View
577
Download
2
Category
Tags:
Preview:
Citation preview
Quantitative assessment on the requirements of DESDynI mission for crustal deformation study
Sang-Ho Yun, Julian Chaubell, Eric Fielding, Zhen Liu,
Scott Hensley, Frank Webb, Paul RosenJet Propulsion Laboratory
David Bekaert, Shizhuo LiuDelft University of Technology
1
National Aeronautics and Space Administration
Jet Propulsion LaboratoryCalifornia Institute of Technology
Atmosphere in InSAR for solid earth study
2
Considered as noise
Ignored
Covariance function assumed Covariance matrix
Corrected using independent measurements (MODIS,MERIS,GPS) or time series analysis (PS-InSAR, SBAS)
Mean velocity from PS-InSAR time series analysis
3Bekaert & Yun, 2010
4.8
-23.6
cm / yr
Central californiaJuly 2007 – December 2009
When removing atmosphere with PS-InSAR
4
Processed with StaMPSFilter length: 2 month
Bekaert & Yun, 2010
When removing atmosphere with PS-InSAR
5
Bekaert & Yun, 2010
Processed with StaMPSFilter length: 12 month
Outline
6
Covariance and structure function
Prediction-Error Filter
Atmospheric error budget in Los Angeles basin
MODIS data
Conclusions
Why Covariance?
7
- Interferogram (double difference): Δρ(x1,y1) – Δρ(x2,y2) - How much is due to deformation?- How much is due to differential tropospheric delay variation?
Δρ(x1,y1)
Δρ(x2,y2)
Covariance Matrix
8
Yun, 2007
Objective function in inverse problems:
(d – Gm)T(d – Gm) d – Gm ~ N(0,I) (d – Gm)TC-1(d – Gm) d – Gm correlated
Data usage
9
Geophysical Modeling
Error budget analysisQuantitative assessment of mission requirements
Atmosphere in InSAR Covariance function
Structure functionMODIS NIR
Prediction-Error Filter Interpolation
10
Yun et al., 2005
2 km
Prediction-Error Filter Interpolation
11
Claerbout & Fomel, 2002; Yun et al., 2005
PE Filter Interpolation (1-D example)
12
PE Filter Interpolation (2-D example)
13
Original image Image with a hole
Interpolated image Interpolated - Original
PE Filter Interpolation (2-D example)
14
PE Filter Interpolation of Real Data
15
Zenith delay converted from interferometric phase (2008/11/20 – 2009/01/05, Bp = 275 m)
(mm)
PE Filter Interpolation of Real Data
16
Original image Image with a hole Interpolated image Interpolated - Original
(mm)
17
PE Filter Interpolation of Real Data
Study Area: Los Angeles basin
18
Some statistics
19
Envisat interferograms
20
35 Envisat interferograms from ascending track 392 (2002.10.28 – 2007.01.15)
104 Envisat interferograms from descending track 170 (2003.09.27 – 2010.02.27)
Envisat interferograms
21
Interpretation
22
For example, | Δρ(x1,y1) – Δρ(x2,y2) | = 5 mm
30 % probability of the measurement value placed below the mean atmospheric noise level
Δρ(x1,y1)
Δρ(x2,y2)
| Δρ(x1,y1) – Δρ(x2,y2) |
How much is the signal against atmospheric noise
23
- Mw 5.4 earthquake at a depth of 1 km.- Interferogram reduced with variance-equalizing method (quadtree)- 71 % of reduced data values above 5 percentile of atmospheric noise level
MODIS (Moderate Resolution Imaging Spectroradiometer)
24
Terra (launched on 1999.12.18)Aqua (launched on 2002.05.04)
Wide swath: 2000 km
Spatial resolution: 1 km
Near daily global coverage
NIR channel has PWV (precipitable water vapor)
Cloud mask
OSCAR project team at JPL: Paul Von Allmen, Eric Fielding, Zhangfan Xing, Lei Pan
Li & Fielding
Conclusions
25
Covariance function is useful for geophysical modeling and structure function is useful for quantitative assessment of mission requirements and error budget analysis.
Prediction-Error filter is tested for image recovery of tropospheric delay variation and turned out to be useful for robust production of spectral analysis.
The structure functions of tropospheric signal from Los Angeles basin from 2002 through 2010 derived from 139 Envisat interferograms are bounded within one order of magnitude.
MODIS data are being tested against the InSAR data analysis and be used to characterize and produce global library of covariance and structure functions; Fcov(r,t,lat,lon), Fstr(r,t,lat,lon).
23 ALOS interferograms (asc. 2006.06.30 – 2010.01.08)
26
Recommended