A Physics informed neural network approach for solving time fractional Black-Scholes partial differential equations

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Samuel M. Nuugulu, Kailash C. Patidar, Divine T. Tarla
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引用次数: 0

Abstract

We present a novel approach for solving time fractional Black-Scholes partial differential equations (tfBSPDEs) using Physics Informed Neural Network (PINN) approach. Traditional numerical methods are faced with challenges in solving fractional PDEs due to the non-locality and non-differentiability nature of fractional derivative operators. By leveraging the ideas of Riemann sums and the refinement of tagged partitions of the time domain, we show that fractional derivatives can directly be incorporated into the loss function when applying the PINN approach to solving tfBSPDEs. The approach allows for the simultaneous learning of the underlying process dynamics and the involved fractional derivative operator without a need for the use of numerical discretization of the fractional derivatives. Through some numerical experiments, we demonstrate that, the PINN approach is efficient, accurate and computationally inexpensive particularly when dealing with high frequency and noisy data. This work augments the understanding between advanced mathematical modeling and machine learning techniques, contributing to the body of knowlege on the advancement of accurate derivative pricing models.

Abstract Image

解决时间分数 Black-Scholes 偏微分方程的物理信息神经网络方法
我们提出了一种利用物理信息神经网络(PINN)方法求解时间分数布莱克-斯科尔斯偏微分方程(tfBSPDEs)的新方法。由于分数导数算子的非位置性和不可分性,传统数值方法在求解分数偏微分方程时面临挑战。通过利用黎曼和的思想以及对时域标记分区的细化,我们证明了在应用 PINN 方法求解 tfBSPDEs 时,可以直接将分数导数纳入损失函数。这种方法可以同时学习底层过程动力学和所涉及的分数导数算子,而无需使用分数导数的数值离散化。通过一些数值实验,我们证明了 PINN 方法的高效、准确和计算成本低廉,尤其是在处理高频和高噪声数据时。这项工作加深了人们对先进数学建模和机器学习技术的理解,有助于提高精确衍生品定价模型的知识水平。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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