Alternating Bi-Objective Optimization for Explainable Neuro-Fuzzy Systems
Abstract
Fuzzy systems show strong potential in explainable AI due to their rule-based architecture and linguistic variables. Existing approaches navigate the accuracy-explainability trade-off either through evolutionary multi-objective optimization (MOO), which is computationally expensive, or gradient-based scalarization, which cannot recover non-convex Pareto regions. We propose X-ANFIS, an alternating bi-objective gradient-based optimization scheme for explainable adaptive neuro-fuzzy inference systems. Cauchy membership functions are used for stable training under semantically controlled initializations, and a differentiable explainability objective is introduced and decoupled from the performance objective through alternating gradient passes. Validated in approximately 5,000 experiments on nine UCI regression datasets, X-ANFIS consistently achieves target distinguishability while maintaining competitive predictive accuracy, recovering solutions beyond the convex hull of the MOO Pareto front.
Cite
@article{arxiv.2602.19253,
title = {Alternating Bi-Objective Optimization for Explainable Neuro-Fuzzy Systems},
author = {Qusai Khaled and Uzay Kaymak and Laura Genga},
journal= {arXiv preprint arXiv:2602.19253},
year = {2026}
}
Comments
Accepted at IEEE Conference on Artificial Intelligence 2026 (IEEE CAI 2026)