This thesis considers the relationship between collision regulations and an automatic
collision avoidance system (ACAS).
Automation of ship operations is increasingly common. The automation of the
collision avoidance task may have merit on grounds of reduced manual workload
and the elimination of human error. Work to date by engineers and computer
programmers has focused on modelling the requirements of the current collision
regulations. This thesis takes a new approach and indicates that legislative change is
a necessary precursor to the implementation of a fully automatic collision avoidance
system.
A descriptive analysis has been used to consider the nature of the collision
avoidance problem and the nature of rules as a solution. The importance of
coordination between vessels is noted and three requirements for coordination are
established. These are a mutual perception of: risk, the strategy to be applied, and
the point of manoeuvre. The use of rules to achieve coordination are considered.
The analysis indicates that the current collision regulations do not provide the
means to coordinate vessels.
A review of current and future technology that may be applied to the collision
avoidance problem has been made. Several ACAS scenarios are contrived. The
compatibility of the scenarios and the current collision regulations is considered. It
is noted that both machine sensors and processors affect the ability to comply with
the rules.
The case is made for judicial recognition of a discrete rule-base for the sake of an
ACAS. This leads to the prospect of quantified collision regulations for application
by mariners.
A novel rule-base to match a pm1icular ACAS scenario has been devised. The rules
are simple and brief. They avoid inputs dependent on vision and visibility, and meet
all the aforementioned coordination requirements. Their application by mariners to
two-vessel open sea, encounters was tested on a navigation simulator. The
experimental testing of such a rule-base is unique.
Mariners were given experience of applying the rule-base in certain circumstances
and asked by questionnaire what their agreeable action would be. This was
compared with their usual action. While the number of experiments was small, an
indication was given of the impm1ant issues in applying a quantified rule-base.
Aspects identified for fm1her study include the testing of rule base elements in
isolation, and the use of quantified rules in multi-ship and confined water
encounters.
Date of Award | 1996 |
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Original language | English |
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Awarding Institution | |
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INTERNATIONAL COLLISION REGULATIONS FOR AUTOMATIC COLLISION AVOIDANCE
PERKINS, C. J. (Author). 1996
Student thesis: PhD