errors in the indications of the machine. On the other hand, the machine
provides a very reliable, and reasonably convenient three-dimensional test
field for calibrating photogrammetric systems. We were fortunate to have
contact with the Quality Assurance Directorate (Ordnance) of the Ministry of
Defence at the Royal Arsenal Woolwich, in whose establishment is an
exceptionally well designed three-axis machine produced by the Cranfield Unit
for Precision Engineering (C.U.P.E.). This machine has a design volumetric
accuracy of 50pm, with an available travel of 4m X 2m X 0.76m, and is shown
in plate 1. The wide angle laser source was mounted on the quill, and the two
UMK 10FP cameras set up on the machine table, as shown. The plates used were
Agfa 10E75, which have a very fine grain (less than 1pm), very slow speed
(less than 1ASA) and very high contrast emulsion. This ensured that the
recorded images were as sharp, and as well defined as possible. The lens
shutters were opened permanently, and exposure (1sec.) controlled by a paper
lens cap. Exposures were made, on the same plate, of the probe at 48 points
regularly spaced within a 1.6m X 1.5m X 0.6m volume. The resulting
photographs were clear plates with 48 sharp elliptical images. The plates
were measured ( with a repeatability of 2um) on a Zeiss Jena ZKM 01 250 D
measuring microscope, and the results processed using Granshaw's bundle
solution.
It is well known that at least three photographs are necessary for
self-calibration, so that this could not be used.A form of calibration was
achieved, however, by using a third of the points as "knowns" (ie. machine
Xyz co-ordinates accepted as error free). The resulting calibration
parameters were then held fixed in the bundle solution, and the remaining
points co-ordinated. The standard deviation of the photograph co-ordinates
was found to be 2.8)m, which corresponds to a standard deviation of 70pm
against the machine co-ordinates. This is very much better than the original
"cube" test at University College (Table 1).
Measurement of records
In the attempts described above to extend classical practices of close
range photogrammetry, some improvements have been made to the process of
measuring the records. Monocomparator measuring was used initially, but most
of the later plates have been measured visually on a Zeiss Jena ZKM 01 250D
two co-ordinate measuring microscope, equipped with Heidenhain moiré scales
reading to 0.11pm, Recently, provision has been made for automatic recording
of the readings on punched tape for direct input to the computation of the
photogrammetric solution. This will speed up the process, and will reduce the
risk of reading errors, and will justify further attention to the control of
the optical measurement process, and to the possibility of partial
automation. Specialized sensor techniques already being developed offer the
possibility of replacing the eye as the critical factor in the setting on the
record of each point. Parallel developments in the optical systems employed
in cameras will demand specialized sensors in any case, but from the evidence
presented here it may be deduced that there is already a promising
opportunity to begin to apply automatic setting and measurement to the
Specialized recordings we are obtaining from conventional cameras.
Effects of photographic plate flatnesss in photogrammetry
Conventional photogrammetry assumes that the image is formed on a
perfectly flat photographic plate, which is subsequently measured on an X-y
measuring machine or plotter. If the plate is not flat, then errors in
position will occur in regions of the plate which are not in the intended
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