Bayesian Optimization (BO) is a sample efficient approach for approximating the global optimum of black-box and computationally expensive optimization problems which has proved its effectiveness in a wide range of engineering and machine learning problems. A limiting factor in its applications is the difficulty of scaling over 15–20 dimensions. It has been remarked that global optimization problems often have a lower intrinsic dimensionality which can be exploited to construct a feature mapping the original problem into low dimension manifold. In this paper we take a novel approach mapping the original problem into a space of discrete probability distributions endowed with a Wasserstein metric. In this new approach both the Gaussian process model and the acquisition function work in a 1-dimensional Wasserstein (WST) space. The results in the WST space are then mapped back to the original space using a neural network. Computational results show that, at least for high dimension additive test functions, the exploration in the Wasserstein space is significantly more effective.
Candelieri, A., Ponti, A., Archetti, F. (2022). Bayesian Optimization in Wasserstein Spaces. In Learning and Intelligent Optimization 16th International Conference, LION 16, Milos Island, Greece, June 5–10, 2022, Revised Selected Papers (pp.248-262). Springer Science and Business Media Deutschland GmbH [10.1007/978-3-031-24866-5_19].
Bayesian Optimization in Wasserstein Spaces
Candelieri, A
;Ponti, A;Archetti, F
2022
Abstract
Bayesian Optimization (BO) is a sample efficient approach for approximating the global optimum of black-box and computationally expensive optimization problems which has proved its effectiveness in a wide range of engineering and machine learning problems. A limiting factor in its applications is the difficulty of scaling over 15–20 dimensions. It has been remarked that global optimization problems often have a lower intrinsic dimensionality which can be exploited to construct a feature mapping the original problem into low dimension manifold. In this paper we take a novel approach mapping the original problem into a space of discrete probability distributions endowed with a Wasserstein metric. In this new approach both the Gaussian process model and the acquisition function work in a 1-dimensional Wasserstein (WST) space. The results in the WST space are then mapped back to the original space using a neural network. Computational results show that, at least for high dimension additive test functions, the exploration in the Wasserstein space is significantly more effective.
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
