TARGET RANGES FOR CALIBRATION OF CLOSE RANGE CAMERAS
Torlegard (1967) provides the development of a method of calibration of close
range cameras from reduction of exposures of suitably constructed, three dimensional
target ranges. He also provides specific results from a particular range comprised of
a steel framework 3.6 m wide by 2.4 m high and 2.8 m deep on which a total of 177
targets are supported. The coordinates of the targets were established by triangu-
lation with a Wild T3 theodolite to an estimated rms accuracy of 0.07mm. The
method employed by Torlegard for the photogrammetric calibration is equivalent to
the special case of Aerial SMAC in which only a single frame is reduced (hence, the
need for such a large number of targets). As in the original development of Aerial
SMAC, Torlegard's method does not take into account the variation of distortion with-
in the photographic field (i.e., distortion at midfield is assumed to hold throughout
the field).
The major problem associated with the three dimensional target range method
lies in the practical difficulties associated with constructing, surveying and maintain-
ing the range. Because of SMAC's sufficiency with a small set of targets, this problem
is alleviated to a considerable degree by the exercise of SMAC (properly modified to
account for variation of distortion within the photographic field). Of even greater
significance is the fact that SMAC opens up the possibility of employing a two
dimensional target range to effect a full calibration of the inner cone. Such a range
has been constructed at DBA Systems. It consists of a black-painted horizontal slab
of concrete, 5 by 5 meters square by 0.3m thick, onto the surface of which a total
of 650 targets have been attached. The targeting density of about 25 targets/square
meter is sufficient to permit sections as small as one half square meter to be exercised
effectively in a SMAC calibration. The process used for determination of target
locations will be considered later; for the present discussion we shall assume the
locations to have been pre-established.
The basic requirements for a complete and satisfactory calibration by means
of Aerial SMAC in conjunction with a sufficiently accurate and sufficiently dense
two dimensional target range are that:
the formulation takes into account the variation of distortion within the
photographic field according to the model presented in this paper;
a minimum of two frames are exposed and reduced;
at least two of the frames are taken with camera axis inclined at moderate
angles, preferably about 45*, to the normal to the target array;
the swing angles of at least two of the exposures differ substantially
(e.g., X &0* and x«90*).
When these conditions are met, a sharp recovery can be expected not only for the
coefficients of radial and decentering distortion but also for all three elements of
interior orientation, x, ALE The coordinates X¢ ,YC¢ ,Z¢ of the various exposure
stations are also accurately recoverable. Hence the solution does not require the
imposition of a priori constraints on exposure stations, as would have been the case
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