Jingqin Gao

Fan Zuo, Donglin Zhou, Jingqin Gao et al.

Accurate, scalable traffic monitoring is critical for real-time and long-term transportation management, particularly during disruptions such as natural disasters, large construction projects, or major policy changes like New York City's first-in-the-nation congestion pricing program. However, widespread sensor deployment remains limited due to high installation, maintenance, and data management costs. While traffic cameras offer a cost-effective alternative, existing video analytics struggle with dynamic camera viewpoints and massive data volumes from large camera networks. This study presents an end-to-end AI-based framework leveraging existing traffic camera infrastructure for high-resolution, longitudinal analysis at scale. A fine-tuned YOLOv11 model, trained on localized urban scenes, extracts multimodal traffic density and classification metrics in real time. To address inconsistencies from non-stationary pan-tilt-zoom cameras, we introduce a novel graph-based viewpoint normalization method. A domain-specific large language model was also integrated to process massive data from a 24/7 video stream to generate frequent, automated summaries of evolving traffic patterns, a task far exceeding manual capabilities. We validated the system using over 9 million images from roughly 1,000 traffic cameras during the early rollout of NYC congestion pricing in 2025. Results show a 9% decline in weekday passenger vehicle density within the Congestion Relief Zone, early truck volume reductions with signs of rebound, and consistent increases in pedestrian and cyclist activity at corridor and zonal scales. Experiments showed that example-based prompts improved LLM's numerical accuracy and reduced hallucinations. These findings demonstrate the framework's potential as a practical, infrastructure-ready solution for large-scale, policy-relevant traffic monitoring with minimal human intervention.

Zilin Bian, Jingqin Gao, Kaan Ozbay et al.

While deep learning has shown success in predicting traffic states, most methods treat it as a general prediction task without considering transportation aspects. Recently, graph neural networks have proven effective for this task, but few incorporate external factors that impact roadway capacity and traffic flow. This study introduces the Roadway Capacity Driven Graph Convolution Network (RCDGCN) model, which incorporates static and dynamic roadway capacity attributes in spatio-temporal settings to predict network-wide traffic states. The model was evaluated on two real-world datasets with different transportation factors: the ICM-495 highway network and an urban network in Manhattan, New York City. Results show RCDGCN outperformed baseline methods in forecasting accuracy. Analyses, including ablation experiments, weight analysis, and case studies, investigated the effect of capacity-related factors. The study demonstrates the potential of using RCDGCN for transportation system management.

Zilin Bian, Jingqin Gao, Kaan Ozbay et al.

Although traffic prediction has been receiving considerable attention with a number of successes in the context of intelligent transportation systems, the prediction of traffic states over a complex transportation network that contains different road types has remained a challenge. This study proposes a multi-scale graph wavelet temporal convolution network (MSGWTCN) to predict the traffic states in complex transportation networks. Specifically, a multi-scale spatial block is designed to simultaneously capture the spatial information at different levels, and the gated temporal convolution network is employed to extract the temporal dependencies of the data. The model jointly learns to mount multiple levels of the spatial interactions by stacking graph wavelets with different scales. Two real-world datasets are used in this study to investigate the model performance, including a highway network in Seattle and a dense road network of Manhattan in New York City. Experiment results show that the proposed model outperforms other baseline models. Furthermore, different scales of graph wavelets are found to be effective in extracting local, intermediate and global information at the same time and thus enable the model to learn a complex transportation network topology with various types of road segments. By carefully customizing the scales of wavelets, the model is able to improve the prediction performance and better adapt to different network configurations.

Ding Wang, Fan Zuo, Jingqin Gao et al.

The COVID-19 pandemic has affected travel behaviors and transportation system operations, and cities are grappling with what policies can be effective for a phased reopening shaped by social distancing. This edition of the white paper updates travel trends and highlights an agent-based simulation model's results to predict the impact of proposed phased reopening strategies. It also introduces a real-time video processing method to measure social distancing through cameras on city streets.

Fan Zuo, Jingxing Wang, Jingqin Gao et al.

The COVID-19 outbreak has dramatically changed travel behavior in affected cities. The C2SMART research team has been investigating the impact of COVID-19 on mobility and sociability. New York City (NYC) and Seattle, two of the cities most affected by COVID-19 in the U.S. were included in our initial study. An all-in-one dashboard with data mining and cloud computing capabilities was developed for interactive data analytics and visualization to facilitate the understanding of the impact of the outbreak and corresponding policies such as social distancing on transportation systems. This platform is updated regularly and continues to evolve with the addition of new data, impact metrics, and visualizations to assist public and decision-makers to make informed decisions. This paper presents the architecture of the COVID related mobility data dashboard and preliminary mobility and sociability metrics for NYC and Seattle.