• DocumentCode
    1838255
  • Title

    Computational fluid flow simulation on body fitted mesh geometry with FPGA based emulated digital cellular neural networks

  • Author

    Kiss, A. ; Nagy, Z.

  • Author_Institution
    Dept. Inf. Technol., Pazmany Peter Catholic Univ., Budapest, Hungary
  • fYear
    2010
  • fDate
    3-5 Feb. 2010
  • Firstpage
    1
  • Lastpage
    6
  • Abstract
    The analog CNN-UM can be used to solve the Navier-Stokes equations quite fast. But using in engineering applications it can not be sufficiently accurate and reliable because noises from the environment, such as power supply noise or temperature fluctuation. With the proper Field Programmable Gate Array (FPGA) we can gain sufficient (adequate) computation speed with high precision. The dedicated hardware elements of the FPGA can highly accelerate the computations on curved surface. Consequently it can be used in industrial applications where fluid flow simulation around complex shapes is required. In the paper the implementation and optimization of a new Computational Fluid Dynamics (CFD) solver architecture, which can work on Body Fitted Mesh geometry, on FPGA is described. The proposed new architecture is compared to existing solutions in terms of area, speed, accuracy and power dissipation.
  • Keywords
    Navier-Stokes equations; computational fluid dynamics; field programmable gate arrays; flow simulation; neural nets; physics computing; FPGA; Navier-Stokes equations; body fitted mesh geometry; computational fluid flow simulation; digital cellular neural networks; field programmable gate array; Cellular neural networks; Computational fluid dynamics; Computational geometry; Computational modeling; Computer networks; Field programmable gate arrays; Fluid flow; Power engineering computing; Solid modeling; Working environment noise;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Cellular Nanoscale Networks and Their Applications (CNNA), 2010 12th International Workshop on
  • Conference_Location
    Berkeley, CA
  • Print_ISBN
    978-1-4244-6679-5
  • Type

    conf

  • DOI
    10.1109/CNNA.2010.5430318
  • Filename
    5430318