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SELF-CALIBRATING POLARIMETERS AND ADVANCED IMAGE-LIKE DATA RECONSTRUCTION/PROCESSING ALGORITHMS
J. Zallat, S. Faisan, M. Karnoukian, C. Heinrich, M. Torzynski, A. Lallement
slb
r F QI0
I
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Distributed measurements of polarization parameters
Access specific properties of objects and media.Application dependent.
Physical imaging modality
Measured quatities(radiances)
Physical quantitiesStokes - Mueller
Observation model
Experimental developments• Polarimeters• Calibration
– Authenticate acquisitions– Robustness
Theoretical developments• Model inversion• Polarization algebra• Signal/Image processing• Physical interpretation• Relevant display
Polarization imaging
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• Polarization imaging consists in an indirect distributed measurement of polarization properties of light. Observables that lead to desired physical quantities are “noisy”.
• A multi-component information is attached to each pixel of the image.
• Simple observation model that amplify noise when classical pseudo-inverse approach is used.
• Classical analysis methods are pixel-wise oriented.
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SNR = 20 dB: 54% des pixels sont non admissibles!
SNR = 10 dB: 57% des pixels sont non admissibles!
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True
Mue
ller Intensities
Naïv
e in
vers
ion
Better approach
Application: données synthétiques
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(I1) (I2)
(I3) (I4)
(s0) (s1)
(s2) (s3)
(Pseudo-inverse) (Notre approche)
Application: données réelles (1)
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2 3
1 0.03 0.01 0.000.05 0.00 0.00 0.000.02 0.00 0.00 0.00
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M M
Application: données réelles (2)
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DOP image: naïve approach
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DOP image: better approach
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1DOP images
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Spectral calibration of a polarimeter: RWP
Polarimetric Calibration
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Spectral calibration of a polarimeter: LCVR
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Spectral calibration of a polarimeter: LCVR
Classical LCVR - PSA
P L1 L2
New LCVR – PSADifferential PSA
P L1 L2HW
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Spectral calibration of a polarimeter: Without Polarizer
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Spectral calibration of a polarimeter: With Polarizer
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P L1 L2HW P’
Spectral calibration of a polarimeter: Stability
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• Very well conditioned polarimeter.• The PSA is very stable, no necessity to recalibrate over
a long period!• It is used now to construct a full field Mueller imaging
polarimeter dedicated to small animals tissues studies.
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Data reduction
For each pixel location (s), we have
For each class:
To account for non uniform illumination, a gaussian mixture density is used to model:
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Data reduction: synthetic data
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Data reduction: real data (intensities)
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Data reduction: real data
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M1 = [ 1.0000 0.0044 -0.0243 0.0488 -0.0166 0.3616 -0.0552 -0.1671 -0.0417 -0.0122 0.2991 -0.3169 -0.0077 0.1675 0.2551 0.2231 ]
M2 = [ 1.0000 0.0249 0.0101 0.0014 0.0135 0.9011 -0.2090 -0.3613 0.0115 -0.1105 0.6968 -0.6963 0.0179 0.4028 0.6741 0.6083 ]
M3 = [ 1.0000 -0.3102 -0.5205 0.7648 -0.4711 0.1691 0.2453 -0.3734 -0.8678 0.2605 0.4672 -0.6785 -0.0083 0.0112 0.0224 0.0052 ]
M4 = [ 1.0000 0.0053 0.0075 0.0052 0.0012 0.8993 -0.2341 -0.3621 0.0042 -0.0898 0.7110 -0.6907 0.0069 0.4224 0.6565 0.6171 ]
M5 = [ 1.0000 0.4296 0.4694 -0.7280 0.5207 0.2426 0.2414 -0.3865 0.8273 0.3613 0.4156 -0.6273 0.0013 0.0042 0.0285 0.0002 ]
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Efficient imaging polarimetry:Balance between system complexity and ad hoc data reduction algorithms.
To find an information, it must be present in the data: The most informative data are the « raw data ».
Conclusion