Multi-sensor fusion for AI-driven behavior planning in medical applications
Chang Jianming, XU Yan-ling, Li Li, Mianhua Wu, Lulu Wang
- 发表年份
- 2025
- 引用次数
- 2
- 访问权限
- 开放获取
摘要
Introduction Multi-sensor fusion has emerged as a transformative approach in AI-driven behavior planning for medical applications, significantly enhancing perception, decision-making, and adaptability in complex and dynamic environments. Traditional fusion methods primarily rely on deterministic techniques such as Kalman Filters or rule-based decision models. While effective in structured settings, these methods often struggle to maintain robustness under sensor degradation, occlusions, and environmental uncertainties. Such limitations pose critical challenges for real-time decision-making in medical applications, where precision, reliability, and adaptability are paramount. Methods To address these challenges, we propose an Adaptive Probabilistic Fusion Network (APFN), a novel framework that dynamically integrates multi-modal sensor data based on estimated sensor reliability and contextual dependencies. Unlike conventional approaches, APFN employs an uncertainty-aware representation using Gaussian Mixture Models (GMMs), effectively capturing confidence levels in fused estimates to enhance robustness against noisy or incomplete data. We incorporate an attention-driven deep fusion mechanism to extract high-level spatial-temporal dependencies, improving interpretability and adaptability. By dynamically weighing sensor inputs and optimizing feature selection, APFN ensures superior decision-making under varying medical conditions. Results We rigorously evaluate our approach on multiple large-scale medical datasets, comprising over one million trajectory samples across four public benchmarks. Experimental results demonstrate that APFN outperforms state-of-the-art methods, achieving up to 8.5% improvement in accuracy and robustness, while maintaining real-time processing efficiency. Discussion These results validate APFN’s effectiveness in AI-driven medical behavior planning, providing a scalable and resilient solution for next-generation healthcare technologies, with the potential to revolutionize autonomous decision-making in medical diagnostics, monitoring, and robotic-assisted interventions.
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