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Main Authors: Fonseca, Yesid, Ríos, Manuel S., Quijano, Nicanor, Giraldo, Luis F.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.12548
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author Fonseca, Yesid
Ríos, Manuel S.
Quijano, Nicanor
Giraldo, Luis F.
author_facet Fonseca, Yesid
Ríos, Manuel S.
Quijano, Nicanor
Giraldo, Luis F.
contents Patch foraging involves the deliberate and planned process of determining the optimal time to depart from a resource-rich region and investigate potentially more beneficial alternatives. The Marginal Value Theorem (MVT) is frequently used to characterize this process, offering an optimality model for such foraging behaviors. Although this model has been widely used to make predictions in behavioral ecology, discovering the computational mechanisms that facilitate the emergence of optimal patch-foraging decisions in biological foragers remains under investigation. Here, we show that artificial foragers equipped with learned world models naturally converge to MVT-aligned strategies. Using a model-based reinforcement learning agent that acquires a parsimonious predictive representation of its environment, we demonstrate that anticipatory capabilities, rather than reward maximization alone, drive efficient patch-leaving behavior. Compared with standard model-free RL agents, these model-based agents exhibit decision patterns similar to many of their biological counterparts, suggesting that predictive world models can serve as a foundation for more explainable and biologically grounded decision-making in AI systems. Overall, our findings highlight the value of ecological optimality principles for advancing interpretable and adaptive AI.
format Preprint
id arxiv_https___arxiv_org_abs_2512_12548
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle World Models Unlock Optimal Foraging Strategies in Reinforcement Learning Agents
Fonseca, Yesid
Ríos, Manuel S.
Quijano, Nicanor
Giraldo, Luis F.
Artificial Intelligence
Machine Learning
Patch foraging involves the deliberate and planned process of determining the optimal time to depart from a resource-rich region and investigate potentially more beneficial alternatives. The Marginal Value Theorem (MVT) is frequently used to characterize this process, offering an optimality model for such foraging behaviors. Although this model has been widely used to make predictions in behavioral ecology, discovering the computational mechanisms that facilitate the emergence of optimal patch-foraging decisions in biological foragers remains under investigation. Here, we show that artificial foragers equipped with learned world models naturally converge to MVT-aligned strategies. Using a model-based reinforcement learning agent that acquires a parsimonious predictive representation of its environment, we demonstrate that anticipatory capabilities, rather than reward maximization alone, drive efficient patch-leaving behavior. Compared with standard model-free RL agents, these model-based agents exhibit decision patterns similar to many of their biological counterparts, suggesting that predictive world models can serve as a foundation for more explainable and biologically grounded decision-making in AI systems. Overall, our findings highlight the value of ecological optimality principles for advancing interpretable and adaptive AI.
title World Models Unlock Optimal Foraging Strategies in Reinforcement Learning Agents
topic Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2512.12548