Preface to the First Edition |
Preface to the Second Edition |
Interpretation of Flow Visualization / 1: |
Introduction / 1.1: |
Critical Points in Flow Patterns / 1.2: |
Relationship between Streamlines, Pathlines, and Streaklines / 1.3: |
Sectional Streamlines / 1.4: |
Bifurcation Lines / 1.5: |
Interpretation of Unsteady Flow Patterns with the Aid of Streaklines and Streamlines / 1.6: |
Concluding Remarks / 1.7: |
References / 1.8: |
Hydrogen Bubble Visualization / 2: |
The Hydrogen Bubble Generation System / 2.1: |
Safety / 2.2.1: |
Bubble Probes / 2.3: |
Lighting / 2.4: |
Unique Applications / 2.5: |
Dye and Smoke Visualization / 2.6: |
Flow Visualization in Water / 3.1: |
Conventional dye / 3.2.1: |
Laundry brightener / 3.2.2: |
Milk / 3.2.3: |
Fluorescent dye / 3.2.4: |
Methods of dye injection / 3.2.5: |
Rheoscopic fluid / 3.2.6: |
Electrolytic precipitation / 3.2.7: |
Flow Visualization in Air / 3.3: |
Smoke tunnel / 3.3.1: |
Smoke generator / 3.3.2: |
Smoke-wire technique / 3.3.3: |
Titanium tetrachloride / 3.3.4: |
Photographic Equipment and Techniques / 3.4: |
Camera / 3.4.1: |
Lens / 3.4.3: |
Film / 3.4.4: |
Cautionary Notes / 3.5: |
Molecular Tagging Velocimetry And thermometry / 3.6: |
Properties of Photo-Sensitive Tracers / 4.1: |
Photochromic dyes / 4.2.1: |
Phosphorescent supramolecules / 4.2.2: |
Caged dyes / 4.2.3: |
Examples of Molecular Tagging Measurements / 4.3: |
Caged dye tracers / 4.3.1: |
Image Processing and Experimental Accuracy / 4.4: |
Line processing techniques / 4.4.1: |
Grid processing techniques / 4.4.2: |
Ray tracing / 4.4.3: |
Molecular tagging thermometry / 4.4.4: |
Planar Imaging of Gas Phase Flows / 4.5: |
Planar Laser-Induced Fluorescence / 5.1: |
Velocity tracking by laser-induced fluorescence / 5.2.1: |
Rayleigh Imaging from Molecules and Particles / 5.3: |
Filtered Rayleigh Scattering / 5.4: |
Planar Doppler Velocimetry / 5.5: |
Summary / 5.6: |
Digital Particle Image Velocimetry / 5.7: |
Quantitative Flow Visualization / 6.1: |
DPIV Experimental Setup / 6.2: |
Particle Image Velocimetry: A Visual Presentation / 6.3: |
Image Correlation / 6.4: |
Peak finding / 6.4.1: |
Computational implementation in frequency space / 6.4.2: |
Video Imaging / 6.5: |
Post Processing / 6.6: |
Outlier removal / 6.6.1: |
Differentiable flow properties / 6.6.2: |
Integrable flow properties / 6.6.3: |
Sources of Error / 6.7: |
Uncertainty due to particle image density / 6.7.1: |
Uncertainty due to velocity gradients within the interrogation windows / 6.7.2: |
Uncertainty due to different particle size imaging / 6.7.3: |
Effects of using different sizes of interrogation windows / 6.7.4: |
Mean-bias error removal / 6.7.5: |
DPIV Applications / 6.8: |
Investigation of vortex ring formation / 6.8.1: |
A novel application for force prediction DPIV / 6.8.2: |
DPIV and a CFD counterpart: Common ground / 6.8.3: |
Conclusion / 6.9: |
Surface Temperature Sensing With Thermochromic Liquid Crystals / 6.10: |
Properties of liquid crystals / 7.1: |
Temperature calibration techniques / 7.1.2: |
Convective heat transfer coefficient measurement techniques / 7.1.3: |
Implementation / 7.2: |
Sensing sheet preparation / 7.2.1: |
Test surface illumination / 7.2.2: |
Image capture and reduction / 7.2.3: |
Calibration and measurement uncertainty / 7.2.4: |
Examples / 7.3: |
Turbine cascade / 7.3.1: |
Turbulent spot and boundary layer / 7.3.2: |
Turbulent juncture flow / 7.3.3: |
Particle image thermography / 7.3.4: |
Pressure and Shear Sensitive Coatings / 7.4: |
Pressure-Sensitive Paint / 8.1: |
Obtaining and applying pressure-sensitive paint / 8.2.1: |
Lamps / 8.2.2: |
Cameras / 8.2.3: |
Data reduction / 8.2.4: |
Shear-Sensitive Liquid Crystal Coating Method / 8.3: |
Color-change responses to shear / 8.3.1: |
Coating application / 8.3.2: |
Lighting and imaging / 8.3.3: |
Data acquisition and analysis / 8.3.4: |
Example: Visualization of transition and separation / 8.3.5: |
Example: Application of shear vector method / 8.3.6: |
Fringe Imaging Skin Friction Interferometry / 8.4: |
Physical principles / 8.4.1: |
Surface preparation / 8.4.2: |
Imaging / 8.4.3: |
Calibration / 8.4.5: |
Uncertainty / 8.4.6: |
Methods for Compressible Flows / 8.4.8: |
Basic Optical Concepts / 9.1: |
Index of Refraction for a Gas / 9.3: |
Light Ray Deflection and Retardation in a Refractive Field / 9.4: |
Shadowgraph / 9.5: |
Schlieren Method / 9.6: |
Interferometry / 9.7: |
Interference / 9.8: |
Mach-Zehnder Interferometer / 9.9: |
Holography / 9.10: |
Holographic Interferometry / 9.11: |
Applications / 9.12: |
Three-Dimensional Imaging / 9.13: |
Three-Dimensional Imaging Techniques / 10.1: |
Image Data Types / 10.3: |
Laser Scanner Designs / 10.4: |
Discrete Laser Sheet Systems / 10.5: |
Double Scan Laser Sweep Systems / 10.6: |
Single Scan Laser Sweep Systems (Discrete) / 10.7: |
Drum Scanners / 10.8: |
Multiple Fixed Laser Sheets / 10.9: |
Moving Laser Sheet Systems / 10.10: |
Imaging Issues and Trade-Offs / 10.11: |
Position accuracy of laser sheets / 10.11.1: |
Illumination issues / 10.11.2: |
Sweeps versus sheets for CW lasers / 10.11.3: |
Optical components / 10.11.4: |
Methods of control / 10.11.5: |
Operational considerations / 10.11.6: |
Imaging devices / 10.11.7: |
Detailed Example / 10.12: |
Control system design / 10.12.1: |
Analysis and Display of Data / 10.13: |
Processing and analysis of data / 10.13.1: |
Methods of presentation and display / 10.13.2: |
Concluding remarks / 10.14: |
Quantitative Flow Visualization Via Fully Resolved Four-Dimensional Imaging / 10.15: |
Technical Considerations / 11.1: |
Laser induced fluorescence / 11.2.1: |
Beam scanning electronics / 11.2.2: |
Data acquisition system / 11.2.3: |
Signal levels / 11.2.4: |
Signal-to-noise ratio / 11.2.5: |
Spatial and temporal resolution / 11.2.6: |
Data processing / 11.2.7: |
Sample Applications / 11.3: |
Fine structure of turbulent scalar fields / 11.3.1: |
Assessment of Taylor's hypothesis / 11.3.2: |
Scalar imaging velocimetry / 11.3.3: |
Fractal scaling of turbulent scalar fields / 11.3.4: |
Further Information / 11.4: |
Visualization, Feature Extraction, and Quantification of Numerical Visualizations of High-Gradient Compressible Flows / 11.5: |
Fundamental configuration / 12.1: |
Visualization Techniques / 12.2: |
Numerical analog of experimental techniques / 12.2.1: |
Smoothing and noise suppression / 12.2.2: |
Selection of variables for visualization / 12.2.3: |
Quantification of Shocks and Contacts / 12.3: |
One-dimensional example / 12.3.1: |
Algorithm / 12.3.2: |
Two-dimensional example / 12.3.3: |
Contact tracking and convergence of simulations / 12.3.4: |
Quantification of local shock properties / 12.3.5: |
Appendix A: Pseudo-code to Extract the Discontinuity Curves / 12.4: |
Color Plates and Flow Gallery / 12.6: |
Index |
Preface to the First Edition |
Preface to the Second Edition |
Interpretation of Flow Visualization / 1: |
Introduction / 1.1: |
Critical Points in Flow Patterns / 1.2: |
Relationship between Streamlines, Pathlines, and Streaklines / 1.3: |