A group-based traffic signal control with adaptive learning ability

Jin, Junchen; Ma, Xiaoliang

doi:10.1016/j.engappai.2017.07.022

Cited by 55 publications

(42 citation statements)

References 17 publications

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“…In particular, an on-line learning process will be facilitated to adaptively enhance the models when streaming data is received. In addition, the approach will be integrated into a group-based intelligent signal control system proposed by Jin and Ma [8] with a proper understanding of traffic system. The conditional distribution, P(y N+1 |X, x N+1 , y, θ, η), can be written as P(y N+1 |X, x N+1 , y, θ, η) = P(y, y N+1 |X, x N+1 , θ, η) P(y|X, x N+1 , y, θ, η)…”

Section: Discussionmentioning

confidence: 99%

“…While many studies in literature were devoted to link-based TSE with regards to intersections controlled by fixedtime traffic signal, group-based and lane-based control approaches provided benefits due to more flexible phase structures and sequences for both conventional traffic signal systems [e.g., 9,15] and adaptive signal systems [8]. Lanebased traffic states are one of the most important inputs for enabling the functionalities of group-based and lane-based controllers.…”

Section: Relevant Studiesmentioning

confidence: 99%

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A non-parametric Bayesian framework for traffic-state estimation at signalized intersections

Jin

2019

Information Sciences

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An accurate and practical traffic-state estimation (TSE) method for signalized intersections plays an important role for real-time operations to facilitate efficient traffic management. This paper presents a generalized modeling framework for estimating traffic states at signalized intersections. The framework is non-parametric and data-driven, without the requirement on explicit models of traffic. Additionally, in principle, any type of data source together with any type of signal controller can be incorporated with the proposed framework. The Bayesian filter (BF) approach is the core of the framework and introduces a recursive state estimation process. The required transition and measurement models of the BFs are trained using Gaussian process (GP) regression models with respect to a set of historical data. A Gaussian process model uses kernel functions to describe the proximity among data points, and the hyper-parameters adopted in the GP model are optimized according to the training data. In addition to the detailed derivation of the integration of BFs and GP regression models, an algorithm based on the extended Kalman filter is presented for real-time traffic estimation. The effectiveness of the proposed framework is demonstrated through several numerical experiments using data generated in microscopic traffic simulations. Both fixed-location data (i.e., loop detector) and mobile data (i.e., connected vehicle) are examined with the framework. As a result, the method performs well for the tested traffic conditions. In particular, the estimator provides a competitive estimation accuracy merely using the position information of a small portion of vehicles at the intersection. The approach is suitable for a short-term estimation requirement, which is normally a challenging task in traffic control and operations.

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Section: Discussionmentioning

confidence: 99%

Section: Relevant Studiesmentioning

confidence: 99%

A non-parametric Bayesian framework for traffic-state estimation at signalized intersections

Jin

2019

Information Sciences

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“…Group-based phasing approaches have proved their utilities by dynamically generating phase structures and sequences with respect to traffic detected at intersection (e.g., Wong and Wong, 2003;Jin et al, 2017b). A previous study by the same authors proposed an RL-based adaptive TLC system suitable for group-based phasing strategies (Jin and Ma, 2017). The system showed the benefits in improving traffic mobility when compared to a conventional logic-based timing approach.…”

Section: Relevant Studiesmentioning

confidence: 99%

“…This paper extends the RL-based intersection adaptive control approach proposed in Jin and Ma (2017) for operating a network of signalized intersections. The rest of this paper is organized as follows.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical multi-agent control of traffic lights based on collective learning

Jin

2018

Engineering Applications of Artificial Intelligence

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“…However, most adaptive signal control systems work with stage-based control in which phase sequence is predetermined. To generate phase sequences dynamically, some group-based control methods [18][19][20][21] have been proposed. Recently, some innovative methods such as machine learning, artificial intelligence and reinforcement learning have been used in the adaptive signal control method [22][23][24][25][26][27], and Jing et al [28] proposed an adaptive signal control method in a connected vehicle environment.…”

Section: Introductionmentioning

confidence: 99%

An Adaptive Signal Control Method with Optimal Detector Locations

Zhu

Ke²,

Guo

et al. 2019

Sustainability

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The adaptive traffic signal control system is a key component of intelligent transportation systems and has a primary role in effectively reducing traffic congestion. The high costs of implementation and maintenance limit the applicability of the adaptive traffic signal control system, especially in developing countries. This paper proposes a low-cost adaptive signal control method that is easy to implement. Two detectors are installed in each vehicle lane at an optimal location determined by the proposed method to detect green and red redundancy time, based on which the original signal timing is adjusted through a signal controller. The proposed method is evaluated through case studies with low and high volume-to-capacity ratio intersections. The results show that the proposed adaptive signal control method can significantly reduce total traffic delay at intersections.

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A group-based traffic signal control with adaptive learning ability

Cited by 55 publications

References 17 publications

A non-parametric Bayesian framework for traffic-state estimation at signalized intersections

A non-parametric Bayesian framework for traffic-state estimation at signalized intersections

Hierarchical multi-agent control of traffic lights based on collective learning

An Adaptive Signal Control Method with Optimal Detector Locations

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