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Advanced Reasoning about Dynamical SystemsGu, Yilan 17 February 2011 (has links)
In this thesis, we study advanced reasoning about dynamical systems in a logical framework -- the situation calculus. In particular, we consider promoting the efficiency of reasoning about action
in the situation calculus from three different aspects.
First, we propose a modified situation calculus based on the two-variable predicate logic with counting quantifiers. We show that solving the projection and executability problems via regression in such language are decidable. We prove that generally these two problems are co-NExpTime-complete in the modified language. We also consider restricting the format of regressable formulas and basic action theories (BATs) further to gain better computational complexity for reasoning about action via regression. We mention possible applications to formalization of
Semantic Web services.
Then, we propose a hierarchical representation of actions based on the situation calculus to facilitate development, maintenance and elaboration of very large taxonomies of actions. We show that our axioms can be more succinct,
while still using an extended regression operator to solve the projection problem.
Moreover, such representation has significant computational advantages. For taxonomies of actions that can be represented
as finitely branching trees, the regression operator can sometimes work exponentially faster with our theories than it works with the BATs current situation calculus. We also propose a general guideline on how a taxonomy of actions can be constructed from the given set of effect axioms.
Finally, we extend the current situation calculus with the order-sorted logic. In the new formalism, we add sort theories to the usual initial theories to describe taxonomies of objects. We then investigate what is the well-sortness for BATs under such framework. We consider extending the current regression operator with well-sortness checking and unification techniques. With the modified regression,
we gain computational efficiency by terminating the regression earlier when
reasoning tasks are ill-sorted and by reducing the search spaces for well-sorted
objects. We also study that the connection between the order-sorted situation calculus and the current situation calculus.
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Advanced Reasoning about Dynamical SystemsGu, Yilan 17 February 2011 (has links)
In this thesis, we study advanced reasoning about dynamical systems in a logical framework -- the situation calculus. In particular, we consider promoting the efficiency of reasoning about action
in the situation calculus from three different aspects.
First, we propose a modified situation calculus based on the two-variable predicate logic with counting quantifiers. We show that solving the projection and executability problems via regression in such language are decidable. We prove that generally these two problems are co-NExpTime-complete in the modified language. We also consider restricting the format of regressable formulas and basic action theories (BATs) further to gain better computational complexity for reasoning about action via regression. We mention possible applications to formalization of
Semantic Web services.
Then, we propose a hierarchical representation of actions based on the situation calculus to facilitate development, maintenance and elaboration of very large taxonomies of actions. We show that our axioms can be more succinct,
while still using an extended regression operator to solve the projection problem.
Moreover, such representation has significant computational advantages. For taxonomies of actions that can be represented
as finitely branching trees, the regression operator can sometimes work exponentially faster with our theories than it works with the BATs current situation calculus. We also propose a general guideline on how a taxonomy of actions can be constructed from the given set of effect axioms.
Finally, we extend the current situation calculus with the order-sorted logic. In the new formalism, we add sort theories to the usual initial theories to describe taxonomies of objects. We then investigate what is the well-sortness for BATs under such framework. We consider extending the current regression operator with well-sortness checking and unification techniques. With the modified regression,
we gain computational efficiency by terminating the regression earlier when
reasoning tasks are ill-sorted and by reducing the search spaces for well-sorted
objects. We also study that the connection between the order-sorted situation calculus and the current situation calculus.
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