Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
GPT-4o
Gemini 2.5 Pro Pro
o3 Pro
GPT-4.1 Pro
DeepSeek R1 via Azure Pro
2000 character limit reached

UruDendro, a public dataset of cross-section images of Pinus taeda (2404.10856v1)

Published 16 Apr 2024 in cs.CV and q-bio.QM

Abstract: 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.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (36)
  1. A method for tree-ring analysis using diva-gis freeware on scanned core images. Tree-Ring Research, 71:118–129.
  2. A powerful and promising tool used in the tree ring measurements. Revista de Silvicultura \textcommabelowsi Cinegetica, 21(38):27–30.
  3. Forests expand as livestock pressure declines in subtropical south america. Ecology and Society, 24(2).
  4. Robust tree-ring detection. In Mery, D. and Rueda, L., editors, Advances in Image and Video Technology, Second Pacific Rim Symposium, PSIVT 2007, Santiago, Chile, December 17-19, 2007, Proceedings, volume 4872 of Lecture Notes in Computer Science, pages 575–585. Springer.
  5. Ant Colony Optimization for Estimating Pith Position on Images of Tree Log Ends. Image Processing On Line, 12:558–581. https://doi.org/10.5201/ipol.2022.338.
  6. Devernay, F. (1995). A non-maxima suppression method for edge detection with sub-pixel accuracy. Technical report, INRIA RESEARCH REP. 2724, SOPHIAANTIPOLIS.
  7. DGF (2022). Superficie forestal del uruguay. Technical report, MGAP. https://www.gub.uy/ministerio-ganaderia-agricultura-pesca/sites/ministerio-ganaderia-agricultura-pesca/files/2023-01/Superficie%20Plantado%20Informe%202022.pdf.
  8. DIEA-MGAP (2022). Anuario estadistico agropecuario 2022 25 aniversario. data, Direccion Estadísticas Agropecuerias - DIEA, Ministerio de Ganadería Agricultura y Pesca - MGAP. 2022, https://descargas.mgap.gub.uy/DIEA/Anuarios/Anuario2022/O_MGAP_Anuario_estad%C3%ADstico_%202022-DIGITAL.pdf.
  9. Compression wood in conifers - the characterisation of its formation and its relevance to timber quality. data, Great Britain Forest Research. 2005, https://www.forestresearch.gov.uk/research/compression-wood-in-conifers-compression-wood/.
  10. Capturing: A do-it-yourself tool for wood sample digitization. Methods in Ecology and Evolution, 13(6):1185–1191.
  11. Iterative next boundary detection, for instance, segmentation of tree rings in microscopy images of shrub cross sections.
  12. Gigapixel macro photography of tree rings. Tree-Ring Research, 77(2):86–94.
  13. A Sub-Pixel Edge Detector: an Implementation of the Canny/Devernay Algorithm. Image Processing On Line, 7:347–372. https://doi.org/10.5201/ipol.2017.216.
  14. Semiautomatic tree ring segmentation using active contours and an optimised gradient operator / poloautomatizovana segmentacia ronych radialnych kruhov stromov s vyuitim metody active contoure a optimalizovaneho gradientoveho operatora. Forestry Journal, 60:185 – 190.
  15. Inc., R. I. C. (2022). WinDENDRO™ 2022, Tree-Ring and Wood Density Analyser Optimised for Optical Scanners. https://regentinstruments.com/assets/images_windendro/WinDENDRO_2023.pdf.
  16. INIA (2023). Open database: Meteorological data. tacuarembo station. http://www.inia.uy/gras.
  17. ITRDB (2023). International tree-ring data bank (itrdb). https://www.ncei.noaa.gov/products/paleoclimatology/tree-ring.
  18. An automated method for tree-ring delineation based on active contours guided by DT-CWT complex coefficients in photographic images: Application to abies alba wood slice images. Comput. Electron. Agric., 118:204–214.
  19. Kingsbury, N. G. (2001). Complex wavelets for shift invariant analysis and filtering of signals. Applied and Computational Harmonic Analysis, 10:234–253.
  20. Traceability and quality assessment of Norway spruce (Picea abies (L.) H.Karst.) logs: the TreeTrace_spruce database. Annals of Forest Science, 80(1):9.
  21. Automatic tree ring detection using jacobi sets.
  22. The gentree dendroecological collection, tree-ring and wood density data from seven tree species across europe. Scientific Data, 7.
  23. Measuring tree-ring widths using the coorecorder software application. Dendrochronologia, 67:125841.
  24. Norell, K. (2009). An automatic method for counting annual rings in noisy sawmill images. In Foggia, P., Sansone, C., and Vento, M., editors, Image Analysis and Processing – ICIAP 2009, pages 307–316, Berlin, Heidelberg. Springer Berlin Heidelberg.
  25. Grey weighted polar distance transform for outlining circular and approximately circular objects. 14th International Conference on Image Analysis and Processing (ICIAP 2007), pages 647–652.
  26. Real-time spectral classification of compression wood in picea abies. Journal of wood science, 45:30–37.
  27. Automation of tree-ring detection and measurements using deep learning. bioRxiv.
  28. Disc image-processing software for three-dimensional mapping of stem ring width and compression wood. New Zealand Journal of Forestry Science, 37(2):169.
  29. U22{}^{\mbox{2}}start_FLOATSUPERSCRIPT 2 end_FLOATSUPERSCRIPT-net: Going deeper with nested u-structure for salient object detection. CoRR, abs/2005.09007.
  30. Sheppard, P. (1995). Reflected-light image analysis of conifer tree rings for dendrochronological research. Master’s thesis, University of Arizona.
  31. MtreeRing: A Shiny Application for Automatic Measurements of Tree-Ring Widths on Digital Images. https://docs.ropensci.org/MtreeRing, https://github.com/ropensci/MtreeRing.
  32. Increasing wood production through old age in tall trees. Forest Ecology and Management, 259(5):976–994.
  33. Speer, J. H. (2010). Fundamentals of the-ring research. The University of Arizona Press.
  34. Rate of tree carbon accumulation increases continuously with tree size. Nature, letter research, 507:90 – 93.
  35. Wada, K. (2018). Labelme: Image Polygonal Annotation with Python.
  36. Method of tree-ring image analysis for dendrochronology. Optical Engineering, 51(7):077202.

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now
Dice Question Streamline Icon: https://streamlinehq.com

Follow-up Questions

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now