磁化卡松纳米流体沿楔形流的研究:高斯过程回归

M. Shanmugapriya, R. Sundareswaran, S. G. K. Subramanian, A. Alameri
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引用次数: 0

摘要

在热辐射和化学反应的作用下,构建了楔形上的非稳态二维磁化卡松纳米流体流动模型。在楔形表面附近还假设了多重滑移效应以及对流边界限制。本研究探讨了软计算技术的应用,以应对问题建模和数值方法的复杂性所带来的挑战。包含各种模型因素的传统方法可能难以提供精确的解决方案。为解决这一问题,采用了高斯过程回归(GPR)来预测所提出的流动模型的解。在数值射击法和 Runge-Kutta-Fehlberg 四阶-五阶 (RKF-45) 参考数据的帮助下,对 GPR 模型进行了训练。数值模拟结果表明,卡松流体参数 β 和不稳定性参数 S 可增强摩擦因数,辐射参数 Rd 越大,传热速率越高。此外,Biot 数 Bi1 和 Bi2 会使纳米粒子温度升高;而皮肤摩擦系数 S˜fxRex0.5、传热速率 H˜txRex0.5 和纳米粒子传热速率 C˜txRex0.5 则与之相反。在预测 S˜fxRex0.5、H˜tx Rex0.5 和 C˜txRex0.5 时,使用指数核函数的 GPR 模型在训练数据集和检验数据集上的性能均优于其他函数。采用 RMSE、MAE、MAPE、MSE、R2 和 R 等统计指标来检查通过 GPR 和 RKF-45 获得的预测解和数值解的准确性和收敛性。结果表明,所有三个 GPR 模型的 R2 值均高于 0.9。拟议的研究证明了采用软计算方法(GPR)有效分析复杂流动模型行为的优势。
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Investigation of Magnetized Casson Nanofluid Flow along Wedge: Gaussian Process Regression
An unsteady two-dimensional magnetized Casson nanofluid flow model is constructed over a wedge under the effect of thermal radiation and chemical reaction. The multiple slip effects are also assumed near the surface of the wedge along with the convective boundary restrictions. This study investigates the application of soft computing techniques to address the challenges posed by the complexity of problem modeling and numerical methods. Traditional approaches incorporating various model factors may struggle to provide accurate solutions. To resolve this issue, Gaussian process regression (GPR) is employed to predict the solution of the proposed flow model. With the help of the numerical shooting method together with Runge–Kutta–Fehlberg fourth-fifth-order (RKF-45) reference data, the GPR model is trained. The numerical simulation illustrated that the Casson fluid parameter β and the unsteadiness parameter S strengthen the friction factor, and the heat transfer rate is enhanced as the radiation parameter Rd becomes larger. In addition, the Biot numbers Bi1 & Bi2 lead to strengthen nanoparticle temperature; an opposite behavior is noticed with the skin friction coefficient S˜fxRex0.5, heat transfer rate H˜tx Rex0.5, and nanoparticle transfer rate C˜txRex0.5. The GPR model with the exponential Kernel function provided better performance than other functions on both training and checking datasets to predict S˜fxRex0.5,H˜tx Rex0.5, and C˜txRex0.5. Statistical metrics including RMSE, MAE, MAPE, MSE, R2, and R are employed to check the accuracy and convergences of the predicted and numerical solutions obtained through GPR and RKF-45. It is observed that all three GPR models had an R2 value of higher than 0.9. The proposed study demonstrates the advantages of employing soft computing methods (GPR) to effectively analyse the behavior of complex flow models.
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来源期刊
INTERNATIONAL JOURNAL OF MATHEMATICS AND MATHEMATICAL SCIENCES
INTERNATIONAL JOURNAL OF MATHEMATICS AND MATHEMATICAL SCIENCES Mathematics-Mathematics (miscellaneous)
CiteScore
2.30
自引率
8.30%
发文量
60
审稿时长
17 weeks
期刊介绍: The International Journal of Mathematics and Mathematical Sciences is a refereed math journal devoted to publication of original research articles, research notes, and review articles, with emphasis on contributions to unsolved problems and open questions in mathematics and mathematical sciences. All areas listed on the cover of Mathematical Reviews, such as pure and applied mathematics, mathematical physics, theoretical mechanics, probability and mathematical statistics, and theoretical biology, are included within the scope of the International Journal of Mathematics and Mathematical Sciences.
期刊最新文献
Properties of a Linear Operator Involving Lambert Series and Rabotnov Function Investigation of Magnetized Casson Nanofluid Flow along Wedge: Gaussian Process Regression Horadam Polynomials and a Class of Biunivalent Functions Defined by Ruscheweyh Operator The Fuzzy Prime Spectrum of Partially Ordered Sets Improved Finite Difference Technique via Adomian Polynomial to Solve the Coupled Drinfeld’s–Sokolov–Wilson System
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