Secondary data

Two main secondary data types were utilized in spatial and regression analyses: investment outside Volcanoes National Park, and illegal activities inside the Park. Firstly, community development investment data was acquired, including a revenue sharing dataset and a separate dataset for projects funded by conservation NGOs and private sector ecotourism partners (Sabuhoro et al., Reference Sabuhoro, Wright, Munanura, Nyakabwa and Nibigira2017; Community Conservation Warden, Volcanoes National Park, pers. comm., 2018). The revenue sharing data includes observations of projects funded annually in each Rwandan sector during 2006–2015 and funds allocated to each project. There are 134 projects in the dataset for the 12 sectors bordering Volcanoes National Park, including infrastructure projects and projects proposed by cooperatives (Table 1). The separate dataset for conservation NGO/private sector community development projects contains 297 observations of projects, including latitude/longitude coordinates, for 2006–2015 (Sabuhoro et al., Reference Sabuhoro, Wright, Munanura, Nyakabwa and Nibigira2017). Interventions include those funded by organizations such as the International Gorilla Conservation Programme and Rwanda Eco-Tours (Table 1). We sorted projects with multiple funding sources into the category that provided majority funding.

Secondly, ranger patrol logs were acquired for Volcanoes National Park (Research and Monitoring Warden, Volcanoes National Park, pers. comm., 2018). This ranger-based monitoring data includes latitude/longitude coordinates and descriptions of illegal activity recorded on routine patrols during 2006–2015. On such patrols, rangers travel in small groups along predetermined routes, marking observation coordinates, time, descriptions and counts (e.g. two snares, four water collectors). The cleaned ranger patrol data includes 14,720 observations for a total of 35,116 illegal activities recorded during 2006–2015 in Volcanoes National Park, excluding 2009 because of data loss caused by a change in data management software in that year (Fig. 2, Supplementary Table 1, Supplementary Material 1).

Fig. 2 (a) Total number of illegal activities recorded, and (b) patrol coverage as a per cent of area covered annually in Volcanoes National Park (Fig. 1) during 2005–2015 (data: Research and Monitoring Warden, Volcanoes National Park, pers. comm., 2018).

Biases in secondary data

Ranger-based monitoring data is vulnerable to biases from data collectors (rangers) and data generators (individuals extracting resources; Keane et al., Reference Keane, Jones and Milner-Gulland2011). As a law enforcement tool intended for deterrence, ranger patrols involve non-random spatial patterns of patrolling and thus introduce sampling bias. Increasing effort or coverage can reduce total illegal activities through deterrence, but also increase the proportion of total activities detected (Keane et al., Reference Keane, Jones and Milner-Gulland2011; Moore et al., Reference Moore, Mulindahabi, Masozera, Nichols, Hines, Turikunkiko and Oli2018). Selection of patrol areas and subsequent effort may be based on known problems with illegal activity (Albers, Reference Albers2010; Critchlow et al., Reference Critchlow, Plumptre, Alidria, Nsubuga, Driciru and Rwetsiba2017).

Raw, uncorrected data has been used in the literature, but common methods to address bias in ranger-based monitoring data include weighting encounters using catch per unit effort (δ), incorporating a detectability coefficient, and new methods in Bayesian hierarchical modelling (Hilborn et al., Reference Hilborn, Arcese, Borner, Hando, Hopcraft and Loibooki2006; Watson et al., Reference Watson, Becker, McRobb and Kanyembo2013; Beale et al., Reference Beale, Brewer and Lennon2014; Critchlow et al., Reference Critchlow, Plumptre, Alidria, Nsubuga, Driciru and Rwetsiba2017). We calculated weighted catch per unit effort using annual number of rangers present on patrols and a proportional measure of annual patrol coverage (Keane, Reference Keane, Jones and Milner-Gulland2011; Research and Monitoring Warden, Volcanoes National Park, pers. comm., 2018; Law Enforcement Warden, Volcanoes National Park, pers. comm., 2018). For further details regarding the data used for these calculations, see Supplementary Material 1.

We used the following equations (Keane et al., Reference Keane, Jones and Milner-Gulland2011):

(1)$${\rm \delta }_{st} = {\rm Encounter}{\rm s}_{st}\,{\rm \times \,Effor}{\rm t}_t\,{\rm \delta }_{st} = Encounters_{st}\times Effort_t$$

(2)$$\hskip-5pt{\rm Effor}{\rm t}_t = {\rm Ranger}{\rm s}_t\,{\rm \times\, Coverag}{\rm e}_t\,Effort_t = Rangers_t\times Coverage_t$$

where δ is weighted detected encounters in sector s for year t. Encounters is raw encounters in sector s for year t. Effort is proxied by annual number of rangers participating in routine patrols, and Coverage is the proportion of Park area covered by patrols in year t, the latter determined using ArcGIS 10.6 (Esri, Redlands, USA). This assumes a directly proportional relationship between detection, abundance of incidents and effort exerted. Although this calculation is coarse, this approximate correction is preferred over none (Keane et al., Reference Keane, Jones and Milner-Gulland2011). There are many factors contributing to effort and coverage, such as daily fluctuation in the number of patrollers, individual abilities, perceived severity of illegal activity in a given area, length of patrol, and weather conditions (Plumptre et al., Reference Plumptre, Fuller, Rwetsiba, Wanyama, Kujirakwinja and Driciru2014).

Primary data collection for qualitative GIS

Key informant interviews were guided by results of quantitative analysis of secondary data, in particular to ascertain the prioritization driving investment decision-making by different stakeholders. Numerical weighting of an interviewee's priority sectors produced attributes that were spatially joined to administrative boundaries. Eleven key informants with knowledge of funding prioritization were interviewed in June and July 2018 based on their positions as project decision makers in the government, conservation NGO or private sectors. This sample includes a variety of perspectives on investment decision-making, providing supplementary information to enrich and answer questions prompted by results of spatial and quantitative analysis (Knigge & Cope, Reference Knigge, Cope, Cope and Elwood2009; Supplementary Table 3).

Spatial statistics

Firstly, using kernel density estimation for point pattern analysis, we produced raster-based maps visualizing regions with high densities of unauthorized resource use in Volcanoes National Park. Kernel density estimates using a quartic biweight kernel for illegal activity were overlain with proportional indicators of tourism revenue sharing investment for the respective year (Fig. 3), and total conservation NGO/private sector investment for the 2011–2015 period (Fig. 4; Silverman, Reference Silverman1986).

Fig. 3 Kernel density estimation of illegal activities in Volcanoes National Park for 2012–2015, clipped to Park boundaries (radius 10 m) overlain with a proportional indicator (circle indicator in each sector) of the tourism revenue sharing (TRS0 funding distributed to each sector annually. Point-level data were not available for visualization of revenue-sharing distribution at a finer spatial scale (data: Research and Monitoring Warden, Volcanoes National Park, pers. comm., 2018).

Fig. 4 Kernel density estimation of illegal activities in Volcanoes National Park (radius 10 m) in 2015 clipped to Park boundaries and overlain with a proportional indicator (circle indicator in each sector) of the conservation NGO/private sector project funding (CNGO funding) distributed to each sector during 2011–2015 (data: Research and Monitoring Warden, Volcanoes National Park, pers. comm., 2018).

Following this exploratory spatial data analysis, we then tested the statistical significance of the relation of clusters to each other using a bivariate local indicator of spatial association, the bivariate local Moran's I statistic. A bivariate local Moran's I value of zero indicates random sorting of one variable relative to the other, with −1 signifying dispersion and 1 signifying clustering. This statistic is mathematically identical to spatial autoregression of y (Wy) on x. A cautionary approach is suggested by Lee (Reference Lee2001) and Anselin (Reference Anselin2018) when interpreting bivariate local Moran's I, analysing X and Y at location A. The bivariate statistic does not consider the spatial relationship between the value of X at location A and the value of Y at location A, only the value of X at location A and the neighbourhood's value of Y, as the equation uses a spatial lag of Y (queen contiguity). The bivariate local Moran's I is given by:

(3)$$I_B = \displaystyle{{\Sigma _i( \Sigma _jW_{ij}y_j\times x_i) } \over {\Sigma _ix_1^2 }}$$

(Anselin, Reference Anselin2018), where x_i is revenue sharing at sector i. W_ijy_j is the spatial lag of y, which is the illegal activities count in sector j, using a row-normalized queen contiguity weight, selected to accommodate the sector-level scale. The weights structure is:

(4)$$W_{ij} = \displaystyle{{w_{ij}} \over {\sum\nolimits_j {w_{ij}} }}$$

(Lee, Reference Lee2001), with w_ij = 1 indicating contiguity between sectors i and j. This spatial weight essentially averages the values of illegal activities for all sectors bordering the sector of interest. The bivariate local indicator of spatial association cluster and significance maps (Supplementary Fig. 4) show areas of high-low and low-high, which respectively indicate sectors receiving high revenue sharing in a cluster of low illegal activities, or low revenue sharing in a cluster of high illegal activities. This reveals sectors in which the prioritization of funding is not aligned with levels of illegal activity occurring in that neighbourhood of sectors. The overall significance threshold for Moran's I outputs in this study was 10%.

Econometric models

Two models were constructed for panel regression analysis: (a) spatial lag of x model (Equation 5, below) and (b) site-demeaned fixed effects (Equation 6, below). Unauthorized resource use is a function of local, sector, national, transboundary regional and global factors, both time-invariant and time-variant (Hsiang & Sekar, Reference Hsiang and Sekar2016). Panel econometrics facilitates site-demeaned fixed-effects regression, accounting for time-invariant unobservables such as sector-level ecological and socio-economic conditions affecting unauthorized resource use, and time-variant factors are addressed in spatial lag of x regression. The two model types thus facilitate corroboration of results. Time variant factors addressed by spatial lag of x regression at sector level include integrated conservation–development project investment, population density, movement of poachers between sites, and local conditions such as agricultural yields and precipitation. National factors include tourism influx, which affects revenue sharing investment, and overall national economic and political stability. Armed conflict in the transboundary system can affect demand for protected area resources, as can global economic conditions (Rainer, Reference Rainer2013). Time-invariant factors addressed by fixed effects include the proportion of a sector that is within protected area boundaries and areas where tourist presence is highest, which has a consistent annual deterrence effect. Removing site-level means, site-demeaned fixed effects nonparametrically holds these factors constant.

Although identifying clusters of funding and unauthorized resource use across the study area is a standalone interest of this study, isolating spatial autocorrelation was necessary prior to spatial lag of x regression, to eliminate spatial bias in the regression (Anselin, Reference Anselin1988). The same Moran's I statistics can be used for both identifying clusters and for determining spatial autocorrelation. For example, sectors of higher human population density, which are also temporally variant, may report more unauthorized resource use encounters. But sectors of high and low human population density are also clustered (univariate local Moran's I: 0.4526; Supplementary Figs 5 & 6); the top quantiles of population density are in the south-west and easternmost sectors, with low density in central sectors. In this example, the regression coefficient for population density (explanatory) on unauthorized resource use (response) would be inflated without spatial weighting.

We estimated the relationship between illegal activities and community development investment by the following multivariate linear spatial lag of x model:

(5)$${\rm \delta }_{st} = {\rm \alpha } + {\rm \beta }_1X_{st} + {\rm \beta }_2WX_{st} + {\rm \beta }_3trs_{st} + {\rm \beta }_4Wtrs_{st} + {\rm \beta }_5ngo_{st} + {\rm \beta }_6Wngo_{st} + {\rm \varepsilon }_{st}$$

where δ_st is the value of illegal activities corrected for catch per unit effort in year t and sector s; X_st is a vector of controls, such as annual sector human population density and precipitation and area of a sector within the Park boundaries, calculated with ArcGIS (Goodman et al., Reference Goodman, BenYishay, Lv and Runfola2019); trs_st is revenue sharing funds distributed to sector s for year t; ngo_st is the conservation NGO and private sector investment in sector s for year t; and W indicates spatially lagged variables. We tested spatial autocorrelation using univariate local Moran's I and constructed lags using queen contiguity matrices for those exhibiting Moran's I > 0.4000 (Supplementary Figs 4 & 5). The model was adjusted as needed to account for collinearity, determined by Pearson's correlation coefficient, and a stepwise procedure was used to ensure robustness and model fit.

Next, using site-demeaned fixed effects (selected over random effects using a Hausman test, P = 0.004), we estimated the following model:

(6)$${\rm \delta }_t = {\rm \mu }_s + {\rm \gamma }_t + {\rm \rho }_{st} + {\rm \varepsilon }_{st}$$

where δt is corrected illegal activities in year t, μ_s is the sector fixed effect, γ_t is time (year), ρ_st is a vector of time-varying interest and control variables including trs_st and ngo_st, and ɛ_st denotes the error term (i.e. unobservables across sectors). With clustered standard errors and lack of multicollinearity verified using Pearson's r, ordinary least squares estimation was used (Stock & Watson, Reference Stock and Watson2006). Omitted variable bias is possible in spatial lag of x modelling (Equation 5) but the fixed effects (Equation 6) provides verification.

As policy or other country-level change impacts the spatial distribution of illegal activities at regional (country) and local (sector) levels, standard errors are unlikely to be independent across observations. Throughout the analysis, we cluster standard errors to sector to ensure robustness to heteroscedasticity (Stock & Watson, Reference Stock and Watson2006; Hsiang & Sekar, Reference Hsiang and Sekar2016).

Spatial regression is sensitive to numerous technicalities, such as the endogenous structure of queen contiguity weights (Anselin, Reference Anselin1988; Gibbons & Overman, Reference Gibbons and Overman2012). This analysis is also sensitive to issues of scale such as the ecological fallacy (Moulton, Reference Moulton1990; Briant et al., Reference Briant, Combes and Lafourcade2010). Lastly, analyses presented in this study do not isolate causality in the relationship between integrated conservation–development project investments and unauthorized resource use in Volcanoes National Park but, taken together, these analyses establish spatial correlations between investments and unauthorized resource use.