Cluster Formations of Free and Congested Flows in Urban Road Networks (2408.08122v1)

Abstract: Understanding traffic behavior is crucial for enhancing the stable functioning and safety of transportation systems. Previous percolation-based transportation studies have analyzed transition behaviors from free-flow to traffic-jam states, with a focus on robustness and resilience during congestion. However, relatively less attention is paid to the percolation analysis of the free-flow states, specifically how free-flow clusters form and grow. In this study, we investigate the percolation patterns of two opposing traffic scenarios -- traffic jam state and free-flow state -- within the same road network using Chengdu taxi data and compare their percolating behaviors. Our analysis reveals differences between the two scenarios in the growth patterns of the giant connected component (GCC), which is captured by a persistent gap between the GCC size curves, particularly during peak hours. We attribute these disparities to a long-range spatial correlation of traffic speed within a road network. Empirically, we find distinct long-range spatial correlations in traffic, using rescaled taxi speeds on roads, and we examine their relationship with each percolation pattern. Our analysis provides an integrated view of traffic dynamics and uncovers intrinsic traffic correlations within urban areas that drive these intriguing percolation patterns. Our findings also offer valuable metrics for effective traffic management and accident prevention strategies, aligning with urban transportation safety and reliability goals. These insights are beneficial for assessing and designing resilient urban road networks that maintain functionality under stress, ultimately improving the reliability of traffic assessments and reducing accidents.