4
1. Basic Principles for Testing Photogrammetric
Instruments and for Establishing Tolerances
1.1 Test Measurements and Adjustments
The usual method of testing a photogrammetric instrument in practice is to
use it to measure given data of high geometrical quality. It is obviously
desirable that the quality of such test data be expressed in well defined con
cepts and terms. The commonly used data consist of coordinates of the inter
sections of regular and closely spaced grid lines on glass plates.
If the grids are not observed orthogonally to the surface, it is also necessary
to know the flatness of the grid surface i. e. the third coordinate of the grid
lines intersections must be given with high and known quality.
In practice, the data for the intersections on the glass grid must be deter
mined originally by measurement in instruments of the highest known quality.
Independent measurement in at least two instruments with different operators
is always desirable. Then the geometrical quality of the results obtained can
be determined from numerical comparisons of the different, independent sets
of coordinates. 1 ) In principle the geometrical quality of the given data should
be so high as to be regarded as errorless in comparison with the instrument to
be tested. Obviously, compromise in this requirement is sometimes necessary.
The general principles of the instrument tests are as follows.
With the instrument to be tested the coordinates of the grid are measured
under operational, as distinct from special laboratory, conditions. The orien
tation of the grid should usually be such that the differences between the
measured and the given data are sufficiently small to be treated with linear
differential formulas. The necessary calculations are then simple. Sometimes,
however, there are reasons to use a completely arbitrary orientation or com
bination of orientations of the grid. The computations in such a case usually
must be of iterative character. If possible, the grid points to be measured
should be chosen in a regular pattern around the center point.
The basic measurements must always be made with great care. The operator
must use a certain “warming up” period of at least 10— 15 minutes in the instru
ment. Enlargement and measuring marks should be personally chosen, if
1 ) An example of this procedure has been given in Lycken 1956.
In this case the coordinates of all grid intersections were given by the manufacturer of the
grid. Independent measurements of the coordinates of the grid were then performed in a
SIP-comparator and coordinate transformations including adjustment according to the
method of least squares were made. Assuming the same order of magnitude of the errors
for both sets of coordinates the standard error of each set became about one micron. The
grid had the total format 9" x9". The flatness of a grid is preferably measured according to
the microscope method, which does not require the surface to be touched. See Hallert 1960 a.
