Abstract
In large-scale high-speed rail networks (HSRNs), the occurrence of occasional malfunctions or accidents is unavoidable. The key issue considered in this study is the optimal allocation of the maintenance costs, based on the stochastic risk assessment for HSRNs. Inspired by the theoretical risk evaluation methods in the complex network, three major factors, including the local effects, global effects, and component self-effects are considered in the process of assessing the impact on the network components (nodes or lines). By introducing the component failure occurrence probability, which is considered to be an exponential function changing with the component maintenance costs, a feasible stochastic risk assessment model of the HSRNs together with the component impact assessment is proposed that can better unify the impact assessment of both the high-speed rail stations and railways. An optimal allocation algorithm based on a Lagrangian relaxation approach is designed. Correspondingly, the optimal cost allocation scheme can be determined using the algorithm to eliminate the various HSRN risks under the given costs. Furthermore, a real-world case study of the HSRNs in eastern China is illustrated. Compared with the genetic algorithm, the simulation shows that the approach can solve the optimal cost allocation problem to more effectively reduce the risks of large-scale HSRNs in practice.
Highlights
High-speed rail (HSR) is considered as one of the prevailing intercity travel modes, providing brand-new and high-quality travel services for various passengers
An increasing number of HSR lines are located in the same region, leading to the implementation of large-scale high-speed rail networks (HSRNs), for instance, in Western Europe, Japan, and China [2, 3]
Compared with common rail networks, HSRNs are vulnerable to most stochastic contingencies
Summary
High-speed rail (HSR) is considered as one of the prevailing intercity travel modes, providing brand-new and high-quality travel services for various passengers. For the sake of feasibility, the prevalent risk assessment methods are inclined to directly remove the target nodes (or lines) from a transportation network instead of considering a stochastic failure probability of a component (node or line). (1) For a new application field (HSRN), on the basis of the specific characteristics of HSR stations and railways, a united risk assessment model is formulated (see Section 3).
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