Biased Mean Quadrangle and Applications
Abstract
This paper introduces \emph{biased mean regression}, estimating the \emph{biased mean}, i.e., , where . The approach addresses a fundamental statistical problem that covers numerous applications. For instance, it can be used to estimate factors driving portfolio loss exceeding the expected loss by a specified amount (e.g., x=\10 billionx=0$; (ii) in portfolio optimization, minimizing \emph{superexpectation risk}, associated with the superexpectation error, is equivalent to CVaR optimization. The approach is computationally attractive, as minimizing the superexpectation error reduces to linear programming (LP), thereby offering algorithmic and modeling advantages. It is also a good alternative to ordinary least squares (OLS) regression. The approach is based on the \emph{Risk Quadrangle} (RQ) framework, which links four stochastic functionals -- error, regret, risk, and deviation -- through a statistic. For the biased mean quadrangle, the statistic is the biased mean. We study properties of the new quadrangle, such as \emph{subregularity}, and establish its relationship to the quantile quadrangle. Numerical experiments confirm the theoretical statements and illustrate the practical implications.
Cite
@article{arxiv.2603.26901,
title = {Biased Mean Quadrangle and Applications},
author = {Anton Malandii and Stan Uryasev},
journal= {arXiv preprint arXiv:2603.26901},
year = {2026}
}