State-of-Art Review of Traffic Light Synchronization for Intelligent Vehicles: Current Status, Challenges, and Emerging Trends
Abstract
:1. Introduction
- To explore the key role of real-time traffic signal control technology in managing congestion at road junctions within smart cities.
- To summarize the benefits and implementation status of traffic light synchronization and directions for future research for networking traffic lights at intersections of roads.
2. Background of Traffic Signal Synchronization for Intelligent Vehicles
2.1. Overview of the Traffic Signal Control Technology
2.1.1. Traditional Traffic Control Methods
2.1.2. Vision-Based Traffic Control Methods
2.1.3. Sensor-Based Traffic Control Methods
2.1.4. Connected Vehicle-Based Traffic Control Methods
2.1.5. Learning-Based Traffic Control Methods
2.1.6. Miscellaneous Traffic Control Methods
3. Advantages of Synchronizing the Traffic Lights
4. Development Status of Synchronization of Traffic Lights
5. Discussion and Potential Directions
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A
Reference Number | Objective | Strategies Used | Disadvantages | Comments |
---|---|---|---|---|
[62] | Traffic light synchronization strategy for saturated road networks | Long green and long red method for highly saturated road networks | Not suitable to the undersaturated HGRN |
|
[63] | To synchronize traffic signals | Multiagent fuzzy logic and Q-learning |
| |
[64] | Traffic signal synchronization with dynamic timer value | Image processing and Raspberry Pi in synchronization with cloud |
|
|
[65] | Self-organized traffic light control based on sensors |
| No synchronization of traffic signals | Increases traffic flow efficiency and reduce the waiting time at intersections |
[67] | Wireless traffic light synchronization system |
| For single-lane traffic control only |
|
[68] | Rerouting and synchronization of traffic | Using the Long Range (LoRa) module | Synchronization for two traffic signals only |
|
[69] | Synchronization scheme for traffic light controller |
| Difficulty of modeling the FSM | Flexible architecture that uses a clock divider to give a delay in a certain state |
[71] | Distributed traffic signal control method based on spontaneous synchronization |
| Mathematical complexity |
|
[72,73] | Distributed approach for synchronizing traffic signals | CTM-UT i.e., (Cell Transmission Model for Urban Traffic) via simulation | Computational complexity | Surrogate method (SM), based on an online and stochastic control scheme, used for synchronizing the traffic signals |
[74] | IoT-based traffic signal synchronization method | Uses magnetic sensors as the main IoT sensing technology | Not suitable for all kinds of road networks | Reduces the average travel time up to 39% using the road traffic simulator SUMO |
[75] | Traffic signals synchronization for Bus Rapid Transit systems | Parallel evolutionary algorithm | In the context of Bus Rapid Transit systems |
|
[76] | Model for synchronizing the traffic lights at road intersections | Hybrid metaheuristic approach that combines variable neighborhood search and Tabu search | Mathematical and computational complexity | Flexible and robust approach |
[77] | Decentralized spatial decomposition of network for synchronization of traffic signals at the road junctions | Uses platoon model to calculate the weighted sum of delays induced by signalized crossings | More robust to failure | Distributed communication architecture for networking of traffic lights |
[79] | To synchronize the traffic signals at intersections | Using floating car data (FCD) | Only a beginning step toward addressing the synchronization problem; need for more comprehensive optimization algorithms for general cases | Increases the traffic safety and energy efficiency of transportation systems |
[80] | Traffic signal synchronization in a small urban road network | Cellular automation | Synchronization for two traffic signals only | Minimize total delay and maximize the flow |
[82] | Survey of the synchronization techniques | Highlight current developments and give future perspectives on synchronization in V2V and V2X | Not Specified | Reviews synchronization standards and approaches for V2V and D2D-enabled cellular networks |
[83] | Vehicle-to-Everything (V2X) speed synchronization at road junctions | Rule-based algorithm | Based on optimal scheduling | Improves the performance of cooperative intersection management |
Reference Number | Objective/Context | Intersection | Traffic Signal Control Strategies | Source of Data Collection | Comments | |||||
---|---|---|---|---|---|---|---|---|---|---|
Isolated | Single | Network | Real Time | Fixed Time | Sensors/Detectors | Field Cameras | GPS/DSRC | |||
[8] | Split Cycle Offset Optimization Technique (SCOOT) | ✓ | ✓ | Detectors |
| |||||
[9] | Sydney Cooperation Adaptive Traffic System (SCATS) | ✓ | ✓ | Sensors |
| |||||
[10] | Optimized Policies for Adaptive Control (OPAC) | ✓ | ✓ | ✓ |
| |||||
[11] | Real-Time Hierarchical Optimized Distributed Effective System (RHODES) | ✓ | ✓ | ✓ | Decomposition of traffic network by modules that individually deal with sub-problems | |||||
[15] | Traffic signal control of road networks in real time | ✓ | ✓ | Based on Webster procedure | ||||||
[16] | Traffic monitoring and prediction on roads | ✓ | ✓ | ✓ |
| |||||
[17,18] | Travel time prediction framework | Freeway | ✓ | Robust Travel Time framework |
| |||||
[19] | To reduce waiting time of vehicles at road intersections | ✓ | ✓ | ✓ | A video-based adaptive traffic signaling system | |||||
[21] | Assign equal green signal durations and arrange fair lane departure at an intersection | ✓ | ✓ | GPS | Adaptive traffic signal timings and lane scheduling | |||||
[22] | To enhance the flow of traffic on current road network using a data fusion approach | ✓ | ✓ | GPS |
| |||||
[23] | Traffic signal control system | ✓ | ✓ | ✓ |
| |||||
[27] | To minimize the waiting time at a crossroad | ✓ | ✓ | ✓ |
| |||||
[28,29] | WSN-based traffic light control systems | ✓ | ✓ | ✓ |
| |||||
[30] | TSC at signalized intersections | ✓ | ✓ | V2V communication |
| |||||
[31] | V2V traffic control for traffic management at intersections | ✓ | ✓ | DSRC | Virtual Traffic Light phenomenon based on DSRC | |||||
[33,34] | Removal of intersection traffic signal infrastructures | ✓ | ✓ | DSRC |
| |||||
[35] | Intersection traffic control scheme | ✓ | DSRC | Based on DSRC-Actuated Traffic Control | ||||||
[36] | Autonomous intersection management (AIM) | ✓ | ✓ | Simulator |
| |||||
[40] | Reinforcement Learning based traffic signal control | ✓ | ✓ | Mathematical Model |
| |||||
[41] | Traffic signal control at a very large scale using Multiagent reinforcement learning (MARL) technique | ✓ | ✓ | Simulator |
| |||||
[45] | Deep Q-learning algorithm based system for partially detected intelligent vehicles | ✓ | ✓ | DSRC |
|
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Tomar, I.; Sreedevi, I.; Pandey, N. State-of-Art Review of Traffic Light Synchronization for Intelligent Vehicles: Current Status, Challenges, and Emerging Trends. Electronics 2022, 11, 465. https://doi.org/10.3390/electronics11030465
Tomar I, Sreedevi I, Pandey N. State-of-Art Review of Traffic Light Synchronization for Intelligent Vehicles: Current Status, Challenges, and Emerging Trends. Electronics. 2022; 11(3):465. https://doi.org/10.3390/electronics11030465
Chicago/Turabian StyleTomar, Ishu, Indu Sreedevi, and Neeta Pandey. 2022. "State-of-Art Review of Traffic Light Synchronization for Intelligent Vehicles: Current Status, Challenges, and Emerging Trends" Electronics 11, no. 3: 465. https://doi.org/10.3390/electronics11030465
APA StyleTomar, I., Sreedevi, I., & Pandey, N. (2022). State-of-Art Review of Traffic Light Synchronization for Intelligent Vehicles: Current Status, Challenges, and Emerging Trends. Electronics, 11(3), 465. https://doi.org/10.3390/electronics11030465