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Point Cloud Denoising and Feature Preservation: An Adaptive Kernel Approach Based on Local Density and Global Statistics

Lianchao Wang, Yijin Chen, Wenhui Song, Hanghang Xu

2024Sensors25 citationsDOIOpen Access PDF

Abstract

Noise removal is a critical stage in the preprocessing of point clouds, exerting a significant impact on subsequent processes such as point cloud classification, segmentation, feature extraction, and 3D reconstruction. The exploration of methods capable of adapting to and effectively handling the noise in point clouds from real-world outdoor scenes remains an open and practically significant issue. Addressing this issue, this study proposes an adaptive kernel approach based on local density and global statistics (AKA-LDGS). This method constructs the overall framework for point cloud denoising using Bayesian estimation theory. It dynamically sets the prior probabilities of real and noise points according to the spatial function relationship, which varies with the distance from the points to the center of the LiDAR. The probability density function (PDF) for real points is constructed using a multivariate Gaussian distribution, while the PDF for noise points is established using a data-driven, non-parametric adaptive kernel density estimation (KDE) approach. Experimental results demonstrate that this method can effectively remove noise from point clouds in real-world outdoor scenes while maintaining the overall structural features of the point cloud.

Topics & Concepts

Point cloudComputer scienceArtificial intelligenceNoise (video)Kernel density estimationProbability density functionKernel (algebra)Variable kernel density estimationMultivariate kernel density estimationNoise reductionSegmentationPattern recognition (psychology)Feature (linguistics)Density estimationComputer visionMathematicsStatisticsKernel methodSupport vector machineImage (mathematics)EstimatorPhilosophyCombinatoricsLinguistics3D Surveying and Cultural HeritageRemote Sensing and LiDAR Applications3D Shape Modeling and Analysis