English

Generalising Random Forest Parameter Optimisation to Include Stability and Cost

Machine Learning 2018-07-03 v2 Computers and Society Machine Learning

Abstract

Random forests are among the most popular classification and regression methods used in industrial applications. To be effective, the parameters of random forests must be carefully tuned. This is usually done by choosing values that minimize the prediction error on a held out dataset. We argue that error reduction is only one of several metrics that must be considered when optimizing random forest parameters for commercial applications. We propose a novel metric that captures the stability of random forests predictions, which we argue is key for scenarios that require successive predictions. We motivate the need for multi-criteria optimization by showing that in practical applications, simply choosing the parameters that lead to the lowest error can introduce unnecessary costs and produce predictions that are not stable across independent runs. To optimize this multi-criteria trade-off, we present a new framework that efficiently finds a principled balance between these three considerations using Bayesian optimisation. The pitfalls of optimising forest parameters purely for error reduction are demonstrated using two publicly available real world datasets. We show that our framework leads to parameter settings that are markedly different from the values discovered by error reduction metrics.

Keywords

Cite

@article{arxiv.1706.09865,
  title  = {Generalising Random Forest Parameter Optimisation to Include Stability and Cost},
  author = {C. H. Bryan Liu and Benjamin Paul Chamberlain and Duncan A. Little and Angelo Cardoso},
  journal= {arXiv preprint arXiv:1706.09865},
  year   = {2018}
}

Comments

To appear in ECML-PKDD 2017

R2 v1 2026-06-22T20:33:41.420Z