Multi-physics and Multi-scale Electromagnetic Modeling and High Performance Algorithms

被引:0
|
作者
Wu, Yu Mao [1 ]
Jin, Ya-Qiu [1 ]
机构
[1] Fudan Univ, Sch Informat Sci & Technol, Shanghai, Peoples R China
来源
2019 INTERNATIONAL APPLIED COMPUTATIONAL ELECTROMAGNETICS SOCIETY SYMPOSIUM - CHINA (ACES), VOL 1 | 2019年
关键词
Method of moment physical optics (MoM-PO); numerical steepest descent path (NSDP) method; parallel PO method; physical optics (PO); two-dimensional numerical steep.est descent path (TD-NSDP) method; z buffer;
D O I
10.23919/aces48530.2019.9060570
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
This paper implements the method of moment and physical optics hybrid method in calculating scattered field from complex multi-scale scatterers. The numerical steepest descent path (NSDP) method is introduced to calculate high oscillatory PO integrals. As for acceleration, we introduce GPU's rendering and zbuffer shadowing to accelerate the lit judgement and the MPI structure to fast calculation. A vessel with the sea surface is chosen to validate the result.
引用
收藏
页数:2
相关论文
共 50 条
  • [21] Pragmatic multi-scale and multi-physics analysis of Charles Bridge in Prague
    Zeman, Jan
    Novak, Jan
    Sejnoha, Michal
    Sejnoha, Jiri
    [J]. ENGINEERING STRUCTURES, 2008, 30 (11) : 3365 - 3376
  • [22] Multi-physics and multi-scale methods used in nuclear reactor analysis
    Mylonakis, A. G.
    Varvayanni, M.
    Catsaros, N.
    Savva, P.
    Grigoriadis, D. G. E.
    [J]. ANNALS OF NUCLEAR ENERGY, 2014, 72 : 104 - 119
  • [23] Advanced computations of multi-physics, multi-scale effects in beam dynamics
    Amundson, J. F.
    Macridin, A.
    Spentzouris, P.
    Stern, E. G.
    [J]. SCIDAC 2009: SCIENTIFIC DISCOVERY THROUGH ADVANCED COMPUTING, 2009, 180
  • [24] Multi-Scale, Multi-Physics NEGF Quantum Transport for Nitride LEDs
    Geng, Junzhe
    Sarangapani, Prasad
    Nelson, Erik
    Wordelman, Carl
    Browne, Ben
    Kubis, Tillmann
    Klimeck, Gerhard
    [J]. 2016 INTERNATIONAL CONFERENCE ON NUMERICAL SIMULATION OF OPTOELECTRONIC DEVICES (NUSOD), 2016, : 107 - 108
  • [25] A multi-scale multi-physics modeling framework of laser powder bed fusion additive manufacturing process
    [J]. Zhang, Jing (jz29@iupui.edu), 2018, Elsevier Ltd (73)
  • [26] A review of multi-scale and multi-physics simulations of metal additive manufacturing processes with focus on modeling strategies
    Bayat, Mohamad
    Dong, Wen
    Thorborg, Jesper
    To, Albert C.
    Hattel, Jesper H.
    [J]. ADDITIVE MANUFACTURING, 2021, 47
  • [27] OpenCMISS: A multi-physics & multi-scale computational infrastructure for the VPH/Physiome project
    Bradley, Chris
    Bowery, Andy
    Britten, Randall
    Budelmann, Vincent
    Camara, Oscar
    Christie, Richard
    Cookson, Andrew
    Frangi, Alejandro F.
    Gamage, Thiranja Babarenda
    Heidlauf, Thomas
    Krittian, Sebastian
    Ladd, David
    Little, Caton
    Mithraratne, Kumar
    Nash, Martyn
    Nickerson, David
    Nielsen, Poul
    Nordbo, Oyvind
    Omholt, Stig
    Pashaei, Ali
    Paterson, David
    Rajagopal, Vijayaraghavan
    Reeve, Adam
    Roehrle, Oliver
    Safaei, Soroush
    Sebastian, Rafael
    Steghoefer, Martin
    Wu, Tim
    Yu, Ting
    Zhang, Heye
    Hunter, Peter
    [J]. PROGRESS IN BIOPHYSICS & MOLECULAR BIOLOGY, 2011, 107 (01): : 32 - 47
  • [28] Multi-scale and multi-physics: towards next-generation engineering materials
    Barchiesi, Emilio
    [J]. CONTINUUM MECHANICS AND THERMODYNAMICS, 2020, 32 (03) : 541 - 554
  • [29] Multi-Scale, Multi-Physics Analysis for Device, Chip, Package, and Board Level
    Chew, Weng C.
    [J]. 2012 IEEE/ACM INTERNATIONAL CONFERENCE ON COMPUTER-AIDED DESIGN (ICCAD), 2012, : 497 - 497
  • [30] Multi-scale and multi-physics: towards next-generation engineering materials
    Emilio Barchiesi
    [J]. Continuum Mechanics and Thermodynamics, 2020, 32 : 541 - 554
12345