Possibilities and Limitations of a Geospatial Approach to Refine Habitat Mapping for Greater Gliders (Petauroides spp.)

Jess E. Evans; Elizabeth A. Brunton; Javier X. Leon; Teresa J. Eyre; Romane H. Cristescu

doi:10.3390/land14040784

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Possibilities and Limitations of a Geospatial Approach to Refine Habitat Mapping for Greater Gliders (Petauroides spp.)

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Possibilities and Limitations of a Geospatial Approach to Refine Habitat Mapping for Greater Gliders (Petauroides spp.)

Jess E. Evans, Elizabeth A. Brunton, Javier X. Leon, Teresa J. Eyre and Romane H. Cristescu

Land, Vol.14(4), pp.1-17

2025

DOI: https://doi.org/10.3390/land14040784

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Abstract

hollow-bearing tree

geospatial analysis

hollow-dependent

greater glider

lidR

Hollow-dependent wildlife has been declining globally due to the removal of hollow-bearing trees, yet these trees are often unaccounted for in habitat mapping. As on-ground field surveys are costly and time-consuming, we aimed to develop a simple, accessible and transferrable geospatial approach using freely accessible LiDAR to refine habitat mapping by identifying high densities of potential hollow-bearing trees. We assessed if LiDAR from 2009 could be accurately used to detect tree heights, which would correlate to tree diameter at breast height (DBH), which in turn would identify trees that are more likely to be hollow-bearing. Here, we use habitat mapping of greater gliders (Petauroides spp.) in the Fraser Coast region of Australia as a case study. Across four sites, field surveys were conducted in 2023 to assess the tree height and density of large trees (>50 cm DBH per 1 km2) at 19 transects (n = 91). This was compared to outputs from individual tree detection derived from unsupervised classification using a local maximal filter and variable window size to identify treetops in freely available LiDAR. Tree height was measured with an accuracy of RMSE 5.75 m, and we were able to identify transects with large trees (>50 cm DBH), which were more likely hollow bearing. However, there was no statistical evidence to suggest that transects with a high density of large trees could be accurately identified based on LiDAR alone (>50 cm DBH p 0.2298). Despite this, we have demonstrated that freely accessible LiDAR and unsupervised machine learning techniques can be utilised to identify large, potentially hollow-bearing trees on a broad scale to refine habitat mapping for hollow-dependent species. It is important to develop geospatial analysis methods that are more accessible to land managers, as deep machine learning methods and current LiDAR can be computationally intensive and expensive. We propose a workflow using free and accessible geospatial analysis methods to identify large, potentially hollow-bearing trees and determine how to address some limitations in this geospatial approach.

Details

Title: Possibilities and Limitations of a Geospatial Approach to Refine Habitat Mapping for Greater Gliders (Petauroides spp.)
Authors: Jess E. Evans (Corresponding Author) - University of the Sunshine Coast, Queensland, School of Science, Technology and Engineering
Elizabeth A. Brunton - University of the Sunshine Coast, Queensland, School of Science, Technology and Engineering
Javier X. Leon - University of the Sunshine Coast, Queensland, School of Science, Technology and Engineering
Teresa J. Eyre - Queensland Department of Environment and Science
Romane H. Cristescu - University of the Sunshine Coast, Queensland, School of Science, Technology and Engineering
Publication details: Land, Vol.14(4), pp.1-17
Publisher: MDPI AG
Date published: 2025
DOI: 10.3390/land14040784
ISSN: 2073-445X
Copyright note: © 2025 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Data Availability: Individual tree detection code used the lidR package in R version 4.2.3 and was based on the guidelines set out by Roussel et al. (2020) and Roussel and Auty (2023) [19,20]. The LiDAR data “Fraser Coast 2009 Project” used for this study can be accessed through Queensland Spatial Catalogue—QSpatial, which is retrieved from https://qldspatial.information.qld.gov.au/catalogue/custom/detail.page?fid={E8CEF5BA-A1B7-4DE5-A703-8161FD9BD3CF} (accessed on 31 July 2022).
Grant note: This research was funded by the Wildlife Preservation Society of Queensland, Fraser Coast branch, which issued a student research grant, however no grant number was provided. The Forest Research Institute based at the University of the Sunshine Coast also assisted by rewarding a scholarship to the primary author to assist this honours research project. This was also funded by the University of the Sunshine Coast Honours fund allocation.
Organisation Unit: Marketing and Communications; School of Science, Technology and Engineering
Language: English
Record Identifier: 991121900302621
Output Type: Journal article

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