Operator-counting is a recently developed framework for analysing and integrating many state-of-the-art heuristics for planning using Linear Programming. In cost-optimal planning only the objective value of these heuristics is traditionally used to guide the search. However the primal solution, i.e. the operator counts, contains useful information. We exploit this information using a SAT-based approach which given an operator-count, either finds a valid plan; or generates a generalized landmark constraint violated by that count. We show that these generalized landmarks can be used to encode the perfect heuristic, h*, as a Mixed Integer Program. Our most interesting experimental result is that finding or refuting a sequence for an operator-c...
Branching and lower bounds are two key notions in heuristic search and combinatorial optimization. B...
It has been shown recently that planning problems are easier to solve when they are cast as model fi...
Symbolic search, using Binary Decision Diagrams (BDDs) to represent sets of states, is a competitive...
Operator-counting is a recently developed framework for analysing and integrating many state-of-the-...
A search algorithm with an admissible heuristic function is the most common approach to optimally so...
Operator cost partitioning is a well-known technique to make admissible heuristics additive by distr...
Recent work by Kautz et al. provides tantalizing evidence that large, classical planning problems ma...
Many recent planning heuristics are based on LP optimization. However, planning experts mostly use L...
For the past 25 years, heuristic search has been used to solve domain-independent probabilistic plan...
Most of the key computational ideas in planning have been developed for simple planning languages wh...
Simplifying classical planning tasks by removing operators while preserving at least one optimal sol...
In the planning-as-SAT paradigm there have been numerous recent developments towards improving the s...
This paper presents the Operator Distribution Method for Parallel Planning (ODMP), a parallelization...
Cost partitioning is a method for admissibly combining a set of admissible heuristic estimators by d...
In recent work we showed that planning problems can be efficiently solved by general propositional s...
Branching and lower bounds are two key notions in heuristic search and combinatorial optimization. B...
It has been shown recently that planning problems are easier to solve when they are cast as model fi...
Symbolic search, using Binary Decision Diagrams (BDDs) to represent sets of states, is a competitive...
Operator-counting is a recently developed framework for analysing and integrating many state-of-the-...
A search algorithm with an admissible heuristic function is the most common approach to optimally so...
Operator cost partitioning is a well-known technique to make admissible heuristics additive by distr...
Recent work by Kautz et al. provides tantalizing evidence that large, classical planning problems ma...
Many recent planning heuristics are based on LP optimization. However, planning experts mostly use L...
For the past 25 years, heuristic search has been used to solve domain-independent probabilistic plan...
Most of the key computational ideas in planning have been developed for simple planning languages wh...
Simplifying classical planning tasks by removing operators while preserving at least one optimal sol...
In the planning-as-SAT paradigm there have been numerous recent developments towards improving the s...
This paper presents the Operator Distribution Method for Parallel Planning (ODMP), a parallelization...
Cost partitioning is a method for admissibly combining a set of admissible heuristic estimators by d...
In recent work we showed that planning problems can be efficiently solved by general propositional s...
Branching and lower bounds are two key notions in heuristic search and combinatorial optimization. B...
It has been shown recently that planning problems are easier to solve when they are cast as model fi...
Symbolic search, using Binary Decision Diagrams (BDDs) to represent sets of states, is a competitive...