Full Index for Basic foilset 
| This presentation gives the application perspective on PDE's and their role in simulation compared to particle dynamics and Monte Carlo Methods |
| We derive Navier Stokes equations and discuss immense computational requirements needed in aerospace simulations |
| The importance of small viscosity and emergence of boundary layers is discussed |
| Approximations used in practical CFD such as Euler's equation and Reynold's averaging are presented |
)(focus style:
) Denote Foils where Image Critical
)(focus style:
) Denote Foils where HTML is sufficient
CPS 615 -- Computational Science in
Abstract of PDE and CFD Background Presentation
Field Simulations
Four Descriptions of Matter -- Quantum,Particle,Statistical, Continuum
Quantum Physics and Examples of Use of Computation
Particle Dynamics and Examples of Use of Computation
Particle Dynamics and Example of Astrophysics
Statistical Physics and Comparison of Monte Carlo and Particle Dynamics
Continuum Physics as an approximation to Particle Dynamics
Computational Fluid Dynamics (CFD) as an an Example of Continuum Physics
Detailed Discussion of CFD and Navier Stokes Equations
First Four Variables of CFD: Derivation of the Continuity Equation
Travelling Time Derivatives (D/ Dt) versus local time derivatives in continuity equation
Newton's Laws or the Momentum Equation in CFD
The Last (Energy) Equation of CFD: Features of the Full Navier Stokes Equation
Discretization of CFD in 2 or 3 Dimensions -- Regular Example
This is a typical non-uniform grid used to define an aircraft
NASA Estimates of Computational Needs 1994
NASA's Estimate of Computing Needs for Reynolds Averaged Approximation (1994)
Results for the LU Simulated CFD Application of NAS Benchmark for Cray YMP, iPSC860, CM2
Results for the SP Simulated CFD Application of NAS Benchmarks for Cray YMP, iPSC860 and CM2
Results for the BT Simulated CFD Application of NAS Benchmarks for Cray YMP, iPSC860 and CM2
Multidisciplinary Simulations: Structures, Propulsion,Controls, Acoustics
Base CFD Requirements for GigaFlops and Run-time Memory Megawords
Features of
Simple Model CFD-like Equation in Dimensionless Form
The Reynolds Number R and Discussion of Interesting R and Viscosity Regimes
Approximation levels for CFD
What is so Strange about Large Reynolds Number? The second derivative Anomaly
Laminar Flow Compared to Turbulent Flow Pictorially
Why are boundaries important in the discontinuous limit of zero viscosity ?
Approximations to Navier Stokes Equations used in practical CFD
Length scales and Averaging used in the Reynolds Averaged Equations or Reynolds Equation
Turbulence Modeling and the Nature of Reynolds Averaging in Continuum Physics
Euler's Equations Should Hold far from the Vehicle in Large Reynolds Number R Limit
Large R Region - Boundary Layer Analysis To Extrapolate from Euler Equation Regime to the Boundary
Importance of Boundary Layer in Computation of Drag
Approximations used in derivation of Thin-Layer and Parabolized Navier-Stokes Equations
High Viscosity Limit: Stokes Equation and its Steady and Unsteady Forms
Euler's Equation and its Solution by Potential Methods
The Burger's Equation: A One Dimensional Approximation to the Navier Stokes Equations which Neglects Pressure Gradients
General Issues in CFD
Relative Role of Computer Scientists and CFD(Aerospace Engineers) or PDE Domain Experts
Computational Issues in PDE Solution in CFD and Related Fields Full WebWisdom URL and this Foilset Search
This contains all WebWisdom links preceded by those referenced in this foilset