lt than measuring
microscopic scale.
h illuminated tar-
or positioning the
Jontrast transmis-
'anning the aerial
quivalent appara-
aréchal points out
e of lenses.
em, but they have
. The descriptions
presentative tech-
ies sinusoidally in
view inset below.
ne slit S forming
ut is amplified at
The photocell can
tions.
For photographie
10u. For accurate
traversing of the
uch fine working,
n S and the focus
jjective is so good
nally be neglected.
e, and for televi-
and the work can
f targets, forming
at constant speed
form is shown in
"he D.C. amplifier
oscilloscope as a
THE PHOTOGRAPHIC IMAGE, BROCK 19
trace of amplitude against frequency. The square wave response can be corrected to sine
wave if necessary.
A different group of methods dispenses with periodic gratings of any kind and
analyses the image of a fine slit or series of slits. In a method used for testing television
lenses in England the test object in Fig. 8 is replaced by a single illuminated slit, and
the intensity distribution in the image of this is measured by traversing the photomulti-
plier slit across it. A perfect image would be a line of zero width, but the actual image
is broadened as suggested in Fig. 15. The Fourier transform of this curve gives the
contrast transmission. Graphical and electro-mechanical methods for performing the
transform have been devised. In another method using slits, several are mounted around
a rotating drum and imaged via a collimator and the test lens on to a fixed search slit.
As the moving slit images sweep past the search slit they generate a series of pulsed
signals. Such pulses contain the fundamental frequency, corresponding to the number
of slits and the rate of rotation, plus all the harmonics at equal amplitude up to very
high orders. The resulting complex wave-form from the photomultiplier can be analysed
electronically (by a “multiplication” process) for
measurement of the relative amplitude of all the
frequencies in the image cast by the lens. The
first of these slit methods is simpler and probably
more accurate, but requires mathematical anal-
ysis of each energy distribution curve before the
INTENSITY
DISTANCE
Fig, 14. Progressive-frequency Fig.15. Intensity distribution in
line test-object. the image of a fine slit.
contrast transmission can be derived. The second method will give results quickly, but at
the cost of complex electronics.
As yet, no accurate method for determining contrast transmission competes in sim-
plicity with the resolution test. With the improvement of techniques, however, and in
particular the automation of the process as far as possible, this situation will change,
and the difficulty will become that of assimilating the information rather than ob-
taining it.
Some of the practical difficulties are concerned with the reproducibility and relia-
bility of electronic amplifiers. These would be less serious in the application of frequency
response technique to the focusing of cameras. The object of the focusing operation is
then to obtain maximum response at some definite frequency chosen to suit the film in
use and the kind of scene photographed. Suppose this to be 20 lines per mm, a target
giving this frequency is chosen and the focus varied for maximum response; questions
of repeatability do not arise and the operation could be much quicker than a photographic
determination.
Some difficulties in the way of measuring film contrast transmission have already
been mentioned. Subject to these, the methods can be essentially the same as for lenses.
The method described for measuring threshold contrast as a function of frequency, using
sinusoidal test objects, could be adapted to contrast transmission measurement by micro-
densitometry on the image. Alternately, micro-densitometry on a slit image recorded by
the emulsion, followed by the transform operations on the transparency distribution curve,
could be used.
