Related papers: Pick-to-Learn for Systems and Control: Data-driven Synthesis with State-of-the-art Safety Guarantees

Pick-to-Learn for Systems and Control: Data-driven Synthesis with State-of-the-art Safety Guarantees

URL: http://arxiv.org/abs/2512.04781v1
Date: Thu, 04 Dec 2025 13:27:11 GMT
Title: Pick-to-Learn for Systems and Control: Data-driven Synthesis with State-of-the-art Safety Guarantees
Authors: Dario Paccagnan, Daniel Marks, Marco C. Campi, Simone Garatti,
Abstract summary: Pick-to-Learn (P2L) is a framework that allows any data-driven control method to be equipped with state-of-the-art safety and performance guarantees.<n>P2L enables the use of all available data to jointly synthesize and certify the design, eliminating the need to set aside data for calibration or validation.
Score: 7.548053815192648
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Data-driven methods have become paramount in modern systems and control problems characterized by growing levels of complexity. In safety-critical environments, deploying these methods requires rigorous guarantees, a need that has motivated much recent work at the interface of statistical learning and control. However, many existing approaches achieve this goal at the cost of sacrificing valuable data for testing and calibration, or by constraining the choice of learning algorithm, thus leading to suboptimal performances. In this paper, we describe Pick-to-Learn (P2L) for Systems and Control, a framework that allows any data-driven control method to be equipped with state-of-the-art safety and performance guarantees. P2L enables the use of all available data to jointly synthesize and certify the design, eliminating the need to set aside data for calibration or validation purposes. In presenting a comprehensive version of P2L for systems and control, this paper demonstrates its effectiveness across a range of core problems, including optimal control, reachability analysis, safe synthesis, and robust control. In many of these applications, P2L delivers designs and certificates that outperform commonly employed methods, and shows strong potential for broad applicability in diverse practical settings.

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