| چکیده انگلیسی مقاله |
Extended Abstract
Introduction
LiDAR (Light Detection and Ranging) technology has emerged as an essential tool in 3D remote sensing and spatial analysis, particularly in urban environments where accurate modeling is crucial. This technology enables precise mapping of terrain and urban structures by capturing high-density point cloud data. However, despite its precision, LiDAR data is often affected by noise introduced by environmental conditions, sensor inaccuracies, and surface properties. This noise degrades the quality of the data, impacting its usability in various applications, including urban planning, forestry, and hazard assessment. Effective noise removal methods are therefore essential for enhancing data reliability while preserving its structural integrity.
Materials & Methods
This study introduces a hybrid approach for noise removal in LiDAR point cloud data by integrating a guided filter with the Density-Based Spatial Clustering of Applications with Noise (DBSCAN) algorithm. The guided filter is leveraged for its edge-preserving smoothing capabilities, which reduce elevation noise while maintaining critical features. Unlike traditional filters, which often compromise structural details, the guided filter ensures that essential features like building edges and vegetation patterns are retained. Parameters such as neighborhood radius and smoothing strength are optimized to balance noise reduction with detail preservation. Complementing the guided filter, the DBSCAN algorithm is employed to identify and remove outliers. DBSCAN operates by analyzing the density of points within a specified radius (epsilon) and identifying clusters based on the density threshold. Points that do not belong to any cluster are classified as noise and removed. This dual-method approach ensures a comprehensive noise removal process, targeting both widespread elevation noise and sparse outliers that traditional filters might overlook. To enhance the efficiency and adaptability of the hybrid method, Bayesian optimization is utilized for parameter tuning. This optimization technique systematically searches for the optimal parameter values, reducing the reliance on trial-and-error methods and ensuring the approach is tailored to the specific characteristics of the dataset. Key parameters optimized include the neighborhood radius and epsilon for DBSCAN and the smoothing parameters for the guided filter. The dataset for this study comprises aerial LiDAR scans collected from the coastal region of Duck, North Carolina, USA. The data includes high-resolution 3D point clouds with attributes such as elevation and reflectance intensity. Quantitative evaluations were conducted using statistical metrics like variance and standard deviation, while qualitative assessments involved visual inspections of digital elevation models (DEMs), triangulated irregular networks (TINs), and elevation profiles of flat surfaces.
Results & Discussion
Results indicate that the hybrid approach outperforms traditional methods such as mean, median, and standalone guided filtering. The guided filter effectively reduces elevation noise on flat surfaces like rooftops and roads, preserving critical structural features. Concurrently, DBSCAN identifies and removes residual outliers in low-density regions, which are often missed by other methods. Statistical analyses demonstrate significant reductions in variance and standard deviation, confirming enhanced data homogeneity. Visual inspections further validate these findings, showcasing smoother DEMs and more coherent TINs with fewer artifacts. One of the major advantages of this hybrid approach is its computational efficiency. The integration of the guided filter and DBSCAN ensures effective noise removal without excessive processing time, making the method scalable for large datasets. Additionally, the flexibility of DBSCAN allows it to adapt to diverse datasets without requiring prior assumptions about point distribution. This adaptability, combined with the systematic parameter tuning provided by Bayesian optimization, enhances the method's robustness and applicability across various contexts. Beyond noise removal, the proposed approach has broader implications for LiDAR data processing. By preserving structural integrity and minimizing point loss, the method supports high-accuracy spatial analyses crucial for applications like urban development, forest management, and disaster risk assessment. For instance, in urban planning, accurate LiDAR data can facilitate the creation of detailed 3D models, enabling better infrastructure planning and monitoring. Similarly, in forestry, the method can improve canopy height estimation and biomass calculations by ensuring clean and reliable data.
Conclusion
In conclusion, the hybrid approach combining the guided filter and DBSCAN algorithm represents a robust, efficient, and adaptable solution for noise removal in LiDAR point cloud data. By addressing both elevation noise and sparse outliers, the method improves data quality while preserving essential features, making it suitable for a wide range of applications. Its balance of computational efficiency and data accuracy ensures its relevance in both academic research and practical implementations. Future advancements in parameter optimization and integration with machine learning are likely to further enhance the utility and scalability of this approach. |