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Main Author: Charalambous, Christos
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.10342
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author Charalambous, Christos
author_facet Charalambous, Christos
contents This study introduces an agent-based model to study how regret, uncertainty, and social norms interact to shape vaccination behavior during epidemics. The model integrates three behavioral mechanisms, anticipated regret, evolving norms, and uncertainty-dependent trust, within a unified learning framework. Grounded in psychology and behavioral economics, it captures how individuals make probabilistic choices influenced by material payoffs, fear, trust, and social approval. Simulations of the Susceptible-Infected-Recovered process show that collective outcomes are best when agents display an intermediate level of rationality; they deliberate enough to respond to risk but remain flexible enough to adapt, avoiding the instability of both random and overly rigid decision-making. Regret exerts a dual influence; moderate levels encourage adaptive self-correction, while excessive regret or greed destabilize choices. Uncertainty has a similarly non-linear effect; moderate ambiguity promotes caution, but too much uncertainty disrupts coordination. Social norms restore cooperation by compensating for incomplete information. Personal norms guide behavior when individuals have reliable information and feel confident in their judgments. Injunctive norms-signals of others' approval-become more influential under uncertainty, while descriptive norms, which arise from observing others' actions, provide informational cues that help people decide what to do when direct knowledge is limited. Overall, the model provides a psychologically grounded, computationally explicit account of how emotion, cognition, and social norms govern preventive behavior during epidemics.
format Preprint
id arxiv_https___arxiv_org_abs_2511_10342
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Regret, Uncertainty, and Bounded Rationality in Norm-Driven Decisions
Charalambous, Christos
Physics and Society
Adaptation and Self-Organizing Systems
Computational Physics
This study introduces an agent-based model to study how regret, uncertainty, and social norms interact to shape vaccination behavior during epidemics. The model integrates three behavioral mechanisms, anticipated regret, evolving norms, and uncertainty-dependent trust, within a unified learning framework. Grounded in psychology and behavioral economics, it captures how individuals make probabilistic choices influenced by material payoffs, fear, trust, and social approval. Simulations of the Susceptible-Infected-Recovered process show that collective outcomes are best when agents display an intermediate level of rationality; they deliberate enough to respond to risk but remain flexible enough to adapt, avoiding the instability of both random and overly rigid decision-making. Regret exerts a dual influence; moderate levels encourage adaptive self-correction, while excessive regret or greed destabilize choices. Uncertainty has a similarly non-linear effect; moderate ambiguity promotes caution, but too much uncertainty disrupts coordination. Social norms restore cooperation by compensating for incomplete information. Personal norms guide behavior when individuals have reliable information and feel confident in their judgments. Injunctive norms-signals of others' approval-become more influential under uncertainty, while descriptive norms, which arise from observing others' actions, provide informational cues that help people decide what to do when direct knowledge is limited. Overall, the model provides a psychologically grounded, computationally explicit account of how emotion, cognition, and social norms govern preventive behavior during epidemics.
title Regret, Uncertainty, and Bounded Rationality in Norm-Driven Decisions
topic Physics and Society
Adaptation and Self-Organizing Systems
Computational Physics
url https://arxiv.org/abs/2511.10342