Modern Aerodynamic Methods for Direct and Inverse Applications

Book description

Just when classic subject areas seem understood, the author, a Caltech, M.I.T. and Boeing trained aerodynamicist, raises profound questions over traditional formulations.  Can shear flows be rigorously modeled using simpler “potential-like” methods versus Euler equation approaches?  Why not solve aerodynamic inverse problems using rapid, direct or forward methods similar to those used to calculate pressures over specified airfoils?  Can transonic supercritical flows be solved rigorously without type-differencing methods?  How do oscillations affect transonic mean flows, which in turn influence oscillatory effects?  Or how do hydrodynamic disturbances stabilize or destabilize mean shear flows?  Is there an exact approach to calculating wave drag for modern supersonic aircraft?

This new book, by a prolific fluid-dynamicist and mathematician who has published more than twenty research monographs, represents not just another contribution to aerodynamics, but a book that raises serious questions about traditionally accepted approaches and formulations – and provides new methods that solve longstanding problems of importance to the industry.  While both conventional and newer ideas are discussed, the presentations are readable and geared to advanced undergraduates with exposure to elementary differential equations and introductory aerodynamics principles.  Readers are introduced to fundamental algorithms (with Fortran source code) for basic applications, such as subsonic lifting airfoils, transonic supercritical flows utilizing mixed differencing, models for inviscid shear flow aerodynamics, and so on – models they can extend to include newer effects developed in the second half of the book.  Many of the newer methods have appeared over the years in various journals and are now presented with deeper perspective and integration.

This book helps readers approach the literature more critically.  Rather than simply understanding an approach, for instance, the powerful “type differencing” behind transonic analysis, or the rationale behind “conservative” formulations, or the use of Euler equation methods for shear flow analysis when they are unnecessary, the author guides and motivates the user to ask why and why not and what if.  And often, more powerful methods can be developed using no more than simple mathematical manipulations.  For example, Cauchy-Riemann conditions, which are powerful tools in subsonic airfoil theory, can be readily extended to handle compressible flows with shocks, rotational flows, and even three-dimensional wing flowfields, in a variety of applications, to produce powerful formulations that address very difficult problems.  This breakthrough volume is certainly a “must have” on every engineer’s bookshelf. 

Table of contents

  1. Cover
  2. Title page
  3. Copyright page
  4. Preface
  5. Acknowledgements
  6. Chapter 1: Basic Concepts, Challenges and Methods
    1. 1.1 Governing Equations – An Unconventional Synopsis
    2. 1.2 Fundamental “Analysis” or “Forward Modeling” Ideas
    3. 1.3 Basic “Inverse” or “Indirect Modeling” Ideas
    4. 1.4 Literature Overview and Modeling Issues
    5. 1.5 References
  7. Chapter 2: Computational Methods: Subtleties, Approaches and Algorithms
    1. 2.1 Coding Suggestions and Baseline Solutions
    2. 2.2 Finite Difference Methods for Simple Planar Flows
    3. 2.3 Examples – Analysis, Direct or Forward Applications
    4. 2.4 Examples – Inverse or Indirect Applications
  8. Chapter 3: Advanced Physical Models and Mathematical Approaches
    1. 3.1 Nonlinear Formulation for Low-Frequency Transonic Flow
    2. 3.2 Effect of Frequency in Unsteady Transonic Flow
    3. 3.3 Harmonic Analysis of Unsteady Transonic Flow
    4. 3.4 Supersonic Wave Drag for Nonplanar Singularity Distributions
    5. 3.5 Supersonic Wave Drag for Planar Singularity Distributions
    6. 3.6 Pseudo-Transonic Equation with a Diffusion Term
    7. 3.7 Numerical Solution for Viscous Transonic Flow
    8. 3.8 Type-Independent Solutions for Mixed Subsonic and Supersonic Compressible Flow
    9. 3.9 Algorithm for Inviscid Compressible Flow Using the Viscous Transonic Equation
    10. 3.10 Inviscid Parallel Flow Stability with Nonlinear Mean Profile Distortion
    11. 3.11 Aerodynamic Stability of Inviscid Shear Flow Over Flexible Membranes
    12. 3.12 Goethert's Rule with an Improved Boundary Condition
    13. 3.13 Some Singular Aspects of Three-Dimensional Transonic Flow
  9. Chapter 4: General Analysis and Inverse Methods for Aerodynamic Modeling
    1. 4.1 On the Design of Thin Subsonic Airfoils
    2. 4.2 Airfoil Design in Subcritical and Supercritical Flows
    3. 4.3 Direct Approach to Aerodynamic Inverse Problems
    4. 4.4 Superpotential Solution for Jet Engine External Potential and Internal Rotational Flow Interaction
    5. 4.5 Thin Airfoil Theory for Planar Inviscid Shear Flow
    6. 4.6 Class of Shock-free Airfoils Producing the Same Surface Pressure
    7. 4.7 Engine Power Simulation for Transonic Flow-Through Nacelles
    8. 4.8 Inviscid Steady Flow Past Turbofan Mixer Nozzles
  10. Chapter 5: Engine and Airframe Integration Methods
    1. 5.1 Big Picture Revisited
    2. 5.2 Engine Component Analysis
    3. 5.3 Engine Power Simulation Using Actuator Disks
    4. 5.4 Mixers and Supersonic Nozzles
    5. 5.5 References
  11. Cumulative References
  12. Index
  13. About the Author
  14. End User License Agreement

Product information

  • Title: Modern Aerodynamic Methods for Direct and Inverse Applications
  • Author(s): Wilson C. Chin
  • Release date: April 2019
  • Publisher(s): Wiley-Scrivener
  • ISBN: 9781119580560