Vector field visualization techniques are essential to help us understand the complex dynamics of flow fields. These can be found in a wide range of applications such as study of flows around an aircraft, the blood flow in our heart chambers, ocean circulation models, and severe weather predictions. The vector fields from these various applications can be visually depicted using a number of techniques such as particle traces and advecting textures. In this tutorial, we present several fundamental algorithms in flow visualization including particle integration, particle tracking in time-dependent flows, and seeding strategies. For flows near surfaces, a wide variety of synthetic texture-based algorithms have been developed to depict near-body flow features. The most common approach is based on the Line Integral Convolution (LIC) algorithm. There also exist extensions of LIC to support more flexible texture generations for 3D flow data. This tutorial reviews these algorithms. Tensor fields are found in several real-world applications and also require the aid of visualization to help users understand their data sets. Examples where one can find tensor fields include mechanics to see how material respond to external forces, civil engineering and geomechanics of roads and bridges, and the study of neural pathway via diffusion tensor imaging. This tutorial will provide an overview of the different tensor field visualization techniques, discuss basic tensor decompositions, and go into detail on glyph based methods, deformation based methods, and streamline based methods. Practical examples will be used when presenting the methods; and applications from some case studies will be used as part of the motivation

Kao, David

Shen, Han-Wei

NASA Technical Reports Server

2/16/10
Introduction to Vector
Field Visualization
David Kao	 Han-Wei Shen
NASA Advanced
	 Computer Science and
Supercomputing (NAS) Division	 Engineering Department
NASA Ames Research Center 	 The Ohio State University
A Tutorial for
IEEE Pacific Visualization Symposium 2010
(.+A es Feseaieh'Cen(er
Topics Today
n Vector Field Visualization (Kao)
– CFD/numerical flow visualization
– Particle tracking algorithms
– Instantaneous vs time-dependent
visualization
– Unsteady flow volumes
n Surface Flow Texture Visualization (Shen)
– Steady and time-dependent flow
textures
• LIC,UFLIC, LEA, IBFV, and IBFVS
– 2D and 3D seed placement algorithms
• Energy-based methods
• Evenly-spaced methods
• Topology-based methods
https://ntrs.nasa.gov/search.jsp?R=20100026479 2019-08-30T10:16:43+00:00Z
2/16/10
Introduction to Vector Field Visualization
David Kao
NASAAdvanced Supercomputing (NAS) Division
NASAAmes Research Center
L {^esesrch Cutler
Vector Field Visualization - Applications
Vector fields are found in many real-world applications:
• Study of flow around an aircraft
• Blood flow in our heart chambers
• Ocean circulation models
• Severe weather predictions
The vector fields from these various applications can be visually depicted using
a number of techniques such as particle traces and advecting textures
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Summer Condition	 Winter Condition
• Simulated airflow over across a mountainous portion of Northern California under two contrasting
meteorological conditions
• Visualization of cloud texture overlay with streamlines
• Streamline paths are computed based on the input wind field
• 4th-order Runge-Kutta integration scheme is used to advect the particles
• Animations depicting flow over this geographical location provide immediate assistance in decision support
and crisis management
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Vector Field Visualization - Problem
n A vector field V(p) is given for discrete points p where p lie in either a 2D or
3D grid
n 2D vector field visualization is straightforward
n 3D vector field visualization is challenging due to 3D perspective
n Time-dependent flow visualization has additional challenges
n A vector field V(p,t) is given for discrete points p and at many time steps
n Time-dependent flow visualization is also known as unsteady flow
visualization
Visualization Techniques
n Geometry-based methods
rendering primitives built from
particle trajectories
–1 D: streamlines, pathlines,
streaklines
– Line variations: tubes, ribbons
– 2D: stream surfaces
– 3D: flow volumes
4
n Texture-based methods
shading every pixels/voxels in
the visualization
– LIC
– Texture Splats
– Chameleon
n Topological-based methods
extracting features based on flo
topology
– Critical points
– Vortex cores
– Skin-friction lines
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Visualization Techniques -II
Visualization Techniques - III
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Computational Fluid Dynamics
A computational technology that
enables one to study the dynamics of
things that flow
• Runs on computer systems to model
fluid flows using mathematically
modeling, numerical methods, and
software tools for pre-processing and
post processing
The wind tunnel has been traditionally
used to simulate physical flows
• With the advent of more powerful
computers, CFD is now the preferred
means of flow simulation before final
experimental testing (if any)
A Space Shuttle orbiter model in NASA Ames
Research Center’s 40x80 ft wind tunnel.
NASA Ames Image Library (Photo:A. Melliar, 1975)
Typical Steps in a CFD Analysis: Pre-Processing
• Geometry processing (CAD surface geometry, surface domain
decomposition)
• Grid generation (surface grids, hole cutting, volume gri
• Flow solver input preparation (solver input files)
• Boundary conditions (per grid basis, at each grid face.
periodic, in-flow, out-flow, no-slip/viscous)
• Flow conditions (e.g., Mach number, Reynolds number, angle of
attack)
• Numerical methods (parameters for the Navier-Stokes Eqs)
6
A corner view of the 51,200 core SGI Altix ICE system
housed at the NASA Advanced Supercomputing facility.
Photo Credit: NASA Ames Research Center/Marco Libero
2/16/10
Typical Steps in a CFD Analysis: Flow Computation
• Selection of physics model
Ð inviscid/viscous/turbulence
Ð body dynamics
Ð no. of species
• Selection of numerical methods
parameters
Ð accuracy
Ð stability
Ð convergence
• Run the simulation
Typical Steps in a CFD Analysis: Post-Processing
• Convergence analysis 	 °,°3	 1FORCE'Yj
• Flow residual history plots
	 I -, - L 1 C
	
_LL
10 s^
• Turbulence residuals (if any) 	 N	 ^'^	 ^ ^,^{003
• Forces and moments computation ° A 1-1 Li	 1 wC ^,^, ] Ci I
• CoefÞcient plots
	
° '	
G 1 w °01
•
cas 71j_" ; r	 ' v^^0.	 _I
Flow visualization 	
°°°Tmes^390nero0^ fi
	
°01	 '
aa_17 l r-
^	 7me step^ ^NUmbT
As computation power continues to increase over the past decade, flow
simulations require less amount of time to run.
Nowadays, the pre-processing and post-processing stages consume most of
the analysis time.
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Common Methods in Experimental Flow
Visualization - Adding Foreign Material
• Streaklines: dye injected from a fixed position. By injecting the dye
for a period of time, a line of dye in the fluid is visible
• Timelines: a row of small particles (hydrogen bubbles) released at
right angles to flow. The motion of the particles shows the fluid
behavior
• Pathlines: small particles (magnesium powder in liquid; oil drops
in gas) are added to the fluid. Velocity is measured by
photographing the motion of the particles with a known exposure
time
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Experimental Flow Visualization
Smoke and laser lighting sheet 	 Oil flow visualization
(NASA Langley, FS-2001-04-64-LaRC)
	
(NASA Dryden, IS-97/08-DFRC-02)
NASA Photos (in Public Domain)
Numerical Flow Visualization
Though numerical flow visualization is not able to totally replicate the
results from experimental flow visualization, it has been widely accepted
as an effective mean to obtain accurate representation of the CFD flow
solutions.
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Numerical Flow Visualization – Basic Methods
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Streamlines
• Streamline: a line that is tangential to the instantaneous velocity
direction (velocity is a vector, and it has a magnitude and a
direction)
• Release a particle into the flow and perform numerical integration to
compute the path of the particle
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Pathlines
• A pathline shows the trajectory of a single particle released from a
fixed location (seed point)
• Experimental method: marking a fluid particle and taking a time
exposure photo of its motion will generate a pathline
• This is similar to what you see when you take a long-exposure
photograph of car lights on a freeway at night
Streaklines
• S treakline: a line joining the positions, at an instantin time, of all
particles that were previously released from a fixed location (seed
point)
• Continuously inject particles into the flow at each time step and
track the paths of the particles
• In a steady flow field, streamlines, pathlines, and streaklines are
identical. However, they can be very different in unsteady flows
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Timelines
• Timeline: a line connecting a row of particles that released
simultaneously
• Timelines are generated by injecting rows of particles at some fixed
time interval
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Stream/Path/Streak/Time Lines - Summary
• Streamline: a field line tangent to the velocity field at an instant in
time
• Pathline: shows the trajectory of a single weightless particle
released from a seed point
• Streakline: a line joining the positions, at an instant in time, of all
particles released from a seed point
• Timeline: a line connecting a row of particles that released
simultaneously
In a steady flow field, streamlines, pathlines, and streaklines are
identical
Particle Tracing
The path of a massless particle at position p at time t is determined by:
dp/dt = v( p(t) )
	 for steady flow
or
dp/dt = v( p(t), t )
	 for unsteady flow
The actual particle position at any given time can be determined by
integrating the above equation (assuming that p(0) is given):
t+t
p(t + t) = p(t) + f v(p(t),t)dt
t
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Numerical Integration Methods
• Euler's Method: (Not recommended due to inaccuracy)
pk+j = pk + v(pk) t	 p0 = seed point
• 2nd Order Runge-Kutta Method: (commonly used)
p
* = pk + v(pk) t
pk+j = pk + [v(pk) + v(p*) ] t/2
• Higher Order Methods: (4th order RK and others) (recommended)
a = 2t v(pk), b = 2 t v(pk+a/2), c = 2t v(pk+b/2)
d = 2t v(pk+c/2), pk+j = pk + (a+2b+2c+d)/6
A good comparison of several integration methods can be found in [Teitzel et al. '97]
Notes on Particle Integration
• The accuracy of particle tracing depends highly on the integration
method used.
• Flow solvers are often second-order accurate in time. Particle
integration methods should be at least third-order or higher.
• Though multi-stage integration methods such as 4th RK are
commonly used, they require velocity data to be interpolated
between the two consecutive time steps.
• [Darmofal & Haimes `96] recommended using a fourth-order
interpolant instead of linear interpolation:
u"+1/2 (x)= 5 u"+ 1 (x) + 15u"(x) _ 5 u" 1 (x) + 1 u"2 (x)
16	 16	 16	 16
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Basic Particle Tracing Algorithm
1. Specify the seed point p(0), t=0
2. Perform cell search to locate the cell that contains p(t)
3. Interpolate the velocity field to determine the velocity at p(t)
4. Advance the particle at p(t) using either RK4 or a higher-order
method
Note: cell search and velocity interpolation are needed for the
intermediate points p* during the integration
5. Repeat from Step 2 until the particle leaves the flow field
Computational VS Physical Space
• Particle Tracing in Computational Space
– Map the given curvilinear grid and the associated velocity field onto a
uniform grid by computing and then transforming Jacobian matrices
– Since a typical grid is large, transformation is performed on-the-fly
– Main advantage: cell search is eliminated
– Disadvantages: Particle traces may not be accurate because the
transforming Jacobian matrices are only approximations
• Particle Tracing in Physical Space
– More accurate because the interpolation and integration steps are
performed in Cartesian space
– Velocity field transformation is not necessary
– Cell search is more time consuming, especial in multi-block grids
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Cell Search Based on Tetrahedral Decomposition
• Decompose the current hexadhedral cell into five tetrahedra
• Odd or even configuration based on the sum of the node's indices (i,j,k)
• Coordinate and velocity interpolation are based on natural coordinates
• Have been shown to gain a speed up factor of up to six times faster!
Alternate between two configurations to ensure
continuity between cells 	 [Kenwright & Lane ‘96]
Cell Search Based on Tetrahedral Decomposition
• A point p is inside the tetrahedron if its natural coordinates satisfy
the following conditions:
0,	 0,
	
0,
Tetrahedron geometry in natural (non-dimensional) and
physical coordinate spaces
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Particle Tracing Issues
• Adaptive integration step size
– Variable integration step size, dt, is based on the local velocity vector
• Particle tracing in multi-block grids
– Overlapping multi-block grids are common in complex grid geometries
– Particle paths are likely to cross multiple grids (grid jumping is necessary)
• Particle tracking in moving grids
– Particle position is based on the current grid block and time step
– The Jacobian matrix needs to consider the grid velocity
x x x x
J =
 y
g y ,J yg yt
	(x,y,z) = Pti+1(,,)Pti( , , )
z z z z
0
	
0
	 0 t
,+ 1 - t,	
See [Lane ‘93] for more discussions
Particle Traces - A Comparison
• 2D oscillating airfoil
• Unsteady flow
• Moving grid
• 200 Time Steps
• Data set: Sungho Ko (`95)
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Instantaneous Flow Visualization
• Streamlines, vector plots, contours, and cutting planes
• Calculation is based on one time step of the flow
• Effective for depicting the flow at an instant in time
• Interactive visualization is possible
• Time-variable is not used in the calculation
Time-Dependent Flow Visualization
• Calculation is based on many time steps
• Time variable is used in the calculation
• Effective for depicting time-varying phenomena such as vortex
shedding, vortex breakdown, and shock waves
• Require large disk storage
• Interactive visualization is limited
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Animation
• Animation is an effective method to depict time-varying
phenomena in unsteady flows
• Sometimes, instantaneous visualization techniques are applied to
unsteady flow data one time step at a time, then the results are
animated
• Instantaneous and time-dependent flow visualization can reveal
very different information
• Time-dependent flow visualization should be used to complement
instantaneous visualization
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Some Extensions of 3D Particle Tracking
Stream surface [Hultquist‘92]
Stream ribbon and tube [Ueng, Sikorski and Ma ’96]
Stream ball and streak ball [Brill et al. ‘94]
Dash tube [Fuhrmann and Gršller ’98]
Time surface [Westermann, Johnson and Ertl ’01]
Smoke surface [von Funck et al. ‘08]
Integral surface [Garth et al. ‘08]
Streak surface [BŸrger et al. ’09] and [Krishnan et al. ‘09]
Flow volume [Max, Becker and Crawfis ‘93]
Unsteady flow volume [Becker, Lane, and Max ’95]
Flow Volume
• Advect multiple streamlines from a polygon
• Flow volume is the volume bounded by the 3D streamlines
• Sorting is avoided by assuming monochrome flow volume
• When an edge is too long, it is subdivided at midpoint
• The flow volume is decomposed into tetrahedron cells
[Max, Becker and Crawfis '93]
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Unsteady Flow Volume
• Advect multiple streaklines from a polygon
• Flow volume is the volume bounded by the 3D streaklines
• Flow volume evolves in time by moving “sideways” as the
streaklines shift with the time-varying flow
• All vertices in the flow volume need to be advected over time
• Unsteady flow volume changes more rapidly than steady flow
volume
Adaptive Subdivision
• Unlike steady flow volume, where only the last layer of particles (at
the flow font) are advected in pseudo time
• Unsteady flow volume requires the ENTIRE flow volume to be
reconstructed at each time step
• A new particle is inserted at the midpoint of a segment when a
segment becomes too long
• An existing particle is deleted when two adjacent segments become
too short
23
[Becker, Lane and Max ‘95]
2/16/10
Unsteady Flow Volume Over A Wing With
Oscillating Flap
Unsteady Flow Visualization/Large-Scale Data
Visualization
• Unsteady flow visualization often has the challenges associated
with large-scale data visualization due to the time-varying nature of
the data
• Some previous workshops/symposiums on large-scale data
visualization:
o Symposium on Visualizing Time Varying Data (ICASE/NASA
LaRC '95)
o Visualizing Large-scale Data, BOF (Visualization '97)
o Visualizing Large Datasets: Challenges and Opportunities
(SIGGRAPH '99)
o Time-Varying Data Visualization Workshop (Supercomputing '05)
o Ultra-Scale Visualization Workshop (SC '06 – SC '09)
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Large-scale Data Visualization Challenges
• “Time-varying datasets present difficult problems for both analysis
and visualization. For example, the data may be terabytes in size,
distributed across mass storage systems at several sites, with
time scales ranging from femtoseconds to eons.”
v David Banks et al., Symposium on Visualizing Time-Varying Data at
ICASE/NASA LaRC #95
• “The output from leading-edge scientific simulations is so
voluminous and complex that advanced visualization techniques
are necessary to interpret the calculated results. Even though
visualization technology has progressed significantly in recent
years, we are barely capable of exploiting terascale data to its full
extent, and petascale datasets are on the horizon.”
v Kwan-Liu Ma, Ultra-Scale Visualization at SC 07
Progress in Large-Scale Data Visualization
Though, there has been many good progresses made in:
• Flow visualization techniques
• Hardware-assisted/GPU-based visualization
• Out-of-core algorithms
• Parallel algorithms
• Multiresolution and data compression techniques
• High performance computing
• In situ visualization and data reduction
The size of the flow simulation continues to increase É
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Grid Systems of Past and Present
Mid 1990's: 5 - 10 grids, 5 -10 mi11ion vo1ume grid points
Today: 100+ grids, 100+ mi11ion vo1ume grid points
Courtesy of William Chan (NASA)
References
•B. Becker, D. Lane, and N. Max. Unsteady flow volumes, Visualization 1995.
• M. Brill, H. Hagen, H.-C. Rodrian, W. Djatschin, and S. Klimenko. Streamball techniques for flow
visualization, Visualization 1994.
• P. Buning. Numerical algorithms in CFD post-processing, In Computer Graphics and Flow
Visualization in CFD. VKI Lecture Series, 1989.
• K. Biirger, F. Ferstl, H. Theisel, and R. Westermann. Interactive streak surface visualization on
the GPU, IEEE TVCG, Vol. 15 (6), November/December 2009.
• D. Darmofal and R. Haimes. An analysis of 3-D Particle Path Integration Algorithms, Journal of
Computational Physics, Vol. 123, 1996.
•A. Fuhrmann and E. Gršller. Real-time techniques for 3D flow visualization, Visualization 1998.
•C. Garth, H. Krishnan, X. Tricoche, T. Bobach, and K. Joy. Generation of accurate integral
surfaces in time-depedent vector fields, IEEE TVCG, Vol. 14 (6), November/December 2008.
•J. Hultquist. Constructing stream surfaces in steady 3D vector fields, Visualization 1992.
•D. Kenwright and D. Lane. Interactive time-dependent particle tracing using tetrahedral
decomposition, IEEE TVCG, Vol 2 (2), June 1996.
• H. Krishnan, C. Garth, and K. Joy. Time and streak surface for flow visualization in large time-
varying data sets, IEEE TVCG, Vol. 15 (6), November/December 2009.
• D. Lane. ÒScientific Visualization of Large-Scale Unsteady Fluid Flows” in Focus on Scientific
Visualization, H. Hagen, H. Mueller, G. Nielson, eds., Springer, 1993.
• D. Lane. Visualizing time-varying phenomena in numerical simulations of unsteady flows,
AIAA-96-0048 ,1996.
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References
• N Max, B. Becker, R. Crawfis. Flow volumes for interactive vector field visualization,
Visualization 1993.
•W. Merzkirch. Flow Visualization. Academic Press, 2nd edition, 1987.
• F. Post and T. Walsum. “Fluid Flow Visualization” in Focus on Scientific Visualization, H. Hagen,
H. Mueller, G. Nielson, eds., Springer, 1993.
• C. Teitzel, R. Grosso, and T. Ertl. “Efficient and reliable integration methods for particle tracing in
unsteady flows on discrete meshes” in Visualization in Scientific Computing '97, Eurographics.
•S. Ueng, C. Sikorski, and K.-L. Ma. Efficient streamline, streamribbon, and streamtube
constructions on unstructured grids, IEEE TVCG, Vol. 2 (2), September/October 1996.
• M. van Dyke. An Album of Fluid Motion. The Parabolic Press, 1982.
•W. von Funck, T. Weinkauf, H. Theisel, and H.-P. Seidel. Smoke surfaces: an interactive flow
visualization technique inspired by real-world flow experiments, IEEE TVCG, Vol. 14 (6), 2008.
•T. Weinkauf, J. Sahner, H. Theisel, and H.-C. Hege. Cores of swirling particle motion in unsteady
flows, Visualization 2007.
• R. Westermann, C. Johnson, and T. Ertl. Topology-preserving smoothing of vector fields, IEEE
TVCG, Vol. 7 (3), 2001.
•A. Wiebel and G. Scheuermann. Eyelet particle tracing - steady visualization of unsteady flow,
Visualization 2005.
•A. Wiebel, X. Tricoche, H. Janicke, and G. Scheuermann. Generalized streak lines: analysis and
visualization of boundary induced vortices, IEEE TVCG, Vol. 13 (6), Nov/Dec 2007.
•W. Yang. Handbook of Flow Visualization, Hemisphere Publishing, 1989.
• U FAT – www.nas.nasa.gov/Software/UFAT
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