基于变道行为分析的高精度轨迹数据生成车道级道路网

IF 4.3 1区 地球科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS International Journal of Geographical Information Science Pub Date : 2023-11-12 DOI:10.1080/13658816.2023.2279977
Mengyue Yuan, Peng Yue, Can Yang, Jian Li, Kai Yan, Chuanwei Cai, Chongshan Wan
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Erroneous lanes generated by lane-changing behavior are pruned based on a constructed lane intersection graph. In regions with merging and diverging lanes, a lane-group fitting algorithm is designed. This algorithm estimates lane locations by incorporating a Gaussian mixture model with lane width prior knowledge and then infers lane-level topological structures using trajectory flow information. The proposed method is evaluated on a real-world high-precision trajectory dataset. Comprehensive experiments demonstrate that it outperforms state-of-the-art methods in four metrics. 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引用次数: 0

摘要

移动测绘系统的最新进展促进了高精度轨迹数据的收集,定位精度达到厘米级。它提供了推断车道级道路网络的潜力,这对自动驾驶导航至关重要。由于轨迹数据中存在复杂的车道合并和发散结构以及变道模式,这一任务具有一定的挑战性。提出了一种基于变道行为分析的高精度轨迹数据的车道级道路网生成方法。首先通过检测道路交叉口和车道结构的变化对轨迹进行分割。然后,在车道结构一致的区域,提出一种主曲线拟合算法提取车道中心线。基于构建的车道交叉图,对变道行为产生的错误车道进行修剪。在车道合并和发散区域,设计了一种车道群拟合算法。该算法通过引入具有车道宽度先验知识的高斯混合模型来估计车道位置,然后利用轨迹流信息推断车道级拓扑结构。在实际高精度轨迹数据集上对该方法进行了验证。综合实验表明,它优于最先进的方法在四个指标。在复杂场景下,该方法生成的车道级道路网络具有更高的完整性和更少的碎片。关键词:车道级路网高精度轨迹数据改变行为感谢编辑和匿名审稿人提出的建设性意见。数据和代码可用性声明支持本研究结果的数据和代码可从以下链接获得:https://doi.org/10.6084/m9.figshare.23529336。为了演示目的,共享数据的一个子集。披露声明作者未报告潜在的利益冲突。注1我们用变道来描述轨迹数据中的驾驶行为,而车道过渡是指车道合并或分流的特殊路网结构。额外informationFundingThe工作得到了重庆技术创新和应用程序开发项目(批准号CSTB2022TIAD-DEX0013];智能汽车安全技术国家重点实验室和重庆长安汽车股份有限公司资助;中央高校基本科研业务费[批准号:2042022dx0001]。袁孟岳,武汉大学遥感与信息工程学院硕士研究生。主要研究方向为地理空间数据挖掘和交通地理。她对本文的构思、研究设计、方法、实施和稿件撰写都做出了贡献。彭岳是武汉大学的一名教授。现任遥感与信息工程学院副院长、湖北省智能地理信息处理工程中心主任、地理空间信息与定位服务研究所所长。他监督了这项研究,并对研究的设计、方法和手稿的撰写做出了贡献。杨灿,武汉大学遥感与信息工程学院博士后研究员。主要研究方向为轨迹模式挖掘与识别。他对这篇论文的思想、研究设计、方法和手稿的撰写都做出了贡献。李健,智能汽车安全技术国家重点实验室、重庆长安汽车有限公司工程师。他对本文的思想、研究设计和方法都做出了贡献。严凯,智能汽车安全技术国家重点实验室、重庆长安汽车有限公司工程师。他对本文的思想、研究设计和方法都做出了贡献。蔡传伟,武汉大学遥感与信息工程学院博士生。他对本文的研究设计和方法做出了贡献。万崇山,武汉大学遥感与信息工程学院硕士研究生。他对本文的实现做出了贡献。
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Generating lane-level road networks from high-precision trajectory data with lane-changing behavior analysis
ABSTRACT–Recent advances in mobile mapping systems have facilitated the collection of high-precision trajectory data in centimeter positioning accuracy. It provides the potential to infer lane-level road networks, which are essential for autonomous driving navigation. This task is challenging due to the complicated lane merging and diverging structures as well as the lane-changing patterns in trajectory data. This paper presents a lane-level road network generation method from high-precision trajectory data with lane-changing behavior analysis. Trajectories are firstly partitioned by detecting road intersections and changes in lane structure. Subsequently, in regions with consistent lane structure, a principal curve fitting algorithm is developed to extract lane centerlines. Erroneous lanes generated by lane-changing behavior are pruned based on a constructed lane intersection graph. In regions with merging and diverging lanes, a lane-group fitting algorithm is designed. This algorithm estimates lane locations by incorporating a Gaussian mixture model with lane width prior knowledge and then infers lane-level topological structures using trajectory flow information. The proposed method is evaluated on a real-world high-precision trajectory dataset. Comprehensive experiments demonstrate that it outperforms state-of-the-art methods in four metrics. Under complex scenarios, the method is capable of generating lane-level road networks with higher completeness and fewer fragments.Keywords: Lane-level road networkhigh-precision trajectory datalane-changing behavior AcknowledgmentWe thank the editor and anonymous reviewers for their constructive comments.Data and codes availability statementThe data and codes that support the findings of this study are available at the link: https://doi.org/10.6084/m9.figshare.23529336. A subset of the data is shared for demonstration purposes.Disclosure statementNo potential conflict of interest was reported by the author(s).Notes1 We use the term lane-changing to describe the driving behavior in trajectory data, while lane transition refers to special road network structure where lanes merge or diverge.Additional informationFundingThe work was supported by the Chongqing Technology Innovation and Application Development Project [Grant No. CSTB2022TIAD-DEX0013]; funding from the State Key Laboratory of Intelligent Vehicle Safty Technology and Chongqing Changan Automobile Co. Ltd; and the Fundamental Research Funds for the Central Universities [Grant No. 2042022dx0001].Notes on contributorsMengyue YuanMengyue Yuan is an M.S. student in the School of Remote Sensing and Information Engineering at Wuhan University. Her research interest is geospatial data mining and transportation geography. She contributed to the idea, study design, methodology, implementation, and manuscript writing of this paper.Peng YuePeng Yue is a professor at Wuhan University. He serves as the deputy dean at the School of Remote Sensing and Information Engineering, the director at the Hubei Province Engineering Center for Intelligent Geoprocessing, and the director at the Institute of Geospatial Information and Location Based Services. He supervised this study and contributed to the study design, methodology, and manuscript writing.Can YangCan Yang is a postdoctoral researcher in the School of Remote Sensing and Information Engineering at Wuhan University. His research interest is in trajectory pattern mining and recognition. He contributed to this paper’s idea, study design, methodology, and manuscript writing.Jian LiJian Li is an engineer at the State Key Laboratory of Intelligent Vehicle Safty Technology and Chongqing Changan Automobile Co. Ltd. He contributed to this paper’s idea, study design, and methodology.Kai YanKai Yan is an engineer at the State Key Laboratory of Intelligent Vehicle Safty Technology and Chongqing Changan Automobile Co. Ltd. He contributed to this paper’s idea, study design, and methodology.Chuanwei CaiChuanwei Cai is a Ph.D. student in the School of Remote Sensing and Information Engineering at Wuhan University. He contributed to this paper’s study design and methodology.Chongshan WanChongshan Wan is an M.S. student in the School of Remote Sensing and Information Engineering at Wuhan University. He contributed to this paper’s implementation.
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来源期刊
CiteScore
11.00
自引率
7.00%
发文量
81
审稿时长
9 months
期刊介绍: International Journal of Geographical Information Science provides a forum for the exchange of original ideas, approaches, methods and experiences in the rapidly growing field of geographical information science (GIScience). It is intended to interest those who research fundamental and computational issues of geographic information, as well as issues related to the design, implementation and use of geographical information for monitoring, prediction and decision making. Published research covers innovations in GIScience and novel applications of GIScience in natural resources, social systems and the built environment, as well as relevant developments in computer science, cartography, surveying, geography and engineering in both developed and developing countries.
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