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Main Authors: Poudel, Bibek, Zhu, Lei, Heaslip, Kevin, Swaminathan, Sai, Li, Weizi
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.21311
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author Poudel, Bibek
Zhu, Lei
Heaslip, Kevin
Swaminathan, Sai
Li, Weizi
author_facet Poudel, Bibek
Zhu, Lei
Heaslip, Kevin
Swaminathan, Sai
Li, Weizi
contents Modern vision systems can detect, track, and forecast urban actors at scale, yet translating perception outputs to urban design remains limited. We introduce DeCoR, a two-stage reinforcement learning framework that leverages flow observations to co-optimize crosswalk layout and network-level signal control. The design stage encodes the pedestrian network as a graph and learns a generative policy that parameterizes a Gaussian mixture model over crosswalk location and width, from which new crosswalks are sampled. For each layout, a shared control policy learns adaptive signal timings to minimize joint pedestrian and vehicle delay. On a 750 m real-world urban corridor with demand sensed from video and Wi-Fi logs, DeCoR learns a layout that reduces pedestrian arrival time to their nearest crosswalk by 23% while using fewer crosswalks than existing configurations. On the control side, DeCoR reduces pedestrian and vehicle wait time by 79% and 65%, respectively, relative to fixed-time signalization. Further, the control policy generalizes to demands outside of training and is robust to layout changes without retraining.
format Preprint
id arxiv_https___arxiv_org_abs_2605_21311
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle DeCoR: Design and Control Co-Optimization for Urban Streets Using Reinforcement Learning
Poudel, Bibek
Zhu, Lei
Heaslip, Kevin
Swaminathan, Sai
Li, Weizi
Machine Learning
Artificial Intelligence
Modern vision systems can detect, track, and forecast urban actors at scale, yet translating perception outputs to urban design remains limited. We introduce DeCoR, a two-stage reinforcement learning framework that leverages flow observations to co-optimize crosswalk layout and network-level signal control. The design stage encodes the pedestrian network as a graph and learns a generative policy that parameterizes a Gaussian mixture model over crosswalk location and width, from which new crosswalks are sampled. For each layout, a shared control policy learns adaptive signal timings to minimize joint pedestrian and vehicle delay. On a 750 m real-world urban corridor with demand sensed from video and Wi-Fi logs, DeCoR learns a layout that reduces pedestrian arrival time to their nearest crosswalk by 23% while using fewer crosswalks than existing configurations. On the control side, DeCoR reduces pedestrian and vehicle wait time by 79% and 65%, respectively, relative to fixed-time signalization. Further, the control policy generalizes to demands outside of training and is robust to layout changes without retraining.
title DeCoR: Design and Control Co-Optimization for Urban Streets Using Reinforcement Learning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2605.21311