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system and
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ints and well
ANALYTICAL AERIAL TRIANGULATION, DISCUSSION 25
defined planimetric co-ordinates which will be
easily transformed into geographical co-or-
dinates or in any other cartographic projections.
Finally a few small variations of the programme
allow the introduction of the statoscopic data, of
the solar data and the radar profile, and also the
simultaneous introduction of two or three of
these elements.
As we said before, we use the condition
equation expressing the vanishing of the Y-
parallaxes; this method in Mr Schut's paper is
referred to as not sound. However, we wish to
point out that the factor by which he multiplies
the complanarity expression in order to obtain
the parallax, varies according to the heights of
the points; therefore, if there are redundant ob-
servations, the factor becomes essential in the
least squares method. Furthermore, it would be
wise to check if the use of the parallax or similar
expressions does actually cause a larger amount
of work.
Let us now examine the proceeding by
which we solve the system of the orientation
equations. The linearisation leads, at the first
iteration, to the tangent hyperplanes and then,
at the following iterations, to secant hyperplanes
parallel to the preceding ones. In this connec-
tion, we wish to note that the parallel hyper-
planes method cannot be defined not sound. In
fact, it leads to the same solutions which we
would obtain with the Newton's method, avoid
the computation of the coefficients and the solu-
tion of a system at each iteration (ie a fairly
large amount of computations). One might ob-
ject that with the parallel hyperplanes method a
large number of iterations is needed; however,
our experience on several strips has shown that
the solution is reached with an average of three
iterations, provided that the deviation of the
photograph axis from the vertical is not more
than three sexagesimal degrees. Of course, the
rate of convergency relative to the parallel
hyperplanes method is much better than the one
we obtain with predetermined or special solu-
tions.
As far as the method of strip triangulation
is concerned, we believe it convenient to start
the computations from the first photograph
oriented on the known points. The advantages
are quite evident if we consider both this method
and the introduction of a variable reference
system, since the only cause of disorientation
derives from the errors of the strip; therefore,
the models are almost oriented and in all the
following operations we will be able to use the
linear formulae. A further advantage will be an
easier introduction of the solar data and of the
gyroscopic data (which are local data) and also
of the statoscopic and radar profile data.
We believe that the comparison among the
analytical triangulation methods should be made
from the scientific and practical points of view.
From the scientific point of view it is important
to examine in detail the computation method: in
other words, the expression and solution of the
equations, the convergency of the iterations, the
degrees of error sensibility, etc.
On the contrary, from the practical point of
view, we should examine the analytical trian-
gulation methods as a whole, namely how many
manual operations are required in order to
obtain the data, what instruments are used, how
many programmes we must perform on the
computer before the final data are reached, the
time requirements both in terms of the com-
puter, instrument and man power, how many
controls are needed, the ease with which a gross
error can be detected and avoided during the
computations, the characteristics of the com-
puter which will be used, etc.
I am afraid my time is up.
Prof P. WisEn: Si nous voulons terminer dans
le délai prescrit, il est indispensable que je puisse
maintenant donner la parole à Monsieur McNair
qui est le dernier orateur inscrit. Monsieur
McNair.
Prof A. J. McNarR: My remarks will be very
brief, but I have two or three comments which I
should like to make concerning the papers which
have been presented and the comments which
have been made so far.
First, with regard to the paper which Mr
Schut has produced. I feel that he has done a
very good job and should be complimented on
the keen analysis which he has made. In my
own case, we discovered back in 1956 that there
was a weakness in the Herget method of analyt-
ical aerial triangulation in that the so-called
weighting factor was, in fact, not a valid weight-
ing factor at all. This has subsequently been
eliminated from computations.
At Cornell University in the United States
we developed a method known as a general
solution to analytical aerial triangulation. This
was developed in 1957 and subsequently. has
become known as the direct geodetic restraint
method, on which the United States geological
survey has worked. This method gives a general
aerial triangulation problem to either strips or
blocks. It gives a simultaneous solution to what-
ever size you may have.
At this point I would like to urge that we
