Data

Australia-Wide 30 m Machine Learning-Derived Canopy Height Models Composites: Best Pick and Median

Name: Australia-Wide 30 m Machine Learning-Derived Canopy Height Models Composites: Best Pick and Median
Published: 2025

Terrestrial Ecosystem Research Network

Pucino, Nicolas ; McVicar, Tim R ; Levick, Shaun ; Van Dijk, Albert

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ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rfr_id=info%3Asid%2FANDS&rft_id=info:doi10.25901/xqv7-jk46&rft.title=Australia-Wide 30 m Machine Learning-Derived Canopy Height Models Composites: Best Pick and Median&rft.identifier=10.25901/xqv7-jk46&rft.publisher=Terrestrial Ecosystem Research Network&rft.description=This dataset is part of the OzTreeMap project and provides two new 30 m spatial resolution canopy height products for continental Australia: the best-pick canopy height model (pick-CHM) and the median canopy height model (med-CHM). Both products represent estimates of vegetation canopy height across Australia and were developed to improve the accuracy and consistency of existing large-scale canopy height models, which were generated by researchers to represent canopy heights from variable time periods ranging from 2007 until 2020. The best-pick and median products are composites and derive from an extensive validation of the 4 original CHMs. Each product is provided as a single-band GeoTIFF raster in the Australian Albers (EPSG:3577) coordinate reference system, with 30 m spatial resolution and float32 data type. These datasets support applications in forest structure monitoring, carbon accounting, and ecosystem assessment across Australia.A total of 26,987 LiDAR and photogrammetry point cloud tiles (1–4 km² each) were obtained from the Elevation and Depth (ELVIS) and Terrestrial Ecosystem Research Network (TERN) open repositories, representing a 5% stratified sample designed to match the distribution of Australia’s 16 vegetation structure classes (Scarth et al., 2019). For each tile, a 0.5 m canopy height model (CHM) was generated using the pit-free algorithm (Khosravipour et al., 2014), and individual tree crowns were delineated with the Dalponte segmentation algorithm (Dalponte & Coomes, 2016) using vegetation-specific optimized parameters (Pucino et al., 2025, under review). The resulting point-cloud-derived CHMs served as reference data for evaluating the vertical accuracy of four publicly available satellite-based machine-learning or deep learning-derived CHMs: (1) Lang et al. (2023); (2) Liao et al. (2020); (3) Potapov et al. (2021); and (4) Tolan et al. (2024). All datasets were co-registered and resampled to 30 m resolution. Pixel-wise error metrics were computed, and a combined score defined for each vegetation class which publicly available dataset is the most accurate. Water bodies are masked using Digital Earth Australia Waterbodies dataset. Three new continental-scale 30 m CHMs were then produced: (i) a pixel-wise median composite; (ii) a vegetation-class-specific best-pick composite; and (iii) a deep-learning CHM derived from a multi-layer perceptron (MLP - not publicly available). Note: this document's Start Date and End Date indicate the nominal dates of the datasets we tested, not the publication dates of their associated articles.Progress Code: completedMaintenance and Update Frequency: notPlanned&rft.creator=Pucino, Nicolas &rft.creator=McVicar, Tim R &rft.creator=Levick, Shaun &rft.creator=Van Dijk, Albert &rft.date=2025&rft.edition=1&rft.coverage=Australia-wide 30 m datasets.&rft.coverage=northlimit=-9.03; southlimit=-43.74; westlimit=112.92; eastLimit=153.64; projection=EPSG:3577; uplimit=9999; downlimit=0&rft_rights=Creative Commons Attribution 4.0 International Licence http://creativecommons.org/licenses/by/4.0&rft_rights=TERN services are provided on an as-is and as available basis. Users use any TERN services at their discretion and risk. They will be solely responsible for any damage or loss whatsoever that results from such use including use of any data obtained through TERN and any analysis performed using the TERN infrastructure. <br />Web links to and from external, third party websites should not be construed as implying any relationships with and/or endorsement of the external site or its content by TERN. <br /><br />Please advise any work or publications that use this data via the online form at https://www.tern.org.au/research-publications/#reporting&rft_rights=Please cite this dataset as {Author} ({PublicationYear}). {Title}. {Version, as appropriate}. Terrestrial Ecosystem Research Network. Dataset. {Identifier}.&rft_subject=environment&rft_subject=elevation&rft_subject=FORESTS&rft_subject=EARTH SCIENCE&rft_subject=BIOSPHERE&rft_subject=TERRESTRIAL ECOSYSTEMS&rft_subject=VEGETATION HEIGHT&rft_subject=CANOPY CHARACTERISTICS&rft_subject=VEGETATION&rft_subject=Forest ecosystems&rft_subject=Forestry Fire Management&rft_subject=AGRICULTURAL AND VETERINARY SCIENCES&rft_subject=FORESTRY SCIENCES&rft_subject=Forestry Product Quality Assessment&rft_subject=earth observation satellite&rft_subject=LANDSAT-5&rft_subject=LANDSAT-6&rft_subject=LANDSAT-7&rft_subject=LANDSAT-8&rft_subject=Sentinel-2A&rft_subject=Sentinel-2B&rft_subject=Advanced Land Observing Satellite (ALOS)&rft_subject=Ice, Cloud and Land Elevation Satellite (ICESat)&rft_subject=canopy height (Metre)&rft_subject=Metre&rft_subject=30 meters - < 100 meters&rft_subject=1 meter - < 10 meters&rft_subject=Multi-Year&rft_subject=CHM&rft.type=dataset&rft.language=English Access the data

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Licence & Rights:

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Creative Commons Attribution 4.0 International Licence
http://creativecommons.org/licenses/by/4.0

TERN services are provided on an "as-is" and "as available" basis. Users use any TERN services at their discretion and risk. They will be solely responsible for any damage or loss whatsoever that results from such use including use of any data obtained through TERN and any analysis performed using the TERN infrastructure.
Web links to and from external, third party websites should not be construed as implying any relationships with and/or endorsement of the external site or its content by TERN.

Please advise any work or publications that use this data via the online form at https://www.tern.org.au/research-publications/#reporting

Please cite this dataset as {Author} ({PublicationYear}). {Title}. {Version, as appropriate}. Terrestrial Ecosystem Research Network. Dataset. {Identifier}.

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Contact Information

Street Address:
Terrestrial Ecosystem Research Network
Building 1019, 80 Meiers Rd
QLD 4068
Australia
Ph: +61 7 3365 9097

[email protected]

Brief description

This dataset is part of the OzTreeMap project and provides two new 30 m spatial resolution canopy height products for continental Australia: the best-pick canopy height model (pick-CHM) and the median canopy height model (med-CHM). Both products represent estimates of vegetation canopy height across Australia and were developed to improve the accuracy and consistency of existing large-scale canopy height models, which were generated by researchers to represent canopy heights from variable time periods ranging from 2007 until 2020. The best-pick and median products are composites and derive from an extensive validation of the 4 original CHMs.

Each product is provided as a single-band GeoTIFF raster in the Australian Albers (EPSG:3577) coordinate reference system, with 30 m spatial resolution and float32 data type. These datasets support applications in forest structure monitoring, carbon accounting, and ecosystem assessment across Australia.

Notes

Supplemental Information
Link to download the tiles footprints geojson file : Land Cover Class

Lineage

A total of 26,987 LiDAR and photogrammetry point cloud tiles (1–4 km² each) were obtained from the Elevation and Depth (ELVIS) and Terrestrial Ecosystem Research Network (TERN) open repositories, representing a 5% stratified sample designed to match the distribution of Australia’s 16 vegetation structure classes (Scarth et al., 2019). For each tile, a 0.5 m canopy height model (CHM) was generated using the pit-free algorithm (Khosravipour et al., 2014), and individual tree crowns were delineated with the Dalponte segmentation algorithm (Dalponte & Coomes, 2016) using vegetation-specific optimized parameters (Pucino et al., 2025, under review).

The resulting point-cloud-derived CHMs served as reference data for evaluating the vertical accuracy of four publicly available satellite-based machine-learning or deep learning-derived CHMs: (1) Lang et al. (2023); (2) Liao et al. (2020); (3) Potapov et al. (2021); and (4) Tolan et al. (2024). All datasets were co-registered and resampled to 30 m resolution. Pixel-wise error metrics were computed, and a combined score defined for each vegetation class which publicly available dataset is the most accurate. Water bodies are masked using Digital Earth Australia Waterbodies dataset.

Three new continental-scale 30 m CHMs were then produced: (i) a pixel-wise median composite; (ii) a vegetation-class-specific best-pick composite; and (iii) a deep-learning CHM derived from a multi-layer perceptron (MLP - not publicly available).

Note: this document's Start Date and End Date indicate the nominal dates of the datasets we tested, not the publication dates of their associated articles.

Progress Code: completed

Maintenance and Update Frequency: notPlanned

Notes

Credit
We at TERN acknowledge the Traditional Owners and Custodians throughout Australia, New Zealand and all nations. We honour their profound connections to land, water, biodiversity and culture and pay our respects to their Elders past, present and emerging.
This research was conducted under the ANU-CSIRO Collaborative Research Agreement entitled ‘Spatial and vertical distributions of individual tree and shrub canopies across Australian ecosystems’. We thank Drs Libby Pinkard, Steve Roxburgh, and Glenn Newnham (all from CSIRO Environment) for their continued support.

Purpose
These datasets provide better Canopy Height Model estimates as validated versus an extensive point cloud datasets, therefore, these could improve downstream modelling works where the original datasets are used.

Created: 2025-01-01

Issued: 2025-10-29

Modified: 2025-12-15

Data time period: 2007-01-01 to 2020-01-01

This dataset is part of a larger collection

Click to explore relationships graph

text: Australia-wide 30 m datasets.

Subjects

User Contributed Tags

Other Information

Point-of-truth metadata URL

uri : https://geonetwork.tern.org.au/geonetwork/srv/eng/catalog.search#/metadata/36c98155-39c8-4eec-9070-a978933f3fa3 External Link

Dalponte, M., Coomes, D.A., 2016. Tree-centric mapping of forest carbon density from airborne laser scanning and hyperspectral data. Methods Ecol. Evol. 7, 1236–1245.

doi : https://doi.org/10.1111/2041-210X.12575 DOI Link

Khosravipour, A., Skidmore, A.K., Isenburg, M., Wang, T., Hussin, Y.A., 2014. Generating Pit-free Canopy Height Models from Airborne Lidar. Photogrammetric Engineering & Remote Sensing 80, 863–872.

doi : https://doi.org/10.14358/PERS.80.9.863 DOI Link

Lang, N., Jetz, W., Schindler, K., Wegner, J.D., 2023. A high-resolution canopy height model of the Earth. Nat Ecol Evol 7, 1778–1789.

doi : https://doi.org/10.1038/s41559-023-02206-6 DOI Link

Liao, Z., Van Dijk, A.I.J.M., He, B., Larraondo, P.R., Scarth, P.F., 2020. Woody vegetation cover, height and biomass at 25-m resolution across Australia derived from multiple site, airborne and satellite observations. Int. J. Appl. Earth Obs. Geoinf. 93, 102209.

doi : https://doi.org/10.1016/j.jag.2020.102209 DOI Link

Potapov, P., Li, X., Hernandez-Serna, A., Tyukavina, A., Hansen, M.C., Kommareddy, A., Pickens, A., Turubanova, S., Tang, H., Silva, C.E., Armston, J., Dubayah, R., Blair, J.B., Hofton, M., 2021. Mapping global forest canopy height through integration of GEDI and Landsat data. Remote Sens. Environ. 253, 112165.

doi : https://doi.org/10.1016/j.rse.2020.112165 DOI Link

Scarth, P., Armston, J., Lucas, R., Bunting, P., 2019. A Structural Classification of Australian Vegetation Using ICESat/GLAS, ALOS PALSAR, and Landsat Sensor Data. Remote Sensing 11, 147

doi : https://doi.org/10.3390/rs11020147 DOI Link

Tolan, J., Yang, H.-I., Nosarzewski, B., Couairon, G., Vo, H.V., Brandt, J., Spore, J., Majumdar, S., Haziza, D., Vamaraju, J., Moutakanni, T., Bojanowski, P., Johns, T., White, B., Tiecke, T., Couprie, C., 2024. Very high resolution canopy height maps from RGB imagery using self-supervised vision transformer and convolutional decoder trained on aerial lidar. Remote Sens. Environ. 300, 113888.

doi : https://doi.org/10.1016/j.rse.2023.113888 DOI Link

Identifiers

URI : geonetwork.tern.org.au/geonetwork/srv/eng/catalog.search#/metadata/36c98155-39c8-4eec-9070-a978933f3fa3
global : 36c98155-39c8-4eec-9070-a978933f3fa3