Allometric equations to estimate the dry mass of Sahel woody plants mapped with very-high resolution satellite imagery

Pierre Hiernaux*, Hassane Bil Assanou Issoufou, Christian Igel, Ankit Kariryaa, Moussa Kourouma, Jérôme Chave, Eric Mougin, Patrice Savadogo

*Corresponding author for this work

Research output: Contribution to journalJournal articleResearchpeer-review

10 Citations (Scopus)

Abstract

Very high-resolution satellite images and deep learning are achieving the mapping of individual trees and shrubs over large areas in Africa. Each woody plant is precisely georeferenced and defined by its crown area and, sometimes, its height. The challenge is to build allometric equations for foliage, wood and root dry masses based either on crown area alone, or the product crown area × tree height as independent variables regardless of species. This was met by reanalyzing existing Sahel woody plant data from destructive sampling. Overall, the foliage (seasonal maximum), wood and root dry masses were measured on 900, 698 and 26 trees or shrubs from 27, 26 and 5 species respectively. The regression models tested for foliage, wood or root masses were linear or power functions using a range of different approaches: Ordinary least square (OLS) regression after log–log transform with or without Baskerville correction (1972), and non-linear regressions (NLR). All the models outputs were intercompared for fit indicators and prediction uncertainty, as well as the resulting trends in root to wood ratio, and foliage to wood ratio over the range of crown areas. This process selected a set of OLS log–log equations with crown area as independent variable. When the Baskerville correction is applied the approximation errors are 0.4 kg Dry Matter (DM) for foliage, 12.2 for wood and 6.3 for roots, aggregating at 13.8 kg DM per tree. These allometry equations were compared to published equations for tropical trees, most from the more humid tropics that were generally based on stem diameter, tree height and wood density. This paper's allometry predictions were within the range of these other allometry equations, reinforcing the confidence in their use even beyond the Sahel domain towards sub-humid savannas.

Original languageEnglish
Article number120653
JournalForest Ecology and Management
Volume529
Number of pages13
ISSN0378-1127
DOIs
Publication statusPublished - 1 Feb 2023

Bibliographical note

Funding Information:
The authors thank Jorge Pinzon and Robert Kaufmann for the fruitful discussions about data heteroskedasticity and the generalized least square (GLS) application that allowed to discuss the uncertainty estimates and facilitate the choice among allometry models. The authors thank Compton J. Tucker for his advices and help in editing. The authors are also grateful to late Mohamed Idrissa Cissé and ILRI staff in Niono, in the Gourma and in Niger who contributed to the field data collection under research projects of the International Livestock Research Institute, ILRI. More recent observations were funded by the AMMA-CATCH observatory (http://www.amma-catch.org). C.I. and A.K. acknowledge support by the Villum Foundation through the project Deep Learning and Remote Sensing for Unlocking Global Ecosystem Resource Dynamics (DeReEco).

Funding Information:
The authors thank Jorge Pinzon and Robert Kaufmann for the fruitful discussions about data heteroskedasticity and the generalized least square (GLS) application that allowed to discuss the uncertainty estimates and facilitate the choice among allometry models. The authors thank Compton J. Tucker for his advices and help in editing. The authors are also grateful to late Mohamed Idrissa Cissé and ILRI staff in Niono, in the Gourma and in Niger who contributed to the field data collection under research projects of the International Livestock Research Institute, ILRI. More recent observations were funded by the AMMA-CATCH observatory (http://www.amma-catch.org). C.I. and A.K. acknowledge support by the Villum Foundation through the project Deep Learning and Remote Sensing for Unlocking Global Ecosystem Resource Dynamics (DeReEco). P.H, B.-A. H. I. M.K.: contributed to data collection; P.H. C.I. A.K.: participated to data analysis; P.H. wrote the first draft all authors contributing to revisions and editing.

Publisher Copyright:
© 2022 Elsevier B.V.

Keywords

  • Africa drylands
  • Allometry
  • Foliage
  • Root
  • Sahel
  • Sudan
  • Wood

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