- Parallel Computational Fluid Dynamics '92 R. Pelz, A. Ecer & J. Hauser, eds.
- ILASS Americas, 15th Annual Conference on Liquid Atomization and Spray Systems, Madison, WI, May 2002
- Partitioning Coarse grained parallelism requires computing on many machines, and communicating
- Modeling return to isotropy using kinetic equations Blair Perota
- The 9th International Symposium on Transport Phenomena and Dynamics of Rotating Machinery
- A Self-Adapting Turbulence Model for Hybrid RANS/LES
- APPLICATION OF THE TURBULENT POTENTIAL MODEL TO COMPLEX FLOWS
- Implementation of an Efficient Conjugate Gradient Algorithm for Poisson Solutions on Graphics Processors
- Prof. Perot Heat Transfer, MIE354
- A spectral element semi-Lagrangian (SESL) method for the spherical shallow water equations
- Laminar drag reduction in microchannels using ultrahydrophobic surfaces Jia Ou, Blair Perot, and Jonathan P. Rothstein
- MIE 607/ME 741-A Prof. Blair Perot
- Implementation of an Efficient Conjugate Gradient Algorithm for Poisson Solutions on Graphics Processors
- Shearfree turbulent boundary layers, Part II: New concepts for Reynolds stress transport
- Center for Turbulence Research Proceedings of the Summer Program 1996
- A note on turbulent energy dissipation in the viscous wall region Peter Bradshaw and J. Blair Perot
- A moving unstructured staggered mesh method for the simulation of incompressible free-surface flows
- Reformulation of the unstructured staggered mesh method as a classic
- MIE 707/ME 745-A Spring 2000
- An analysis of superhydrophobic turbulent drag reduction mechanisms using direct numerical simulation
- Editorial Manager(tm) for Journal of Computational Physics Manuscript Draft
- Connectivity Data Structures E2N: edge-to-node
- J. Fluid Mech. (2009), vol. 620, pp. 3141. c 2009 Cambridge University Press doi:10.1017/S0022112008004916 Printed in the United Kingdom
- A Self-adapting Turbulence Model for Flow Simulation at any Mesh Resolution.
- styleb.cls TFJI068-04-190650 August 17, 2006 14:21 Journal of Turbulence
- Higher-order mimetic methods for unstructured meshes V. Subramanian, J.B. Perot *
- Direct Interface Tracking of Droplet Deformation Meizhong Dai, Haoshu Wang, J. Blair Perot, and David P. Schmidt
- Modeling of the Internal Two-Phase Flow in a Gas-Centered Swirl Coaxial Fuel Injector
- Higher-Order Discrete Calculus 22nd Dundee
- On the Development of Discrete Calculus Methods V. Subramanian and J. B. Perot
- Exact Fractional Step Methods for Solving the Incompressible Navier-Stokes Equations
- Simulating Interfacial Tension of a Falling Drop in a Moving Mesh Framework
- EDDY COLLISION MODELS FOR TURBULENCE Blair Perot and Chris Chartrand
- (c)2000 American Institute of Aeronautics & Astronautics or published with permission of author(s) and/or author(s)' sponsoring organization. AIAA-2000-0134
- AIAA 2000-0914 Modeling Three-Dimensional Boundary
- ModelingSeparationandReattachmentUsingtheTurbulentPotentialModel Blair Perot & Hudong Wang
- The Development of a MovingThe Development of a Moving Staggered Mesh Method forStaggered Mesh Method for
- Prof. Perot Pricey Oil Could Be Boon for European Car
- Prof. Perot Nishita Nickey sent me this.
- Prof. Perot Control Mass Problems
- Structured (Cartesian, Stretched, Mapped, Block) Structured look: quads, hexahedra
- Mesh Adaptation Accurate solution of physics usually requires adaptation. The location of critical physics
- MIE 607/Ch.E 631 Prof. Blair Perot
- Compatible Spatial Discretizations for Partial
- Iterative Methods for Linear Systems
- This article appeared in a journal published by Elsevier. The attached copy is furnished to the author for internal non-commercial research
- Journal of Computational Physics 159, 5889 (2000) doi:10.1006/jcph.2000.6424, available online at http://www.idealibrary.com on
- An Exact Projection Method Blair Perot
- Prof. Blair Perot Computational Fluid Dynamics, MIE 604
- Solution of Incompressible Flow Problems on Moving
- Prof. Blair Perot Advanced Numerical Methods, MIE 603
- A self-adapting turbulence model for flow simulation at any mesh resolution
- JoT3(2002)001 JOURNAL OF TURBULENCEJOT
- Prof. Perot Thermodynamics, MIE 230
- Prof. Perot Multivariable Calculus A Very Quick Review
- Comments on the Fractional Step Method J. Blair Perot
- Prof. Perot Aerospace Fluid Dynamics, MIE 440
- A NEAR WALL MODEL FOR THE DISSIPATION TENSOR Blair Perot & Parviz Moin
- Shearfree turbulent boundary layers, Part I: Physical insights into near wall turbulence
- 1 Copyright 2002 by ASME Proceedings of ASME
- POTENTIAL TURBULENCE MODEL PREDICTIONS OF FLOW PAST A TRIANGULAR CYLINDER USING AN UNSTRUCTURED
- UNSTRUCTURED ADAPTIVE MOVING MESH SOLUTION OF UNSTEADY SHEAR FLOWS AND FREE-SURFACE FLOWS
- A model for the dissipation rate tensor in inhomogeneous and anisotropic turbulence
- Mechanical and Industrial Engineering Department Points of Pride Newsletter Fall 201 MESSAGE FROM DONALD FISHER
- TURBULENT TRANSPORT As a turbulent flow moves, it carries
- SPECTRAL DYNAMICS In Chapter 6, the energy spectrum, defined as the
- THE STATISTICAL DESCRIPTION OF TURBULENCE Up to now, we have considered only average values of fluctuating quantities,
- THE DYNAMICS OF TURBULENCE In Chapter 2, we studied the effects of the turbulent velocity fluctuations on
- INTRODUCTION Most flows occurring in nature and in engineering applications are turbulent.
- WALL-BOUNDED SHEAR FLOWS Boundary-layer flows are more complicated than flows in free shear layers
- BOUNDARY-FREE SHEAR FLOWS Turbulent shear flows that occur in nature and in engineering are usually
- 2TURBULENT TRANSPORT OF MOMENTUM AND HEAT Turbulence consists of random velocity fluctuations, so that it must be
- BIBLIOGRAPHY AND REFERENCES A comprehensive up-to-date bibliography may be found in Monin and
