Adaptive Signal Control for Overflow Prevention at Isolated Intersections Based on Fuzzy Control

Yao, Tianyu; Zhang, Cheng; Zhao, Jing; Gupta, Ankit; Mondal, Satyajit

doi:10.1177/03611981221143380

Cited by 4 publications

(3 citation statements)

References 48 publications

(48 reference statements)

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“…The traffic signal timing plan optimization procedure employed typically takes on one of two forms: fixed timing plans (off-line) and adaptive signal controls (on-line), with their own advantages and disadvantages in practice. Yao et al [32] proposed an adaptive signal control method based on fuzzy control, which extends existing real-time adaptive signal control to explicitly consider the risk of queue spillover. The integrated optimization of all parameters requires expensive calculations, which are more suitable for offline methods.…”

Section: Literature Reviewmentioning

confidence: 99%

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A two‐stage robust optimal traffic signal control with reversible lane for isolated intersections

Sun,

Wang,

et al. 2023

IET Intelligent Trans Sys

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The integrated design of traffic signal control (TSC) and reversible lane (RL) is an effective way to solve the problem of tidal congestion with uncertainty at isolated intersections, because of its advantage in making full use of temporal‐spatial transportation facilities. Considering the contradiction between the dynamic TSC scheme and the fixed RL scheme in one period, a two‐stage optimization method based on improved mean‐standard deviation (MSD) model for isolated intersections with historical and real‐time uncertain traffic flow is proposed. In the first stage, applying the same‐period historical data of multiple days, a robust optimal traffic signal control model with reversible lane based on MSD model (MSD‐RTR model) is put forward to obtain the fixed RL scheme and the compatible initial TSC scheme. A double‐layer nested genetic algorithm (DN‐GA) is designed to solve this model. In the second stage, applying real‐time period data and multi‐day same‐period historical data, a robust optimal dynamic traffic signal control model based on MSD model (MSD‐RDT model) is put forward to obtain the dynamic TSC scheme. Three modes which reflect the different weights of historical period and real‐time period in this MSD‐RDT model are presented to improve the model stability, and a multi‐mode genetic algorithm (MM‐GA) is designed. Finally, a case study is presented to demonstrate the efficiency and applicability of the proposed models and algorithms.

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Section: Literature Reviewmentioning

confidence: 99%

“…Yao et al. [32] proposed an adaptive signal control method based on fuzzy control, which extends existing real‐time adaptive signal control to explicitly consider the risk of queue spillover. The integrated optimization of all parameters requires expensive calculations, which are more suitable for offline methods.…”

Section: Literature Reviewmentioning

confidence: 99%

A two‐stage robust optimal traffic signal control with reversible lane for isolated intersections

Sun,

Wang,

et al. 2023

IET Intelligent Trans Sys

View full text Add to dashboard Cite

show abstract

“…Queue spillback is a critical issue in traffic signal control operations. Many studies have addressed this issue, focusing on preventing spillbacks at isolated intersections [35], coordinated controlled arterials [36][37][38][39], and intersections connected to freeway on-ramps [40,41]. Despite efforts by traffic engineers and researchers to mitigate spillbacks through signal plan design, they can still occur during peak hours in urban areas, possibly due to excessive traffic volumes.…”

Section: Introductionmentioning

confidence: 99%

An emergency vehicle traffic signal preemption system considering queue spillbacks along routes and negative impacts on non‐priority traffic

Chen,

Wang,

et al. 2024

IET Intelligent Trans Sys

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In urban areas, emergency vehicles (EVs) need efficient traffic signal preemption to ensure timely responses during peak hours. While emergency vehicle traffic signal preemption (EVTSP) has garnered significant attention in the literature, the issues of queue spillbacks and negative impacts on non‐priority traffic have been relatively underreported. These issues are particularly critical during peak hours, notably in densely populated urban areas. This study presents an EVTSP system that considers queue spillbacks on approaches along the routes of EVs and the negative impacts of signal preemption on non‐priority traffic. The proposed control system has four key components: (1) a queue length management algorithm to ensure that an EV will not be impeded by excessive queues, particularly on its initial approaches along its route; (2) a signal preemption algorithm to guarantee uninterrupted passage of an EV even for approaches experiencing queue spillbacks; (3) a traffic status recovery algorithm to alleviate the extra waiting time for non‐priority vehicles after an EV crosses each intersection; and (4) a signal plan recovery algorithm to smoothly transit traffic signals to normal operation. The experimental results confirm that the proposed system considerably improves the travel time of an EV and mitigates the negative impacts on non‐priority traffic.

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Integrative review of data sciences for driving smart mobility in intelligent transportation systems

Jalil,

Xia,

Chen

et al. 2024

Computers and Electrical Engineering

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Adaptive Signal Control for Overflow Prevention at Isolated Intersections Based on Fuzzy Control

Cited by 4 publications

References 48 publications

A two‐stage robust optimal traffic signal control with reversible lane for isolated intersections

A two‐stage robust optimal traffic signal control with reversible lane for isolated intersections

An emergency vehicle traffic signal preemption system considering queue spillbacks along routes and negative impacts on non‐priority traffic

Integrative review of data sciences for driving smart mobility in intelligent transportation systems

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