Abstract
Scan matching methods have been widely applied in the fields of autonomous localization and mapping. However, in structured environments where feature differences are less significant, such as long straight corridors, conventional positioning algorithms often suffer from characteristic mismatching, resulting in lower accuracy. As such, a new global localization algorithm, based on environmental difference evaluation and correlation scan matching fusion, is proposed in this study. In this process, the surrounding space was evaluated using a priori understanding of the environment based on a linear fit. Corresponding evaluation and positioning results from correlation scan matching were then modified using dynamic selection and a posture updating strategy. The performance of the proposed technique was compared with other conventional methods using open datasets exhibiting long straight features and a series of tests conducted in a physical corridor. Results showed that the proposed algorithm could effectively improve localization accuracy in narrow environments. The translation and rotation absolute pose errors were reduced by an average of 27.29% and 25.82%, respectively, compared with a correlation matching approach that does not consider the surrounding geometry. These results suggest the proposed technique offers higher adaptability and positioning accuracy in narrow environments.
Highlights
T HE simultaneous localization and mapping (SLAM) building problem involves placing a mobile robot in an unknown starting location in an unfamiliar environment
It is more practical to track the pose of a robot against a known map, which could be constructed from the workspace of other mobile robots
Scan matching seeks a set of translation and rotation parameters to maximize the overlap of two scanned point clouds after alignment [4]– [6].Two or more consecutive scanned laser point clouds can be unified in the same coordinate system, by solving for the coordinate transformation relationship
Summary
T HE simultaneous localization and mapping (SLAM) building problem involves placing a mobile robot in an unknown starting location in an unfamiliar environment. The robot must incrementally construct a map of this environment while simultaneously using this map to calculate its absolute location [1]–[3]. The scanning matching global localization method, based on 2D laser input data, has played an important role in the positioning of mobile robots. The current scanned point cloud can be registered with an established map to recover changes in robot body posture.
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