An Expository Examination of Temporally Evolving Graph-Based Approaches for the Visual Investigation of Autonomous Driving

IF 1.5 4区 计算机科学 Q3 COMPUTER SCIENCE, SOFTWARE ENGINEERING
IET Software Pub Date : 2024-03-20 DOI:10.1049/2024/5802816
Li Wan, Wenzhi Cheng
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引用次数: 0

Abstract

With the continuous advancement of autonomous driving technology, visual analysis techniques have emerged as a prominent research topic. The data generated by autonomous driving is large-scale and time-varying, yet more than existing visual analytics methods are required to deal with such complex data effectively. Time-varying diagrams can be used to model and visualize the dynamic relationships in various complex systems and can visually describe the data trends in autonomous driving systems. To this end, this paper introduces a time-varying graph-based method for visual analysis in autonomous driving. The proposed method employs a graph structure to represent the relative positional relationships between the target and obstacle interferences. By incorporating the time dimension, a time-varying graph model is constructed. The method explores the characteristic changes of nodes in the graph at different time instances, establishing feature expressions that differentiate target and obstacle motion patterns. The analysis demonstrates that the feature vector centrality in the time-varying graph effectively captures the distinctions in motion patterns between targets and obstacles. These features can be utilized for accurate target and obstacle recognition, achieving high recognition accuracy. To evaluate the proposed time-varying graph-based visual analytic autopilot method, a comparative study is conducted against traditional visual analytic methods such as the frame differencing method and advanced visual analytic methods like visual lidar odometry and mapping. Robustness, accuracy, and resource consumption experiments are performed using the publicly available KITTI dataset to analyze and compare the three methods. The experimental results show that the proposed time-varying graph-based method exhibits superior accuracy and robustness. This study offers valuable insights and solution ideas for developing deep integration between intelligent networked vehicles and intelligent transportation. It provides a reference for advancing intelligent transportation systems and their integration with autonomous driving technologies.

Abstract Image

基于时序演进图的自动驾驶视觉研究方法的阐述性研究
随着自动驾驶技术的不断进步,可视化分析技术已成为一个突出的研究课题。自动驾驶产生的数据规模大、时变性强,要有效处理这些复杂的数据,需要比现有的可视化分析方法更多的方法。时变图可以用来对各种复杂系统中的动态关系进行建模和可视化,并能直观地描述自动驾驶系统中的数据趋势。为此,本文介绍了一种基于时变图的自动驾驶可视化分析方法。所提出的方法采用图结构来表示目标和障碍物干扰之间的相对位置关系。通过结合时间维度,构建了一个时变图模型。该方法探索了图中节点在不同时间实例下的特征变化,建立了区分目标和障碍物运动模式的特征表达式。分析表明,时变图中的特征向量中心性能有效捕捉目标和障碍物运动模式的区别。这些特征可用于准确识别目标和障碍物,从而实现较高的识别准确率。为了评估所提出的基于时变图的视觉分析自动驾驶方法,我们将其与传统的视觉分析方法(如帧差分法)和先进的视觉分析方法(如视觉激光雷达测距和测绘)进行了比较研究。使用公开的 KITTI 数据集进行了鲁棒性、准确性和资源消耗实验,以分析和比较这三种方法。实验结果表明,所提出的基于时变图的方法具有更高的准确性和鲁棒性。本研究为发展智能网联汽车与智能交通的深度融合提供了有价值的见解和解决思路。它为推进智能交通系统及其与自动驾驶技术的融合提供了参考。
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来源期刊
IET Software
IET Software 工程技术-计算机:软件工程
CiteScore
4.20
自引率
0.00%
发文量
27
审稿时长
9 months
期刊介绍: IET Software publishes papers on all aspects of the software lifecycle, including design, development, implementation and maintenance. The focus of the journal is on the methods used to develop and maintain software, and their practical application. Authors are especially encouraged to submit papers on the following topics, although papers on all aspects of software engineering are welcome: Software and systems requirements engineering Formal methods, design methods, practice and experience Software architecture, aspect and object orientation, reuse and re-engineering Testing, verification and validation techniques Software dependability and measurement Human systems engineering and human-computer interaction Knowledge engineering; expert and knowledge-based systems, intelligent agents Information systems engineering Application of software engineering in industry and commerce Software engineering technology transfer Management of software development Theoretical aspects of software development Machine learning Big data and big code Cloud computing Current Special Issue. Call for papers: Knowledge Discovery for Software Development - https://digital-library.theiet.org/files/IET_SEN_CFP_KDSD.pdf Big Data Analytics for Sustainable Software Development - https://digital-library.theiet.org/files/IET_SEN_CFP_BDASSD.pdf
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