Object-based land use classification using airborne lidar

Antonarakis, A S, Richards, K S and Brasington, J (2008) Object-based land use classification using airborne lidar. Remote Sensing of Environment, 112 (6). pp. 2988-2998. ISSN 0034-4257

[img] PDF - Published Version
Restricted to SRO admin only

Download (2MB)

Abstract

Better information on roughness of various types of vegetation is needed for use in resistance equations and eventually in flood modelling. These types include woody riparian species with different structural characteristics. Remote Sensing information such as 3D point cloud data from LiDAR can be used as a tool for extracting simple roughness information relevant for the condition of below canopy flow, as well as roughness relevant for more complex tree morphology that affects the flow when it enters the canopy levels. A strategy for extracting roughness parameters from remote sensing techniques is to use a data fusion object classification model. This means that multiple datasets such as LiDAR, digital aerial photography, ground data and satellite data can be combined to produce roughness parameters estimated for different vegetative patches, which can subsequently be mapped spatially using a classification methodology. Airborne LiDAR is used in this study in order to classify forest and ground types quickly and efficiently without the need for manipulating multispectral image files. LiDAR has the advantage of being able to create elevation surfaces that are in 3D, while also having information on LiDAR intensity values, thus it is a spatial and spectral segmentation tool. This classification method also uses point distribution frequency criteria to differentiate between land cover types. The classification of three meanders of the Garonne and Allier rivers in France has demonstrated overall classification accuracies of 95%. Five types of riparian forest were classified with accuracies between 66-98%. These forest types included planted and natural forest stands of different ages. Classifications of short vegetation and bare earth also produced high accuracies averaging above 90%.

Item Type: Article
Schools and Departments: School of Global Studies > Geography
Subjects: G Geography. Anthropology. Recreation > GB Physical geography > GB0651 Hydrology. Water (Ground and surface waters) > GB1201 Rivers. Stream measurements
G Geography. Anthropology. Recreation > GB Physical geography > GB5000 Natural disasters
Depositing User: Alexander Antonarakis
Date Deposited: 02 Nov 2013 10:27
Last Modified: 13 Mar 2017 11:02
URI: http://sro.sussex.ac.uk/id/eprint/46887

View download statistics for this item

📧 Request an update