State-of-the-art planners often exhibit substantial runtime variation, making it useful to be able to efficiently predict how long a given planner will take to run on a given instance. In other areas of AI, such needs are met by building so-called empirical performance models (EPMs), statistical models derived from sets of problem instances and performance observations. Historically, such models have been less accurate for predicting the running times of planners. A key hurdle has been a relative weakness in instance features for characterizing instances: mappings from problem instances to real numbers that serve as the starting point for learning an EPM. We propose a new, extensive set of instance features for planning, and investigate its...
We investigate the applicability of an existing framework for algorithm runtime prediction to the fi...
One of the latest advances for solving classical planning prob-lems is the development of new approa...
When designing state-of-the-art, domain-independent plan-ning systems, many decisions have to be mad...
State-of-the-art planners often exhibit substantial runtime vari-ation, making it useful to be able ...
We describe a large scale study of planners and their performance: 28 planners on 4726 benchmark pro...
In recent work we showed that models constructed from plan-ner performance data over a large suite o...
Empirical performance models play an important role in the development of planning portfolios that m...
Empirical performance models play an important role in the development of planning portfolios that m...
Perhaps surprisingly, it is possible to predict how long an algorithm will take to run on a previous...
The acquisition and use of macro actions has been shown to be effective in improving the speed of AI...
Recent trends in planning research have led to empirical comparison becoming com-monplace. The eld h...
The use of computational complexity in planning, and in AI in general, has always been a disputed to...
We investigate the applicability of an existing framework for algorithm runtime prediction to the fi...
We investigate learning heuristics for domainspecific planning. Prior work framed learning a heurist...
Outlines an experimental machine learning implementation, called `FM', that applies both explanation...
We investigate the applicability of an existing framework for algorithm runtime prediction to the fi...
One of the latest advances for solving classical planning prob-lems is the development of new approa...
When designing state-of-the-art, domain-independent plan-ning systems, many decisions have to be mad...
State-of-the-art planners often exhibit substantial runtime vari-ation, making it useful to be able ...
We describe a large scale study of planners and their performance: 28 planners on 4726 benchmark pro...
In recent work we showed that models constructed from plan-ner performance data over a large suite o...
Empirical performance models play an important role in the development of planning portfolios that m...
Empirical performance models play an important role in the development of planning portfolios that m...
Perhaps surprisingly, it is possible to predict how long an algorithm will take to run on a previous...
The acquisition and use of macro actions has been shown to be effective in improving the speed of AI...
Recent trends in planning research have led to empirical comparison becoming com-monplace. The eld h...
The use of computational complexity in planning, and in AI in general, has always been a disputed to...
We investigate the applicability of an existing framework for algorithm runtime prediction to the fi...
We investigate learning heuristics for domainspecific planning. Prior work framed learning a heurist...
Outlines an experimental machine learning implementation, called `FM', that applies both explanation...
We investigate the applicability of an existing framework for algorithm runtime prediction to the fi...
One of the latest advances for solving classical planning prob-lems is the development of new approa...
When designing state-of-the-art, domain-independent plan-ning systems, many decisions have to be mad...