Details

Autor(en) / Beteiligte

• Srivastava, Shivangi
• Vargas-Muñoz, John E.
• Tuia, Devis

Titel

Understanding urban landuse from the above and ground perspectives: A deep learning, multimodal solution

Ist Teil von

• Remote sensing of environment, 2019-07, Vol.228, p.129-143

Ort / Verlag

New York: Elsevier Inc

Erscheinungsjahr

2019

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• Landuse characterization is important for urban planning. It is traditionally performed with field surveys or manual photo interpretation, two practices that are time-consuming and labor-intensive. Therefore, we aim to automate landuse mapping at the urban-object level with a deep learning approach based on data from multiple sources (or modalities). We consider two image modalities: overhead imagery from Google Maps and ensembles of ground-based pictures (side-views) per urban-object from Google Street View (GSV). These modalities bring complementary visual information pertaining to the urban-objects. We propose an end-to-end trainable model, which uses OpenStreetMap annotations as labels. The model can accommodate a variable number of GSV pictures for the ground-based branch and can also function in the absence of ground pictures at prediction time. We test the effectiveness of our model over the area of Île-de-France, France, and test its generalization abilities on a set of urban-objects from the city of Nantes, France. Our proposed multimodal Convolutional Neural Network achieves considerably higher accuracies than methods that use a single image modality, making it suitable for automatic landuse map updates. Additionally, our approach could be easily scaled to multiple cities, because it is based on data sources available for many cities worldwide. •We propose a CNN model to predict landuse at the object level from multi-modal data.•The model fuses image features from aerial and ground views.•The model is scalable to many cities due to use of widely available data repositories.•The observed accuracies are considerably better than those of unimodal models.•Our model is robust to the lack of ground-based pictures at test time.