Building Damage Assessment in Aftermath of Disaster Events by Leveraging Geoai (Geospatial Artificial Intelligence): Review
1. Western Illinois University, Department of Earth, Atmospheric and GIS, College of Art and Sciences, Macomb, Illinois, USA.
2. Department of Atmospheric and Oceanic Science, College Park, Maryland, University of Maryland.
3. Department of Public Health, Birmingham City University, Birmingham, England.
4. School of Public Policy and Urban Affairs, Northeastern University, Boston, Massachusetts, USA.
5. Department of Urban informatics, University of Wyoming, Dept of civil and architectural engineering and construction management, USA.
Review Article
World Journal of Advanced Research and Reviews, 2024, 23(01), 667–687
Publication history:
Received on 23 May 2024; revised on 06 July 2024; accepted on 08 July 2024
Abstract:
While traditional approaches to building damage assessment in the aftermath of natural disasters have relied heavily on time-intensive and costly manual techniques, recent advances in geospatial artificial intelligence (GeoAI) have opened up new possibilities for automating and scaling up this crucial process. Leveraging technologies such as computer vision, remote sensing, and machine learning applied to geospatial data from satellites, drones, and other sensors, GeoAI has the potential to revolutionize how communities assess building damage in disaster-stricken areas and target recovery resources more quickly and effectively. However, efforts to apply GeoAI for building damage assessment also face important challenges regarding data and model quality that require further research.
To properly evaluate both the opportunities and challenges of leveraging GeoAI for building damage assessment, this comprehensive review explores the current state of the field through an analysis of recent literature and case studies. An in-depth examination is provided of innovative applications of technologies such as deep learning to high-resolution aerial imagery for automated detection and classification of structural damage. Critical requirements are identified for developing robust GeoAI solutions, such as acquiring comprehensive training data that captures the full range of possible damage patterns and accounting for environmental factors. The review also analyzes efforts by humanitarian organizations and companies to deploy initial GeoAI-powered damage assessment systems in real-world disaster events, highlighting lessons learned.
Keywords:
Building Damage Assessment; Disaster Events; Geospatial Artificial Intelligence; Geoai; Remote Sensing; Convolutional Neural Networks; Unmanned Aerial Systems; Volunteered Geographic Information; Vgi; Field Observations; Crowd-Ai Partnerships; Model Training; Big Data Challenges; Distributed Computing; Semantic Interoperability; Disaster Management.
Full text article in PDF:
Copyright information:
Copyright © 2024 Author(s) retain the copyright of this article. This article is published under the terms of the Creative Commons Attribution Liscense 4.0