Taming Model Uncertainty in Self-adaptive Systems Using Bayesian Model Averaging

Matteo Camilli, R. Mirandola, P. Scandurra
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引用次数: 6

Abstract

Research on uncertainty quantification and mitigation of software-intensive systems and (self-)adaptive systems, is increasingly gaining momentum, especially with the availability of statistical inference techniques (such as Bayesian reasoning) that make it possible to mitigate uncertain (quality) attributes of the system under scrutiny often encoded in the system model in terms of model parameters. However, to the best of our knowledge, the uncertainty about the choice of a specific system model did not receive the deserved attention.This paper focuses on self-adaptive systems and investigates how to mitigate the uncertainty related to the model selection process, that is, whenever one model is chosen over plausible alternative and competing models to represent the understanding of a system and make predictions about future observations. In particular, we propose to enhance the classical feedback loop of a self-adaptive system with the ability to tame the model uncertainty using Bayesian Model Averaging. This method improves the predictions made by the analyze component as well as the plan that adopts metaheuristic optimizing search to guide the adaptation decisions. Our empirical evaluation demonstrates the cost-effectiveness of our approach using an exemplar case study in the robotics domain.CCS CONCEPTS• Software and its engineering → Software system models; Software functional properties; • Computer systems organization → Self-organizing autonomic computing
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基于贝叶斯模型平均的自适应系统模型不确定性控制
对软件密集型系统和(自)适应系统的不确定性量化和缓解的研究正日益获得动力,特别是随着统计推断技术(如贝叶斯推理)的可用性,它可以减轻被审查的系统的不确定性(质量)属性,这些属性通常以模型参数的形式编码在系统模型中。然而,据我们所知,选择特定系统模型的不确定性并没有得到应有的重视。本文的重点是自适应系统,并研究了如何减轻与模型选择过程相关的不确定性,也就是说,每当一个模型被选择在可信的替代和竞争模型中,以代表对系统的理解并对未来的观测做出预测。特别地,我们建议利用贝叶斯模型平均来增强自适应系统的经典反馈回路,使其具有驯服模型不确定性的能力。该方法既改进了分析组件的预测,又改进了采用元启发式优化搜索指导适应决策的方案。我们的经验评估证明了我们的方法使用机器人领域的范例案例研究的成本效益。•软件及其工程→软件系统模型;软件功能属性;•计算机系统组织→自组织自主计算
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