English

Portfolio Optimization for Cointelated Pairs: SDEs vs. Machine Learning

Portfolio Management 2019-10-29 v2 Machine Learning

Abstract

With the recent rise of Machine Learning as a candidate to partially replace classic Financial Mathematics methodologies, we investigate the performances of both in solving the problem of dynamic portfolio optimization in continuous-time, finite-horizon setting for a portfolio of two assets that are intertwined. In Financial Mathematics approach we model the asset prices not via the common approaches used in pairs trading such as a high correlation or cointegration, but with the cointelation model that aims to reconcile both short-term risk and long-term equilibrium. We maximize the overall P&L with Financial Mathematics approach that dynamically switches between a mean-variance optimal strategy and a power utility maximizing strategy. We use a stochastic control formulation of the problem of power utility maximization and solve numerically the resulting HJB equation with the Deep Galerkin method. We turn to Machine Learning for the same P&L maximization problem and use clustering analysis to devise bands, combined with in-band optimization. Although this approach is model agnostic, results obtained with data simulated from the same cointelation model as FM give an edge to ML.

Keywords

Cite

@article{arxiv.1812.10183,
  title  = {Portfolio Optimization for Cointelated Pairs: SDEs vs. Machine Learning},
  author = {Babak Mahdavi-Damghani and Konul Mustafayeva and Stephen Roberts and Cristin Buescu},
  journal= {arXiv preprint arXiv:1812.10183},
  year   = {2019}
}
R2 v1 2026-06-23T06:55:59.139Z