Collaborative Research:ITR/AP: Enabling Microscopic Simulators to Perform System-Level Analysis

合作研究：ITR/AP：使微观模拟器能够执行系统级分析

• 批准号: 0205484
• 负责人: Yannis Kevrekidis
• 金额: $ 80万
• 依托单位: Princeton University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-08-15 至 2006-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0205484&HistoricalAwards=false
• 关键词: Collaborative; Research; ITR; AP; Enabling

An interdisciplinary research team, at four universities, is collaborating on this medium-size Information Technology Research (ITR) project aimed at systematically bridging the gap between microscopic descriptions of complex material systems and systems-level analysis of direct engineering importance. A mathematics-assisted computational methodology will be developed that will enable microscopic-level simulators to perform systems-level analysis directly, without the need to pass through an intermediate level description of the material system through macroscopic (partial differential or integro-differential) evolution equations. Specifically, an ensemble-averaged "coarse" time-stepper-based computational superstructure will be "wrapped around" state-of-the-art microscopic dynamic simulators, such as molecular dynamics, kinetic Monte Carlo, Lattice-Boltzmann or hybrid codes. This methodology will enable microscopic simulators to perform advanced systems-level analysis: stability, bifurcation, "coarse" integration, sensitivity, and control tasks, of complex, nonlinear distributed processes. The planned algorithms will run on massively parallel machines.The computational framework will consist of the following basic elements: (i) choice of statistics of interest (e.g. distribution moments) for describing the coarse behavior; (ii) "lifting" of a macroscopic initial condition to an ensemble of consistent microscopic configurations; (iii) evolution over the same (short) time period of each initial microscopic configuration in the ensemble according to a microscopic simulator that embodies the best current description of the physical system; (iv) averaging ("restriction") over the ensemble of the evolved microscopic configurations to provide a macroscopic evolved system state; and (v) execution of the previous three steps over a finite set of macroscopic initial conditions. This new approach is robust in its implementation and portable in its range of scientific and engineering applications. It has general applicability to all systems for which a macroscopic description is conceptually possible, yet unavailable in closed form. It circumvents the difficulty in obtaining and closing such macroscopic models, while computationally extracting precisely the information that would be obtained by a macroscopic model, had the model been available in closed form. This provides the link between ITR and a spectrum of application areas.Impact:The impact of the research will be on establishing a powerful and general link between state-of-the-art microscopic-level simulations and fast systems level analysis capabilities. Although the research focuses on specific problems in heterogeneous hard materials and complex fluids, the computational framework is applicable to a broad range of complex systems, including biological systems, their processing and function. Since it has the potential to revolutionize engineering systems-level analysis, it could have educational impact as well as furthering advances in microelectronics, bioinformatics and nanotechnology.

一个跨学科的研究团队，在四所大学，正在合作这个中型信息技术研究（ITR）项目，旨在系统地弥合复杂材料系统的微观描述和直接工程重要性的系统级分析之间的差距。 将开发一种辅助计算方法，使微观级模拟器能够直接进行系统级分析，而不需要通过宏观（偏微分或积分微分）演化方程对材料系统进行中间级描述。 具体来说，一个整体平均的“粗糙”的基于时间步进的计算超结构将“包裹”最先进的微观动态模拟器，如分子动力学，动力学蒙特卡罗，格子玻尔兹曼或混合代码。 这种方法将使微观模拟器进行先进的系统级分析：稳定性，分叉，“粗”集成，灵敏度和控制任务，复杂的，非线性的分布式过程。 计划中的算法将在大规模并行计算机上运行。计算框架将包括以下基本要素：（i）选择感兴趣的统计数据（ii）将宏观初始条件“提升”为一致的微观配置的集合;（iii）根据体现物理系统的最佳当前描述的微观模拟器，系综中的每个初始微观配置在相同（短）时间段内的演化;（iv）在演化的微观配置的系综上求平均（“限制”），以提供宏观演化的系统状态;以及（v）在宏观初始条件的有限集合上执行前三个步骤。 这种新方法在其实施中是稳健的，并且在其科学和工程应用范围内是便携式的。 它具有普遍适用性的宏观描述是概念上可能的，但在封闭的形式不可用的所有系统。 它避免了获得和关闭这样的宏观模型的困难，同时精确地计算提取将通过宏观模型获得的信息，如果该模型以封闭形式可用。 这提供了ITR和一系列应用领域之间的联系。影响：研究的影响将是在最先进的微观级模拟和快速系统级分析能力之间建立一个强大的和一般的联系。 虽然研究重点是非均质硬材料和复杂流体中的特定问题，但计算框架适用于广泛的复杂系统，包括生物系统，它们的处理和功能。 由于它有可能彻底改变工程系统级的分析，它可能会产生教育影响，并进一步推动微电子学，生物信息学和纳米技术的进步。