research-article

RoadRunner: improving the precision of road network inference from GPS trajectories

Authors:

Favyen Bastani,

Mohammad Alizadeh,

Hari Balakrishnan,

Sam MaddenAuthors Info & Claims

SIGSPATIAL '18: Proceedings of the 26th ACM SIGSPATIAL International Conference on Advances in Geographic Information Systems

Pages 3 - 12

https://doi.org/10.1145/3274895.3274974

Published: 06 November 2018 Publication History

Abstract

Current approaches to construct road network maps from GPS trajectories suffer from low precision, especially in dense urban areas and in regions with complex topologies such as overpasses and underpasses, parallel roads, and stacked roads. This paper proposes a two-stage method to improve precision without sacrificing recall (coverage). The first stage, RoadRunner, is a method that can generate high-precision maps even in challenging scenarios by incrementally following the flow of trajectories, using the connectivity between observations in each trajectory to decide whether overlapping trajectories are traversing the same road or distinct parallel roads, and to correctly infer road segment connectivity. By itself, RoadRunner is not designed to achieve high recall, but we show how to combine it with a wide range of prior schemes, some that use GPS trajectories and some that use aerial imagery, to achieve recall similar to prior schemes but at substantially higher precision. We evaluated RoadRunner in four U.S. cities using 60,000 GPS trajectories, and found that precision improves by 5.2 points (a 33.6% error rate reduction) and 24.3 points (a 60.7% error rate reduction) over two existing schemes, with a slight increase in recall.

References

[1]

G. Agamennoni, J. I. Nieto, and E. M. Nebot. Robust inference of principal road paths for intelligent transportation systems. IEEE T-ITS, 12(1):298--308, 2011.

Digital Library

[2]

M. Ahmed, S. Karagiorgou, D. Pfoser, and C. Wenk. A comparison and evaluation of map construction algorithms using vehicle tracking data. GeoInformatica, 19(3):601--632, 2015.

Digital Library

[3]

M. Ahmed and C. Wenk. Constructing street networks from GPS trajectories. In ESA, 2012.

Digital Library

[4]

H. Alt and M. Godau. Computing the fréchet distance between two polygonal curves. International Journal of Computational Geometry & Applications, 5(01n02):75--91, 1995.

[5]

F. Bastani, S. He, S. Abbar, M. Alizadeh, H. Balakrishnan, S. Chawla, S. Madden, and D. DeWitt. Roadtracer: Automatic extraction of road networks from aerial images.

[6]

J. Biagioni and J. Eriksson. Map inference in the face of noise and disparity. In ACM SIGSPATIAL 2012.

Digital Library

[7]

J. Biagioni and J. Eriksson. Inferring road maps from global positioning system traces: Survey and comparative evaluation. TRR-JTRB, (2291), 2012.

[8]

L. Cao and J. Krumm. From GPS traces to a routable road map. In ACM SIGSPATIAL, pages 3--12, 2009.

Digital Library

[9]

C. Chen and Y. Cheng. Roads digital map generation with multi-track gps data. In International Workshop on Geoscience and Remote Sensing, 2008.

Digital Library

[10]

C. Chen, C. Lu, Q. Huang, Q. Yang, D. Gunopulos, and L. J. Guibas. City-Scale Map Creation and Updating using GPS Collections. In KDD, 2016.

Digital Library

[11]

J. J. Davies, A. R. Beresford, and A. Hopper. Scalable, distributed, real-time map generation. IEEE Pervasive Computing, 5(4), 2006.

Digital Library

[12]

O. H. Dørum. Deriving double-digitized road network geometry from probe data. In Proceedings of the 25th ACM SIGSPATIAL International Conference on Advances in Geographic Information Systems, page 15. ACM, 2017.

Digital Library

[13]

S. Edelkamp and S. Schrödl. Route planning and map inference with global positioning traces. In Computer Science in Perspective. 2003.

Digital Library

[14]

M. Haklay and P. Weber. OpenStreetMap: User-generated street maps. IEEE Pervasive Computing, 7(4):12--18, 2008.

Digital Library

[15]

X. Liu, J. Biagioni, J. Eriksson, Y. Wang, G. Forman, and Y. Zhu. Mining Large-Scale, Sparse GPS Traces for Map Inference: Comparison of Approaches. In KDD, 2012.

Digital Library

[16]

G. Máttyus, W. Luo, and R. Urtasun. Deeproadmapper: Extracting road topology from aerial images. In International Conference on Computer Vision, volume 2, 2017.

[17]

S. Schroedl, K. Wagstaff, S. Rogers, P. Langley, and C. Wilson. Mining gps traces for map refinement. Data Mining and Knowledge Discovery, 9(1):59--87, Jul 2004.

Digital Library

[18]

W. Shi, S. Shen, and Y. Liu. Automatic generation of road network map from massive gps, vehicle trajectories. In IEEE ITSC 2009, 2009.

[19]

R. Stanojevic, S. Abbar, S. Thirumuruganathan, S. Chawla, F. Filali, and A. Aleimat. Robust road map inference through network alignment of trajectories. In Proceedings of the 2018 SIAM International Conference on Data Mining. SIAM, 2018.

[20]

J. D. Wegner, J. A. Montoya-Zegarra, and K. Schindler. A higher-order CRF model for road network extraction. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pages 1698--1705, 2013.

Digital Library

[21]

K. Zheng and D. Zhu. A novel clustering algorithm of extracting road network from low-frequency floating car data. Cluster Computing, pages 1--10, 2018.

Cited By

Hong ZWang HDing YWang GHe TZhang D(2024)SmallMap: Low-cost Community Road Map Sensing with Uncertain Delivery BehaviorProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36595968:2(1-26)Online publication date: 15-May-2024
https://dl.acm.org/doi/10.1145/3659596
Musleh MMokbel M(2024)Let's Speak Trajectories: A Vision to Use NLP Models for Trajectory Analysis TasksACM Transactions on Spatial Algorithms and Systems10.1145/365647010:2(1-25)Online publication date: 1-Jul-2024
https://dl.acm.org/doi/10.1145/3656470
Aguilar JBuchin KBuchin MHosseini Sereshgi ESilveira RWenk C(2024)Graph Sampling for Map ComparisonSpatial Gems, Volume 210.1145/3617291.3617293(1-16)Online publication date: 25-Jan-2024
https://dl.acm.org/doi/10.1145/3617291.3617293
Show More Cited By

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RoadRunner: improving the precision of road network inference from GPS trajectories

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cover image ACM Conferences

SIGSPATIAL '18: Proceedings of the 26th ACM SIGSPATIAL International Conference on Advances in Geographic Information Systems

November 2018

655 pages

ISBN:9781450358897

DOI:10.1145/3274895

General Chairs:
Farnoush Banaei-Kashani
University of Colorado, Denver
,
Erik Hoel
Esri
,
Program Chairs:
Ralf Hartmut Güting
FernUniversität in Hagen, Germany
,
Roberto Tamassia
Brown University
,
Li Xiong
Emory University

Copyright © 2018 ACM.

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SIGSPATIAL: ACM Special Interest Group on Spatial Information

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New York, NY, United States

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Published: 06 November 2018

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SIGSPATIAL '18: 26th ACM SIGSPATIAL International Conference on Advances in Geographic Information Systems

November 6 - 9, 2018

Washington, Seattle

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SIGSPATIAL '18 Paper Acceptance Rate 30 of 150 submissions, 20%;

Overall Acceptance Rate 220 of 1,116 submissions, 20%

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Cited By

Hong ZWang HDing YWang GHe TZhang D(2024)SmallMap: Low-cost Community Road Map Sensing with Uncertain Delivery BehaviorProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36595968:2(1-26)Online publication date: 15-May-2024
https://dl.acm.org/doi/10.1145/3659596
Musleh MMokbel M(2024)Let's Speak Trajectories: A Vision to Use NLP Models for Trajectory Analysis TasksACM Transactions on Spatial Algorithms and Systems10.1145/365647010:2(1-25)Online publication date: 1-Jul-2024
https://dl.acm.org/doi/10.1145/3656470
Aguilar JBuchin KBuchin MHosseini Sereshgi ESilveira RWenk C(2024)Graph Sampling for Map ComparisonSpatial Gems, Volume 210.1145/3617291.3617293(1-16)Online publication date: 25-Jan-2024
https://dl.acm.org/doi/10.1145/3617291.3617293
Zao YZou ZShi Z(2024)Topology-Guided Road Graph Extraction From Remote Sensing ImagesIEEE Transactions on Geoscience and Remote Sensing10.1109/TGRS.2023.334415062(1-14)Online publication date: 2024
https://doi.org/10.1109/TGRS.2023.3344150
Zao YZou ZShi Z(2024)Road Graph Extraction via Transformer and Topological RepresentationIEEE Geoscience and Remote Sensing Letters10.1109/LGRS.2024.338059321(1-5)Online publication date: 2024
https://doi.org/10.1109/LGRS.2024.3380593
Yang LAi MKwan MZuo ZZhang YZhou SLuo SChen Y(2024)Generation of intra-community roads based on human-flow modeling (HFM)International Journal of Geographical Information Science10.1080/13658816.2024.234305438:7(1256-1290)Online publication date: 25-Apr-2024
https://doi.org/10.1080/13658816.2024.2343054
Yang CYue PGong JLi JYan K(2024)Detecting road network errors from trajectory data with partial map matching and bidirectional recurrent neural network modelInternational Journal of Geographical Information Science10.1080/13658816.2024.2306158(1-25)Online publication date: 24-Jan-2024
https://doi.org/10.1080/13658816.2024.2306158
Musleh MMokbel M(2023)Kamel: A Scalable BERT-Based System for Trajectory ImputationProceedings of the VLDB Endowment10.14778/3632093.363211317:3(525-538)Online publication date: 1-Nov-2023
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Shen WWu WMao JChen JCao SZhao LZhou AZhou L(2023)SAMI: A Shape-Aware Cycling Map Inference Framework for Designated Driving Service2023 IEEE 39th International Conference on Data Engineering (ICDE)10.1109/ICDE55515.2023.00251(3269-3281)Online publication date: Apr-2023
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Yuan MYue PYang CLi JYan KCai CWan C(2023)Generating lane-level road networks from high-precision trajectory data with lane-changing behavior analysisInternational Journal of Geographical Information Science10.1080/13658816.2023.2279977(1-31)Online publication date: 12-Nov-2023
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