Abstract
The use of Very High Spatial Resolution (VHSR) imagery in remote sensing applications is nowadays a current practice whenever fine-scale monitoring of the earth’s surface is concerned. VHSR Land Cover classification, in particular, is currently a well-established tool to support decisions in several domains, including urban monitoring, agriculture, biodiversity, and environmental assessment. Additionally, land cover classification can be employed to annotate VHSR imagery with the aim of retrieving spatial statistics or areas with similar land cover. Modern VHSR sensors provide data at multiple spatial and spectral resolutions, most commonly as a couple of a higher-resolution single-band panchromatic (PAN) and a coarser multispectral (MS) imagery. In the typical land cover classification workflow, the multi-resolution input is preprocessed to generate a single multispectral image at the highest resolution available by means of a pan-sharpening process. Recently, deep learning approaches have shown the advantages of avoiding data preprocessing by letting machine learning algorithms automatically transform input data to best fit the classification task. Following this rationale, we here propose a new deep learning architecture to jointly use PAN and MS imagery for a direct classification without any prior image sharpening or resampling process. Our method, namely M u l t i R e s o L C C , consists of a two-branch end-to-end network which extracts features from each source at their native resolution and lately combine them to perform land cover classification at the PAN resolution. Experiments are carried out on two real-world scenarios over large areas with contrasted land cover characteristics. The experimental results underline the quality of our method while the characteristics of the proposed scenarios underline the applicability and the generality of our strategy in operational settings.
Highlights
The production of precise and timely Land Use/Land Cover (LULC) maps for monitoring human and physical environment is nowadays a matter of fact
In consonance with recent Remote sensing developments in the field of Very High Spatial Resolution (VHSR) land cover classification [3,20,24], in this paper we propose a two-branch approach that performs classification at pixel-level taking as input PAN and MS imagery at their native resolution
The first of each table shows the performances of the deep learning competing methods (CNNPS, Deep Multiple Instance Learning (DMIL) and MultiResoLCC) while the second summarizes the results of the random forest classifier trained on the features learned by the different deep learning architectures as well as the spatio-spectral representation obtained from the Pansharpened image
Summary
The production of precise and timely Land Use/Land Cover (LULC) maps for monitoring human and physical environment is nowadays a matter of fact. Their use in a multitude of different domains, ranging from ecology, agriculture, mobility to health, risk monitoring and management policies is a consolidated practice [1]. The range of LULC maps applications has even increased since the large-scale availability of Very High Spatial Resolution (VHSR) imagery They are helpful to retrieve fine-scale thematic information over territories [2] supporting spatial analysis in many real-world contexts (urban monitoring, road network updating, cadastral abuses, environmental police, etc.). Examples are the IKONOS, Quickbird and GeoEye sensors (4 m MS and 1 m PAN images), Pléiades (2 m MS and 0.5 m PAN images) and SPOT6/7 (6 m MS and 1.5 m PAN images)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
