Analysis

A schematic representation of the analysis pipeline is shown in Figure 2. We used the R programming language (R Development Core Team 2013) for data analysis. We rectified any erroneous data entries and performed preliminary data transformation (such as calculating monthly reporting rates) using the dplyR package (Wickham et al. Reference Wickham, Averick, Bryan, Chang, McGowan and François2019). To analyse date-time formatted columns, we utilised the lubridate package (Grolemund and Wickham Reference Grolemund and Wickham2011). We fitted Generalised Linear Mixed Models (GLMMs) in each bootstrapping iteration for each species using the “lmer()” function in the lme4 package (Bates et al. Reference Bates, Mächler, Bolker and Walker2015). To calculate confidence intervals (CIs) for each month in the seasonality analysis, we used the DescTools package (Signorell et al. Reference Signorell, Aho, Alfons, Anderegg, Aragon and Arachchige2023). Finally, we used the ggplot2 for plotting (Wickham Reference Wickham2016), followed by the cowplot package (Wilke Reference Wilke2020) to combine multiple ggplot2 plots into a single figure.

Figure 2. A schematic representation of the analysis pipeline.

We did not have information on the number of individuals that were seen by SM. Rather, we had data on presence and absence (more accurately, detection and non-detection). Assuming that the probability of detection rises asymptotically with population density (Altwegg and Nichols Reference Altwegg and Nichols2019), we calculated and used the “reporting rate” (the fraction of checklists containing a species in a given time period) as a relative index of population density over time. Importantly, we could do this because we did not compare absolute reporting rates between species. Rather, we are only interested in studying how the reporting rates of each species change over time, in other words, we examine the trends in reporting rate for individual species. Further, because of the asymptotic nature of the relationship between reporting rate and absolute population density, reporting rate is expected to be a particularly sensitive index at low and medium densities; at high densities, reporting rate is likely to underestimate underlying population change.

For resident species, we calculated monthly reporting rates, i.e. the fraction of days in the month when a particular species was observed. Winter migrants are absent during the summer at Nannaj, and therefore for these species, we used only those months in each year with reporting rate above 0.05, thereby excluding months where the species was largely or completely absent. The Black Redstart Phoenicurus ochruros was recorded only sporadically and hence removed from any further analyses. For visualisation purposes alone (in Figure 3), we calculated the annual reporting rates, which were the average of all monthly reporting rates for the species in each year.

Figure 3. Examples of different species showing declining, indistinguishable from stable, and increasing trends in their annual reporting rates over time. The shaded regions represent 95% confidence interval around the mean.

To quantify and examine trends over years, we used the lme4 package (Bates et al. Reference Bates, Mächler, Bolker and Walker2015) in R to fit a binomial GLMM for each species with the month of the year as the random effect. The reason we did this was that the same month (for instance, January) is expected to have similar characteristics in terms of species occurrence across years in comparison with another month (for instance, May). A key assumption we make is that while the detection probability of a species may vary between months, it does not change across the years of the study period. In brief, this method calculates an average month-specific trend for a species across years, taking into account that different months might have different baseline reporting rates.

The slope estimates from the GLMMs for each species were tabulated along with 95% confidence intervals, calculated through robust non-parametric bootstrapping within months across years (i.e. with replacement). This allowed us to visualise broad trends (increasing, indistinguishable from stable, or declining; examples shown in Figure 3) in the reporting rate and a CI around a slope estimate (shown in Figure 4). Any species whose CI overlapped zero was categorised as “indistinguishable from stable”, while those with CIs fully above and fully below zero were categorised as “increasing” and “declining”, respectively. The model fitted to each species was as follows:

$$ {\displaystyle \begin{array}{l}{\mathrm{presence}}_i\sim \mathrm{Binomial}\left(n=1,{\mathrm{prob}}_{\mathrm{presence}}=\hat{P}\right)\\ {}\hskip-0.5em \log \left[\frac{\hat{P}}{1-\hat{P}}\right]={\alpha}_{j\left[i\right]}+{\beta}_1\left(\mathrm{year}\right)\\ {}\hskip6em {\alpha}_j\sim N\left({\mu}_{\alpha j},{\sigma}_{\alpha j}^2\right),\mathrm{for}\ \mathrm{month}\;\mathrm{j}=1,\dots, \mathrm{J}\end{array}} $$

In addition to examining annual trends, we also investigated seasonal changes in bird reporting rates for select species by calculating reporting rates for each month, averaged across years. 95% CIs for the month estimates were calculated using the Agresti–Coull method (Brown et al. Reference Brown, Cai and DasGupta2001).

To understand how trends might differ among different kinds of species, we also classified species into different habitat specialisation guilds. This classification was based largely on the State of India’s Birds report (SoIB 2020), supplemented with information from The Book of Indian Birds (Ali Reference Ali1990) and the Birds of the World database (Billerman et al. Reference Billerman, Keeney, Rodewald and Schulenberg2022). Definitions for each habitat guild are in Table 2. To visualise temporal changes in reporting rates for a guild as a whole (Figure 5), we first calculated the reporting rate of each species in each year (as shown above). For each year, we then calculated the mean reporting rates and 95% CIs across all the species in that guild.

Table 2. Description and example species of each guild in the study.

With this information in hand, we asked three broad questions:

1. 1. How did the reporting rates of habitat guilds change over the study period?

2. 2. How did the species-level reporting rates change over time?

3. 3. Within a single species, can we observe seasonal changes/patterns in reporting rates?