Predictive distribution model

The model was built on the basis of presence-absence data gathered during 2000–2012 and extracted from several citizen-science ornithological databases (see Acknowledgements). All the available georeferenced observations were spatially matched to the appropriate recording unit, which was the 10*10 km square of the national grid PUWG 1992 (EPSG: 2180). The records extracted from the databases contained information on breeding status (proved, probable or possible breeding), and those which were classified as “possible” were excluded from the training data set. Altogether, 809 records were acquired in this way: 493 were presence and 316 were absence squares. This data set was unbalanced (presence to absence ratio: 1.56), and classification algorithms are known to be biased in such cases (He and Garcia Reference He and Garcia2009). Thus, to balance the data, 177 pseudo-absences were generated using the following algorithm:

1. 1. Select a predefined set of unsuitable squares (U). Montagu’s Harrier is known to avoid human settlements and forests (Cormier et al. 2008, Trierweiler et al. 2010, authors’ unpubl. data). Based on the distributions of the land cover characteristics calculated for squares with recorded presence, unsuitable squares were defined as those with artificial surfaces (CLC class 1) covering > 15% of the square area or with forests (CLC class 3) covering > 75%.

2. 2. Select randomly k pseudo-absences from the set of unsuitable squares defined in the previous step (U), where k is the number of pseudo-absences needed to balance the data.

3. 3. Form a balanced training data set (B) by merging true-presences, true-absences and pseudo-absences selected in step 2.

4. 4. Fit a random forest to the data generated in step 3.

5. 5. Calculate the predicted probabilities of Montagu’s Harrier presence (pr) from the model fitted in step 4.

6. 6. Re-define the set of unsuitable squares U as those meeting the condition pr < 0.1. Retain only those false-absences in B that are also present in U. Calculate k.

7. 7. Repeat steps 2–6 until k = 0.

Balancing the learning data set substantially improved the model predictions (Appendix S1 and Table S2 in the online supplementary material).

The habitat data used as predictors for the predictive distribution model are explained in detail in the supplementary material (Appendix S1; Table S1). In general, a total of 82 environmental variables were used from the following sources: (1) Corine Land Cover database; (2) landscape characteristic derived from Corine Land Cover using Fragstat software (McGarigal and Marks Reference McGarigal and Marks1995); (3) SRTM digital elevation; (4) bioclimatic variables; (5) vegetation phenology; (6) farming variables derived from Polish Agricultural Census 2002; and (7) DMSP-OLS night-time lights.

The random forest (RF) algorithm (Breiman Reference Breiman2001), which was used for building the predictive distribution model, represents a machine learning method based on classification and regression trees (CART). It constructs multiple trees, each fitted to randomly perturbed data, where a single tree is produced from a random sample of cases and each split from a random sample of predictors. The final output is achieved by voting. The bootstrap mechanism ensures that approximately one-third of the instances are left out and not used in the fitting process. These out-of-bag (OOB) samples are used to assess the prediction error of the procedure, which overcomes the common problem of bias of prediction error.

The model achieved good accuracy: the OOB classification error rate was less than 6%. The distribution of model residuals and model performance parameters are presented in the Supplementary Material (Appendix S1; Figure S1, Table S3). We did not explore the habitat use of Montagu’s Harrier in this paper, so we did not interpret the model in detail here. For the purpose of this study, predictions from the model were necessary for the delimitation of the following sampling strata:

1. 1. Optimal stratum. It comprised the area with a very high probability of Montagu’s Harrier occurrence, arbitrarily defined as those 10-km squares for which the predicted probability of presence pr (obtained from the aforementioned habitat model) was greater than 0.9 and provided that they were not within the Biebrza Marshes (a separate sampling scheme was designed to estimate the number of birds breeding there - see the following paragraph). The optimal stratum had an extent of 111,429 km².

2. 2. Biebrza Marshes stratum. The Special Protection Area “Ostoja Biebrzańska” (Biebrza Marshes; PLB200006; 1,485 km²) was reported in the literature as the country’s main breeding area, hosting over 2% of the national population (Sikora et al. 2007, Krupiński Reference Krupiński, Zawadzka, Ciach, Figarski, Kajtoch and Rejt2013). For this reason, this area was separated from the optimal stratum, and a distinct sampling scheme was designed for the population assessment in this area.

3. 3. Suboptimal stratum. This included all 10-km squares with predicted probability of Montagu’s Harrier occurrence between 0.9 and 0.77 (Appendix S1, Figure S2). The area of this stratum was 38,713 km².

4. 4. Unsuitable stratum. All of the other remaining squares formed this stratum, with the predicted probabilities of occurrence between zero and 0.28. The unsuitable stratum had an extent of 160,270 km².

Selection of sampling plots

Field surveys were made exclusively within the optimal and Biebrza Marshes strata. Different sampling schemes were used, due to the different spatial extents of those areas.

For the optimal stratum, 100 of the 10-km squares were randomly selected. Sampling was proportional to prediction values: the higher the prediction values from the model, the higher the chance of selection of a particular square. Additionally, the distance between each pair of squares was calculated at each turn, and if a newly added square was adjacent to another one, it was eliminated. The procedure was repeated iteratively until a required number of squares was obtained. The resulting locations of the sampling plots are shown on Figure 2.

Figure 2. Location of sampling plots within the optimal stratum.

The surveys within Biebrza Marshes were conducted in 30 2-km squares randomly chosen from the set of 215 squares meeting the two criteria: 1) at least 50% of the square area was situated within the SPA ’Ostoja Biebrzańska’ and 2) woodlands covered, at the very most, 50% of the square area. The locations of the sampling plots within the Biebrza Marshes stratum are shown in Appendix S2, Figure S3.

Fieldwork methods within Biebrza Marshes

The survey was conducted in 2-km squares and encompassed two all-day visits between early May and late July. Experienced ornithologists were involved in the survey. Observers were required to apply the above-described procedure (see Fieldwork methods within optimal stratum) and verify the locations of the viewpoints, move (if necessary) the locations of the viewpoints, and conduct the observations. They needed to spend 60 minutes at each point.

“Optimal” stratum

The number of Montagu’s Harrier territories within each sampling square was estimated using the following Bayesian hierarchical model:

$$\eqalign{ &#x0026;amp; {y_{ij}}{\rm{\~}}Pois({\lambda _{ij}} \cdot p) \cr &#x0026;amp; \ln ({\lambda _{ij}}) &#x003D; {\alpha _j} &#x002B; {\varepsilon _i} \cr &#x0026;amp; \varepsilon {\rm{\~}}N(0,\delta ) \cr}$$

This model assumes that the number of territories y _ij found on the plot i in the year j follows the Poisson distribution, with the expectation being the product of the “true” number of territories λ _ij and estimated detectability of a single territory p. The detectability was estimated for the subsample of 30 plots surveyed by two independent observers using the parameter-expanded data augmentation method (Royle et al. 2007, Royle and Dorazio Reference Royle and Dorazio2012). Due to small sample size, estimates of detectability for both seasons were pooled. The number of territories (log-transformed) is the function of fixed year effect α _j and the random plot effect ε _i, which is normally distributed with the mean zero and variance δ ². This model allows for over-dispersion, imperfect detection and separate estimation of yearly effects. The total number of territories in the stratum was calculated by multiplying the mean density (i.e. the mean value of λ) by the stratum area.

“Suboptimal” stratum

The number of squares meeting the condition 0.77 < pr < 0.9 was 392. However, based on the pre-survey presence-absence data, we found that 40 of these squares were in fact occupied. From this, the rough and conservative proportion of occupied squares in the “suboptimal” stratum was estimated: q = 40/392 = 0.102. The density of territories in this stratum remains unknown and was assumed to be a half of that in the “optimal” stratum. This guess was based on the following clue: we fitted a smooth line to the relationship between predicted population density and predicted probability of occurrence of the Montagu’s Harrier in all 10*10 km squares (Figure 3). Then, we calculated expected densities for the middle-points of probability classes which we used to separate strata. Those values were: 0.57 and 1.32 territories/100 km². The ratio of these values is 2.3 which is quite close to the value of 2 that we chose. This multiplier has very little effect on final population size estimates. If we assume the value of 2 (as we chose), estimated number of territories in “suboptimal” stratum is 58 (vs. 3,275 in the whole country) which constitutes only 1.7%. The total number of territories in the “suboptimal” stratum was calculated by multiplying the (guessed) mean density of territories (i.e. the mean value of λ/2) by the proportion of occupied squares (q) and the stratum area.

Figure 3. Relationship between the predicted population density and predicted probability of occurrence in all 10*10 km squares across Poland. Vertical lines represent 0.77 and 0.90 probabilities. Black dots show expected densities for the mid-points of those probability classes.

“Biebrza Marshes” stratum

The total number of territories was calculated by multiplying the mean density of territories estimated for the surveyed squares by the area of suitable habitats within this stratum (see paragraph Selection of sampling plots above).