Learning-Based Robust Bayesian Persuasion with Conformal Prediction Guarantees
Abstract
Classical Bayesian persuasion assumes that senders fully understand how receivers form beliefs and make decisions--an assumption that rarely holds when receivers possess private information or exhibit non-Bayesian behavior. In this paper, we develop a learning-based framework that integrates neural networks with conformal prediction to achieve robust persuasion under uncertainty about receiver belief formation. The proposed neural architecture learns end-to-end mappings from receiver observations and sender signals to action predictions, eliminating the need to identify belief mechanisms explicitly. Conformal prediction constructs finite-sample valid prediction sets with provable marginal coverage, enabling principled, distribution-free robust optimization. We establish exact coverage guarantees for the data-generating policy and derive bounds on coverage degradation under policy shifts. Furthermore, we provide neural network approximation and estimation error bounds, with sample complexity , where denotes the effective network dimension, and finite-sample lower bounds on the sender's expected utility. Numerical experiments on smart-grid energy management illustrate the framework's robustness.
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Cite
@article{arxiv.2511.06223,
title = {Learning-Based Robust Bayesian Persuasion with Conformal Prediction Guarantees},
author = {Heeseung Bang and Andreas A. Malikopoulos},
journal= {arXiv preprint arXiv:2511.06223},
year = {2025}
}
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8 pages