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Main Authors: Xu, Zhihao, Ding, Saisai, Zhang, Zhikun, Wang, Xiangjun
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.00933
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author Xu, Zhihao
Ding, Saisai
Zhang, Zhikun
Wang, Xiangjun
author_facet Xu, Zhihao
Ding, Saisai
Zhang, Zhikun
Wang, Xiangjun
contents Integral equations are widely used in fields such as applied modeling, medical imaging, and system identification, providing a powerful framework for solving deterministic problems. While parameter identification for differential equations has been extensively studied, the focus on integral equations, particularly stochastic Volterra integral equations, remains limited. This research addresses the parameter identification problem, also known as the equation reconstruction problem, in Volterra integral equations driven by Gaussian noise. We propose an improved deep neural networks framework for estimating unknown parameters in the drift term of these equations. The network represents the primary variables and their integrals, enhancing parameter estimation accuracy by incorporating inter-output relationships into the loss function. Additionally, the framework extends beyond parameter identification to predict the system's behavior outside the integration interval. Prediction accuracy is validated by comparing predicted and true trajectories using a 95% confidence interval. Numerical experiments demonstrate the effectiveness of the proposed deep neural networks framework in both parameter identification and prediction tasks, showing robust performance under varying noise levels and providing accurate solutions for modeling stochastic systems.
format Preprint
id arxiv_https___arxiv_org_abs_2506_00933
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Reconstruction and Prediction of Volterra Integral Equations Driven by Gaussian Noise
Xu, Zhihao
Ding, Saisai
Zhang, Zhikun
Wang, Xiangjun
Machine Learning
Integral equations are widely used in fields such as applied modeling, medical imaging, and system identification, providing a powerful framework for solving deterministic problems. While parameter identification for differential equations has been extensively studied, the focus on integral equations, particularly stochastic Volterra integral equations, remains limited. This research addresses the parameter identification problem, also known as the equation reconstruction problem, in Volterra integral equations driven by Gaussian noise. We propose an improved deep neural networks framework for estimating unknown parameters in the drift term of these equations. The network represents the primary variables and their integrals, enhancing parameter estimation accuracy by incorporating inter-output relationships into the loss function. Additionally, the framework extends beyond parameter identification to predict the system's behavior outside the integration interval. Prediction accuracy is validated by comparing predicted and true trajectories using a 95% confidence interval. Numerical experiments demonstrate the effectiveness of the proposed deep neural networks framework in both parameter identification and prediction tasks, showing robust performance under varying noise levels and providing accurate solutions for modeling stochastic systems.
title Reconstruction and Prediction of Volterra Integral Equations Driven by Gaussian Noise
topic Machine Learning
url https://arxiv.org/abs/2506.00933