A decision support tool for habitat connectivity in Australia

Connectivity related datasets

A systematic approach was used to identify the spatial layers needed for modelling connectivity in the study region. Web platforms were searched for datasets relating to: vegetation, forest cover, habitat connectivity, fragmentation, streamlines, fire history, and logging history, between January and June, 2022. Platforms accessed were from a series of government sources, including states and territories intersecting the study area along with national repositories. National data sources searched included TERN (Cleverly et al. 2019), data Australia (Australian Government 2023) and Geosciences Australia (Geosciences Australia 2023). State and territory layers were sourced from each jurisdiction’s official data repositories, which included SEED (NSW Government 2023), Qspatial (Qld Government 2023), TheList (Tas Government 2023), Data Vic (Vic Government 2023) and Data WA (WA Government 2023). Additionally, global data repositories were also searched including Earth Engine Data Catalogue (Google 2023) and the Global Forest Watch open data portal (World Resources Institute 2023). All gathered spatial layers were assessed using QGIS (QGIS Development Team 2023) and checked for validity. Datasets were later compared to others across state and territory borders to check for continuity and relatedness. Globally applicable datasets were sourced during the process and later compared to those found during the search through national datasets.

Species habitat mapping

Species habitats mapping was performed through using preestablished sources or by modelling species and guilds habitats using the EcoCommons platform (EcoCommons Australia 2022) in conjunction with data from the Atlas of Living Australia (Atlas of Living Australia 2020) and eBird (Sullivan et al. 2014). Additional species related information was derived from other sources including habitats of Glossy Black Cockatoos in South East Queensland (Glossy Black Conservancy 2022) and the south-western Western Australian Black Cockatoos (Birdlife International 2023). For the gliding possums and rainforest pigeon guilds, which did not have publicly available habitat models, species habitat mapping was performed using the EcoCommons platform. The modelling platform provides access to the relevant biological data, environmental data, statistical models, and compute power (EcoCommons Australia 2022). Variable and model performance was assessed within the platform, allowing for a seamless output of species distribution models for input to the connectivity modelling. The species guilds required the use of an aggregation of distribution models for the three species using a combination of the best performing boosted regression tree and random forest species distribution models. Models were assessed using variable importance plots along with the area under the curve values (AUC).

Quantifying habitat patch connectivity

We modelled habitat patch connectivity for each species and species guild using the Integral Index of Connectivity (IIC) (Saura and Pascua-Hortal 2007) with the Makurhini R package (Godínez-Gómez and Correa Ayram 2020). The IIC metric quantifies habitat patch network interconnectivity and aids understanding of patterns and ecological dynamics within a landscape (Keeley et al. 2021). The key output of the analysis is the delta Integral Index of Connectivity (dIIC), which measures the importance of habitat patches to overall landscape connectivity by partitioning their contributions into three fractions: intra (internal size); flux (species movement); and connector (stepping stone role).

To calculate the index for each species and guild, the edge distance between patches was used, along with the maximum forest gap crossing from the literature (Table 1). The landscape level forest connectivity patches were divided by roads as these form anthropic barriers to species movements (Cork et al. 2024). Roads were defined using the OpenStreetMap selecting only for roads (OpenStreetMap Contributors 2023). Due to system memory constraints, for each iteration of the analysis a minimum patch threshold was used as shown in Table 1. All patches were then assessed for their conservation status by determining how much of their areas were located within protected areas. The resulting outputs from the analysis can be accessed using the decision support tool.

Optimum connectivity pathway mapping

For each species and guild, a set of criteria was applied to ensure that the connectivity models accurately represent movement requirements. This study built upon a connectivity mapping methodology developed by Drielsma et al. (2007) and Barrett and Love (2012), which uses pathways modelling based upon a resistance-based metric utilising a least cost path approach. This requires calculation of cost (movement resistance) spatial layers. Associated movement cost layers are important as they help to identify pathways by finding the path of least resistance between habitat areas (Keeley et al. 2021). The methods used for this study were also used to assess and map potential habitat connectivity for greater gliders in Queensland, Australia (Norman and Mackey 2023). Due to both study regions having forests and woodlands as the dominant growth form, the identified optimum connectivity pathways were primarily restricted to areas with tree cover greater than 10% (Hansen et al. 2013), aligning with the Food and Agricultural Organization’s definition of forests (FAO 2020). It was also assumed that all species and guilds prefer habitats in a better condition, and therefore a weighting was applied using the Habitat Condition Assessment System (HCAS) spatial layer (Harwood et al. 2016). Forest types were established using the forests of Australia dataset (Australian Government 2018).

A description of the key ecological assumptions and values for each species and guild made in the connectivity modelling is given in Table 1, including in relation to forest gap and water crossing distances, as well as habitat and disturbance weights. These values drew upon findings from two comprehensive reviews on habitat connectivity (Correa Ayram et al. 2016; Keeley et al. 2021) along with specific species values established through other source materials (Eyre 2006; Price 2006; Drielsma and Ferrier 2009; Barrett and Love 2012; Foster et al. 2017; Rycken 2019; Drielsma et al. 2022; Glossy Black Conservancy 2022; Rycken et al. 2022).

A workflow was created to streamline the analytical process and ensure a consistent and reproducible method. The pathways modelling method, based upon a resistance-based metric utilising a least cost path approach, combines both the direct paths approach with a forced randomness of start and end points within habitat areas. All programming was through a Bash script and used the following software; PostGIS (PostGIS Project Steering Committee and Others 2022), Guidos Toolbox (Vogt and Riitters 2017), OrfeoToolbox (Grizonnet et al. 2017) and Whitebox Tools (Lindsay 2016). The workflow (Fig. 1) allowed for tens of millions of paths to be assessed to reveal potential connections for target species within a given landscape, making the method workable over large geographic areas.

Fig. 1.

The methodological workflow used for the connectivity modelling based on the optimum connectivity pathway analyses and the integral index of connectivity.

Initially, habitat patches were identified for each species and guild, and then aggregated into clusters using the Influence Zone tool in the GuidosToolbox software (Vogt and Riitters 2017). This processing step ensured that the start and finish paths were not located within the same patch, promoting the search for interpatch connectivity. Randomised points were generated throughout each cluster in proportion to patch size to serve as the start and finish points for the least cost paths using the sf R package (Pebesma 2018). By employing a randomised start and finish approach, the analysis ensured that all parts of the patches and potential connectivity pathways were equally considered, preventing any unintentional bias in pathway prioritisation. The process involved finding the nearest start and finish points between different clusters and randomly changing target clusters over 50 iterations. All paths were subsequently summed and smoothed to highlight optimal pathway importance. Finally, output rasters were normalised to values between 0 and 1.

Following the calculation of each connectivity model, we identified a set of key pathways by selecting the 99.9th percentile within each layer, using the Geospatial Data Abstraction Library (GDAL) through the bash command line and Python (GDAL/OGR 2024). This approach was chosen to focus attention on areas of highest importance for connectivity within the expansive set of potential pathways. However, we recognise that thresholding connectivity in this way did result in some discontinuous paths. Additionally, the location of each pathway in relation to protected areas was established using the Collaborative Australian Protected Areas Database 2022 (Australian Government 2022), providing a basis for integrating these findings into broader conservation planning efforts.

Findings from spatial data searches

A systematic search of spatial layers revealed a range of datasets that wereeither useful for the direct assessment of connectivity conservation or that could be utilised for additional spatial prioritisation or connectivity analyses. In total, 71 spatial datasets were identified from 61 projects using the search and screening process. The identified spatial layers are listed in Supplementary Table S1. They ranged from the extensive global layers, including potential habitat pathways, such as the Global Safety Net project (Dinerstein et al. 2020) with a wide range of input species, to the fine-scale layers like the koala corridors produced by Logan City Shire, in Queensland (Logan City Council 2019).

The usefulness of these datasets depends on the approach and question assessed by platform users, species or assemblages, and the scale required. Many national datasets were found to provide seamless crossjurisdictional information applicable for broader scaled approaches to connectivity mapping. However, boundary effects are evident on the edges of jurisdictions (e.g. state boundaries within Australia), which limit many spatial datasets from being used to map connectivity at a continental scale.

Patch connectivity results

In total, 35,632 patches were assessed for connectivity using the Integral Index of Connectivity. The extent of patch areas assessed varied among the species and guild models, with the largest being the landscape level forest connectivity patches, covering an area of 69,489,682 M ha of forested habitats across 11,121 patches over 250 ha in extent. The conservation status of patches varied with 69% of rainforest pigeon habitat patches located within protected areas, whereas the other species and guilds patches had less than 35% of habitat patches within protected areas, and landscape level forests had the least at 24%.

The mean patch connectivity results (dIIC) also showed that the adequacy of the protected area network in conserving important patches of habitat differed across species and guilds (Table 2). The lower patch connectivity score (dIIC = 2.82) for the landscape level forest connectivity when compared to the average (dIIC = 3.41) suggests that much of the area located within the important patch areas is outside the current protected area network. A similar result was found for the black cockatoos of south-western WA (total dIIC = 5.13, protected area dIIC = 4.42).

Optimum pathway results

The priority habitat pathways for the south-western Western Australia and along the eastern seaboard of Australia are shown in Fig. 2. The pathways found were identified as the most important for each of the species and guilds as these have been restricted to the 99.9th percentile pathways. There was a marked difference between the protection status of each of the optimum connectivity pathways found (Figs 2 and 3). Optimum rainforest pigeon pathways were found to have the highest percentage of pathways protected with 53.3% located within conservation areas, whereas only 26.2% of black cockatoo of south-western WA were conserved.

Fig. 2.

The optimum connectivity pathways (99.9th percentile) for each species and guild assessed in the study shown in different colours. (a) Zoomed inset maps of south-western Western Australia and (b) eastern Australia. Areas shown as green represent forest and woodland cover with greater than 10% canopy cover (Hansen et al. 2013).

Fig. 3.

The area of important connectivity pathways (99.9th percentile) in relation to the protection status. Numbers shown above each bar are the percentage of important pathways located within protected areas (PAs).

Important movement pathways were identified throughout the eastern seaboard of Australia, with clear pinch points and gaps being identified in numerous landscapes including the upper reaches of the Lockyer and Mary Valley’s in Queensland, the Hunter Valley and Southern Highlands in New South Wales and the Kilmore Gap in Victoria. Likewise in Western Australia, habitat patches north of Albany were found to be important areas for black cockatoo movements across the southern portion of their range.

Decision support tool

An online web-based support tool was created to provide conservation groups and managers with the means to access and view the connectivity pathways for planning and restoration opportunities. As advanced geographic information systems (GIS) capabilities remain limited in many community-based not-for-profit organisations, there is a need for a simple tool that is accessible on desktops and mobile devices. Datasets found during the connectivity dataset search were presented in a table along with the associated links for access. An interactive map was created to allow for rapid assessment by the user of the connectivity pathways (Fig. 4). For users wanting access to the underlying datasets, clipped raster files for each bioregion were produced and were made accessible on the interactive map via a link that retrieves these premade spatial datasets within the area of interest.

Fig. 4.

An example image of the interactive map page of the decision support website, found at www.stateofconnectivity.com. Users are able to interact with the map, along with downloading the created spatial datasets for each associated IBRA region. The map shows the patch importance over the corridor importance for gliding possums on the border between New South Wales and Queensland. The blue and teal patches and corridors represent the more important areas for connectivity found in the analyses.

Future directions

There are a number of potential future directions for our connectivity decision support tool. A user-friendly interface could be developed with streamlined user inputs including point and click menus providing seamless access to both spatial habitat data and life history information for a broad range of species. Furthermore, the functionality could be increased to enable users to upload their own data including species movement start and finishing points, and associated cost layers and ecological assumption parameters. This would make the platform more accessible and useful to a wider range of users, such as those in local governments and larger non-government organisations.

An additional future consideration is the integration of climate change dynamics into the tool’s modelling framework. As climate change continues to exert profound effects on habitats and species’ ranges, it is necessary to develop data and functions that can dynamically account for these changes in assessing wildlife habitat connectivity. Incorporating these into the tool will assist in identifying potential connectivity movement pathways for species whose distributions may shift in response to climate change as they migrate to find more suitable habitat locations (Mackey et al. 2008).

Limitations

Although modelling optimum wildlife connectivity pathways serves as a valuable initial step in recognising crucial habitat connections at a landscape level, the validation and refinement of these models require on-the-ground verification of where and how they are being used by the target species or guilds. On ground observations would help to verify, and modify where necessary, the model parameter values, taking into account factors such as microhabitat variations and local ecological nuances.