估计理论
计算机科学
机器学习
灵敏度(控制系统)
人工智能
任务(项目管理)
计算
贝叶斯概率
反问题
人工神经网络
贝叶斯优化
参数空间
贝叶斯定理
模型参数
费希尔信息
近似贝叶斯计算
数据挖掘
钥匙(锁)
噪音(视频)
算法
数据采集
贝叶斯推理
贝叶斯网络
深层神经网络
反向
无线传感器网络
事先信息
贝叶斯估计量
作者
Venianakis, Georgios,Theodoropoulos, Constantinos,Kavousanakis, Michail
标识
DOI:10.48550/arxiv.2511.15543
摘要
Parameter estimation remains a challenging task across many areas of engineering. Because data acquisition can often be costly, limited, or prone to inaccuracies (noise, uncertainty) it is crucial to identify sensor configurations that provide the maximum amount of information about the unknown parameters, in particular for the case of distributed-parameter systems, where spatial variations are important. Physics-Informed Neural Networks (PINNs) have recently emerged as a powerful machine-learning (ML) tool for parameter estimation, particularly in cases with sparse or noisy measurements, overcoming some of the limitations of traditional optimization-based and Bayesian approaches. Despite the widespread use of PINNs for solving inverse problems, relatively little attention has been given to how their performance depends on sensor placement. This study addresses this gap by introducing a comprehensive PINN-based framework that simultaneously tackles optimal sensor placement and parameter estimation. Our approach involves training a PINN model in which the parameters of interest are included as additional inputs. This enables the efficient computation of sensitivity functions through automatic differentiation, which are then used to determine optimal sensor locations exploiting the D-optimality criterion. The framework is validated on two illustrative distributed-parameter reaction-diffusion-advection problems of increasing complexity. The results demonstrate that our PINNs-based methodology consistently achieves higher accuracy compared to parameter values estimated from intuitively or randomly selected sensor positions.
科研通智能强力驱动
Strongly Powered by AbleSci AI