A bi-level model of dynamic traffic signal control with continuum approximation

Han, Ke; Sun, Yuqi; Liu, Hongcheng; Friesz, Terry L.; Yao, Tao

doi:10.1016/j.trc.2015.03.037

Cited by 36 publications

(17 citation statements)

References 55 publications

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“…The model can be formulated as a linear multiobjective 0-1 integer programming model. To minimize the energy consumption and actual travel time, two objective functions are shown in (18) and (19), that is, minimizing energy consumption and actual travel time. Both two objective functions have a linear form with respect to decision variables .…”

Section: Mathematical Modelmentioning

confidence: 99%

“…Aziz et al [17] presented the system optimal approach for dynamic traffic assignment with an embedded traffic flow model and the signal control optimization considering intersection delay and lost time from phase switches in the objective function. Han et al [18,19] presented a traffic signal optimization problem to illustrate the unique advantages of applying the continuum signal model instead of the on-andoff model. Feng et al [20] presented a real-time adaptive signal phase allocation algorithm using connected vehicle data to optimize the phase sequence and duration, which can minimize the total vehicle delay and the queue length.…”

Section: Introductionmentioning

confidence: 99%

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The Energy-Efficient Dynamic Route Planning for Electric Vehicles

Zhou

Wang

2019

Journal of Advanced Transportation

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Aiming to provide an approach for finding energy-efficient routes in dynamic and stochastic transportation networks for electric vehicles, this paper addresses the route planning problem in dynamic transportation network where the link travel times are assumed to be random variables to minimize total energy consumption and travel time. The changeable signals are introduced to establish state-space-time network to describe the realistic dynamic traffic network and also used to adjust the travel time according to the signal information (signal cycle, green time, and red time). By adjusting the travel time, the electric vehicle can achieve a nonstop driving mode during the traveling. Further, the nonstop driving mode could avoid frequent acceleration and deceleration at the signal intersections so as to reduce the energy consumption. Therefore, the dynamically adjusted travel time can save the energy and eliminate the waiting time. A multiobjective 0-1 integer programming model is formulated to find the optimal routes. Two methods are presented to transform the multiobjective optimization problem into a single objective problem. To verify the validity of the model, a specific simulation is conducted on a test network. The results indicate that the shortest travel time and the energy consumption of the planning route can be significantly reduced, demonstrating the effectiveness of the proposed approaches.

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Section: Mathematical Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Energy-Efficient Dynamic Route Planning for Electric Vehicles

Zhou

Wang

2019

Journal of Advanced Transportation

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“…In that case, a uniform random variable between 0 and 1 must be generated and then compared with the control link capacity to determine if a vehicle is allowed to leave for the next link at each time step. This issue can also be addressed with continuum signal models where there is no need to explicitly model 0–1 controls ( 48 ).…”

Section: Improvement Of Dnl Fidelitymentioning

confidence: 99%

Scalable Computing Architecture for Time-Dependent Transportation Optimization Problems Based on High-Performance Computing Techniques

Wang

Chowdhury

et al. 2019

Transportation Research Record

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Traditional formulations for transportation optimization problems mostly build complicating attributes into constraints while keeping the succinctness of objective functions. A popular solution is the Lagrangian decomposition by relaxing complicating constraints and then solving iteratively. Although this approach is effective for many problems, it generates intractability in other problems. To address this issue, this paper presents an alternative formulation for transportation optimization problems in which the complicating attributes of target problems are partially or entirely built into the objective function instead of into the constraints. Many mathematical complicating constraints in transportation problems can be efficiently modeled in dynamic network loading (DNL) models based on the demand–supply equilibrium, such as the various road or vehicle capacity constraints or “IF–THEN” type constraints. After “pre-building” complicating constraints into the objective functions, the objective function can be approximated well with customized high-fidelity DNL models. Three types of computing benefits can be achieved in the alternative formulation: ( a) the original problem will be kept the same; ( b) computing complexity of the new formulation may be significantly reduced because of the disappearance of hard constraints; ( c) efficiency loss on the objective function side can be mitigated via multiple high-performance computing techniques. Under this new framework, high-fidelity and problem-specific DNL models will be critical to maintain the attributes of original problems. Therefore, the authors’ recent efforts in enhancing the DNL’s fidelity and computing efficiency are also described in the second part of this paper. Finally, a demonstration case study is conducted to validate the new approach.

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“…Han et al (2015a) first presented a rigorous continuity result for the path delay operator, which is the fundamental importance to the existence of DUE conditions, based on the Lighthill-Whitham-Richards (LWR) network model capable of capturing physical queues and spillback, by assuming that the network supply is bounded away from zero or is within desired boundedness. In addition, Han et al (2015b) proposed a bi-level model for traffic network signal control problems where a continuum signal model is employed to ensure the existence of DUE in the lower level problem. As a remark, the dynamic user equilibrium studied in the last two decades is usually analytically expressed of Nash-like equilibrium condition (Han et al, 2015a).…”

Section: Wardrop's User Equilibrium and Bounded Rationality Behaviormentioning

confidence: 99%

Capacitated transit service network design with boundedly rational agents

Liu

Zhou

2016

Transportation Research Part B: Methodological

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This paper proposes a new alternative modeling framework to systemically account for boundedly rational decision rules of travelers in a dynamic transit service network with tight capacity constraints. Within a time-discretized space-time network, the time-dependent transit services are characterized by traveling arcs and waiting arcs with constant travel times. Instead of using traditional flow-based formulations, an agent-based integer linear formulation is proposed to represent boundedly rational decisions under strictly imposed capacity constraints, due to vehicle carrying capacity and station storage capacity. Focusing on a viable and limited sets of space-time path alternatives, the proposed single-level optimization model can be effectively decomposed to a time-dependent routing subproblem for individual agents and a knapsack sub-problem for service arc selections through the Lagrangian decomposition. In addition, several practically important modeling issues are discussed, such as dynamic and personalized transit pricing, passenger inflow control as part of network restraint strategies, and penalty for early/late arrival. Finally, numerical experiments are performed to demonstrate the methodology and computational efficiency of our proposed model and algorithm.

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A bi-level model of dynamic traffic signal control with continuum approximation

Cited by 36 publications

References 55 publications

The Energy-Efficient Dynamic Route Planning for Electric Vehicles

The Energy-Efficient Dynamic Route Planning for Electric Vehicles

Scalable Computing Architecture for Time-Dependent Transportation Optimization Problems Based on High-Performance Computing Techniques

Capacitated transit service network design with boundedly rational agents

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