Abstract
Lacking indoor navigation graph has become a bottleneck in indoor applications and services. This paper presents a novel automated indoor navigation graph reconstruction approach from large-scale low-frequency indoor trajectories without any other data sources. The proposed approach includes three steps: trajectory simplification, 2D floor plan extraction and 3D navigation graph construction. First, we propose a ST-Join-Clustering algorithm to identify and simplify redundant stay points embedded in the indoor trajectories. Second, an indoor trajectory bitmap construction based on a self-adaptive Gaussian filter is developed, and we then propose a new improved thinning algorithm to extract 2D indoor floor plans. Finally, we present an improved CFSFDP algorithm with time constraints to identify the 3D topological connection points between two different floors. To illustrate the applicability of the proposed approach, we conducted a real-world case study using an indoor trajectory dataset of over 4000 indoor trajectories and 5 million location points. The case study results showed that the proposed approach improves the navigation network accuracy by 1.83% and the topological accuracy by 13.7% compared to the classical kernel density estimation approach.
Highlights
Humans spend nearly 87% of their time in enclosed indoor spaces, e.g., office buildings, shopping malls, conference centers, airports and metro stations [1]
We proposed an automated indoor navigation graph construction approach, including three-step processing for an indoor 3D structure reconstruction
We introduced a new concept of a pixel’s neighbors binary code and proposed an indoor trajectory bitmap construction based on a self-adaptive Gaussian filter and developed a new improved thinning algorithm to extract a 2D indoor floor plan
Summary
Humans spend nearly 87% of their time in enclosed indoor spaces, e.g., office buildings, shopping malls, conference centers, airports and metro stations [1]. The navigation graphs of complicated indoor spaces are constructed mainly by handmade field measurements, which are labor intensive and time consuming. CrowdInside [7], JustWalk [5], iFrame [8] and BatMapper [9,10] adopt smartphone sensor data to reconstruct indoor floors. This type of collected data usually includes high precision accelerometers, magnetometers, gyroscopes and so on. I-Git [13] belongs to this type of study, as it may generate a graph-based indoor network, including the floor level and nonlevel paths from IFC data models. The owners of indoor spaces are reluctant to share their floorplans in public for privacy reasons
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