<p>This study constructs a personalized sports training decision-making system using multi-agent reinforcement learning. Integrating IoT sensors for real-time data and serious games for simulation, the system utilizes a centralized training and distributed execution framework combining fuzzy logic and deep residual networks. Physiological limit thresholds are embedded as safety constraints to prevent overtraining. Based on a 12-week dataset from 120 professional athletes and results averaged over five independent runs, empirical results demonstrate that compared to traditional experience-based methods, training efficiency improved by 31.2%, injury risk decreased by 25.6%, and personalized adaptability reached 8.9 points. The MADDPG algorithm achieved a superior average reward of 4,750, converging within 150,000 rounds while handling complex state spaces effectively. This research establishes a quantifiable decision-support paradigm, shifting sports training from discrete fluctuations toward centralized stability.</p>

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Research on multi-agent reinforcement learning optimization of personalized decision-making system for sports training

  • Cuicui Guo,
  • Chengcheng Xu

摘要

This study constructs a personalized sports training decision-making system using multi-agent reinforcement learning. Integrating IoT sensors for real-time data and serious games for simulation, the system utilizes a centralized training and distributed execution framework combining fuzzy logic and deep residual networks. Physiological limit thresholds are embedded as safety constraints to prevent overtraining. Based on a 12-week dataset from 120 professional athletes and results averaged over five independent runs, empirical results demonstrate that compared to traditional experience-based methods, training efficiency improved by 31.2%, injury risk decreased by 25.6%, and personalized adaptability reached 8.9 points. The MADDPG algorithm achieved a superior average reward of 4,750, converging within 150,000 rounds while handling complex state spaces effectively. This research establishes a quantifiable decision-support paradigm, shifting sports training from discrete fluctuations toward centralized stability.