{"title":"A novel method of refining the performance of rail systems: an evaluation of system dynamics using discrete event simulation","authors":"K. Gharehbaghi, K. Farnes, N. Hurst","doi":"10.1108/sasbe-10-2023-0309","DOIUrl":null,"url":null,"abstract":"PurposeThis paper aims to trial a novel method of improving the performance of rail systems. Accordingly, an evaluation of rail system dynamics (SD) using discrete event simulation (DES) will be undertaken. Globally, cities and their transportation systems face ongoing challenges with many of these resulting from complicated rail SD. To evaluate these challenges, this study utilized DES as the basis of the analysis of Melbourne Metro Rail's SD. The transportation SD processes including efficiency and reliability were also developed.Design/methodology/approachUsing DES, this research examines and determines the Melbourne Metro Rail's SD. Although the Melbourne Metro Rail is still in progress, the DES developed in this research examined the system requirements of functionality, performance and integration. As the basis of this examination, the Melbourne Metro Rail's optimization was simulated using the developed DES. As the basis of the experiment, a total of 50 trials were simulated. This included 25 samples for each of efficiency and reliability. The simulation not only scrutinized the SD but also underlined some of its shortfalls.FindingsThis study found that information and communication technology (ICT) was the pinnacle of system application. The DES development highlighted that both efficiency and reliability rates are the essential SD and thus fundamental for Melbourne Metro Rail system functionality. Specifically, the three elements of SD, capacity, continuity and integration are considered critical in improving the system functionality of Melbourne Metro Rail.Research limitations/implicationsThis particular mega rail infrastructure system was carefully analyzed, and subsequently, the DES was developed. However, since the DES is at its inception, the results are relatively limited without inclusive system calibration or validation process. Nonetheless, with some modifications, such as using different KPIs to evaluate additional systems variables and setting appropriate parameters to test the system reliability measures at different intensities, the developed DES can be modified to examine and evaluate other rail systems. However, if a broader system analysis is required, the DES model subsequently needs to be modified to specific system parameters.Practical implicationsThrough evaluation of Melbourne's Metro Rail in the manner described above, this research has shown the developed DES is a useful platform to understand and evaluate system efficiency and reliability. Such an evaluation is considered important when implementing new transport systems, particularly when they are being integrated into existing networks.Social implicationsEfficient rail networks are critical for modern cities and such systems, while inherently complex, aid local economies and societal cohesion through predictable and reliable movement of people. Through improved system functionality and greater efficiencies, plus improved passenger safety, security and comfort, the traveling public will benefit from the enhanced reliability of the transportation network that results from research as that provided in this paper.Originality/valueThis research paper is the first of its kind specifically focusing on the application of DES on the Melbourne Metro Rail System. The developed model aligns with the efficiency optimization framework, which is central to rail systems. The model shows the relationship between increased efficiency and optimizing system reliability. In comparison with more advanced mathematical modeling, the DES presented in this research provides robust, but yet rapid and uncomplicated system enhancements. These findings can better prepare rail professionals to adequately plan and devise appropriate system measures.","PeriodicalId":45779,"journal":{"name":"Smart and Sustainable Built Environment","volume":null,"pages":null},"PeriodicalIF":3.5000,"publicationDate":"2024-05-21","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Smart and Sustainable Built Environment","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1108/sasbe-10-2023-0309","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
PurposeThis paper aims to trial a novel method of improving the performance of rail systems. Accordingly, an evaluation of rail system dynamics (SD) using discrete event simulation (DES) will be undertaken. Globally, cities and their transportation systems face ongoing challenges with many of these resulting from complicated rail SD. To evaluate these challenges, this study utilized DES as the basis of the analysis of Melbourne Metro Rail's SD. The transportation SD processes including efficiency and reliability were also developed.Design/methodology/approachUsing DES, this research examines and determines the Melbourne Metro Rail's SD. Although the Melbourne Metro Rail is still in progress, the DES developed in this research examined the system requirements of functionality, performance and integration. As the basis of this examination, the Melbourne Metro Rail's optimization was simulated using the developed DES. As the basis of the experiment, a total of 50 trials were simulated. This included 25 samples for each of efficiency and reliability. The simulation not only scrutinized the SD but also underlined some of its shortfalls.FindingsThis study found that information and communication technology (ICT) was the pinnacle of system application. The DES development highlighted that both efficiency and reliability rates are the essential SD and thus fundamental for Melbourne Metro Rail system functionality. Specifically, the three elements of SD, capacity, continuity and integration are considered critical in improving the system functionality of Melbourne Metro Rail.Research limitations/implicationsThis particular mega rail infrastructure system was carefully analyzed, and subsequently, the DES was developed. However, since the DES is at its inception, the results are relatively limited without inclusive system calibration or validation process. Nonetheless, with some modifications, such as using different KPIs to evaluate additional systems variables and setting appropriate parameters to test the system reliability measures at different intensities, the developed DES can be modified to examine and evaluate other rail systems. However, if a broader system analysis is required, the DES model subsequently needs to be modified to specific system parameters.Practical implicationsThrough evaluation of Melbourne's Metro Rail in the manner described above, this research has shown the developed DES is a useful platform to understand and evaluate system efficiency and reliability. Such an evaluation is considered important when implementing new transport systems, particularly when they are being integrated into existing networks.Social implicationsEfficient rail networks are critical for modern cities and such systems, while inherently complex, aid local economies and societal cohesion through predictable and reliable movement of people. Through improved system functionality and greater efficiencies, plus improved passenger safety, security and comfort, the traveling public will benefit from the enhanced reliability of the transportation network that results from research as that provided in this paper.Originality/valueThis research paper is the first of its kind specifically focusing on the application of DES on the Melbourne Metro Rail System. The developed model aligns with the efficiency optimization framework, which is central to rail systems. The model shows the relationship between increased efficiency and optimizing system reliability. In comparison with more advanced mathematical modeling, the DES presented in this research provides robust, but yet rapid and uncomplicated system enhancements. These findings can better prepare rail professionals to adequately plan and devise appropriate system measures.
目的 本文旨在尝试一种提高铁路系统性能的新方法。因此,将利用离散事件模拟(DES)对轨道系统动力学(SD)进行评估。在全球范围内,城市及其交通系统都面临着持续的挑战,其中许多挑战都是由复杂的轨道系统动力学造成的。为了评估这些挑战,本研究利用 DES 作为墨尔本地铁 SD 分析的基础。设计/方法/途径利用 DES,本研究考察并确定了墨尔本地铁的 SD。尽管墨尔本地铁仍在建设过程中,但本研究开发的 DES 对系统的功能、性能和集成要求进行了检查。在此基础上,使用开发的 DES 模拟了墨尔本地铁的优化。作为实验的基础,共模拟了 50 次试验。其中包括效率和可靠性各 25 个样本。这项研究发现,信息和通信技术(ICT)是系统应用的顶峰。可持续发展设计的开发强调了效率和可靠率是必不可少的可持续发展因素,因此也是墨尔本地铁系统功能的基础。具体而言,SD 的三个要素,即容量、连续性和集成性,被认为是提高墨尔本地铁系统功能的关键。然而,由于 DES 尚处于起步阶段,在没有进行系统校准或验证的情况下,研究结果相对有限。尽管如此,经过一些修改,例如使用不同的关键绩效指标来评估其他系统变量,以及设置适当的参数来测试不同强度下的系统可靠性措施,所开发的 DES 可以进行修改,以检查和评估其他铁路系统。然而,如果需要进行更广泛的系统分析,则需要根据特定的系统参数对 DES 模型进行修改。通过以上述方式对墨尔本地铁进行评估,本研究表明所开发的 DES 是了解和评估系统效率和可靠性的有用平台。社会意义高效的铁路网络对现代城市至关重要,此类系统虽然本身复杂,但通过可预测和可靠的人员流动,有助于地方经济和社会凝聚力。通过改进系统功能和提高效率,以及改善乘客的安全、安保和舒适度,公众出行将受益于本文所提供的研究成果带来的运输网络可靠性的提升。原创性/价值本文是同类研究中第一份专门针对墨尔本地铁系统应用 DES 的论文。所开发的模型与效率优化框架相一致,而效率优化框架是铁路系统的核心。该模型显示了提高效率与优化系统可靠性之间的关系。与更先进的数学建模相比,本研究中提出的可持续发展设计(DES)可提供稳健、快速和简单的系统改进。这些研究成果可以更好地帮助铁路专业人员充分规划和设计适当的系统措施。