{Benchmark for Evaluating Long-Term Localization in Indoor Environments Under Substantial Static and Dynamic Scene Changes}

Accurate localization is crucial for the autonomous operation of mobile robots. Specifically for indoor scenarios, localization algorithms typically rely on a previously generated map. However, many real-world sites like warehouses or healthcare environments violate the underlying assumption that the robot’s surroundings are mainly static. In this paper, we introduce a new dataset plus a benchmark that enables evaluating and comparing indoor localization methods in complex and changing real-world scenarios. While several datasets for indoor scenes exist, only a few combine the long-term localization aspect of repeatedly revisiting the same environment under varying conditions with precise ground truth over multiple rooms. Our dataset comprises various sequences recorded with a wheeled robot covering an office environment. We provide data from two 2D LiDARs, multiple consumer-grade RGB-D cameras, and the robot’s wheel odometry. By densely placing fiducial markers on every room ceiling, we can also provide accurate pose information within a single global frame for the whole environment, estimated through an additional upward-facing camera. We evaluate existing localization algorithms on our data and make the dataset together with a server-based benchmark evaluation publicly available. This facilitates an unbiased evaluation of localization approaches and enables further research on their application in challenging indoor

scenarios.