On the Lossless Compression of HyperHeight LiDAR Forested Landscape Data

Satellite Light Detection and Ranging (LiDAR) systems produce high-resolution data essential for confronting critical environmental challenges like climate change, disaster management, and ecological conservation. A HyperHeight Data Cube (HHDC) is a novel representation of LiDAR data. HHDCs are stru...

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Vydáno v:	Remote sensing (Basel, Switzerland) Ročník 17; číslo 21; s. 3588
Hlavní autoři:	Makarichev, Viktor, Ramirez-Jaime, Andres, Porras-Diaz, Nestor, Vasilyeva, Irina, Lukin, Vladimir, Arce, Gonzalo, Okarma, Krzysztof
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Basel MDPI AG 01.11.2025
Témata:	Algorithms Analysis Arithmetic coding Binary codes Climate change Climatic changes Compression Compression ratio context-adaptive binary arithmetic encoding Data compression Data structures Data transfer (computers) Data transmission Datasets Disaster management Emergency preparedness Entropy Environmental monitoring Environmental research Height hyperheight data cube (HHDC) Ice sheets Lidar light detection and ranging (LiDAR) lossless compression Mathematical analysis Neon Octrees Optical radar Photons Real time Remote sensing Research facilities Rice codes run-length encoding Sparsity Splitting Tensors Terrain models
ISSN:	2072-4292, 2072-4292
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Popis
Shrnutí:	Satellite Light Detection and Ranging (LiDAR) systems produce high-resolution data essential for confronting critical environmental challenges like climate change, disaster management, and ecological conservation. A HyperHeight Data Cube (HHDC) is a novel representation of LiDAR data. HHDCs are structured three-dimensional tensors, where each cell captures the number of photons detected at specific spatial and height coordinates. These data structures preserve the detailed vertical and horizontal information essential for ecological and topographical analyses, particularly Digital Terrain Models and canopy height profiles. In this paper, we investigate lossless compression techniques for large volumes of HHDCs to alleviate constraints on onboard storage, processing resources, and downlink bandwidth. We analyze several methods, including bit packing, Rice coding (RC), run-length encoding (RLE), and context-adaptive binary arithmetic coding (CABAC), as well as their combinations. We introduce the block-splitting framework, which is a simplified version of octrees. The combination of RC with RLE and CABAC within this framework achieves a median compression ratio greater than 24, which is confirmed by the results of processing two large sets of HHDCs simulated using the Smithsonian Environmental Research Center NEON data.
Bibliografie:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14
ISSN:	2072-4292 2072-4292
DOI:	10.3390/rs17213588