Design and Implementation of an AI-Powered Forest Fire Prediction System
Article Sidebar
Main Article Content
Abstract
Forest fires represent a significant environmental and socio-economic challenge, causing large-scale ecological degradation, loss of biodiversity, and threats to human life and infrastructure. Conventional fire detection systems are predom-inantly reactive, identifying fire incidents only after ignition, which limits the ability to implement timely preventive measures. Additionally, many existing approaches lack the capability to integrate heterogeneous data sources in real time, resulting in delayed predictions and reduced effectiveness. This paper presents the design and implementation of an AI-powered Forest Fire Prediction System that aims to address these limitations through proactive risk assessment. The proposed system leverages machine learning techniques in conjunction with real-time environmental data, satellite imagery, and historical fire records to predict fire-prone regions before ignition. By incorporating multiple data modalities such as meteorological parameters, vegetation indices, and spatial features, the system captures complex patterns associated with fire occurrence. The architecture is based on a scalable cloud-driven frame-work that integrates data collection, preprocessing, model train-ing, and visualization components into a unified pipeline. Fur-thermore, the system provides an interactive dashboard for visualizing fire risk levels and includes an automated alert mecha-nism to notify stakeholders in high-risk scenarios. Experimental evaluation demonstrates improved predictive performance and reduced response time compared to traditional approaches. The proposed solution contributes toward enhancing early warning systems and supports proactive disaster management strategies in wildfire-prone regions.