, data storage, and visualization resources via high-speed networks
  • Grid enabling parallel applications
• Object-oriented scientific programming
  • Parallel software tools for irregular data structures; object-oriented MD; Python wrappers
• Other simulation methods
  • Stochastic simulations: Monte Carlo method
  • Continuum simulations: Schrodinger equation in quantum mechanics

Announcements

• 8/26/09 (W): You may be interested in a Webnar on parallel computing with Matlab on Sep. 22 (T).
• 9/2/09 (W): For assignments, both electronic submission via email and a hard copy at the class will be accepted.
• 9/2/09 (W): You may use any computer with a C compiler for assignment 1.
• 9/14/09 (M): Please see information on Oklahoma Supercomputing Symposium 2009.
• 9/16/09 (W): Tour of HPCC--please bring your photo ID; we will meet at the classroom and will take a tram together. Thank you very much, Maureen, for the great tour.
• 9/28/09 (M): Please see a sample PBS script for assignment 2.
• 10/1/09 (Th): See artiles on parallel molecular-dynamics simulations on GPU and special-purpose hardware in the Communications of the ACM.
• The submission date of assignment 2 has been extended to Friday, Oct. 2.
• 10/7/09 (W): For advanced communication schemes for MD simulation, see: K. J. Bowers, et al., J. Chem. Phys. 124, 184109 ('06).
• 10/7/09 (W): For "metascalable" parallel molecular dynamics, see: K. Nomura, et al., Proc. of IPDPS 2009.
• 10/14/09 (W): Tour of VizLab (SSL 104) + building PC.
• 10/19/09 (M): Special lecture on large scale computing at Linkedin by Bhupesh Bansal (Linkedin); also see (1) Linkedin Grads Guide: How to leverage linkedin to the max for students; and (2) Linkedin job/internship openings.
• 10/26/09 (M): For tensor-field visualization mentioned in assignment 5, see: L. Hesselink, et al., IEEE Computer Graphics & Applications 14, 76 ('93); W. Ribarsky, et al., IEEE Computer 27(7), 57 ('94); A. Sigfridsson, et al., IEEE Visualization 2002, (IEEE, 2002) p. 371.
• 11/2/09 (M): Discussion session for assignment 5 at 5:00pm in VHE 610.
• 11/2/09 (M): If you are woking in a group for the final project, please participate in the survey at the Annenberg School of Communication; for questions regarding the survey, please email Li Lu.
• 11/4/09 (W): Special lecture on "FPGA on-chip debugging tools and methodologies" by Dr. Jingzhao Ou of Xilink, Inc.

Lecture Notes

• Introduction
• Basic molecular dynamics algorithms
• Linked-list cell MD algorithm
• Message Passing Interface; viewgraphs
• Parallel Computation of Pi
• Parallel MD algorithm; introduction
• Visualizing molecular dynamics
• Virtual-reality programming
• Massive data visualization, see also: A. Sharma, et al., Presence 12, 85 ('03); C. Zhang, et al., Comput. Phys. Commun. 175, 339 ('06)
• OpenMP
• Hybrid MPI+OpenMP parallel MD
• Miscellaneous lectures
  • Least-square fitting
  • installing OpenGL and GLUT; see also how to use OpenGL and GLUT with Microsoft Visual Studio

Assignments

• 1: Molecular dynamics (due Monday, Sep. 14)
• 2: Message Passing Interface (due Wednesday, Sep. 30; extended to Friday, Oct. 2)
• 3: Parallel computation of Pi (due Friday, Oct. 9; extended to Monday, Oct. 12)
• 4: Parallel molecular dynamics (due Monday, Oct. 19)
• 5: Animating molecular dynamics (due Wednesday, Nov. 4)

Source Codes

• Sequential MD program: md.c, md.h, md.in
• Linked-list cell MD program: lmd.c, lmd.h, lmd.in
• MPI basics: mpi_simple.c, mpi_comm.c, irecv_comm.c, mpi_simple_sample.pbs
• Parallel MD program: pmd.c, pmd.h, pmd.in
• Visualizing MD simulation: atomv.c, atomv.h, md.conf
• Quantum dynamics: qd.c, qd.h, qd.in; qd1.c, qd1.h, qd1.in
• OpenMP basics: omp_example.c, omp_example_set.c, omp_pi_critical.c, omp_pi.c
• Hybrid MPI+OpenMP: hpi.c

Useful Links

• Message Passing Interface (MPI)
  • Argonne National Laboratory MPI page
  • MPI, The Complete Reference on line
  • MPICH-G2--Grid-enabled MPI
• OpenMP
  • OpenMP homepage
  • OpenMP tutorial
• OpenGL
  • OpenGL homepage
  • OpenGL Programming Guide on line
• CUDA
  • CUDA Zone at NVIDIA
  • CUDA programming course by Prof. Wen-mei Hwu at University of Illinois at Urbana-Champaign
• Parallel Computing
  • Parallel programming bootcamp at UC Berkeley
• Network/Grid Scientific Computing
  • Globus project
  • Global Grid Forum
  • nanoHUB
• Virtual Reality/Visualization
  • CAVE programming at Electronic Visualization Laboratory at University of Illinois at Chicago
  • IEEE Virtual Reality Conference
  • ACM SIGGRAPH Conference
  • IEEE Visualization Conference
  • VMD: Visual Molecular Dynamics at University of Illinois at Urbana-Champaign
  • Atomsviewer: A scalable molecular visualization code
  • VisIT visualization tool at Lawrence Livermore National Laboratory
  • ParaView parallel visualization application at Los Alamos National Laboratory
  • VISTA scalable volume renderer at Sandiego Supercomputing Center
• Scientific Object Oriented Programming
  • NAMD--an object-oriented molecular dynamics at Urbana-Champaign
• Linux Cluster
  • HPC cluster at USC and its node information
• Network/Interconnect
  • Myrinet
  • Infiniband
  • Intenet2 homepage
• Supercomputing & Information Technology for Science & Engineering
  • Microsoft report on Towards 2020 Science
  • Nature special issue on Future of Computing
  • Ultrascale Simulation for Science at the U.S. Department of Energy; see also reports at the DOE Office of Advanced Scientific Computing Research
  • NSF Report on Revolutionizing Science & Engineering through Cyberinfrastructure
  • NSF Report on Cyberscience
  • Top 500 supercomputer list
  • IEEE/ACM Supercomputing Conference
  • IEEE International Parallel & Distributed Processing Symposium
• Computational Science
  • IEEE Computing in Science and Engineering magazine
• Numerical Methods
  • W. H. Press, B. P. Flannery, S. A. Teukolsky, and W. T. Vetterling, "Numerical Recipes, 2nd Ed." (Cambridge U Press, C: 1993)