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routes of the digital road network in the environment of the
vehicle position. The most appropriate route a vehicle has used
and so the position to be found relatively to the digital map by
techniques of pattern recognition and image matching as used in
photogrammetry. The measurement model of such a system is
shown in picture 2.
This type of positioning is named map matching in the literature
due to the fact that the driven route has to be matched with the
map continuously during the driving process. Due to magnetic
disturbances wheel slips and gaps in digitalization of the road
network the loss of position up to a total system failure was
recorded in the past.
This system disadvantage can be explained if we interpret the
measurement of changes in heading versus changes in distance.
This value is known as curvature k in differential geometry. The
curvature Kis a motion and parameter invariance scalar so-called
natural invariant of plain curves and describes a coordinate
system independent formula for the curve. Solution strategies
based on measured curvature patterns in comparison to the cur
vature pattern of a digital road map can be used by pattern recog
nition techniques compared with square computation methods.
Prerequisite is the availability of 3 significant curvature signals
for reliable map matching processes. Practical measurements and
computations have shown the high performance of this technique
based on digital road maps with an accuracy of 10-15m (RMS). A
position accuracy of lm relatively to the digitized road network
can be achieved. In the following the adjustment approach
described in the performance of the solution is shown with 2
different examples.
4 MAP MATCHING WITH CURVATURES
The measured track has to be matched with the sample of road
element of the digital map. Due to measurement errors the coor
dinates of the vehicle position are inaccurate. With an appropriate
search algorithm all available tracks in the digital map are
extracted where the car could have moved mutually. For these
alternate tracks the curvature patterns will be developed and the
orientation of the road segments are filtered and differentiated.
The so developed curvature pattern leads towards the reference
for the map matching process.
The measured curvature pattern in the vehicle will be compared
to the different alternating route tracks and the RMS of the
adjustment result will be used to select the most appropriate track
from the digital map.
Picture 4: Measured and computed curvature patterns
For the map matching of 2 different curvature patterns there are
different recognition algorithms available. Similarity of 2
functions can be described by correlation methods and the cross
correlation can be described by
c(i) = ]►] a(j) • b(i + j) = a(i) o b(i);
j=- °°
where the signals a(i) and b(i) are curvatures(x,) and K 2 (y t )
in the appropriate picture. This method provides sufficient
accuracy for the start solution of a nonlinear least square
adjustment.
5 MAP MATCHING WITH LEAST SQUARE METHODS
Basic idea of the transformation between curvature profiles
/c,(x,) and. ic 2 (y i ) are
- translation u b and scale factor m b between the distance
y, = m b *x i -u b
- translation b and scale factor a between measured curvature
and computed curvature of the digital map
tc l (x i ) = a*K 2 (y i ) + b + n(x )
For the adjustment the following functional model is chosen
K x (x i ) = a*K 1 (m h x i -u b ) + b + n(x i )
and the nonlinear observable equation
K ï (x l ) + V(x l ) = a* f(y,) + b-,
This observable equation is heavily nonlinear and requires solu
tion in a, m b and u b .
