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Students are encouraged to attend the class. You may not be able to understand by just reading the lecture notes. Measurements in Fluid Mechanics 058:180:001 (ME:5180:0001) Time & Location: 2:30P - 3:20P MWF 218 MLH Office Hours: 4:00P – 5:00P MWF 223B-5 HL. Instructor: Lichuan Gui
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Students are encouraged to attend the class. You may not be able to understand by just reading the lecture notes. Measurements in Fluid Mechanics058:180:001 (ME:5180:0001)Time & Location: 2:30P - 3:20P MWF 218 MLHOffice Hours: 4:00P – 5:00P MWF 223B-5 HL Instructor: Lichuan Gui lichuan-gui@uiowa.edu http://lcgui.net
Individuale reading of X: Mean value 0 RMS fluctuation (random error) RMS error Evaluation Errors • Bias & random error for replicated measurement Measuring variable X for N times
3232-pixel window Peak-locking Effect • Example: PIV test in a thermal convection flow One of PIV recordings
Histogram of U & V Peak-locking Effect • Example: PIV test in a thermal convection flow One of vector maps
Correlation-based interrogation Correlation-based tracking MQD-tracking Peak-locking Peak-locking Effect • Example: PIV test in a thermal convection flow Histograms resulting from different algorithms Is the peak-locking an error? Why does the peak-locking exist? How to reduce the peak-locking effect?
Histogram for measuring 0.5 pixels Source of Peak-locking • Probability density function (PDF) Probability to get X when measuring Xo
Distribution density function of true value Xo in region [a,b]: Distribution density function of measured value X: Histogram of measured variable X: Source of Peak-locking • Distribution density function (DDF) - (Xo)/(b-a): probability to find true value Xo in region [a,b] - Physical truth to be investigated - (X)/(b-a): probability to get value X when measuring Xo in region [a,b] - Investigated phenomenon - Defined in region [-,+]: - Number of samples in [X-/2,X +/2] - M: average number in
Possible sources of peak-locking Source of Peak-locking • Distribution density function (DDF) • Histogram determined by • Sample number M • Sub region size • Physical truth (Xo) • Bias error (Xo) • Random error (Xo)
Bias & Random Error Distribution • Simulation of Gaussian particle images Test results with simulated PIV recording pairs - particle image diameter: 2 5 pixels - particle image brightness: 130 150 - particle image number density: 20 particles in 3232-pixel window - vector number used for statistics: 15,000 CDWS – Correlation-based discrete window shift (=DWS) CCWS – Correlation-based continuous window shift (=CWS) FCTR – FFT accelerated correlation-based tracking w/o single pixel random noise with single pixel random noise (CDWS=DWS, CCWS=CWS, FCTR=correlation-base tracking)
Peak-locking Factor • DDFs and histograms for the test results
Simulation of error distributions: Simulated error distributions Response of peak-locking factor Peak-locking Factor • Response of to bias and random error distribution very sensitive to bias error amplitude A sensitive to random error amplitude A when >0.02 not sensitive to constant portion of random error 0
Peak-locking Factor • Response of to bias and random error distribution Contours of peak-locking factor for o=0.025 Peaks locked at integer pixels in bright area and at midpixels in dark area Peak-locking minimum around A=0 Increasing A increaes for A<0 but reduces for A>0
Increasing A when A>0 for CCWS Peak-locking Factor • Influence of particle size on Test results increases with incresing particle size by CDWS descreses with incresing particle size by FCTR & CCWS increases when particle szie too small by FCTR & CDWS smallest when particle szie too small by CCWS generally smallest by FCTR (for Gaussian image profile)
Peak-locking Factor • Influence of particle number density on Test results not sensitive to particle image number density generally smallest by FCTR (for Gaussian image profile)
Peak-locking Factor • Influence of window size on Test results decreases with incresing window size by CDWS slightly increses with incresing window size by CCWS slightly decrease with incresing window size by FCTR generally smallest by FCTR (Gaussian image profile)
Image samples of different quality Non-Gaussian Particle Images • Influence of particle image profile
Gray value histogram & evaluation sample Histogram of particle image displacement Application Examples • PIV measurement in a thermal convection flow - Overexposed particle images - Particle image diameter 3 4 pixels - No peak-locking for CCWS
Gray value histogram & evaluation sample Histogram of particle image displacement Application Examples • PIV measurement in a wake vortex flow - Particle image diameter 1 pixels - Least peak-locking for CCWS
Gray value histogram & evaluation sample Histogram of particle image displacement Application Examples • PIV measurement in a micro channel flow - Particle image diameter 4 6 pixels - Mid-pixel peak-locking for CCWS
References • Guiand Wereley (2002) A correlation-based continues window shift technique for reducing the peak locking effect in digital PIV image evaluation. Exp Fluids 32: 506-517
Matlabprogram for showing peak-locking effect A1=imread('A001_1.bmp'); % input image file A2=imread('A001_2.bmp'); % input image file G1=img2xy(A1); % convert image to gray value distribution G2=img2xy(A2); % convert image to gray value distribution Mg=16; % interrogation grid width Ng=16; % interrogation grid height M=32; % interrogation window width N=32; % interrogation window height [nxny]=size(G1); row=ny/Mg-1; % grid row number col=nx/Mg-1; % grid column number sr=12; % search radius for i=1:col % correlation interrogation begin for j=1:row x=i*Mg; y=j*Ng; g1=sample(G1,M,N,x,y); g2=sample(G2,M,N,x,y); [C m n]=correlation(g1,g2); [cm vxvy]=peaksearch(C,m,n,sr,0,0); U(i,j)=vx; V(i,j)=vy; X(i,j)=x; Y(i,j)=y; end End % correlation interrogation end nn=0; % count number of displacements with 0.1 pixel steps for k=-120:120 nn=nn+1; D(nn)=double(k/10); Px(nn)=0; Py(nn)=0; for i=1:col for j=1:row if U(i,j)>= D(nn)-0.05 & U(i,j) < D(nn)+0.05 Px(nn)=Px(nn)+1; end if V(i,j)>= D(nn)-0.05 & V(i,j) < D(nn)+0.05 Py(nn)=Py(nn)+1; end end end end plot(D,Px,'r*-') % make plots hold on plot(D,Py,'b*-') hold off