Complex infrastructure systems analysis and management: the theory of faults

IF 3.5 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY
Niv Yonat, Shabtai Isaac, Igal M. Shohet
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引用次数: 0

Abstract

Purpose The purpose of this research is to provide a theoretical and practical theory and application that provides understanding and means to manage complex infrastructures. Design/methodology/approach In this research, complexity, nonlinear, noncontinuous effects and aleatoric and data unknowns are bypassed by directly addressing systems' responses. Graph theory, statistics and digital signal processing (DSP) tools are applied within a theoretical framework of the theory of faults (ToF). Motivational complex infrastructure systems (CISs) are difficult to model. Data are often missing or erroneous, changes are not well documented and processes are not well understood. On top of it, under complexity, stalwart analytical tools have limited predictive power. The aleatoric risk, such as rain and risk cascading from interconnected infrastructures, is unpredictable. Mitigation, response and recovery efforts are adversely affected. Findings The theory and application are presented and demonstrated by a step-by-step development of an application to a municipal drainage system. A database of faults is analyzed to produce system statistics, spatio-temporal morphology, behavior and traits. The gained understanding is compared to the physical system's design and to its modus operandi. Implications for design and maintenance are inferred; DSP tools to manage the system in real time are developed. Research limitations/implications Sociological systems are interest driven. Some events are intentionally created and directed to the benefit and detriment of the opposing parties in a project. Those events may be explained and possibly predicted by understanding power plays, not power functions. For those events, sociological game theories provide better explanatory value than mathematical gain theories. Practical implications The theory provides a thematic network for modeling and resolving aleatoric uncertainty in engineering and sociological systems. The framework may be elaborated to fields such as energy, healthcare and critical infrastructure. Social implications ToF provides a framework for the modeling and prediction of faults generated by inherent aleatoric uncertainties in social and technological systems. Therefore, the framework and theory lay the basis for automated monitoring and control of aleatoric uncertainties such as mechanical failures and human errors and the development of mitigation systems. Originality/value The contribution of this research is in the provision of an explicatory theory and a management paradigm for complex systems. This theory is applicable to a wide variety of fields from facilities and construction project management to maintenance and from academic studies to commercial use.
复杂基础设施系统分析与管理:故障理论
本研究的目的是提供一种理论和实践的理论和应用,为管理复杂的基础设施提供理解和方法。设计/方法/方法在这项研究中,通过直接解决系统的响应,绕过了复杂性、非线性、不连续效应以及任意和数据未知数。在故障理论(ToF)的理论框架内应用图论、统计学和数字信号处理(DSP)工具。激励性复杂基础设施系统(CISs)是一个难以建模的系统。数据经常丢失或错误,更改没有很好地记录,过程没有很好地理解。最重要的是,在复杂性下,可靠的分析工具的预测能力有限。随机风险,如降雨和互联基础设施的连锁风险,是不可预测的。缓解、应对和恢复工作受到不利影响。研究结果提出了理论和应用,并通过逐步发展应用于市政排水系统进行了演示。对故障数据库进行分析,得出故障的系统统计、时空形态、行为和特征。将获得的理解与物理系统的设计及其操作方式进行比较。推断对设计和维修的影响;开发了对系统进行实时管理的DSP工具。研究局限/启示社会学系统是利益驱动的。有些事件是故意制造的,目的是为了项目中对立方的利益和损害。这些事件可以通过理解权力游戏而不是权力功能来解释和预测。对于这些事件,社会学博弈论比数学收益理论提供了更好的解释价值。该理论为建模和解决工程和社会学系统中的任意不确定性提供了一个专题网络。该框架可扩展到能源、保健和关键基础设施等领域。社会影响ToF为社会和技术系统中由固有的任意不确定性产生的故障建模和预测提供了一个框架。因此,该框架和理论为机械故障和人为错误等任意不确定性的自动监测和控制以及缓解系统的开发奠定了基础。本研究的贡献在于为复杂系统提供了解释性的理论和管理范式。这一理论适用于从设施和建设项目管理到维护,从学术研究到商业应用的各个领域。
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来源期刊
Smart and Sustainable Built Environment
Smart and Sustainable Built Environment GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY-
CiteScore
9.20
自引率
8.30%
发文量
53
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