Scottish Marine and Freshwater Science Vol 11 No 10
The Scottish Government has set a target of 100% of Scottish demand for electricity to be met by renewable sources by 2020. The marine environment offers considerable potential with respect to harvesting renewable energy, through wind, wave and tidal stream energy generators. However, offshore renewable developments have the potential to impact on seabird populations.
Population Viability Analysis (PVA) is considered best practice in order to understand the population-level consequences of predicted impacts from renewable energy developments on seabirds.
Within this project, we evaluated and compared the performance of a range of different modelling methods for PVAs that have been used in practice. We evaluated the performance of the methods in producing accurate predictions of future “baseline” abundance – i.e., abundance in the absence of an offshore wind farm. PVAs are typically summarised, in the context of offshore renewables, in terms of metrics that compare scenarios of impact against a “baseline” projection of abundance. Caution should, therefore, be taken in relating the results of our evaluation (which is concerned with absolute abundance) directly to the ability of methods to produce accurate values of PVA metrics (which are often concerned with comparing relative abundance under different scenarios). However, we nonetheless expect the results of our evaluation to provide a useful qualitative guide to the relative strengths and limitations of different methods.
Data and Resources
| Field | Value |
|---|---|
| Publisher | |
| Modified | 2020-07-31 |
| Release Date | 2020-07-27 |
| Identifier | 85c9e014-8703-4fbe-b8b5-817861a95334 |
| Spatial / Geographical Coverage Location | Scotland |
| Temporal Coverage | 1998-01-01 to 2017-12-31 |
| License | UK Open Government Licence (OGL) |
| Data Dictionary | At the national scale, we compared deterministic and stochastic Leslie matrix models (which are usually used in practice for PVAs) against each other, and against a range of simple time series growth models. We applied these methods to data on abundance, breeding success and survival for 15 seabird species, for breeding colonies throughout the British Isles. We evaluated performance by applying the methods to abundance and demographic data, with these split in to a training period and a subsequent “test” period, assessing whether the predictions that the methods generated for the “test” period were consistent with the observed counts of abundance for that period. We considered four possible definitions of the test period – 1998-2017, 2003-2017, 2008-2017 and 2013-2017 – and in each case considered the training period to be all years (with suitable available population data) prior to this. In one region (Forth/Tay), for five species, we also used a five year test period (2013-2017) to compared this suite of approaches against the Semi-Integrated Population Models (SIPMs) produced by Freeman et al. (2014) and Jitlal et al. (2017) (termed Bayesian State Space Models in those reports). We assessed performance of methods by looking at: a) whether the method was possible to apply; b) how frequently it yielded “highly implausible” results (i.e., results that are more than 100 times larger or smaller than the actual abundance); c) whether it produced systematically biased results (i.e. over-estimated or under-estimated actual abundance); d) how much error the methods had, on average, in predicting the observed count; e) whether the method provided an accurate quantification of uncertainty; f) the level of uncertainty associated with each method and g) the computational time required to implement the method. |
| Contact Name | Marine Scotland |
| Contact Email | |
| Public Access Level | Public |