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Solar spectrum, J. W. Draper 1840 John W. Draper (1811-1882) Henry Draper (1837-1882) Courtesy of Smithsonian Institution.

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Presentation on theme: "Solar spectrum, J. W. Draper 1840 John W. Draper (1811-1882) Henry Draper (1837-1882) Courtesy of Smithsonian Institution."— Presentation transcript:

1 Solar spectrum, J. W. Draper 1840 John W. Draper (1811-1882) Henry Draper (1837-1882) Courtesy of Smithsonian Institution

2 Lunar rock and mineral mapping using public- domain software with Clementine and Lunar Prospector imagery: the Geological Lunar Research Group (GLR) Experience Richard Evans, MD (GLR group)

3 Solar Spectrum

4 Atmospheric bands AVIRIS DATA

5 Pyroxene Spectra

6 Olivine Spectrum

7 Anorthite Spectrum

8

9

10 Copernicus Apollo 16 Multiplier: Soil sample #62231

11 Band Pass Filter Set

12 NIR camera (Su320Mx)

13

14 Clementine Small Telescope

15 Hyperspectral (AOTF) Imager

16 Data Mining Clementine UVVIS + NIR imagery Lunar Prospector Selene UVVIS + NIR imagery

17 Clementine UVVIS + NIR Spectra

18

19 Mapping of Spectral Parameters in Octave

20 Spatial Enhancement of LP Data using Clementine UVVIS+NIR imagery Matrix Regression: A x = b A = Coefficient Matrix (gain and offset values) X = Clementine spectral parameter map based comparison matrix B = Lunar Prospector elemental abundance map for a particular element

21 Method Development This general method was employed by Shkuratov UG et al. (2005) Planetary Space Sci 53: 1287-1301 but employed only Clementine 5 UVVIS spectra. The GLR method expands this to include the Clementine NIR global mosaic images and employes spectral parameter mapping of this data in the matrix regression. These modifications to the Shkuratov method were pursued in GLR primarily by Christian Wöhler, with the assistance of other GLR members and of Alexey Berezhnoy of the Sternberg Institute, Moscow. Initial results were recently published: C. Wöhler A. Berezhnoy and R. Evans (2009) Estimation of Lunar Elemental Abundances Using Clementine UVVIS+NIR Data. EPSC abstracts. Vol. 4.

22 Increasing spatial resolution of LP Data by Matrix Regression against Clementine based Spectral Parameter Maps Convert mxn Clementine spectral parameter and LP elemental abundance maps into 1 x n row vector matrices. Then: The matrix equation A*x=b is solved for x, the coefficient matrix. Then each Clementine row vector matrix and the ones matrix is multiplied by its corresponding coefficient and they are summed together. The resulting summation matrix is re-converted into a matrix of dimension mxn which will very closely approximate the original mxn LP matrix, but at much higher spatial resolution.

23 Solving the matrix equation A*x = b in Octave: A = mrdivide(B,x);

24 Motivation Lunar elemental abundance vs. multispectral data Lunar Prospector gamma ray spectro- meter data: Al [wt%] 150 km resolution Clementine UVVIS+ NIR global mosaic 100 m resolution Basic Idea:Mapping of UVVIS+NIR data to LP GRS data based on matrix regression techniques

25 Feature extraction from Clementine UVVIS+NIR data Continuum removal continuum  Pixel-wise calibrated UVVIS+NIR spectrum (USGS Map-a-Planet)  Division of the original spectrum by the continuum line defined by the reflectances at 750 nm and 1500 nm (LeMouélic et al., 2000)  Akima interpolation

26 Feature extraction from Clementine UVVIS+NIR data Definition of spectral features (Evans et al., 2009) δ1δ1 FWHM λ1λ1 δ1δ1 δ2δ2 λ1λ1 λ2λ2 λ3λ3 δ3δ3 single absorption minimumtwo absorption minima inflection feature pyroxene pyroxene with high admixed olivine content pyroxene with low admixed olivine content  Continuum slope ( R 1500 – R 750 )  FWHM of the absorption trough  λ 1, λ 2 : Two absorption wavelengths between 890 and 1150 nm (identical values for single absorption)  δ 1, δ 2 : Two relative absorption depths of the absorption minima (identical values for single absorption)  λ 3, δ 3 : Wavelength and absorption depth of an olivine inflection feature 1.05

27 Elemental abundances from spectral features Estimated abundances of Ca, Al, Fe, Mg, Ti, and O Ca (2 – 18 wt%) Al (0 – 20 wt%) Fe (0 – 25 wt%) Mg (0 – 16 wt%) Ti (0 – 6 wt%) O (40 – 47 wt%)

28 Petrographic Mapping from End-members defined by Elemental Abundances, Eimmart Crater Area Red: Mare Basalt Green: Mg Suite Blue: Anorthositic (FAN)

29 Basaltic Mapping based on Al & Ti defined End- Members, Eimmart Area Red: Mare Basalt Green: Highlands Blue: Ti enriched

30 Optical Maturity: OMAT OMAT = [ (R750 – 0.08)2+ (R950/R750 – 1.19)2 ]0.5

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