The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol. XXXVII. Part B5. Beijing 2008
937
&aQ
Obo
^al
&b2
<?d0
_0
a gv
CTgv
0"rv
CTgv
ârv
Comments
[pixel]
[mm]
[16bit]
[16bit]
[16bit]
0.037
0.026
0.008
0.007
4.160
1.0
1.0
X
X
65.112
37.669
Equal weights
0.036
0.026
0.010
0.007
5.742
1.0
l-E+7
X
X
69.930
51.810
Overemphasis intensity measurement
0.069
0.054
0.007
0.007
0.475
l-E+7
1.0
X
X
103.232
7.616
Overemphasis range measurement
0.041
0.034
0.006
0.006
0.641
1.0
1.0
1616.916
120.719
69.108
7.499
VCE (two groups of observation)
Table 1: RIM sequence analysis using different stochastic models. Experimental trials performed with 2.5-D LST using intensity and
range channel.
tr(V(Sc)vcE) tr{V(x) HC ) tr(V(x)HAc) tr(. ( '.')*** R Homogeneity Comments
0.00349*
0.00492**
0.00550***
0.709
0.634
[0.10; 9.60]
tzl
tzl
Static scene
Measuring mark
Images taken form different point of views
0.00688*
0.01696***
0.01234**
0.557
0.405
[0.10; 9.60]
tzl
tzl
tzl
tzl
tzl
tzl
Kinematic scene
0.00260***
0.05099**
0.00257**
0.04448*
0.00256*
0.12381***
0.986
0.872
0.999
0.359
[0.14; 7.15]
[0.14; 7.15]
Natural gray value gradient
Images taken form one point of view over time
Table 2: Homogeneity of variance covariance matrices.
The experiment shows that the use of complementary information
improve accuracy and reliability for RIM matching tasks. 2.5-D
LST is most impressive when dealing with significant range off
sets between template and search patches. In particular the range
channel supports gray value observations in scale adjustment and
provides additional information in the case of low contrast within
intensity patches.
5.2 Experiment 2: Stochastic Model
When processing heterogeneous data, an adaption of the stochas
tic model is necessary. A splitting of a single heterogeneous ob
servation group in several ones allows the consideration of mul
tiple variance factors (Section 3.2). Thus, it is possible to tap
the full information potential of the available observations. The
results of some experiments on a RIM data set with high inten
sity and range contrast as well as a range offset of about 30 cm
between template and search patch accentuate the need for an
adapted stochastic model (Table 1). The following experimental
setup was used: 2.5-D LST with (i) equal weights for intensity
and range observations (ag VtT . v = 1 bit), an overemphasis of (ii)
the intensity (a® v = 1 • E + 7 bit) or (iii) the distance measure
ment (cTg V = 1 • E + 7 bit) and (iv) a stochastic model, which was
estimated by VCE with a® g — 1 bit and a^ g = 1 bit as initial
a-priori SD for a VCE.
In Table 1 (Row 1-3) a negative influence on parameter accura
cies is obvious for a deficient weighting of the measurements.
The specified a-posteriori SD of the adjusted observations have
higher variances, compared to a well-balanced weighting (Row
4). Those balanced weighting could be achieved by VCE with
two groups of observations. The precision of the shift parame
ters is within the order of */30 pixel. The scales can be determined
with a precision cr a i,b2 of 0.006, and the corresponding range
offset SD ado (derived from Equation 7 by the law of the prop
agation of errors) becomes 0.6 mm (based on do = 294.1 mm,
corn 0.2 %).
Applying a VCE, precision information of the original observa
tions becomes available: In this case, the a-priori SD of the inten
sity measurement a gv is 1600 gray value, which corresponds to
16 bit resp. 6 gray values referring to 8 bit. This magnitude is re
alistic and comprehensible due to a poorer signal-to-noise ratio of
CMOS sensors (Lange, 2000), background illumination and vari
ations within charge-to-voltage relation. Furthermore, a gv aligns
with previous results empirically determined by Hempel (2006).
The range values have been measured with an SD of 121 counts
resp. 1.4 cm (it = 20.2 ms; mf = 20.0 MHz), which corre
sponds to Hempel’s results as well. Free of systematic errors, the
averaged a-posteriori SD of the adjusted observations è gv ,rv can
be specified with 69 counts (16 bit-range) resp. 0.3 gray values
(8 bit-range) for the intensity channel and 8 counts resp. 1 mm for
the range channel. Those values reflect that the raw data match
well with the established model.
The experiment shows that 2.5-D LST in combination with a
VCE improves the parameter accuracies. Especially if no ade
quate a-priori precision information is available, an optimal uti
lization of the whole content of information becomes possible.
Furthermore, the procedure delivers valuable information on the
sensor and data quality.
5.3 Experiment 3: Robust VC-Matrix Estimation
The following experiments have been performed to show, whether
an enhanced stochastic model in the form of a robust VC-matrix
estimation (Section 4) is useful for the presented functional model
(Section 3.2) and to quantify differences in the precision of the
underlying VC-estimators (VCE, HC and HAC). Testing the de
terminants of the estimated VC-matrices of the GMM parameter
vector x would be of a great benefit since this approach will in
corporate the covariances between the components of x as well as
their variances. However, this test procedure will only work for
orthogonal regressions or stochastic processes (Rounault, 2007),
which both do not fit into the presented framework. In order to
still derive a valid value for the homogeneity of the several VC-
matrices, the traces tr(V(St)vcE), fr(V(x)nc) and
tr(V(it)HAC) of the estimated matrices are tested against each
other by usual F-test procedures:
• Null hypothesis:
H 0 : al = al (16)
• Test Statistics:
_ ¿r(V(x)«) tr(V(St)„)
£r(V(x)**) ' ir(V(x)***)
with tr(V(x)„) < tr(V(x)»„) < fr (V(x)»»«)
• Acceptance region:
R — ^-^n— l,n— 1, ^ ) F n — l,n—1,1— ?£ j
with F: Quantile of F-distribution
n: Number of unknown parameters
a: Significance level
(17)
(18)
