Aeronautical and marine casualty statistics indicate that the human
being, when under stress or at times of peak load, can be a poor
co-ordinator of the information available to him, particularly when
that information is from a number of different source:, as is often the
case in modern ships. Integration and co-ordination of information and
its useful application in a closed loop feedback system can reduce the
probability of accident as has already been demonstrated in the case of
automatic landing systems for aircraft.
This thesis describes the development of a digital filter/estimator for
use in conjunction with an optimal controller in the automatic guidance
of large ships in the approaches to a port.
A non-linear mathematical model of a ship is developed and validated by
comparison with data from an actual ship. The model is then used in
digital computer simulations of the passage of a twin screw car ferry
into the Port of Plymouth. The simulations show that the control and
guidance system is capable of safely navigating the vessel along the
predetermined track through noisy measurements of position, course and
speed,
A reduced non-linear digital simulation model is then used in the
design of a minimum variance filter suitable for installation in a
physical model of the car ferry. Tests with this physical model
confirm the earlier full scale digital computer simulations, showing
that a minimum variance filter is capable of giving very good estimates
of the measured states, even though the measurement subsystems are
unable to give accurate information because of noise. In the event of
a malfunction of one or more of these measurement systems it is shown
that the filter continues to give good estimates of all the states.
Date of Award | 1984 |
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Original language | English |
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Awarding Institution | |
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A DIGITAL FILTER/ESTIMATOR FOR THE CONTROL OF LARGE SHIPS IN CONFINED WATERS
Dove, M. J. (Author). 1984
Student thesis: PhD