e exterior orientation of the images, with test field
reference points coordinates and interior orientation
parameters being frozen;
e complete unknown parameters vector estimation in
condition of knowing relative distances.
Such a technique allows to obtain the resulting accuracy for
spatial reference points coordinates at the level of 5.14 mm and
the accuracy of angle exterior orientation parameters at the level
of 0.35°. These results are at the required level for the given
problem of road surface 3D reconstruction and obstacle
parameters estimation.
4. RELATIVE ORIENTATION
The next stage of stereo system calibration needed for reliable
estimation of road and obstacle geometry parameters is cameras
relative orientation. The theoretical analysis and the results of
manual relative orientation made using images of road scenes
obtained during first technological laboratory vehicle mission
have shown that the accuracy of simple relative orientation
procedure (eliminating vertical parallaxes for corresponding
points) results in unreliable estimation of relative orientation
parameters.
The relative orientation procedure is performed in on-line mode
using 2D test field similar to calibration procedure. For relative
orientation parameters estimation a set including from three to
six stereo pairs is acquired at different vehicle distances from
the test field. A diapason of distances from test field is
determined by requirement of observing the most part of
reference points by vision system in all parts of images. The
diapason varies from 10 m to 40 m and depends on test field
size. Then the set of 2D test field observations is processed
under conditions of planar location of reference points and
given reference distances, resulting in relative orientation
parameters vector. The estimated relative orientation parameters
are transmitted to obstacle detection software and are used for
estimation of vehicle position in the road, obstacle position in
the lane and obstacle height and width.
For estimation of relative orientation parameters the co-
planarity condition is used:
F = xx'(c{b{ — bie) + xf (bet ~ bjes ) + xz'(bje$ — bef) +
* z'f (bh — byes) + xf (brc? — bef) + ff'(bez-by)- AD)
— x'zb[C5 — zz'bycs — zf bye, - 0
In formula (11) next designations are used:
b,'- -sinag;
b,'=—cosag,;
by'=0;
CJ'=—COSŒg - SIN KB; (12)
C5'— —Sin Og : Sin Kg;
€4'— COSKp;
b,"- —sina'g:cos op;
b,"— cosa pg: cos op;
b,"— —sin 9g;
c"— cosa''p:sin k'g—sin a g:sin 9'g:cos Kp;
C" sina'p-sink'g+cosa'g-sinw'p-cosk'p;
C4" — COS ' g: COS K' p.
where
ap, Kg - elements of relative orientation for the left
image;
Q'p, Op, K'p - elements of relative orientation for the
right image;
x, z, f - coordinates of points and focal distance of left
image;
x^ z/ f! - coordinates of points and focal distance of
right image.
To determine the elements of relative orientation the model of
least squares method was used.
The developed system on-line relative orientation procedure
takes few minutes and is to be performed whenever cameras
position is changed. The outdoor test field includes a set of
reference points located on plane surface. The number and
location of reference points in the test field is taken from
condition of equal density of markers in all parts of the left and
right images acquired from distances of 10 - 30 m. Figure 6
represents a set of stereo pairs acquired during relative
orientation procedure. The test field used for relative orientation
includes 12 reference points marked by coded targets.
Figure 6. A set of test field images for relative orientation
For relative orientation procedure performing laboratory vehicle
is installed in initial position at distance approximately 30 m in
front of the test field and first image stereo pair is taken. Then
the vehicle moves forward to the test fields and next some
images are taken (usually three-four stereo pairs) while vehicle
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