A Relaxed Optimization Approach for Cardinality-Constrained Portfolio Optimization
Abstract
A cardinality-constrained portfolio caps the number of stocks to be traded across and within groups or sectors. These limitations arise from real-world scenarios faced by fund managers, who are constrained by transaction costs and client preferences as they seek to maximize return and limit risk. We develop a new approach to solve cardinality-constrained portfolio optimization problems, extending both Markowitz and conditional value at risk (CVaR) optimization models with cardinality constraints. We derive a continuous relaxation method for the NP-hard objective, which allows for very efficient algorithms with standard convergence guarantees for nonconvex problems. For smaller cases, where brute force search is feasible to compute the globally optimal cardinality- constrained portfolio, the new approach finds the best portfolio for the cardinality-constrained Markowitz model and a very good local minimum for the cardinality-constrained CVaR model. For higher dimensions, where brute-force search is prohibitively expensive, we find feasible portfolios that are nearly as efficient as their non-cardinality constrained counterparts.
Keywords
Cite
@article{arxiv.1810.10563,
title = {A Relaxed Optimization Approach for Cardinality-Constrained Portfolio Optimization},
author = {Jize Zhang and Tim Leung and Aleksandr Aravkin},
journal= {arXiv preprint arXiv:1810.10563},
year = {2018}
}
Comments
8 pages, 5 figures