Modeling residual-vehicle effects on uncertainty estimation of the connected vehicle penetration rate

IF 7.6 1区 工程技术 Q1 TRANSPORTATION SCIENCE & TECHNOLOGY
Shaocheng Jia , S.C. Wong , Wai Wong
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引用次数: 0

Abstract

In the transition to full deployment of connected vehicles (CVs), the CV penetration rate plays a key role in bridging the gap between partial and complete traffic information. Several innovative methods have been proposed to estimate the CV penetration rate using only CV data. However, these methods, as point estimators, may lead to biased estimations or suboptimal solutions when applied directly in modeling or system optimization. To avoid these problems, the uncertainty and variability in the CV penetration rate must be considered. Recently, a probabilistic penetration rate (PPR) model was developed for estimating such uncertainties. The key model input is a constrained queue length distribution composed exclusively of queues formed by red signals in undersaturation conditions with no residual vehicles. However, in real-world scenarios, due to random arrivals, residual vehicles are commonly carried over from one cycle to another in temporary overflow cycles in undersaturation conditions, which seriously restricts the applicability of the PPR model. To address this limitation, this paper proposes a Markov-constrained queue length (MCQL) model that can model the complex effects of residual vehicles on the CV penetration rate uncertainty. A constrained queue with residual vehicles is decomposed into four vehicle groups: observable constrained residual vehicles, unobservable constrained residual vehicles, unconstrained residual vehicles, and new arrivals. Although the first vehicle group is observable in the former cycle, the focus of this work is to model the residual vehicles from the second and third vehicle groups in combination with the new arrivals. The MCQL model includes four sub-models, namely, the residual-vehicle model, convolutional constrained queue model, constrained residual queue model, and observable residual queue model, to isolate and derive the distribution of the constrained vehicle set formed by the three latter vehicle groups. This distribution is then substituted into the PPR model to estimate the uncertainty. Comprehensive VISSIM simulations and applications to real-world datasets demonstrate that the proposed MCQL model can accurately model the residual-vehicle effect and estimate the uncertainty. Thus, the applicability of the PPR model is truly extended to real-world settings, regardless of the presence of residual vehicles. A simple stochastic CV-based adaptive signal control example illustrates the potential of the proposed model in real-world applications.
模拟残余车辆对互联汽车渗透率不确定性估计的影响
在向全面部署联网汽车(CV)过渡的过程中,CV 渗透率在缩小部分交通信息与完整交通信息之间的差距方面发挥着关键作用。目前已提出几种创新方法,仅使用 CV 数据估算 CV 渗透率。然而,这些方法作为点估计器,在直接应用于建模或系统优化时,可能会导致估计偏差或次优解决方案。为了避免这些问题,必须考虑 CV 渗透率的不确定性和可变性。最近,开发了一种概率渗透率 (PPR) 模型,用于估算此类不确定性。该模型的关键输入是一个受限的队列长度分布,它完全由红色信号灯在不饱和条件下形成的队列组成,且没有剩余车辆。然而,在实际场景中,由于随机到达,在不饱和条件下的临时溢出周期中,残余车辆通常会从一个周期延续到另一个周期,这严重限制了 PPR 模型的适用性。针对这一局限性,本文提出了马尔可夫约束队列长度(MQL)模型,该模型可以模拟残余车辆对 CV 渗透率不确定性的复杂影响。有残余车辆的受限队列被分解为四个车辆组:可观测的受限残余车辆、不可观测的受限残余车辆、无约束残余车辆和新到达车辆。虽然第一组车辆在前一循环中是可观测的,但本工作的重点是对第二组和第三组的残余车辆以及新到达车辆进行建模。MCQL 模型包括四个子模型,即残余车辆模型、卷积约束队列模型、约束残余队列模型和可观测残余队列模型,用于分离和推导由后三个车辆组形成的约束车辆集的分布。然后将该分布代入 PPR 模型,以估计不确定性。全面的 VISSIM 仿真和对实际数据集的应用表明,所提出的 MCQL 模型能够准确地模拟残余车辆效应并估算不确定性。因此,无论是否存在残留车辆,PPR 模型的适用性都能真正扩展到真实世界的环境中。一个简单的基于随机 CV 的自适应信号控制示例说明了所提模型在实际应用中的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
15.80
自引率
12.00%
发文量
332
审稿时长
64 days
期刊介绍: Transportation Research: Part C (TR_C) is dedicated to showcasing high-quality, scholarly research that delves into the development, applications, and implications of transportation systems and emerging technologies. Our focus lies not solely on individual technologies, but rather on their broader implications for the planning, design, operation, control, maintenance, and rehabilitation of transportation systems, services, and components. In essence, the intellectual core of the journal revolves around the transportation aspect rather than the technology itself. We actively encourage the integration of quantitative methods from diverse fields such as operations research, control systems, complex networks, computer science, and artificial intelligence. Join us in exploring the intersection of transportation systems and emerging technologies to drive innovation and progress in the field.
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