Automatic Parametrization of Urban Areas Using ALS Data: The Case Study of Santiago de Compostela

Soilán, Mario; Riveiro, Belén; Liñares, Patricia; Pérez-Rivas, Andrea

doi:10.3390/ijgi7110439

Cited by 4 publications

(1 citation statement)

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“…Airborne laser scanning (ALS), also known as airborne light detection and ranging (LiDAR), is an important active remote sensing technique that has displayed rapid development in recent years [ 1 ]. The technique has the advantage of quickly acquiring large-scale, high-density, and high-precision 3D ground data, and plays an increasingly important role in many applications, including topographic mapping [ 2 ], urban planning [ 3 ], forest biomass estimation [ 4 ], environmental monitoring [ 5 ], and power line detection [ 6 ]. By employing ALS for ground-based scanning, a massive and disordered point cloud can be obtained.…”

Section: Introductionmentioning

confidence: 99%

Graph Attention Feature Fusion Network for ALS Point Cloud Classification

Yang

Zhang

Huang

2021

Sensors

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Classification is a fundamental task for airborne laser scanning (ALS) point cloud processing and applications. This task is challenging due to outdoor scenes with high complexity and point clouds with irregular distribution. Many existing methods based on deep learning techniques have drawbacks, such as complex pre/post-processing steps, an expensive sampling cost, and a limited receptive field size. In this paper, we propose a graph attention feature fusion network (GAFFNet) that can achieve a satisfactory classification performance by capturing wider contextual information of the ALS point cloud. Based on the graph attention mechanism, we first design a neighborhood feature fusion unit and an extended neighborhood feature fusion block, which effectively increases the receptive field for each point. On this basis, we further design a neural network based on encoder–decoder architecture to obtain the semantic features of point clouds at different levels, allowing us to achieve a more accurate classification. We evaluate the performance of our method on a publicly available ALS point cloud dataset provided by the International Society for Photogrammetry and Remote Sensing (ISPRS). The experimental results show that our method can effectively distinguish nine types of ground objects. We achieve more satisfactory results on different evaluation metrics when compared with the results obtained via other approaches.

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