Efficient space‐filling and non‐collapsing sequential design strategies for simulation‐based modeling

Efficient space‐filling and non‐collapsing sequential design strategies for simulation‐based modeling

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Article ID: iaor20117350
Volume: 214
Issue: 3
Start Page Number: 683
End Page Number: 696
Publication Date: Nov 2011
Journal: European Journal of Operational Research
Authors: , ,
Abstract:

Simulated computer experiments have become a viable cost‐effective alternative for controlled real‐life experiments. However, the simulation of complex systems with multiple input and output parameters can be a very time‐consuming process. Many of these high‐fidelity simulators need minutes, hours or even days to perform one simulation. The goal of global surrogate modeling is to create an approximation model that mimics the original simulator, based on a limited number of expensive simulations, but can be evaluated much faster. The set of simulations performed to create this model is called the experimental design. Traditionally, one‐shot designs such as the Latin hypercube and factorial design are used, and all simulations are performed before the first model is built. In order to reduce the number of simulations needed to achieve the desired accuracy, sequential design methods can be employed. These methods generate the samples for the experimental design one by one, without knowing the total number of samples in advance. In this paper, the authors perform an extensive study of new and state‐of‐the‐art space‐filling sequential design methods. It is shown that the new sequential methods proposed in this paper produce results comparable to the best one‐shot experimental designs available right now.

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