Intelligent Transportation Systems (ITS)
Enhancing Traffic Efficiency Through Deep Reinforcement Learning-Based Traffic Signal Control with Cooperative Connected and Autonomous Vehicles
Optimizing traffic performance using artificial intelligence (AI) has consistently been a prominent direction in the development of intelligent transportation systems. While numerous studies have proposed methodologies for integrating cooperative connected and autonomous vehicles (CCAVs) with traffic signal systems via V2X communication, they often rely on simplified control strategies or lack effective coordination between signal timing and vehicle behavior. In this study, we propose a novel, integrated traffic signal control strategy combined with CAVs using deep reinforcement learning. Our key differentiation lies in the simultaneous optimization of signal phases using the Soft Actor-Critic (SAC) algorithm and the regulation of CCAVs via cooperative adaptive cruise control and Green Light Optimal Speed Advisory. This dual approach allows the signal controller to leverage rich state information from CAVs and the road infrastructure, enabling more anticipatory and cooperative decisions. The proposed approach is implemented and evaluated through various scenarios using the Simulation of Urban MObility (SUMO) platform. The results demonstrate the superior learning performance and robustness of the proposed model. Specifically, our proposed model achieves a significant reduction in average vehicle waiting time by up to over 80% compared to baseline models under high-demand scenarios (4800–6000 veh/h). These findings underscore the critical importance of joint optimization in future intelligent transportation systems, paving the way for more resilient urban traffic management.
Executive Impact: Revolutionizing Urban Mobility
This research introduces the SAC_CCAV framework, a groundbreaking approach to intelligent traffic management. By jointly optimizing traffic signal timing with cooperative connected and autonomous vehicle (CCAV) behavior, it establishes a tightly coupled vehicle-infrastructure control loop. The integration of Soft Actor-Critic (SAC) with Cooperative Adaptive Cruise Control (CACC) and Green Light Optimal Speed Advisory (GLOSA) dramatically reduces congestion, improves throughput, and enhances overall system robustness.
0
Waiting Time Reduction
0
Traffic Throughput Increase
0
Average Speed Improvement
0
Robustness in High Demand
Deep Analysis & Enterprise Applications
Select a topic to dive deeper, then explore the specific findings from the research, rebuilt as interactive, enterprise-focused modules.
Integrated Deep Reinforcement Learning and CAV Control
The proposed SAC_CCAV framework integrates adaptive traffic signal control with cooperative vehicle longitudinal behavior. It leverages Soft Actor-Critic (SAC) for robust signal phase optimization, combined with CACC for stable platoon coordination and GLOSA for signal-aware speed planning, all facilitated by real-time V2V and V2I communication.
Enterprise Process Flow
Formulate ATSC as MDP
→
Optimize with SAC Algorithm
→
Integrate CACC for Platoon Stability
→
Develop GLOSA for Signal-Aware Speed
→
V2V/V2I Communication
→
Coordinated Infrastructure-Vehicle Interaction
Unprecedented Performance Against Industry Baselines
The SAC_CCAV model consistently outperforms conventional deep reinforcement learning (DRL) algorithms and traditional model-based controllers across various traffic demand scenarios. Its key strength lies in its ability to maintain high efficiency and stability even under severe congestion.
80%+
Reduction in Average Vehicle Waiting Time at High Demand (4800-6000 veh/h)
| Feature | SAC_CCAV Advantage | Baseline Limitations (DDPG, DQN, A2C, MP) |
|---|---|---|
| Convergence & Stability |
|
|
| Waiting Time Reduction |
|
|
| Throughput |
|
|
| Average Speed |
|
|
| Robustness |
|
|
Optimizing for the Future: The Power of CCAV Penetration
This study demonstrates how increasing the penetration rate of Cooperative Connected and Autonomous Vehicles (CCAVs) significantly enhances overall traffic efficiency at signalized intersections. The coordinated vehicle behavior, facilitated by CACC and GLOSA, improves signal controller effectiveness and reduces congestion.
Case Study: Impact of CCAV Penetration Rate (Traffic Volume: 5000 veh/h)
With a 25% CCAV penetration, the average speed was 3.76 m/s, 1223 vehicles passed the intersection, and the average travel time was 263.922 seconds.
However, by increasing the CCAV penetration to 100%, the system achieved a remarkable improvement:
- Average Speed increased to 5.43 m/s
- Number of Vehicles Passed surged to 4310 vehs
- Average Travel Time reduced to 182.067 seconds
The data shows a clear trend: higher CCAV penetration leads to smoother traffic flow, better signal-vehicle coordination, and improved network performance, underscoring the value of V2X integration.
Quantify Your AI Advantage
Estimate the potential ROI for implementing advanced AI solutions in your organization. This calculator provides a preliminary insight into cost savings and reclaimed operational hours.
Your AI Implementation Roadmap
A typical timeline for integrating advanced AI solutions like SAC_CCAV into your operations, from initial strategy to full-scale deployment and continuous optimization.
Phase 01: Strategic Assessment & Pilot Design
Detailed analysis of existing traffic infrastructure, data sources, and operational goals. Design of a pilot program targeting a specific intersection or corridor to validate SAC_CCAV's effectiveness in a controlled environment. Includes stakeholder workshops and resource planning.
Phase 02: System Integration & Training
Deployment of V2X communication infrastructure and integration with existing traffic management systems. Data collection and pre-processing for DRL agent training. Initial training of the SAC agent in simulation (SUMO) and fine-tuning with real-world or simulated edge data.
Phase 03: Pilot Deployment & Optimization
Rollout of the SAC_CCAV system in the pilot area, starting with a limited CCAV penetration. Continuous monitoring of performance metrics (waiting time, throughput, speed) and iterative optimization of SAC parameters. Gradual increase in CCAV integration and system scale.
Phase 04: Full-Scale Rollout & Continuous Improvement
Expansion of the SAC_CCAV framework across the entire urban network. Implementation of advanced features like multi-intersection coordination. Establishment of a feedback loop for continuous learning and adaptation to evolving traffic patterns and infrastructure changes, ensuring long-term efficiency gains.
Ready to Transform Your Operations?
The future of intelligent urban mobility is here. Let's explore how these cutting-edge AI solutions can be tailored to your specific challenges and goals.
Ready to Get Started?
Book Your Free Consultation.
Let's Discuss Your AI Strategy!
Lets Discuss Your Needs
Select a Date
Sun
Mon
Tue
Wed
Thu
Fri
Sat