https://mp.weixin.qq.com/s/LaCuxYCKTMQ6PM6OIkAQig ES讲堂 | Turbulence structure and modeling in the frequency domain
北京大学工学院 北大工学 昨天
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讲座题目:
Turbulence structure and modeling in the frequency domain
讲座时间:
November 12, 2021 Friday
10:00 am - 11:30 am Beijing Time
Zoom会议注册:
https://zoom.us/meeting/register/tJYtf-GhrzwvG9EHymeNhaldBaK3-0q7lswY
演讲人:
Tim Colonius
Frank and Ora Lee Marble Professor
机械与土木工程系、医学工程系
加州理工学院
主持人:
吕本帅,特聘研究员、博士生导师
北京大学工学院航空航天系
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Tim Colonius
Frank and Ora Lee Marble Professor
加州理工学院
演讲学者简介
Peking University ES Seminars
Tim Colonius is the Frank and Ora Lee Marble Professor of Mechanical Engineering at the California Institute of Technology. He received his B.S. from the University of Michigan in 1987 and M.S and Ph.D.in Mechanical Engineering from Stanford University in 1988 and 1994, respectively. He and his research team use numerical simulations to study a range of problems in fluid dynamics, including aeroacoustics, flow control, instabilities, shock waves, and bubble dynamics. Prof. Colonius also investigates medical applications of ultrasound, and is a member of the Medical Engineering faculty at Caltech. He is a Fellow of the American Physical Society and the Acoustical Society of America, and he is Editor-in-Chief of the journal Theoretical and Computational Fluid Dynamics. He was the recipient of the 2018 AIAA Aeroacoustics Award.
讲座摘要
Peking University ES Seminars
Amongst many available data-driven modal decompositions of utility in fluid mechanics, the frequency-domain (spectral) version of the proper orthogonal decomposition (SPOD) plays a special role in the analysis of stationary turbulence. SPOD modes are optimal in expressing structures that evolve coherently in both space and time, and they can be regarded as optimally-averaged DMD modes. Importantly, the SPOD spectrum is also related to the resolvent spectrum of the linearized dynamics and examination of the relationships between the SPOD and resolvent modes yields information about how coherent structures are forced by nonlinear interactions amongst coherent and incoherent turbulence. We discuss the application of these tools to analyze and model turbulence in high-speed jets and boundary layers. We highlight recent developments including (a) utilizing eddy-viscosity models in resolvent analysis to enable RANS-based prediction of coherent structures, and (b) nonlinear extensions of resolvent analysis to discover worst-case disturbances for laminar-turbulent transition, and (c) the development fast spatial marching methods for large-scale resolvent problems.
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