Flow Visualization - TU Wien...St d tiSteady vs time-ddtfldependent flow Direct vs. indirect flow...
Transcript of Flow Visualization - TU Wien...St d tiSteady vs time-ddtfldependent flow Direct vs. indirect flow...
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Flow Visualization
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Overview: Flow Visualization (1)
Introduction, overviewFl d tFlow dataSimulation vs. measurement vs. modellingg2D vs. surfaces vs. 3DSt d ti d d t flSteady vs time-dependent flowDirect vs. indirect flow visualization
Experimental flow visualizationB i ibilitiBasic possibilitiesPIV (Particle Image Velocimetry) + Example
Eduard Gröller, Helwig Hauser 2
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Overview: Flow Visualization (2)Visualization of modelsFlow visualization with arrowsNumerical integration
Euler-integrationEuler integrationRunge-Kutta-integration
StreamlinesStreamlinesIn 2DParticle pathsParticle pathsIn 3D, sweepsIlluminated streamlinesIlluminated streamlines
Streamline placement
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Overview: Flow Visualization (3)
Flow visualization with integral objectsSt ibbStreamribbons, Streamsurfaces, stream arrows
Line integral convolutionAl ithAlgorithmExamples, alternatives
Glyphs & icons, flow topology
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Flow Visualization
Introduction:FlowVis = visualization of flowsFlowVis = visualization of flows
Visualization of change informationT i ll th 3 d t di iTypically: more than 3 data dimensionsGeneral overview: even more difficult
Flow data:nDnD data, 1D2 /2D2/nD2 (models), 2D2/3D2
(simulations, measurements)Vector data (nD) in nD data space
User goals:Overview vs details (with context)
Eduard Gröller, Helwig Hauser 5
Overview vs. details (with context)
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Flow Data
Where do the data come from:Flow simulation:Flow simulation:
Airplane- / ship- / car-designW th i l ti ( i fl )Weather simulation (air-, sea-flows)Medicine (blood flows, etc.)
Flow measurements:Wind tunnel, fluid tunnelSchlieren-, shadow-technique
Flow models:Flow models:Differential equation systems (ODE)(dynamical systems)
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(dynamical systems)
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Data Source – Examples 1/2
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Data Source – Examples 2/2
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Comparison with Reality
Experiment
SimulationEduard Gröller, Helwig Hauser 9
Simulation
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2D vs. Surfaces vs. 3D
2D-Flow visualization2D 2D Fl2D2D-FlowsModels, slice flows (2D out of 3D)( )
Visualization of surface flows3D fl d “ b t l ”3D-flows around “obstacles”Boundary flows on surfaces (2D)y ( )
3D-Flow visualization3D3D-flowsSimulations, 3D-models
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Simulations, 3D models
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2D/Surfaces/3D – Examples
3D
S fSurface
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Steady vs. Time-Dependent Flows
Steady (time-independent) flows:Fl t ti tiFlow static over timev(x): RnRn, e.g., laminar flows( ) , g ,Simpler interrelationship
Ti d d t ( t d ) flTime-dependent (unsteady) flows:Flow itself changes over timegv(x,t): RnR1Rn, e.g., turbulent flowsM l i t l ti hiMore complex interrelationship
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Time-Dependent vs. Steady Flow
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Direct vs. Indirect Flow Visualization
Direct flow visualization:O i t fl t tOverview on current flow state Visualization of vectorsArrow plots, smearing techniques
I di t fl i li tiIndirect flow visualization:Usage of intermediate representation:g pvector-field integration over timeVisualization of temporal evolutionVisualization of temporal evolutionStreamlines, streamsurfaces
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Direct vs. Indirect Flow Vis. – Example
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ExperimentalExperimental Flow VisualizationFlow VisualizationOptical Methods, etc.
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With Smoke rsp. Color Injection
Injectionof colorof color,smoke, particlesOpticalOpticalmethods:
SSchlieren, shadows
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Example: Car-Design
Ferrari-model,so called fiveso-called five-hole probe (no back flows)
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PIV: Particle Image Velocimetry
Laser + correlation analysis:R l fl i i d t lReal flow, e.g., in wind tunnelInjection of particles (as uniform as possible)j p ( p )At interesting locations:2 times fast illumination with laser slice2-times fast illumination with laser-sliceImage capture (high-speed camera), then correlation analysis of particlesVector calculation / reconstructionVector calculation / reconstruction,typically only 2D-vectors
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PIV - Measurements
Setup and typical result:
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Example: Wing-Tip Vortex
Problem: Air behind airplanes is turbulent
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fVisualization of Models
Dynamical Systems
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Dynamical Systems VisualizationDifferences:
Flow analytically def.:Flow analytically def.:dx/dt = v(x)Navier-Stokes equationsNavier Stokes equationsE.G.: Lorenz-system:dx/dt = (y-x)(y )dy/dt = rx-y-xzdz/dt = xy-bzLarger variety in data:
2D, 3D, nDSometimes no natural constraints like non-compressibility or similar
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Visualization of Models
Sketchy, “hand drawn”hand drawn
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Visualization of 3D Models
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Flow VisualizationFlow Visualization with Arrowswith Arrows
Hedgehog plots etcHedgehog plots, etc.
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Flow Visualization with Arrows
Aspects:Di t Fl Vi li tiDirect Flow VisualizationNormalized arrows vs. scaling with velocity2D: quite usable2D: quite usable,3D: often problematicSometimes limitedexpressivity (temporal p y ( pcomponent missing)Often used!
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Often used!
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Arrows in 2D
Scaled arrows vs. color-coded arrows
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Arrows in 3D
Following problems:AmbiguityAmbiguityPerspective Sh t iShortening1D-objects in 3D:difficult spatial perceptionVisual clutter
Improvement:Improvement:3D-arrows (help to a certain extent)
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Arrows in 3D
Compromise:Arrows only in slicesArrows only in slices
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Arrows in 3D
Well integrable within “real” 3D:
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Integration of Streamlines
Numerical Integration
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Streamlines – Theory
Correlations:fl d t d i ti i f tiflow data v: derivative informationdx/dt = v(x); spatial points xRn, time tR, flow vectors vRn
streamline s: integration over time,g ,also called trajectory, solution, curves(t) = s0 + 0ut v(s(u)) du;s(t) s0 0ut v(s(u)) du;seed point s0, integration variable udifficulty: result s also in the integral analyticaldifficulty: result s also in the integral analytical solution usually impossible!
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Streamlines – Practice
Basic approach:th (t) + ( ( )) dtheory: s(t) = s0 + 0ut v(s(u)) dupractice: numerical integrationidea: (very) locally, the solution is (approx.) linear( y) y, ( pp )
Euler integration: follow the current flow vector v(si) from the currentfollow the current flow vector v(si) from the current streamline point si for a very small time (dt) and therefore distanceEuler integration: si+1 = si + dt · v(si),integration of small steps (dt very small)
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integration of small steps (dt very small)
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Euler Integration – Example
2D model data: vx = dx/dt = yvy = dy/dt = x/2y y
Sample arrows:2
True 0
1
Truesolution:ellipses!
0 1 2 3 4
0
p
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Euler Integration – Example
Seed point s0 = (0 | -1 )T;current flow vector v(s0) = (1 |0)T;( 0) ( | ) ;dt = 1/2
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Euler Integration – Example
New point s1 = s0 + v(s0) ·dt = (1/2 | -1)T;current flow vector v(s1) = (1 |1/4)T;( 1) ( | ) ;
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Euler Integration – Example
New point s2 = s1 + v(s1) ·dt = (1 | -7/8)T;current flow vector v(s2) = (7/8 |1/2)T;( 2) ( | ) ;
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Euler Integration – Example
s3 = (23/16| -5/8)T (1.44| -0.63)T;v(s3) = (5/8 |23/32)T (0.63 |0.72)T;( 3) ( | ) ( | ) ;
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Euler Integration – Example
s4 = (7/4 | -17/64)T (1.75| -0.27)T;v(s4) = (17/64|7/8)T (0.27 |0.88)T;( 4) ( | ) ( | ) ;
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Euler Integration – Example
s9 (0.20|1.69)T;v(s9) ( -1.69 |0.10)T;( 9) ( | ) ;
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Euler Integration – Example
s14 ( -3.22 | -0.10)T;v(s14) (0.10 | -1.61)T;( 14) ( | ) ;
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Euler Integration – Example
s19 (0.75| -3.02)T; v(s19) (3.02|0.37)T;clearly: large integration error dt too large!clearly: large integration error, dt too large!19 steps
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Euler Integration – Example
dt smaller (1/4): more steps, more exact! s36 (0.04| -1.74)T; v(s36) (1.74|0.02)T;36 ( | ) ; ( 36) ( | ) ;36 steps
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Comparison Euler, Step Sizes
Euler is gettingis gettingbetter propor-propor-tionally to dtto dt
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Euler Example – Error Table
dt #steps error
1/2 19 ~200%1/4 36 ~75%
1/10 89 25%1/10 89 ~25%1/100 889 ~2%
1/1000 8889 ~0.2%
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Better than Euler Integr.: RK
Runge-Kutta Approach:theory: s(t) = s + v(s(u)) dutheory: s(t) = s0 + 0ut v(s(u)) duEuler: si = s0 + 0u<i v(su) dtRunge-Kutta integration:
idea: cut short the curve arcidea: cut short the curve arcRK-2 (second order RK):1.: do half a Euler step1.: do half a Euler step2.: evaluate flow vector there3.: use it in the originRK-2 (two evaluations of v per step):si+1 = si + v(si+v(si)·dt /2) ·dt
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RK-2 Integration – One Step
Seed point s0 = (0 | -2 )T;current flow vector v(s0) = (2 |0)T;( 0) ( | ) ;preview vector v(s0+v(s0)·dt /2) = (2|0.5)T; dt = 1
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0 1 2 3 4
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RK-2 – One more step
Seed point s1 = (2 | -1.5)T;current flow vector v(s1) = (1.5 |1)T;( 1) ( | ) ;preview vector v(s1+v(s1)·dt /2) (1|1.4)T; dt = 1
2
0
1
0 1 2 3 4
0
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RK-2 – A Quick Round
RK-2: even with dt=1 (9 steps) betterbetter than Euler with dt=1/8with dt 1/8(72 steps)
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Integration, Conclusions
Summary:analytic determination of streamlinesanalytic determination of streamlines usually not possibleh i l i t tihence: numerical integrationseveral methods available(Euler, Runge-Kutta, etc.)Euler: simple, imprecise, esp. with small dtu e s p e, p ec se, esp s a dRK: more accurate in higher ordersf rthermore adapti e methods implicit methodsfurthermore: adaptive methods, implicit methods, etc.
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Flow Visualizationwith Streamlines
StreamlinesStreamlines, Particle Paths, etc.
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Streamlines in 2D
Adequatefor overviewfor overview
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Visualization with Particles
Particle paths =streamlinesstreamlines(steady flows)
Variants (time-dependent data):dependent data):
streak lines:steadily newsteadily newparticlespath lines:path lines:long-term pathof one particleof one particle
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Streamlines in 3D
Color coding:gSpeedSelectiveSelectivePlacement
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3D Streamlines with Sweeps
Sweeps: better spatial 3Dbetter spatial 3D perception
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Illuminated Streamlines
Illuminated 3D curves 3D curves better 3Dperception!perception!
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SStreamline Placement
in 2D
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Problem: Choice of Seed Points
Streamline placement:If regular grid used: very irregular resultIf regular grid used: very irregular result
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Overview of Algorithm
Idea: streamlines should not get too close to each othereach otherApproach:
choose a seed point with distance dsep from an already existing streamliney gforward- and backward-integration until distance dtest is reached (or …).test ( )
two parameters:d start distancedsep … start distancedtest … minimum distance
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Algorithm – Pseudocode
Compute initial streamline, put it into a queueInitial streamline becomes current streamlineInitial streamline becomes current streamlineWHILE not finished DO:
TRY: get new seed point which is dsep away fromcurrent streamline
fIF successful THEN compute new streamline and put to queue
ELSE IF no more streamline in queueELSE IF no more streamline in queue THEN exit loopELSE next streamline in queue becomesq
current streamline
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Streamline Termination
When to stop streamline integration:when dist to neighboring streamline ≤ dwhen dist. to neighboring streamline ≤ dtest
when streamline leaves flow domainwhen streamline runs into fixed point (v=0)when streamline gets too near to itselfwhen streamline gets too near to itselfafter a certain amount of maximal steps
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New Streamlines
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Different Streamline Densities
Variations of dsep in rel. to image width:
6% 3% 1.5%
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dsep vs. dtest
dtest = 0.9 · dsep dtest = 0.5 · dsep
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Tapering and Glyphs
Thickness in rel. to distto dist.
DirectionalDirectionalglyphs:
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Flow Visualizationith I t l Obj twith Integral Objects
Streamribbons, Streamsurfaces,
etc.
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Integral Objects in 3D 1/3
Streamribbons
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Integral Objects in 3D 2/3
Streamsurfaces
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Stream Arrows
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Integral Objects in 3D 3/3
Flow volumes …
vs. streamtubes(similar to streamribbon)
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Relation to Seed Objects
IntegralObj. Dim. SeedObj. Dim.______________________________________________________________________________________________________
Streamline,… 1D Point 0DStreamribbon 1D++ Point+pt. 0D+0DSt t b 1D++ Pt + t 0D+1DStreamtube 1D++ Pt.+cont. 0D+1D______________________________________________________________________________________________________
Streamsurface 2D Curve 1DStreamsurface 2D Curve 1D______________________________________________________________________________________________________
Flow volume 3D Patch 2D
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CLine Integral Convolution
Flow VisualizationFlow Visualization in 2D or on surfaces
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LIC – Introduction
Aspects:goal: general overview of flowgoal: general overview of flowApproach: usage of texturesIdea: flow visual correlationExample:Example:
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LIC – Approach
LIC idea:for every texel: let the texture valuefor every texel: let the texture value…
… correlate with neighboring texture values along the flow (in flow direction)along the flow (in flow direction)… not correlate with neighboring texture values across the flow (normal to flow dir )across the flow (normal to flow dir.)
result: l t li th t t lalong streamlines the texture values are
correlated visually coherent!approach: “smudge” white noise (no a priori correlations) along flow
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LIC – Steps
Calculation of a texture value: Flow Datatexture value:
look at streamline through point
Flow Data
Integratthrough pointfilter white noise l t li
Streamline (DDA)
g
along streamline (DDA)Convoluwith
White Noiseresults i
LIC Texel
results i
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LIC – Convolution with Noise
Calculation of LIC texture:input 1: flow data v(x): RnRninput 1: flow data v(x): RnRn, analytically or interpolatedi t 2 hit i ( ) Rn R1input 2: white noise n(x): RnR1, normally precomputed as texturet li ( ) th h R1 Rnstreamline sx(u) through x: R1Rn,
sx(u) = x + sgn(u) 0t|u| v(sx(sgn(u)t)) dti t 3 filt h(t) R1 R1 Ginput 3: filter h(t): R1R1, e.g., Gaussresult: texture value lic(x): RnR1,
( )
lic(x) = lic(sx(0)) = n(sx(u))·h(u) du
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More Explanation
So:LIC lic(x) is a convolution ofLIC – lic(x) – is a convolution of
white noise n (or …)and a smoothing filter h (e.g. a Gaussian)
The noise texture values are picked pup along streamlines sx through x
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LIC – Example in 2D
quite laminar flow
Helwig Hauser 79quite turbulent flow
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LIC – Examples on Surfaces
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Arrows vs. StrLines vs. Textures
Streamlines: selectiveA llArrows: well..
Textures: 2D-filling
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Alternatives to LICSimilar approaches:
spot noise
spot noise
t t d l tspot noisevector kernelline bundles / splats
textured splats
line bundles / splatstextured splatsparticle systemsparticle systemsflow volumest t d titexture advection
motionblurred
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particlesflow volume
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Flow Visualizationdependent on local props.
Visualization of v
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Glyphs resp. Icons
Local / topologicaltopologicalproperties
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Icons in 2D
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Icons & Glyphs in 3D
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Flow Topology
Topology:abstractabstractstructureof a flowof a flow
differentelements, e.g.:
checkpoints, defined through v(x)=0cycles, defined through sx(t+T)=sx(t)y , g x( ) x( )connecting structures (separatrices, etc.)
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Flow Topology in 3D
Topology on surfaces:surfaces:
fixedpointspointssepara-t itrices
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Flow Topology in 3D
Lorenz system:system:
1 saddle2 saddlefoci1 chaotic attractor
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Timesurfaces
Idea:start surface e g part of a planestart surface, e.g. part of a planemove whole surface along flow over timetime surface: surface at one point in time
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Literature, ReferencesB. Jobard & W. Lefer: “Creating Evenly-Spaced Streamlines of Arbitrary Density” in Proceedings of 8th Eurographics Workshop on Visualization in ScientificEurographics Workshop on Visualization in Scientific Computing, April 1997, pp. 45-55
B. Cabral & L. Leedom: “Imaging Vector Fields Using Line Integral Convolution” in Proceedings g g gof SIGGRAPH ‘93 = Computer Graphics 27, 1993, pp. 263-270
D. Stalling & H.-C. Hege: “Fast and Resolution g gIndependent Line Integral Convolution” in Proceedings of SIGGRAPH ‘95 = Computer Graphics 29 1995 pp 249 256Graphics 29, 1995, pp. 249-256
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AcknowledgementsFor material for this lecture unit
Hans-Georg PagendarmRoger CrawfisRoger CrawfisLloyd TreinishDavid KenwrightTerry HewittTerry HewittBruno JobardMalte ZöcklerGeorg FischelGeorg FischelHelwig HauserBruno JobardJeff HultquistJeff HultquistLukas Mroz, Rainer WegenkittlNelson Max, Will Schroeder et al.Brian Cabral & Leith LeedomBrian Cabral & Leith LeedomDavid KenwrightRüdiger WestermannJack van Wijk Freik Reinders Frits Post Alexandru Telea Ari SadarjoenJack van Wijk, Freik Reinders, Frits Post, Alexandru Telea, Ari Sadarjoen
Eduard Gröller, Helwig Hauser 92