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Sequential Subspace Search for Functional Bayesian Optimization Incorporating Experimenter Intuition

Machine Learning 2020-09-09 v1 Machine Learning

Abstract

We propose an algorithm for Bayesian functional optimisation - that is, finding the function to optimise a process - guided by experimenter beliefs and intuitions regarding the expected characteristics (length-scale, smoothness, cyclicity etc.) of the optimal solution encoded into the covariance function of a Gaussian Process. Our algorithm generates a sequence of finite-dimensional random subspaces of functional space spanned by a set of draws from the experimenter's Gaussian Process. Standard Bayesian optimisation is applied on each subspace, and the best solution found used as a starting point (origin) for the next subspace. Using the concept of effective dimensionality, we analyse the convergence of our algorithm and provide a regret bound to show that our algorithm converges in sub-linear time provided a finite effective dimension exists. We test our algorithm in simulated and real-world experiments, namely blind function matching, finding the optimal precipitation-strengthening function for an aluminium alloy, and learning rate schedule optimisation for deep networks.

Keywords

Cite

@article{arxiv.2009.03543,
  title  = {Sequential Subspace Search for Functional Bayesian Optimization Incorporating Experimenter Intuition},
  author = {Alistair Shilton and Sunil Gupta and Santu Rana and Svetha Venkatesh},
  journal= {arXiv preprint arXiv:2009.03543},
  year   = {2020}
}
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