Related papers: Tomographic SAR Reconstruction for Forest Height Estimation

Tomographic SAR Reconstruction for Forest Height Estimation

URL: http://arxiv.org/abs/2412.00903v2
Date: Tue, 03 Dec 2024 16:32:27 GMT
Title: Tomographic SAR Reconstruction for Forest Height Estimation
Authors: Grace Colverd, Jumpei Takami, Laura Schade, Karol Bot, Joseph A. Gallego-Mejia,
Abstract summary: Tree height estimation serves as an important proxy for biomass estimation in ecological and forestry applications. In this study, we use deep learning to estimate forest canopy height directly from 2D Single Look Complex (SLC) images, a derivative of Synthetic Aperture Radar (SAR) Our method attempts to bypass traditional tomographic signal processing, potentially reducing latency from SAR capture to end product.
Score: 4.1942958779358674
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Abstract: Tree height estimation serves as an important proxy for biomass estimation in ecological and forestry applications. While traditional methods such as photogrammetry and Light Detection and Ranging (LiDAR) offer accurate height measurements, their application on a global scale is often cost-prohibitive and logistically challenging. In contrast, remote sensing techniques, particularly 3D tomographic reconstruction from Synthetic Aperture Radar (SAR) imagery, provide a scalable solution for global height estimation. SAR images have been used in earth observation contexts due to their ability to work in all weathers, unobscured by clouds. In this study, we use deep learning to estimate forest canopy height directly from 2D Single Look Complex (SLC) images, a derivative of SAR. Our method attempts to bypass traditional tomographic signal processing, potentially reducing latency from SAR capture to end product. We also quantify the impact of varying numbers of SLC images on height estimation accuracy, aiming to inform future satellite operations and optimize data collection strategies. Compared to full tomographic processing combined with deep learning, our minimal method (partial processing + deep learning) falls short, with an error 16-21\% higher, highlighting the continuing relevance of geometric signal processing.

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