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创新班导师 罗海飙

罗海飙

性别:男

职称:助理研究员

职务:助理研究员

电子邮件:luohaibiao@gz.iscas.ac.cn

所在部门:并行软件研发中心

通讯地址:广州南沙区海滨路1121号广州中科院工业技术研究院A栋六楼

电话号码:无

邮政编码: 511458

研究方向/领域:并行算法、高性能计算及性能优化

教育经历

2002.09—2010.08    波士顿大学 机械工程系  博士

2000.01—2002.08    新奥尔良大学 应用数学  硕士

1993.09—1997.07    兰州大学 计算数学系      学士

 

工作经历

2011.09—至今          广州中国科学院软件应用技术研究所     并行软件研发中心      助理研究员

2011.02—2011.09    武汉新迪数字有限公司        MSC中国研发中心                        高级研究员 

  2006.01—2010.08    Physical Acoustics Lab,Boston University  科研助理  

  2002.09—2005.12    Aerospace & Mechanical Engineering Dept.,Boston University,  科研与教学助理

  2000.01—2002.05    Applied Mathematics Dept., University of New Orleans, 科研助理  

 

期刊及会议文章

  • Wei D, Luo H, Finite Element Analysis on Heat Transfer to Molten Polymer Flow in Pipe with Viscous Dissipation International Journal of Heat and Mass Transfer, Vol. 46, 2003, 3097-3108.
  • Luo H, Coldstein I, Udelson D, A Three-Dimensional Theoretical Model of the Relationship Between Cavernosal Expandability and Percent  Cavernosal Smooth Muscle. International Journal of Sexual Medicine, Vol 4, 2007, 644-655
  • Cleveland RO, Luo H, Willams, JC, Jr, Stress waves in human kidney stones: Shear dominates spall. Journal of Urology, Vol 177, 2007, 415-415
  • Luo H, Williams JC, Jr. Cleveland RO, 3D Numerical Simulations of Lithotripsy Shock Wave Propagation In Kidney Stone.. accepted by J. Acoust. Soc. Am. EL.
  • Luo H, Williams JC, Jr. Cleveland RO, Fracture Mechanisms of Kidney Stones Subject To Lithotripsy Shock Wave: a Numerical Study. In reviewed by J. Acoust. Soc. Am.
  • Luo H, Coldstein I, Udelson D, Relationship between Cavernosal Expandability and Percent Cavernosal Smooth Muscle: A Theoretical Model, 5th World Congress of Biomechanics, Munich, German, Aug, 2006
  • Luo, H. Cleveland RO. Williams JC. Jr. Numerical Simulations of Kidney Stones Subject To Lithotripsy Shock Waves. 2nd International Urolithiasis Research Symposium, April, 2008.
  • Luo. H. Cleveland RO. Williams JC. Jr. Lithotripters with Broad Focus of Shock Wave Breaks Kidney Stones More Efficiently: Numerical Simulations of Kidney Stone Comminution Subject To Lithotripsy Shock Wave. Frontiers in Biomedical Devices Conference, ASME, June, 2008.