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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B1. Istanbul 2004
Suppose that the sample {x(0),x(1),--, x(N — bj is divided
into L segments of M elements each (thus, N = LM ) and
that the side for bifrequency smoothing is of length M,, the
estimated bispectrum B(a, o) is (Hinich, 1982)
I
B(w,®,) = 3b" mn) 4)
=
1 mM, —1 nM, —1
b? (m,n) 2 5 s DPF hc) 3
M, k,=(m=l)M, k,=(n=1)M,
Fk, ky) eur n, )X "(a ) X (a), ) and
M-1
X (0, )= NR y? (exp(- j0.1)-
1=0
The statistics for non-Gaussianity test is (Hinich and Wilson,
1990)
TCH -2N «N Y |B(o,. a.) - B(o,. e) "[Scop$ca, )$(o, * &)
CELA)
(5)
where A, — LM,/N = M,/M , and S(q) is the estimate of
power spectra. If A, = VAN , TCH is an approximate Chi-
square distribution with a degree of freedom of 2P , where
PUMA y^.
4.0 Non-Gaussianity of Atmospheric Signals
The null hypothesis for the test is: the atmospheric signatures in
a SAR interferogram are Gaussian. Under the null hypothesis,
B(w,,w,) =0 for all bifrequency pairs, and thus TCH is
approximately 72.00). The a -level test is to reject null
hypothesis if TCH > T,, , where a = Pr 2T. ;
To satisfy the relationship of A, = TEES and to conduct
more detailed tests, we divide each interferogram into a number
of pieces along the azimuth direction and in each piece a test is
carried out. The number of tests, i.e., the number of pieces, and
the test results for each of the study regions are listed in Table
2. Also shown are parameters used in bispectrum estimations
for each study region.
M L M, |Gauss. Nan:
Gauss.
Shanghai 50 1250 | 25 7 0 50
Hong Kong 25 300 | 12 5 0 25
New South =
2 2 7
Wales 25 500 | 20 5 0 25
Interfero. | Number Parameters used in
N : ; : Test Results
of tests | Bispectrum estimation
Table 2. Details of Hinich Non-Gaussianity tests.
The Hinich non-Gaussianity tests show that for all the study
regions the differential atmospheric signals show significant
non-Gaussianity. This contradicts to assumptions made by
some authors that the atmospheric signals are Gaussian
(Ferretti, et al., 1999 and Yue, et al., 2002). The atmospheric
effect on InSAR measurements and parameter estimation are,
however, subject to further study.
5 Spectral Analysis of Atmospheric Signals
The mean differential atmospheric delays in each of the study
areas are calculated and removed from the unwrapped
interferograms. A 2D Fast Fourier Transform (FFT) is
performed next for each of the areas and the results are squared
to obtain the power spectra. The ID rotationally averaged
power spectra thus obtained are given in Figures 7, 8 and 9.
1 0° =. x
\
4 A.
5 10 lA,
8 CAI
De > >
510 N.
3 ™S
n >
10° S
\
x
=
10° dad io xam
10? 10° 10° 10! 10°
Wavenumber (cycles/km)
Figure 7. Power spectrum of differential atmospheric signals in
the Shanghai study region. The dashed lines follow a slope of
vis.
10° s ' c |
No |
A,
4 s
10 uum
5 N
5
Q
$ S
510° |
T
o
oO
x A
10° N
10? 107 10° 10’ 10°
Wavenumber (cycles/km)
