English

Inequalities for Optimization of Classification Algorithms: A Perspective Motivated by Diagnostic Testing

Machine Learning 2025-08-05 v1 Machine Learning Probability

Abstract

Motivated by canonical problems in medical diagnostics, we propose and study properties of an objective function that uniformly bounds uncertainties in quantities of interest extracted from classifiers and related data analysis tools. We begin by adopting a set-theoretic perspective to show how two main tasks in diagnostics -- classification and prevalence estimation -- can be recast in terms of a variation on the confusion (or error) matrix P{\boldsymbol {\rm P}} typically considered in supervised learning. We then combine arguments from conditional probability with the Gershgorin circle theorem to demonstrate that the largest Gershgorin radius ρm\boldsymbol \rho_m of the matrix IP\mathbb I-\boldsymbol {\rm P} (where I\mathbb I is the identity) yields uniform error bounds for both classification and prevalence estimation. In a two-class setting, ρm\boldsymbol \rho_m is minimized via a measure-theoretic ``water-leveling'' argument that optimizes an appropriately defined partition UU generating the matrix P{\boldsymbol {\rm P}}. We also consider an example that illustrates the difficulty of generalizing the binary solution to a multi-class setting and deduce relevant properties of the confusion matrix.

Keywords

Cite

@article{arxiv.2508.01065,
  title  = {Inequalities for Optimization of Classification Algorithms: A Perspective Motivated by Diagnostic Testing},
  author = {Paul N. Patrone and Anthony J. Kearsley},
  journal= {arXiv preprint arXiv:2508.01065},
  year   = {2025}
}
R2 v1 2026-07-01T04:30:17.440Z