„7 m
effects on the accuracies. Designs using linear encoders lend them-
selves well to this separation and allow for easy adherence to Abbe's
principle. The universality is limited by the size of the carriage and
the design of the optics. The first limits the maximal format of the
images and the second one influences the flexibility of the procedures
in man-machine systems and defines the geometrical characteristics of
the images that can be processed. It should be noted that the latter
limitations are actually not the consequence of the inability of the
analytical instrument to cope with a particular image geometry but
solely due to the inability of the operator to accommodate larger
differences in the orientation of epipolar lines and scale differences
between conjugate images. In other words, an analytical instrument that
has the four basic positioning devices will be able to correctly address
the corresponding conjugate points in any type of images (as long as
their geometry is defined), but the operator will not be able in some
cases to fuse the related image segments into a stereoscopic model.
Consequently the interface of a fully universal man-machine analytical
system has eight channels for control of four carriage positioning
devices and four positioning devices for optical magnification and
rotation of images (e.g. Zoom-optics and Dove prisms). Considering the
high precision required, the control of the first four channels must
have a closed feed-back loop. Each of these feed-back loops compares
the desired and the actual state of the device, e.g. an input and a
status register. These two registers are compared at short time-
intervals and the difference between their contents will determine the
action of the motors [2]. To approximate as closely as possible the
desired deterministic behavior of these devices their response time At
has to be shorter than the cycling time AT of the real-time programs.
It is evident that AT < At has no practical value, and that state S of
a channel at time t + At depends only on input I and state S at time t,
i.e. S, PALE e(1, ; S,); (the knowledge of the state at time t - At
is irrelevant at time t + At, and the input at t + At will not influence
the state at t + At).
The other four channels do not require controls as stringent
as the first four ones, since about 10% difference in image scales, and
about 1° difference in image rotation may be tolerated by the operator.
Consequently they may be designed as open loop channels. The time for
transfer of information between the computer and the registers of all
eight channels can be easily kept below 100 usec, thanks to the facility
for fast communication between the computer and the peripherals inherent
in the architecture of most mini-computers. This short transfer time
helps considerably when writing real-time programs. It is worth noting
that the design of interfaces is completely independent from the mathe-
matical model of a particular transformation performed by a real-time
program. This characteristic of the interface design contributes to the
universality of analytical instruments since as long as a functional
relationship between the variables can be mathematically defined, that
is as long as a real-time program can be coded, the positioning devices
will simulate the underlying geometry. Additional channels for the
control of auxiliary devices (e.g. plotting table) are normally included
in the interface. Their number, which depends on the general configura-
tion of the system, is limited by the required overall response time of
the system.
