Abstract
An indoor map is a piece of infrastructure associated with location-based services. Simultaneous Localization and Mapping (SLAM)-based mobile mapping is an efficient method to construct an indoor map. This paper proposes an SLAM algorithm based on a laser scanner and an Inertial Measurement Unit (IMU) for 2D indoor mapping. A grid-based occupancy likelihood map is chosen as the map representation method and is built from all previous scans. Scan-to-map matching is utilized to find the optimal rigid-body transformation in order to avoid the accumulation of matching errors. Map generation and update are probabilistically motivated. According to the assumption that the orthogonal is the main feature of indoor environments, we propose a lightweight segment extraction method, based on the orthogonal blurred segments (OBS) method. Instead of calculating the parameters of segments, we give the scan points contained in blurred segments a greater weight during the construction of the grid-based occupancy likelihood map, which we call the orthogonal feature weighted occupancy likelihood map (OWOLM). The OWOLM enhances the occupancy likelihood map by fusing the orthogonal features. It can filter out noise scan points, produced by objects, such as glass cabinets and bookcases. Experiments were carried out in a library, which is a representative indoor environment, consisting of orthogonal features. The experimental result proves that, compared with the general occupancy likelihood map, the OWOLM can effectively reduce accumulated errors and construct a clearer indoor map.
Highlights
Establishing an accurate and clear indoor map is a basic requirement of Indoor Navigation and Location-Based Services (INLBS)
Based on the data, collected by a 2D laser scanner and Inertial Measurement Unit (IMU) mounted on a mobile platform, a new indoor Simultaneous Localization and Mapping (SLAM) algorithm via scan-to-map matching, aided by the grid-based occupancy likelihood map, was proposed in this paper
Instead of matching two sequential laser scans to find the optimal rigid body transformation, we used IMU-aided scan-to-map matching, which was based on an IMU and
Summary
Establishing an accurate and clear indoor map is a basic requirement of Indoor Navigation and Location-Based Services (INLBS). Simultaneous Localization and Mapping (SLAM) is a popular and applicable method for mobile mapping in a GNSS-denied area, especially indoor environments [1,2]. Vision-based SLAM uses monocular, stereo or RGBD cameras to accomplish navigation and mapping and can obtain rich texture information [4,5,6,7,8]. While it is the cheapest approach, there are some disadvantages that limit its applications in indoor mapping, such as its sensitivity to lighting conditions, computational cost for processing large amounts of image data and the necessity for accurate
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