Enregistré dans:
Détails bibliographiques
Auteurs principaux: Marichal, Henry, Passarella, Diego, Lucas, Christine, Profumo, Ludmila, Casaravilla, Verónica, Galli, María Noel Rocha, Ambite, Serrana, Randall, Gregory
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2404.10856
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866911842284077056
author Marichal, Henry
Passarella, Diego
Lucas, Christine
Profumo, Ludmila
Casaravilla, Verónica
Galli, María Noel Rocha
Ambite, Serrana
Randall, Gregory
author_facet Marichal, Henry
Passarella, Diego
Lucas, Christine
Profumo, Ludmila
Casaravilla, Verónica
Galli, María Noel Rocha
Ambite, Serrana
Randall, Gregory
contents The automatic detection of tree-ring boundaries and other anatomical features using image analysis has progressed substantially over the past decade with advances in machine learning and imagery technology, as well as increasing demands from the dendrochronology community. This paper presents a publicly available database of 64 scanned images of transverse sections of commercially grown Pinus taeda trees from northern Uruguay, ranging from 17 to 24 years old. The collection contains several challenging features for automatic ring detection, including illumination and surface preparation variation, fungal infection (blue stains), knot formation, missing cortex or interruptions in outer rings, and radial cracking. This dataset can be used to develop and test automatic tree ring detection algorithms. This paper presents to the dendrochronology community one such method, Cross-Section Tree-Ring Detection (CS-TRD), which identifies and marks complete annual rings in cross-sections for tree species presenting a clear definition between early and latewood. We compare the CS-TRD performance against the ground truth manual delineation of all rings over the UruDendro dataset. The CS-TRD software identified rings with an average F-score of 89% and RMSE error of 5.27px for the entire database in less than 20 seconds per image. Finally, we propose a robust measure of the ring growth using the \emph{equivalent radius} of a circle having the same area enclosed by the detected tree ring. Overall, this study contributes to the dendrochronologist's toolbox of fast and low-cost methods to automatically detect rings in conifer species, particularly for measuring diameter growth rates and stem transverse area using entire cross-sections.
format Preprint
id arxiv_https___arxiv_org_abs_2404_10856
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle UruDendro, a public dataset of cross-section images of Pinus taeda
Marichal, Henry
Passarella, Diego
Lucas, Christine
Profumo, Ludmila
Casaravilla, Verónica
Galli, María Noel Rocha
Ambite, Serrana
Randall, Gregory
Computer Vision and Pattern Recognition
Quantitative Methods
The automatic detection of tree-ring boundaries and other anatomical features using image analysis has progressed substantially over the past decade with advances in machine learning and imagery technology, as well as increasing demands from the dendrochronology community. This paper presents a publicly available database of 64 scanned images of transverse sections of commercially grown Pinus taeda trees from northern Uruguay, ranging from 17 to 24 years old. The collection contains several challenging features for automatic ring detection, including illumination and surface preparation variation, fungal infection (blue stains), knot formation, missing cortex or interruptions in outer rings, and radial cracking. This dataset can be used to develop and test automatic tree ring detection algorithms. This paper presents to the dendrochronology community one such method, Cross-Section Tree-Ring Detection (CS-TRD), which identifies and marks complete annual rings in cross-sections for tree species presenting a clear definition between early and latewood. We compare the CS-TRD performance against the ground truth manual delineation of all rings over the UruDendro dataset. The CS-TRD software identified rings with an average F-score of 89% and RMSE error of 5.27px for the entire database in less than 20 seconds per image. Finally, we propose a robust measure of the ring growth using the \emph{equivalent radius} of a circle having the same area enclosed by the detected tree ring. Overall, this study contributes to the dendrochronologist's toolbox of fast and low-cost methods to automatically detect rings in conifer species, particularly for measuring diameter growth rates and stem transverse area using entire cross-sections.
title UruDendro, a public dataset of cross-section images of Pinus taeda
topic Computer Vision and Pattern Recognition
Quantitative Methods
url https://arxiv.org/abs/2404.10856