Virtues of polarization in remote sensing of atmospheres and oceans

1. Virtues of polarization in remote sensing of atmospheres and oceans George W. Kattawar Department of Physics and Institute for Quantum Studies Texas A&M University Research Colleagues: Deric Gray, Ping Yang, Yu You, Peng-Wang Zhai, Zhibo Zhang

2. Scattering object Incident beam  Scattering angle Scattering Geometry || Scattering plane || Scattering amplitude matrix || ||

3. Stokes vector-Mueller matrix formulation The electric field can beresolved into components. El and Er are complex oscillatory functions. E = El l+ Er r The four component Stokes vector can now be defined. They are all real numbers and satisfy the relation I2 = Q2 + U2 + V2 The Mueller matrix relates the incident and scattered Stokes vectors

4. DOP= Degree of polarization= DOLP = Degree of linear polarization = Stokes vector and polarization parameters I is the radiance (this is what the human eye sees) Qis the amount of radiation that is polarizedin the0/900 orientation U is the amount of radiation polarized in the +/-450 orientation V is the amount of radiation that is right or left circularly polarized DOCP = Degree of circular polarization = |V|/I Orientation of plane of polarization =  = tan-1(U/Q) Ellipticity= Ratio of semiminor to semimajor axis of polarization ellipse=b/a =tan[(sin-1(V/I))/2]

5. Polarizer and analyzer settings for Mueller matrix measurements Diagram showing the input polarization (first symbol) and output analyzer orientation (second symbol) to determine each element of the SSMM denoted by Sij. For example, HV denotes horizontal input polarized light and a vertical polarization analyzer. The corresponding symbols denoting polarization are V, vertical; H, horizontal; P, +45, M, -45; R, right handed circular polarization; L, left handed circular polarization; and O, open or no polarization optics. This set of measurements was first deduced by Bickel and Bailey.

6. Plankton as viewed by a squid Planktonic animal as seen through "regular" vision As seen when placed between two crossed linear polarizing filters As seen by putting the two polarizers at 45° to each other

7. Photo taken with circular polarized light for illumination and a circular analyzer for viewing Contrast enhancement using polarization Photo taken with a flash lamp and no polarization optics

8. Nissan car viewed in mid-wave infrared Q U I V This data was collected using an Amber MWIR InSb imaging array 256x256. The polarization optics consisted of a rotating quarter wave plate and a linear polarizer. Images were taken at eight different positions of the quarter wave plate (22.5 degree increments) over 180 degrees. The data was reduced to the full Stokes vector using a Fourier transform data reduction technique.

9. Bacillusanthracis

11. Experimental Setup Yong-Le Pan, Kevin B. Aptowicz, Richard K. Chang, Matt Hart, and Jay D. Eversole, Characterizing and monitoring respiratory aerosols by light scattering, Optics Letters, Vol. 28, No. 8, p589 (2003).

12. Coordinate Setup source detector y y x x Z’  z z Laser beam The symmetry axis is in the yz plane.

13. Mueller Image Generating Method We plot the reduced mueller matrix elements on a circular plane shown as in the figure below. Reduced mueller matrix means all mueller elements except M11 are normalized to M11, which are in the range from -1 to +1. For the M11 element, we use the phase matrix P11 value. y 90 M(,) In our mueller image generation, radial position has linear relation to the scattering polar angle. The actual experimental detection may not have same relation. The resultant images will be different than the images shown here. r  x -90 90 -90

14. Outer coat =0.5m Particle Model-1: Spore 1.0m Inner coat Cortex Core m 0.8 Philip J. Wyatt, “Differential Light Scattering: a Physical Method for Identifying Living Bacterial Cells”, Applied Optics, Vol.7,No. 10,1879 (1968)

15. 1.0μm m=1.34 m=1.34 Simulation Models 1.0 or 2.0 μm 0.8μm 0.5 μm (a) (b) (c) (d)

16. =0.5m m=1.34 1.0m m 0.8 Homogenous Spore Mueller Image = 0o

17. =0.5m 1.0m Core m 0.8 Spore with Core Mueller Image = 0o

18. 1.0m Homogenous Cylinder Mueller Imageheight=1m, =0o m=1.35 0.5m = 0.532 m

19. m=1.35 2.0m 0.5m = 0.532 m Homogenous Cylinder Mueller Imageheight = 2m,  = 0o

20. Mueller Image for Three Particles =90o P11 P33 P34 P44 1.0m 0.8 m 1.0m =0.5m m=1.34 1.0m 0.8 m m=1.35 = 0.532 m 0.5m

21. Properties of the Target 2. Depolarizing The target reflects light with a Lambertian distribution. The albedo is constant across surface, but each annular region has a different reduced Mueller matrix. R = 0.10 m.f.p.s R = 0.067 R = 0.033 1. Polarization Preserving 3. Painted Surface

22. Geometry of the Imaging System

23. Properties of the Model The attenuation coefficient is fixed, but the absorption and scattering coefficients can be varied. All distances are given in units of photon mean free path (m.f.p.) The system is assumed to be an active source, so there is full control over all aspects of both source and detector. The detector details are intentionally left out; only the radiometric quantities at the detector location are calculated. The problem is solved for a time-independent case.

24. Inherent Optical Properties of the Medium Two classes of phase functions are used to describe the scattering by the medium: Henyey-Greenstein (HG): Two-Term Henyey-Greenstein (TTH):

26. The single-scatter reduced Mueller matrix for ocean water is taken to be that of Rayleigh scattering:

27. Results The target depth is kept constant at 2 m.f.p.s The target albedo is kept constant with a value of 0.025 The effective Mueller matrix elements of the system are calculated for different phase functions and single scatter albedos of the medium. Due to the form of the matrix elements of the target and the backscattering geometry of the imaging system, only the diagonal elements of the effective Mueller matrix are non-zero.

28. Mueller Matrix Elements HG g=0.95 phase function Medium Albedo = 0.25

29. Radiance HG g=0.8 HG g=0.95 HG g=0.5 v= 0.5 v= 0.25 v= 0.5 v= 0.5 v= 0.25 v= 0.25 TTH SBP TTH LBP v= 0.5 v= 0.5 v= 0.25 v= 0.25

30. HG g=0.8 HG g=0.95 HG g=0.5 v= 0.5 v= 0.25 v= 0.5 v= 0.5 v= 0.25 v= 0.25 TTH SBP TTH LBP v= 0.5 v= 0.5 v= 0.25 v= 0.25

31. HG g=0.95 HG g=0.5 HG g=0.8 v= 0.5 v= 0.25 v= 0.5 v= 0.5 v= 0.25 v= 0.25 TTH SBP TTH LBP v= 0.5 v= 0.5 v= 0.25 v= 0.25

32. HG g=0.8 HG g=0.95 HG g=0.5 v= 0.5 v= 0.25 v= 0.5 v= 0.5 v= 0.25 v= 0.25 TTH SBP TTH LBP v= 0.5 v= 0.5 v= 0.25 v= 0.25

33. Mueller Matrix ElementsMedium Albedo = 0.25

34. Mueller Matrix ElementsMedium Albedo = 0.5

35. Conclusions • Only correct way to do radiative transfer calculations • Mueller matrix contains all the elastic scattering information • one can obtain from either a single particle or an ensemble • of particles • Provides a unique “fingerprint” of particle morphology, orientation, and optical properties • Can provide information about surface features of objects • which can’t be obtained with ordinary radiance measurements • Can even be used for the detection of precancerous skin lesions