• DocumentCode
    3425845
  • Title

    Sustainable Adaptive Grid Supercomputing: Multiscale Simulation of Semiconductor Processing across the Pacific

  • Author

    Takemiya, Hiroshi ; Tanaka, Yoshio ; Sekiguchi, Satoshi ; Ogata, Shuji ; Kalia, Rajiv K. ; Nakano, Aiichiro ; Vashishta, Priya

  • Author_Institution
    Grid Technol. Res. Center, Nat. Inst. of Adv. Ind. Sci. & Technol.
  • fYear
    2006
  • fDate
    Nov. 2006
  • Firstpage
    23
  • Lastpage
    23
  • Abstract
    We propose a reservation-based sustainable adaptive grid supercomputing paradigm to enable tightly coupled computations of considerable scale (involving over 1,000 processors) and duration (over tens of continuous days) on a grid of geographically distributed parallel supercomputers. The paradigm is demonstrated for an adaptive multiscale simulation application, in which accurate but compute-intensive quantum mechanical (QM) simulations are embedded within a classical molecular dynamics (MD) simulation only when and where high fidelity is required. Key technical innovations include: 1) an embedded divide-and-conquer algorithmic framework to maximally expose data and computation localities for enhanced scalability; 2) a buffered-cluster hybridization scheme to adaptively adjust MD/QM boundaries to maintain the model accuracy; and 3) a hybrid grid remote procedure call (GridRPC) + message passing interface (MPI) grid application framework to combine flexibility (adaptive resource allocation and migration), fault tolerance (automated fault recovery), and efficiency (scalable management of large computing resources). We have achieved an automated execution of multiscale MD/QM simulation on a Grid consisting of 6 supercomputer centers in Japan and the US (in total of 150 thousand processor hours) for the dynamic simulation of implanted oxygen atoms in a silicon substrate, in which the number of processors changes dynamically on demand and resources are allocated and migrated dynamically according to both reservations and unexpected faults. The simulation results reveal a strong dependence of the oxygen penetration depth on the incident oxygen-beam position, which is useful information to further advance SIMOX (separation by implanted oxygen) technique to fabricate high speed and low power-consumption semiconductor devices
  • Keywords
    divide and conquer methods; fault tolerant computing; grid computing; message passing; parallel machines; remote procedure calls; resource allocation; SIMOX; divide-and-conquer algorithm; fault tolerance; message passing interface; molecular dynamics; multiscale simulation; quantum mechanical simulation; remote procedure call; resource allocation; semiconductor processing; sustainable adaptive grid supercomputing; Computational modeling; Computer interfaces; Concurrent computing; Distributed computing; Embedded computing; Grid computing; Quantum computing; Quantum mechanics; Resource management; Supercomputers;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    SC 2006 Conference, Proceedings of the ACM/IEEE
  • Conference_Location
    Tampa, FL
  • Print_ISBN
    0-7695-2700-0
  • Electronic_ISBN
    0-7695-2700-0
  • Type

    conf

  • DOI
    10.1109/SC.2006.59
  • Filename
    4090197