Abstract
This article proposes a new surrogate-based multidisciplinary design optimization algorithm. The main idea is to replace each disciplinary solver involved in a non-linear multidisciplinary analysis by Gaussian process surrogate models. Although very natural, this approach creates difficulties as the non-linearity of the multidisciplinary analysis leads to a non-Gaussian model of the objective function. However, in order to follow the path of classical Bayesian optimization such as the efficient global optimization algorithm, a dedicated model of the non-Gaussian random objective function is proposed. Then, an Expected Improvement criterion is proposed to enrich the disciplinary Gaussian processes in an iterative procedure that we call efficient global multidisciplinary design optimization (EGMDO). Such an adaptive approach allows to focus the computational budget on areas of the design space relevant only with respect to the optimization problem. The obtained reduction of the number of solvers evaluations is illustrated on a classical MDO test case and on an engineering test case.
Highlights
This article addresses the numerical resolution of Multidisciplinary Design Optimization (MDO) problems
– Concerning the result obtained with the proposed Efficient Global Multidisciplinary Design Optimization (EGMDO) approach, one can note that the convergence rate of 88% is better than the one obtained using local optimizers but lower than the one obtained by Efficient Global Optimization (EGO)
This adaptive construction is classical when the objective function is modeled by a Gaussian processes (GP) since the work by Jones [14], it represents a challenge in the proposed GP based MDO context
Summary
This article addresses the numerical resolution of Multidisciplinary Design Optimization (MDO) problems. MDO deals with the optimization of complex systems involving several disciplinary solvers coupled together in a non linear system of equations called Multidisciplinary Design Analysis (MDA). Finding an optimal design that satisfies the coupling between disciplines (i.e. the equilibrium of the multidisciplinary system) generally needs a large number of disciplinary solver evaluations. To tackle this issue several formulations of the MDO problem have been proposed. Purpose of the method developed in this article is to solve unconstrained MDO problems of the form, find z ∈ Z such as z arg min z∈Z fobj (z, yc(obj) (z)) (3).
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