概化理论
人工神经网络
非线性系统
离散化
计算机科学
非线性系统辨识
鉴定(生物学)
常微分方程
系统标识
自由度(物理和化学)
颂歌
状态空间
人工智能
算法
控制理论(社会学)
微分方程
数学
应用数学
数据建模
量子力学
数据库
生物
统计
植物
物理
数学分析
控制(管理)
作者
Sarvin Moradi,Burak Duran,Saeed Eftekhar Azam,Massood Mofid
出处
期刊:Buildings
[Multidisciplinary Digital Publishing Institute]
日期:2023-02-28
卷期号:13 (3): 650-650
被引量:35
标识
DOI:10.3390/buildings13030650
摘要
Herein, two novel Physics Informed Neural Network (PINN) architectures are proposed for output-only system identification and input estimation of dynamic systems. Using merely sparse output-only measurements, the proposed PINNs architectures furnish a novel approach to input, state, and parameter estimation of linear and nonlinear systems with multiple degrees of freedom. These architectures are comprised of parallel and sequential PINNs that act upon a set of ordinary differential equations (ODEs) obtained from spatial discretization of the partial differential equation (PDE). The performance of this framework for dynamic system identification and input estimation was ascertained by extensive numerical experiments on linear and nonlinear systems. The advantage of the proposed approach, when compared with system identification, lies in its computational efficiency. When compared with traditional Artificial Neural Networks (ANNs), this approach requires substantially smaller training data and does not suffer from generalizability issues. In this regard, the states, inputs, and parameters of dynamic state-space equations of motion were estimated using simulated experiments with “noisy” data. The proposed framework for PINN showed excellent great generalizability for various types of applications. Furthermore, it was found that the proposed architectures significantly outperformed ANNs in generalizability and estimation accuracy.
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