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Accurate 3D road information is important for applications such as road maintenance and virtual 3D modeling. Mobile laser scanning (MLS) is an efficient technique for capturing dense point clouds that can be used to construct detailed road models for large areas. This paper presents a method for extracting and delineating roads from large-scale MLS point clouds. The proposed method partitions MLS point clouds into a set of consecutive “scanning lines”, which each consists of a road cross section. A moving window operator is used to filter out non-ground points line by line, and curb points are detected based on curb patterns. The detected curb points are tracked and refined so that they are both globally consistent and locally similar. To evaluate the validity of the proposed method, experiments were conducted using two types of street-scene point clouds captured by Optech’s Lynx Mobile Mapper System. The completeness, correctness, and quality of the extracted roads are over 94.42%, 91.13%, and 91.3%, respectively, which proves the proposed method is a promising solution for extracting 3D roads from MLS point clouds. 相似文献
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提出了一种从车载激光扫描数据中自动提取路面的方法。通过分析车载激光扫描点云的空间特征,提出运用近似平面约束法、有序最小二乘坡度估计法和多尺度窗口迭代分析法进行初始路面种子点提取;然后基于局部坡度滤波方法提取所有的路面点;最后选择两组实际点云数据进行实验。结果表明,该方法能快速准确地提取高速公路路面点云,实验数据的提取准确率为95.74%,完整率为98.11%。 相似文献
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A mobile laser scanning (MLS) system allows direct collection of accurate 3D point information in unprecedented detail at highway speeds and at less than traditional survey costs, which serves the fast growing demands of transportation-related road surveying including road surface geometry and road environment. As one type of road feature in traffic management systems, road markings on paved roadways have important functions in providing guidance and information to drivers and pedestrians. This paper presents a stepwise procedure to recognize road markings from MLS point clouds. To improve computational efficiency, we first propose a curb-based method for road surface extraction. This method first partitions the raw MLS data into a set of profiles according to vehicle trajectory data, and then extracts small height jumps caused by curbs in the profiles via slope and elevation-difference thresholds. Next, points belonging to the extracted road surface are interpolated into a geo-referenced intensity image using an extended inverse-distance-weighted (IDW) approach. Finally, we dynamically segment the geo-referenced intensity image into road-marking candidates with multiple thresholds that correspond to different ranges determined by point-density appropriate normality. A morphological closing operation with a linear structuring element is finally used to refine the road-marking candidates by removing noise and improving completeness. This road-marking extraction algorithm is comprehensively discussed in the analysis of parameter sensitivity and overall performance. An experimental study performed on a set of road markings with ground-truth shows that the proposed algorithm provides a promising solution to the road-marking extraction from MLS data. 相似文献
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鉴于城市道路两侧具有路坎这一特点,结合车载激光扫描系统的轨迹数据将整体点云进行分块处理,从每一块点云中截取部分数据投影到相应的截面上;然后,对获取的截面数据进行分割处理提取伪扫描线,根据路坎的坡度以及高差特点从伪扫描线中识别出路坎点;最后,利用三次样条插值的方法对提取的道路路坎点进行插值处理,得到道路边界线。实验证明了该方法的可行性和有效性。 相似文献
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车载激光点云道路边界提取的Snake方法 总被引:2,自引:0,他引:2
针对车载激光点云中道路边界提取困难,自动化程度低的问题,提出一种基于离散点Snake的车载激光点云道路边界提取方法。不同于传统基于图像建立Snake,本文直接基于离散点建立Snake模型。先利用伪轨迹点数据,确定初始轮廓位置,参数化不同类型的道路边界初始轮廓;然后基于离散点构建适合多类型道路边界的Snake模型,定义模型内部、外部和约束能量,通过能量函数最小化推动轮廓曲线移动到显著道路边界特征点处,实现不同道路边界的精细提取。本文试验采用3份不同城市场景的车载激光点云数据验证本文方法的有效性,道路边界提取结果的准确率达到97.62%,召回率达到98.04%,F1-Measure值达到97.83%以上,且提取的道路边界结果与软件交互提取的结果有较好的吻合度。试验结果表明,本文方法能够修正噪声、断裂等数据质量对道路边界提取的影响,能够实现各类复杂城市环境中不同形状道路边界的提取,具有较强的稳健性和适用性。 相似文献
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Terrestrial mobile laser scanning systems provide rapid and cost effective 3D point cloud data which can be used for extracting features such as the road edge along a route corridor. This information can assist road authorities in carrying out safety risk assessment studies along road networks. The knowledge of the road edge is also a prerequisite for the automatic estimation of most other road features. In this paper, we present an algorithm which has been developed for extracting left and right road edges from terrestrial mobile LiDAR data. The algorithm is based on a novel combination of two modified versions of the parametric active contour or snake model. The parameters involved in the algorithm are selected empirically and are fixed for all the road sections. We have developed a novel way of initialising the snake model based on the navigation information obtained from the mobile mapping vehicle. We tested our algorithm on different types of road sections representing rural, urban and national primary road sections. The successful extraction of road edges from these multiple road section environments validates our algorithm. These findings and knowledge provide valuable insights as well as a prototype road edge extraction tool-set, for both national road authorities and survey companies. 相似文献
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车载激光扫描数据中实线型交通标线提取 总被引:1,自引:1,他引:0
本文提出一种基于路面点云强度增强的车载激光点云实线型交通标线提取方法。首先通过预处理提取路面点云,获取各激光点与轨迹线的距离。然后逐段对路面进行强度增强,集合多滤波器集成的策略进行强度变换和去噪,消除距离、点密度、磨损等因素对反射强度值影响,增强路面点云和标线的强度差异。基于增强后的反射强度,采用k均值聚类和连通分支聚类等方法对标线进行分割,并利用归一化图割方法优化强度分割结果。最后利用实线型标线的语义信息和空间分布特征从分割后标线对象中识别实线型交通标线。试验采用四份不同车载激光扫描系统获取的数据用于验证本文方法有效性,实线型标线提取结果的准确率达到95.98%,召回率达到91.87%,综合评价指标F1-Measure值达到95.55%以上。试验结果表明本文方法能够有效增强受扫描距离、路面磨损及点密度分布不均等因素影响的点云强度信息,实现不同车载激光扫描获取的复杂道路环境下实线型交通标线的提取。 相似文献
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为了解决路面手工三维建模速度慢、工作量大等问题,本文面向规范化处理的高精度矢量数据,对不同路口进行精细化设计,自动生成路面三维模型。首先使用道路高精度三维信息采集软件,在获取的点云数据中半自动化提取准确的道路边线、道路标识线等矢量信息;然后针对不同路口进行精细化线形设计,提出连续四边形重建方法、弯道平滑处理方法、交叉口重建方法及路面标识线投射重建方法;最后对提取的高精度矢量数据进行规范化处理,在满足路面线形设计要求后,借助MAXScript脚本实现路面三维自动化建模。以车载移动测量系统获取的某段道路点云数据进行试验,验证了该方法的可行性和有效性。 相似文献
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谭敏 《测绘与空间地理信息》2015,(7)
以车载激光点云数据为研究对象,提出了一种新的路面检测与重建的方法。该方法根据GPS定位器中的索引文件或激光扫描仪的旋转角度值提取扫描车的车行路径,利用提取到的车行路径去检测对应的路沿。然后,对检测到的路沿中出现的各种异常进行相应的平滑处理。在得到精确的路沿线后,可得到路面的三维模型,从而完成对路面的重建。输出的路面三维模型为OBJ格式,可满足相关领域对精确路面的需求,比如三维城市建模。 相似文献
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道路边界精确提取建模是城市道路管理、智能交通规划和高精度地图制作等领域的重要课题之一。本文提出了一种基于车载激光雷达点云数据和开源街道地图(OSM)的三维道路边界精确提取方法。首先,针对原始车载LiDAR点云数据应用布料模拟滤波分离地面点,再结合相对高程分析获取道路边界点候选数据集。然后,应用OSM矢量道路网数据的节点辅助道路边界点候选点集进行分段。最后,在各分段点云数据集中基于随机抽样一致性算法获得三维道路边界点集。通过直道、弯道及高密度复杂场景3种不同类型的城区道路边界路段分类提取试验。结果表明,利用该方法进行道路边界提取的准确率和召回率分别达96.12%和95.17%,F1值达92.11%,本文方法可用于高精度道路边界的三维精细提取与矢量化,进而为智能交通与无人驾驶导航提供支撑。 相似文献
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车载激光扫描系统获取的复杂道路环境点云数据量大、目标复杂,难以有效提取出道路的点云。本文通过分析扫描线上激光点云的空间分布和统计特征,提出一种适用于复杂道路环境的道路点云自动提取方法。该方法首先根据点的扫描角度或GPS时间信息提取扫描线;利用移动窗口法进行高程滤波,提取地面点云,然后采用基于路坎模型的移动窗口法提取路坎点;利用局部区域相邻扫描线的相似性特点,对提取的路坎点云进行跟踪和优化;最后利用优化后的路坎作为道路的边界实现道路路面精确提取。经过实验和分析,该方法不仅适应于有固定道路宽度的结构化道路提取,同样适用于无固定宽度的复杂道路提取。 相似文献
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基于法向量模糊聚类的道路面点云数据滤波 总被引:1,自引:0,他引:1
针对道路面三维激光扫描的特点,结合点云法向量分布特征,提出了基于法向量模糊聚类的点云数据滤波算法。通过对3种不同类型实测道路面数据的实验表明,该算法对于路面扫描过程中产生的非路面冗余数据有较好的滤波效果,为点云数据滤波提供了一种新的手段。 相似文献
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利用车载LiDAR点云数据提取城市道路边界 总被引:2,自引:1,他引:1
随着高精地图产业的兴起,精确提取道路边界点云数据成为研究的重点。本文首先将车载LiDAR扫描系统获取的城市道路数据根据采集轨迹进行分段,对每一段路段点云进行滤波处理;然后通过分析点云的高程与平面信息,采用点云分割算法分离路面与非路面点云,再对处理后的路面点云进行投影;最后运用边界特征估计提取算法获取道路边界点云。通过对两种典型路段进行试验分析表明,该方法用于提取城市道路边界点云效果较好,精确性与稳健性高,对今后道路边界线的提取起到借鉴作用。 相似文献
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User Contribution Patterns and Completeness Evaluation of Mapillary,a Crowdsourced Street Level Photo Service 
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下载免费PDF全文 Mapillary is a Web 2.0 application which allows users to contribute crowdsourced street level photographs from all over the world. In the first part of the analysis this article reviews Mapillary data growth for continents and countries as well as the contribution behavior of individual mappers, such as the number of days of active mapping. In the second part of the analysis the study assesses Mapillary data completeness relative to a reference road network dataset at the country level. In addition, a more detailed completeness analysis is conducted for selected urban and rural areas in the US and part of northern Europe for which the completeness of Mapillary data will also be compared with that of Google Street View. Results show that Street View provides generally a better coverage on almost all road categories with some exceptions for pedestrian and cycle paths in selected cities. However, Mapillary data can be conveniently collected from any mobile device that is equipped with a photo camera. This gives Mapillary the potential to reach better coverage along off‐road segments than Google Street View. 相似文献
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Semantic labelling of LiDAR point cloud is critical for effective utilization of 3D points in numerous applications. 3D segmentation, incorporation of ancillary data, feature extraction and classification are the key stages in object-based point cloud labelling. The choice of algorithms and tuning parameters adopted in these stages has substantial impact on the quality of results from object-based point cloud labelling. This paper critically evaluates the performance of object-based point cloud labelling as a function of different 3D segmentation approaches, incorporation of spectral data and computational complexity of the point cloud. The designed experiments are implemented on the datasets provided by the ISPRS and the results are independently validated by the ISPRS. Results indicate that aggregation of dense point cloud into higher-level object analogue (e.g. supervoxels) before 3D segmentation stage offers superior labelling results and best computational performance compared to the popular surface growing-based approaches. 相似文献
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Automatic change detection and geo-database updating in the urban environment are difficult tasks. There has been much research on detecting changes with satellite and aerial images, but studies have rarely been performed at the street level, which is complex in its 3D geometry. Contemporary geo-databases include 3D street-level objects, which demand frequent data updating. Terrestrial images provides rich texture information for change detection, but the change detection with terrestrial images from different epochs sometimes faces problems with illumination changes, perspective distortions and unreliable 3D geometry caused by the lack of performance of automatic image matchers, while mobile laser scanning (MLS) data acquired from different epochs provides accurate 3D geometry for change detection, but is very expensive for periodical acquisition. This paper proposes a new method for change detection at street level by using combination of MLS point clouds and terrestrial images: the accurate but expensive MLS data acquired from an early epoch serves as the reference, and terrestrial images or photogrammetric images captured from an image-based mobile mapping system (MMS) at a later epoch are used to detect the geometrical changes between different epochs. The method will automatically mark the possible changes in each view, which provides a cost-efficient method for frequent data updating. The methodology is divided into several steps. In the first step, the point clouds are recorded by the MLS system and processed, with data cleaned and classified by semi-automatic means. In the second step, terrestrial images or mobile mapping images at a later epoch are taken and registered to the point cloud, and then point clouds are projected on each image by a weighted window based z-buffering method for view dependent 2D triangulation. In the next step, stereo pairs of the terrestrial images are rectified and re-projected between each other to check the geometrical consistency between point clouds and stereo images. Finally, an over-segmentation based graph cut optimization is carried out, taking into account the color, depth and class information to compute the changed area in the image space. The proposed method is invariant to light changes, robust to small co-registration errors between images and point clouds, and can be applied straightforwardly to 3D polyhedral models. This method can be used for 3D street data updating, city infrastructure management and damage monitoring in complex urban scenes. 相似文献