led
ic-
ost
nd
ial
lid
d-
of
ls,
le
BALLISTIC PHOTOGRAMMETRY, SCHMID 37
the corresponding geodetie techniques of measuring angles and directions for the similar
purpose, intersection photogrammetry either determines the spatial position of a point by
triangulating corresponding rays, originating from two or more stations, or the spatial
position and orientation of a specific camera is determined by the method of resection in
space, whereby the double and multiple point resections occupy a place of special interest,
insofar as they represent the geometrical concepts on which the single model, the strip
and the block triangulations, are based.
The historical development of photogrammetry does not reflect these geometrical
fundamentals. The phase of Intersection Photogrammetry was succeeded by the concept
of Stereophotogrammetry, comprising the methods and techniques which presently dom-
inate the applieation of photogrammetry in the topographie field. As a matter of fact,
the purist in stereophotogrammetry often considers it beneath his dignity to pay much
attention to the outmoded concept of intersection photogrammetry. This situation prevails
despite the fact that the stereo-effect in photogrammetry is of basic significance only in
dealing with the problem of measuring or plotting spatial curves (e.g. contour lines) on
a stereoscopic model, after it has been re-established. From a geometrical standpoint, the
stereo-effect contributes nothing during the process of restitution which is undoubtedly
the more important phase, concerned with the re-establishment of the orientations of the
photographs by the methods of relative and absolute orientation. The well known geo-
metrical theorem for the relative orientation demands that five pairs of corresponding
rays of any two associated photogrammetric bundles be intersected. The absolute orien-
tation has its equivalent in a three dimensional coordinate transformation.
Aside from considerations dealing with precision and economy, the restitution of the
orientations of a pair of photographs can be performed by alternately observing first
one and then the other of the two photographs. Analytically speaking, the orientations
can be computed from a certain number of plate coordinate measurements, observed on
a monocular comparator independently, for each of the photographs under consideration.
Qualitatively speaking, the stereoscopic principle becomes significant during the
process of restitution, only with respect to identification. Quantitatively speaking, the
stereoscopic effect increases the metric precision of the measuring operation.
There is no reason to assume that any specific application of photogrammetry can
monopolize these advantages. The field of non-topographic applications, usually signi-
fying the domain of Intersection Photogrammetry, definitely will not forego the possi-
bility of applying the stereoscopic observation method.
Finally, there are problems in the field of non-topographic application which demand
the method of stereoscopic evaluation of the model, once established. For instance, photo-
grammetry is used for the study of cloud formations and for the related problem of
determining wind vectors at great heights by photographing sequences of smoke puffs
or vapor trails, as associated with most missile firings. For reason of identification the
evaluation can only be performed by using three dimensional restitution equipment, in
the same way as these simulators are used in most topographic mapping projects.
The purpose of this introduction is to show that the photogrammetric method as ap-
plied in the non-topographic field and specifically in the field of Ballistic Photogram-
metry is, with respect to the basic geometrical principles, not merely related, but actually
identical with its counterpart in topographic application. Accordingly, the requirements
on field instrumentation, data reduction methods and equipment are similar.
As a matter of fact, the wide variety of problems encountered in the non-topographic
field calls for such flexibility of the measuring method, that nothing short of a solution
of maximum generality will do.
The rigorous request for significance of the results, in terms of X,Y, Z-coordinates
and in terms of corresponding rotational parameters, eliminates any compromise with
regard to rigorous geometry. The use of the photogrammetric camera as a device for
