Abstract
The firefighter problem (FFP) is a combinatorial problem requiring the allocation of ‘firefighters’ to nodes in a graph in order to protect the nodes from fire (or other threat) spreading along the edges. In the original formulation the problem is deterministic: fire spreads from burning nodes to adjacent, unprotected nodes with certainty.
In this paper a nondeterministic version of the FFP is introduced where fire spreads to unprotected nodes with a probability Psp (lower than 1) per time step. To account for the stochastic nature of the problem the simheuristic approach is used in which a metaheuristic algorithm uses simulation to evaluate candidate solutions. Also, it is assumed that the optimization has to be performed in a limited amount of time available for computations in each time step.
In this paper online and offline optimization using a multipopulation evolutionary algorithm is performed and the results are compared to various heuristics that determine how to place firefighters. Given the time-constrained nature of the problem we also investigate for how long to simulate the spread of fire when evaluating solutions produced by an evolutionary algorithm. Results generally indicate that the evolutionary algorithm proposed is effective for Psp≥0.7 , whereas for lower probabilities the heuristics are competitive suggesting that more work on hybrids is warranted.
In this paper a nondeterministic version of the FFP is introduced where fire spreads to unprotected nodes with a probability Psp (lower than 1) per time step. To account for the stochastic nature of the problem the simheuristic approach is used in which a metaheuristic algorithm uses simulation to evaluate candidate solutions. Also, it is assumed that the optimization has to be performed in a limited amount of time available for computations in each time step.
In this paper online and offline optimization using a multipopulation evolutionary algorithm is performed and the results are compared to various heuristics that determine how to place firefighters. Given the time-constrained nature of the problem we also investigate for how long to simulate the spread of fire when evaluating solutions produced by an evolutionary algorithm. Results generally indicate that the evolutionary algorithm proposed is effective for Psp≥0.7 , whereas for lower probabilities the heuristics are competitive suggesting that more work on hybrids is warranted.
Original language | Undefined |
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Title of host publication | Applications of Evolutionary Computation |
DOIs | |
Publication status | Published - 2 Apr 2016 |