Applying Acausal Physics-Based Modeling and Model-Based Systems Engineering to Improve System Model Scalability and Reusability

Sarah Chu, C. Johnstone, M. Balchanos, Michael J. Steffens, D. Mavris
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Abstract

The idea of a digital enterprise has caught traction recently as an efficient and novel means of enhancing the design, verification, validation, manufacturing, and operational processes around complex and integrated systems. The Office of Naval Research (ONR) has demonstrated interest in the digital enterprise as a means of both expanding its use of Unmanned Surface Vehicles (USVs) and scaling them to more complex use cases. The growing wave of digital engineering influence stands to augment current engineering lifecycle processes by enabling the development of digital twins and new practices around them such as virtual experimentation. These new practices will rapidly reduce the time and cost of system development and certification and, if done correctly, will accelerate the evolution of unmanned surface vehicles. However, for these systems to be trusted to operate in the way envisioned by the ONR and larger Defense industry, several issues surrounding digital model creation must be addressed. The purpose of this study was two-fold. Firstly, to investigate a methodology for digital twin creation and virtual experimentation by developing a modelling and simulation dashboard around a prototypical unmanned surface. Secondly, to investigate potential solutions to lack of scalability and reusability in classical physics-based modelling techniques and improved digital enterprise architecting by connecting model simulation to model definition and stakeholder requirements. The first phase revolved around using both physics and data-driven information from the system to capture its behavior in three layers of interest: dynamic, electrical, and thermal. A model was created and simulated in a digital testbed to explore how improved physical and digital experimentation could reduce uncertainty in model performance. The results of this phase suggested that the spiral development approach taken to virtual experimentation platform and digital twin development could reduce the cost of system verification and validation if scaled. One part of the second phase showed that by modeling operational activities and requirements, the overall system functionality can be identified as well as any gaps in the architecture that need to be addressed. This helps identify new requirements for the USV and ensures that the process of data gathering during virtual experimentation is better understood. The structural model is then transformed into an analytical model for the actual simulation of the system. The other part of the second phase focused on causal model development using the Modelica system modelling language as a means of improving scalability. The same unmanned surface vehicle in phase one was recreated and simulated in the Dymola environment. The results were compared against experimental data from phase one and show that the Modelica model solved faster, was simpler to implement, and was more easily adapted to more complex systems than the original state-equation-based model python code.
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应用基于因果物理的建模和基于模型的系统工程提高系统模型的可扩展性和可重用性
最近,数字企业的概念作为一种有效和新颖的手段,在复杂和集成的系统周围增强设计、验证、验证、制造和运营流程,引起了人们的关注。美国海军研究办公室(ONR)对数字企业表现出兴趣,将其作为扩大无人水面车辆(usv)使用并将其扩展到更复杂用例的一种手段。不断增长的数字工程影响浪潮将通过推动数字双胞胎的发展和围绕它们的新实践(如虚拟实验)来增强当前的工程生命周期过程。这些新的实践将迅速减少系统开发和认证的时间和成本,如果做得正确,将加速无人水面车辆的发展。然而,为了使这些系统能够按照ONR和更大的国防工业所设想的方式运行,必须解决围绕数字模型创建的几个问题。这项研究的目的有两个。首先,通过围绕原型无人表面开发建模和仿真仪表板,研究数字孪生创建和虚拟实验的方法。其次,通过将模型仿真与模型定义和利益相关者需求联系起来,研究经典的基于物理的建模技术和改进的数字企业架构中缺乏可扩展性和可重用性的潜在解决方案。第一阶段围绕着使用来自系统的物理和数据驱动信息来捕获其三个感兴趣层的行为:动态、电和热。建立了一个模型,并在数字测试平台上进行了模拟,以探索改进的物理和数字实验如何减少模型性能的不确定性。这一阶段的结果表明,采用螺旋开发方法进行虚拟实验平台和数字孪生开发,如果规模化,可以降低系统验证和验证的成本。第二阶段的一部分表明,通过对操作活动和需求进行建模,可以确定整个系统功能以及需要解决的体系结构中的任何缺口。这有助于确定USV的新要求,并确保更好地理解虚拟实验期间的数据收集过程。然后将结构模型转化为系统实际仿真的解析模型。第二阶段的另一部分侧重于使用Modelica系统建模语言作为改进可伸缩性的手段进行因果模型开发。在Dymola环境中对第一阶段的无人水面飞行器进行了重建和模拟。将结果与第一阶段的实验数据进行了比较,结果表明,与原始的基于状态方程的模型python代码相比,Modelica模型求解速度更快,实现更简单,更容易适应更复杂的系统。
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