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摘要
高精地圖能為自駕車、城市規劃、AR產業帶來展望性的應用,本文所要探討的是如何規模化與持續性的建置高精地圖。隨著各地點雲資料透過裝有光達載具一趟趟的行經各縣市的街道巷弄來擴增,我們設計了一套自動化系統匯集持續增加的資料來建置一個可成長的高精地圖,其中,此高精地圖保留了每一次的修改,並可以輕易地回溯至特定時間,所以即使出現高精地圖失去精確度與密度的情境,我們仍具有能力找出變形的點雲並修正最新的高精地圖。目前,我們已經陸續增加26個隨車收集的資料,同時也對其中一個區域進行內政部所規定精確度的檢查,其結果通過相對精度的測試,儘管目前系統沒有加入地面控制點,但是我們的絕對精度達到了51.1公分以內。
Abstract
Lidar point clouds, and the precise 3-d maps that creates, are enabling new possibilities in applications of autonomous vehicles, urban planning and augmented reality. With the growing number of vehicles carrying Lidar scanners, driving the streets, collecting data – We developed a system for continually adding newly collected data onto a point cloud map, allowing the map to continually grow in coverage, increase in density, and stay up-to-date, in a process that can be fully automated. While mistakes do inevitably occur, our system maintains a revision history of the map's evolution over time, enabling these mistakes to be later found and fixed. Using our system, we have so far successfully added 26 drives into a unified map. In a small scale evaluation, our point cloud satisfied the relative accuracy requirements set by MOI (Ministry of Interior) and despite not using any GCPs (ground control points), our point cloud still achieved absolute accuracy within 51.1 cm.
Introduction Lidar point clouds let us create precise 3-d maps of roads, signs, utility poles, powerlines, buildings, etc., enabling new possibilities in applications such as autonomous vehicles, urban planning, augmented reality, land administration, and infrastructure asset maintenance.
A Lidar point cloud is created by driving a scanner-equipped vehicle through an area and using the scanner's trajectory to transform Lidar distance and angle measurements into 3-d points. But errors in the trajectory can cause misalignments between the point clouds created by separate drives through the same area. Even trajectories measured using high end GNSS+INS can easily have absolute errors in the tens of centimeters, particularly in urban environments with limited sky visibility and multipath effects; this level of error is too large for aligning thin objects such as utility poles.
Future 3-d mapping efforts will involve frequent collecting of large numbers of overlapping drives. We need a sustainable way of maintaining global alignment of this continually growing set of drives.
Many surveying and mapping companies are already offering services for creating high quality Lidar point clouds of a given project area. Alignment within a project is usually very precise, thanks to the use of high end GNSS+INS equipment, manually selected tie points, and automatic plane matching solutions such as Riegl RiPROCESS. But alignment across projects is usually less precise, because it is only indirectly enforced via GCPs. The large number of projects that get created over time present huge opportunities for change detection, seamless 3-d modelling over multiple project areas, and filling in of missing parts e.g. due to parked cars, if only we have a sustainable way of maintaining global alignment across all projects.
Increasingly, tech companies such as DeepMaps, MobilEye and Atlatec are leveraging low cost sensors deployed at a large scale to create maps with greater coverage and freshness. This can nicely complement the accuracy of survey-quality maps, but will require even greater levels of automation to align in a cost-effective fashion.
Automatic creation of aligned point clouds has been studied by many papers in robotics and SLAM (see survey paper by Cadena et.al. [1]). These methods use scan matching to estimate relative poses, which are then combined with IMU and GNSS measurements in a pose graph optimization [2] to obtain a trajectory, a trajectory that can be used to create a point cloud that is aligned with quality commensurate with the quality of scan matching. Existing automatic methods include Cartographer [3] and LIO-SAM [4], which focus on the single drive case; the paper by Ding et.al. [5], which considers alignment of multiple drives; and perhaps the largest scale demonstration in a paper to date by Shiratori et.al. [6], who automatically created an aligned point cloud for the entire city of San Francisco.
However, sustained automation at a large scale still has many challenges. This includes long-term maintenance of pose graphs [7], optimizing large pose graphs [8], and robustness to scan matching mistakes [9]. While these papers focus on full autonomy, we are willing to do manual edits, as long as the overall approach is sustainable.
Sustainability is not only about how large of a geographic area, but also how frequently a map can be updated, how many person-hours for manual edits, and how much compute power and time for automated processing. For example, can we achieve sustained weekly mapping of the entire Hsinchu city (~100 km2) using a single full-time worker and a single cluster of computers? In this article, we describe our initial efforts (Figure 1) towards building such a system.
Figure 1 Coverage of point cloud map created so far by our system.
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