Abstract
Periodic building change detection is important for many applications, including disaster management. Building map databases need to be updated based on detected changes so as to ensure their currency and usefulness. This paper first presents a graphical user interface (GUI) developed to support the creation of a building database from building footprints automatically extracted from LiDAR (light detection and ranging) point cloud data. An automatic building change detection technique by which buildings are automatically extracted from newly-available LiDAR point cloud data and compared to those within an existing building database is then presented. Buildings identified as totally new or demolished are directly added to the change detection output. However, for part-building demolition or extension, a connected component analysis algorithm is applied, and for each connected building component, the area, width and height are estimated in order to ascertain if it can be considered as a demolished or new building-part. Using the developed GUI, a user can quickly examine each suggested change and indicate his/her decision to update the database, with a minimum number of mouse clicks. In experimental tests, the proposed change detection technique was found to produce almost no omission errors, and when compared to the number of reference building corners, it reduced the human interaction to 14% for initial building map generation and to 3% for map updating. Thus, the proposed approach can be exploited for enhanced automated building information updating within a topographic database.
Highlights
A recent spark of natural disasters around the world, including in Australia and New Zealand, for example the bushfire in Victoria, the flood in Queensland and the earthquake in Christchurch, has made it imperative to investigate automatic systems, which forecast the risk of disasters, and help with minimising losses, such as human lives and properties, during the catastrophe and a quick recovery, including resettlement of the local communities, after the incident
This paper presents a semiautomatic technique to create a new building database from LiDAR point cloud data
This paper has presented a new method for both building change detection and the subsequent updating of building changes in a topographic database
Summary
A recent spark of natural disasters around the world, including in Australia and New Zealand, for example the bushfire in Victoria, the flood in Queensland and the earthquake in Christchurch, has made it imperative to investigate automatic systems, which forecast the risk of disasters, and help with minimising losses, such as human lives and properties, during the catastrophe and a quick recovery, including resettlement of the local communities, after the incident These days, bushfires constitute a major natural and socioeconomic hazard, costing Australia in excess of $80 million per year and affecting around three million hectares of land in southern Australia alone [1]. Many local and state governments in remote areas do not have a digital version of the topographic database that includes vegetation, roads and buildings
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