Implicit neural representation for change detection

Identifying changes in a pair of 3D aerial LiDAR point clouds, obtained during two distinct time periods over the same geographic region presents a significant challenge due to the disparities in spatial coverage and the presence of noise in the acquisition system. The most commonly used approaches...

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Bibliographic Details
Published in2024 IEEE/CVF Winter Conference on Applications of Computer Vision (WACV) pp. 924 - 934
Main Authors Naylor, Peter, Di Carlo, Diego, Traviglia, Arianna, Yamada, Makoto, Fiorucci, Marco
Format Conference Proceeding
LanguageEnglish
Published IEEE 03.01.2024
Subjects
Algorithms
Applications
Image recognition and understanding
Laser radar
Noise
Point cloud compression
Remote Sensing
Shape
Surface reconstruction
Three-dimensional displays
Urban planning
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Summary:Identifying changes in a pair of 3D aerial LiDAR point clouds, obtained during two distinct time periods over the same geographic region presents a significant challenge due to the disparities in spatial coverage and the presence of noise in the acquisition system. The most commonly used approaches to detecting changes in point clouds are based on supervised methods which necessitate extensive labelled data often unavailable in real-world applications. To address these issues, we propose an unsupervised approach that comprises two components: Implcit Neural Represenation (INR) for continuous shape reconstruction and a Gaussian Mixture Model for categorising changes. INR offers a grid-agnostic representation for encoding bi-temporal point clouds, with unmatched spatial support that can be regularised to enhance high-frequency details and reduce noise. The reconstructions at each timestamp are compared at arbitrary spatial scales, leading to a significant increase in detection capabilities. We apply our method to a benchmark dataset comprising simulated LiDAR point clouds for urban sprawling. This dataset encompasses diverse challenging scenarios, varying in resolutions, input modalities and noise levels. This enables a comprehensive multi-scenario evaluation, comparing our method with the current state-of-the-art approach. We outperform the previous methods by a margin of 10% in the intersection over union metric. In addition, we put our techniques to practical use by applying them in a real-world scenario to identify instances of illicit excavation of archaeological sites and validate our results by comparing them with findings from field experts.
ISSN:2642-9381
DOI:10.1109/WACV57701.2024.00098