Bayesian Experimental Design of Cyber-Physical Tests for Hydrodynamic Model Calibration

Volume 6: Ocean Engineering Pub Date : 2021-06-21 DOI:10.31224/osf.io/bxpr3

G. Abbiati, T. Sauder

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Abstract

An application of cyber-physical testing to the empirical estimation of difference-frequency quadratic transfer functions is presented. As an alternative to today's procedure based on hydrodynamic tests with broad-banded or realistic (e.g., JONSWAP) wave spectra, tests in bichromatic waves are considered. The laboratory setup is the one developed by Sauder \& Tahchiev (2020) that enables magnifying the sensitivity of the floater response to the low-frequency wave loading by adjusting the stiffness and damping parameters of a virtual soft mooring system. Bayesian experimental design is proposed to optimize the selection of the control variables (frequencies in the bichromatic wave and properties of the virtual mooring system) for a batch of cyber-physical tests. The experimental design algorithm is based on the recent work of Huan \& Marzouk (2013). In a virtual yet realistic case study using an uncertain parametric quadratic transfer function, we demonstrate how the uncertainty of its describing parameters and other calibration parameters (low-frequency added mass and hydrodynamic damping) can be reduced. Results indicate that the proposed procedure has the potential for reducing experimental cost for calibration of hydrodynamic models.

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水动力模型标定信息物理试验的贝叶斯实验设计

介绍了网络物理测试在差频二次传递函数经验估计中的应用。作为目前基于宽频带或现实(例如JONSWAP)波浪谱的水动力试验程序的替代方案，考虑在双色波中进行试验。该实验室装置是由Sauder & Tahchiev(2020)开发的，通过调整虚拟软系泊系统的刚度和阻尼参数，可以放大浮子响应低频波载荷的灵敏度。为了优化控制变量(双色波频率和虚拟系泊系统特性)的选择，提出了贝叶斯实验设计。实验设计算法基于Huan \& Marzouk(2013)最近的工作。在一个使用不确定参数二次传递函数的虚拟但现实的案例研究中，我们演示了如何降低其描述参数和其他校准参数(低频附加质量和流体动力阻尼)的不确定性。结果表明，该方法具有降低水动力模型标定实验成本的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Volume 6: Ocean Engineering

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