arxiv_ai 90% Match Research Paper Autonomous driving engineers,Robotics researchers,Computer vision researchers,AI developers for transportation 3 weeks ago

TopoStreamer: Temporal Lane Segment Topology Reasoning in Autonomous Driving

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📄 Abstract

Abstract: Lane segment topology reasoning constructs a comprehensive road network by capturing the topological relationships between lane segments and their semantic types. This enables end-to-end autonomous driving systems to perform road-dependent maneuvers such as turning and lane changing. However, the limitations in consistent positional embedding and temporal multiple attribute learning in existing methods hinder accurate roadnet reconstruction. To address these issues, we propose TopoStreamer, an end-to-end temporal perception model for lane segment topology reasoning. Specifically, TopoStreamer introduces three key improvements: streaming attribute constraints, dynamic lane boundary positional encoding, and lane segment denoising. The streaming attribute constraints enforce temporal consistency in both centerline and boundary coordinates, along with their classifications. Meanwhile, dynamic lane boundary positional encoding enhances the learning of up-to-date positional information within queries, while lane segment denoising helps capture diverse lane segment patterns, ultimately improving model performance. Additionally, we assess the accuracy of existing models using a lane boundary classification metric, which serves as a crucial measure for lane-changing scenarios in autonomous driving. On the OpenLane-V2 dataset, TopoStreamer demonstrates significant improvements over state-of-the-art methods, achieving substantial performance gains of +3.0% mAP in lane segment perception and +1.7% OLS in centerline perception tasks.

Authors (11)

Yiming Yang

Yueru Luo

Bingkun He

Hongbin Lin

Suzhong Fu

Chao Zheng

+5 more

Submitted

July 1, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

TopoStreamer is an end-to-end temporal perception model that improves lane segment topology reasoning for autonomous driving. It introduces streaming attribute constraints for temporal consistency, dynamic lane boundary positional encoding for up-to-date information, and lane segment denoising, addressing limitations in existing methods for accurate road network reconstruction.

Business Value

Enhances the safety and reliability of autonomous driving systems by enabling more accurate understanding of road networks and lane configurations, crucial for complex maneuvers like lane changes and turns.

Paper Metadata

Innovation Type

Algorithmic Improvement

Deployment Feasibility

High, as it's designed for real-time perception in autonomous vehicles.

Limitations Addressed

Inconsistent positional embedding in existing methods,Limited temporal multiple attribute learning,Difficulty in accurate road network reconstruction,Challenges in lane segment topology reasoning

Technical Tags

lane segment topologyautonomous drivingtemporal perceptionroad network reconstructionpositional encodingattribute learningstreaming constraintsdynamic encodinglane detectionend-to-end perception

Research Topics

Autonomous Driving PerceptionRoad Network UnderstandingTemporal ModelingComputer VisionMachine Learning for Transportation

Methods & Architectures

streaming attribute constraintsdynamic lane boundary positional encodinglane segment denoisingend-to-end temporal perception model TopoStreamer

Applications & Tasks

Autonomous Driving Intelligent Transportation Systems Inconsistent positional embeddingTemporal multiple attribute learningAccurate roadnet reconstructionLane segment topology reasoning Lane segment topology reasoningRoad network reconstructionLane changing maneuversTurning maneuvers

Related Fields

Computer VisionRoboticsAutonomous DrivingMachine LearningPerception Systems

Keywords

lane topologyautonomous drivingtemporal perceptionroad networkpositional encodingattribute learningstreamingdynamic encodinglane detectionperceptionend-to-endcomputer visiondeep learning

Academic Context

#Autonomous Driving Perception#Road Network Understanding#Temporal Modeling#Computer Vision#Machine Learning for Transportation

Commercial Potential

Potential Products

Advanced perception modules for autonomous vehiclesHD map generation tools

Target Industries

AutomotiveTransportationLogistics

Use Case Examples

Enabling safe lane changes in complex intersectionsAccurate navigation through multi-lane highwaysUnderstanding road closures and detours

Competitive Edge

Offers improved accuracy and temporal consistency in lane topology reasoning compared to existing methods.

Market Opportunity

Large market for autonomous driving technology.

Revenue Models

Integration into autonomous driving software stackslicensing.

Resource Requirements

Compute Needs

Requires real-time processing capabilities on automotive-grade hardware.

Data Requirements

Annotated driving datasets with lane markings and topology information.

Deployment Constraints

Real-time performance, robustness to varying environmental conditions.

Scalability

Designed for real-time processing in autonomous driving systems.

Production Readiness

Maturity Level

Research/Development

Time to Market

Medium

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