Traditionally, traffic incident management (TIM) programs coordinate the deployment of emergency resources to immediate incident requests without accommodating the interdependencies on incident evolutions in the environment. However, ignoring inherent interdependencies on the evolution of incidents in the environment while making current deployment decisions is shortsighted, and the resulting naive deployment strategy can significantly worsen the overall incident delay impact on the network. The interdependencies on incident evolution in the environment, including those between incident occurrences, and those between resource availability in near-future requests and the anticipated duration of the immediate incident request, should be considered through a look-ahead model when making current-stage deployment decisions. This study develops a new proactive framework based on the distributed constraint optimization problem (DCOP) to address the above limitations, overcoming conventional TIM models that cannot accommodate the dependencies in the TIM problem. Furthermore, the optimization objective is formulated to incorporate Unmanned Aerial Vehicles (UAVs). The UAVs' role in TIM includes exploring uncertain traffic conditions, detecting unexpected events, and augmenting information from roadway traffic sensors. Robustness analysis of our model for multiple TIM scenarios shows satisfactory performance using local search exploration heuristics. Overall, our model reports a significant reduction in total incident delay compared to conventional TIM models. With UAV support, we demonstrate a further decrease in the overall incident delay through the shorter response time of emergency vehicles, and a reduction in uncertainties associated with the estimated incident delay impact.
翻译:交通事故管理方案(TIM)传统上协调紧急资源对突发事件请求的部署,但不顾及对环境事件演变的相互依赖性;然而,忽视环境事件演变的内在相互依存性,同时作出目前的部署决定是短视的,因此产生的天真的部署战略可能大大加剧事故延误对网络的总体影响; 对环境事件演变的相互依存性,包括事故发生之间,以及近未来请求中资源可用性和直接事故请求预计延迟时间之间的相互依存性,在作出当前阶段部署决定时,应通过 " 外观 " 模式来考虑; 然而,这一研究基于分散限制优化问题(DCOP),为解决上述限制问题而开发了一个新的积极主动框架,克服了传统的TIM模式,无法适应TIM问题依赖性的总体影响;此外,制定了优化目标,以纳入无人驾驶的空中车辆(UAVA)在环境变化变化变化的变化变化中,进一步探讨交通状况的不稳定性,发现意外事件,并增加公路交通传感器的信息; 在多处限制优化控制下,对TIM事件预测性分析模型,在多处的常规事件减少事故预测中显示令人满意的业绩。