Network Uncertainty Quantification for Analysis of Multi-Component Systems

IF 1.8 Q2 ENGINEERING, MULTIDISCIPLINARY
John Tencer, Edward Rojas, Benjamin Schroeder
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Abstract

In order to impact physical mechanical system design decisions and realize the full promise of high-fidelity computational tools, simulation results must be integrated at the earliest stages in the design process. This is particularly challenging when dealing with uncertainty and optimizing for system-level performance metrics, as full-system models (often notoriously expensive and time-consuming to develop) are generally required to propagate uncertainties to system- level quantities of interest. Methods for propagating parameter and boundary condition uncertainty in networks of interconnected components hold promise for enabling design under uncertainty in real-world applications. These methods avoid the need for time consuming mesh generation of full-system geometries when changes are made to components or subassemblies. Additionally, they explicitly tie full-system model predictions to component/subassembly validation data which is valuable for qualification. These methods work by leveraging the fact that many engineered systems are inherently modular, being comprised of a hierarchy of components and subassemblies that are individually modified or replaced to define new system designs. By doing so, these methods enable rapid model development and the incorporation of uncertainty quantification earlier in the design process. The resulting formulation of the uncertainty propagation problem is iterative. We express the system model as a network of interconnected component models, which exchange solution information at component boundaries. We present a pair of approaches for propagating uncertainty in this type of decomposed system and provide implementations in the form of an open-source software library. We demonstrate these tools on a variety of applications and demonstrate the impact of problem-specific details on the performance and accuracy of the resulting UQ analysis. This work represents the most comprehensive investigation of these network uncertainty propagation methods to date.
多组件系统分析中的网络不确定性量化
为了影响物理机械系统设计决策并实现高保真计算工具的全部承诺,必须在设计过程的最早阶段集成仿真结果。在处理不确定性和优化系统级性能指标时,这尤其具有挑战性,因为通常需要完整的系统模型(通常开发起来非常昂贵且耗时)来将不确定性传播到感兴趣的系统级数量。在互连组件网络中传播参数和边界条件不确定性的方法有望在现实应用中实现不确定性下的设计。当对组件或子组件进行更改时,这些方法避免了对整个系统几何图形进行耗时的网格生成的需要。此外,它们显式地将整个系统模型预测与组件/子组件验证数据联系起来,这对鉴定是有价值的。这些方法的工作原理是利用这样一个事实,即许多工程系统本质上是模块化的,由组件和子组件的层次结构组成,这些组件和子组件可以单独修改或替换,以定义新的系统设计。通过这样做,这些方法使快速模型开发和不确定性量化在设计过程的早期结合成为可能。所得的不确定性传播问题的公式是迭代的。我们将系统模型表示为相互连接的组件模型网络,这些组件模型在组件边界交换解决方案信息。我们提出了在这种类型的分解系统中传播不确定性的两种方法,并以开源软件库的形式提供了实现。我们在各种应用程序上演示了这些工具,并演示了特定于问题的细节对最终UQ分析的性能和准确性的影响。这项工作是迄今为止对这些网络不确定性传播方法最全面的研究。
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来源期刊
CiteScore
5.20
自引率
13.60%
发文量
34
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