A Bayesian statistical–dynamical model expanded to multiple release areas

The Bayesian statistical–dynamical model used in this study was developed by Eckert and others (Reference Eckert, Naaim and Parent2010b). According to Naaim and others (Reference Naaim, Naaim-Bouvet, Faug and Bouchet2004), it is based on the depth-averaged Saint Venant equations solved along a curvilinear profile z = f(x), where z is the elevation and x is the horizontal distance measured from the top of the avalanche path. Within the model, the following Saint Venant mass and momentum conservation laws represent a 1-D flow on the curvilinear profile solved using a finite volume scheme (Naaim, Reference Naaim1998). To facilitate the specification of the input conditions corresponding to each avalanche simulation and to reduce computation times, snow incorporation, deposition, entrainment and detrainment are ignored:

(1)$${\partial h\over \partial t} + {\partial ( hv) \over \partial x} = 0,\; $$

(2)$${\partial ( hv) \over \partial t} + {\partial ( hv^{2} + gr( {h^{2}}/{2}) ) \over \partial x} = h( gr\sin\phi-F) ,\; $$

where v is the flow velocity, h is the flow depth, ϕ is the local slope, t is the time, gr is the gravity acceleration and F is the total friction.

The total friction F considered is the classical Voellmy friction law (Voellmy, Reference Voellmy1955):

(3)$$F = gr\mu \cos\phi + {gr\over \xi h}v^{2}.$$

Total friction is thus the sum of a dry-Coulomb coefficient μ and a turbulent term depending on the squared velocity and on the inverse of a coefficient ξ (Voellmy, Reference Voellmy1955).

The full stochastic model (Fig. 3) representing the variability of avalanche events at the study site is noted p(y,  a|θ _M,  λ). Avalanche magnitude y is a random vector including all the correlated multivariate quantitative characteristics that vary from one event to another, namely runout distance, velocity and pressure profiles, or snow volume. Avalanche frequency a is a scalar discrete random variable corresponding to the number of avalanches recorded each winter. Avalanche magnitude and frequency are classically modeled as two independent random processes so that their joint distribution writes as a product and related parameters can be inferred separately (Eckert and others, Reference Eckert, Naaim and Parent2010b):

(4)$$p( y,\; a\vert \theta_{M},\; \lambda) = p( y\vert \theta_{M}) p( a\vert \lambda) .$$

Fig. 3.

Quantitative framework developed in this work to evaluate snow avalanche risk as a function of forest cover and building technology. The three parts of the analysis are as follows: (1) calibration of the statistical–dynamical model. The parameters of the model are: θ _M = (α ₁,  α ₂,  β ₁,  β ₂,  p,  b ₁,  b ₂,  σ _h,  c,  d,  e,  σ,  ξ) and θ _F = λ. (2) Simulation of the forest integration. Here three cases are considered: case I representing the dependency on μ, case II on ξ and case III on both μ and ξ. (3) Risk assessment and (4) risk calculation as a function of forest cover and building technology.

Avalanche frequency is modeled as a Poisson-distributed process, with a scalar parameter θ _F = λ representing the mean annual avalanche number i.e. a|λ ~ P(λ), necessary for the computation of return periods. The magnitude model specified below is more complex, with 13 parameters θ _M = (α ₁,  α ₂,  β ₁,  β ₂,  p,  b ₁,  b ₂,  σ _h,  c,  d,  e,  σ,  ξ). Also, the magnitude model evaluates, for each avalanche, the latent friction μ and the computed runout distance x _stop.

The studied path is characterized by the presence of two distinct starting zones: zone I between 2500 and 2200 m a.s.l. and zone II between 1900 and 1800 m a.s.l. (Figs 2a, b). To include this information into the analysis, rather than by the original single Beta distribution (Eckert and others, Reference Eckert, Naaim and Parent2010b), we herein model x _start as a binomial mixture of two Beta distributions. This could be easily, in the future, generalized to even more complex cases using a multinomial mixture (e.g. Lavigne and others, Reference Lavigne, Bel, Parent and Eckert2012):

(5)$$ \eqalign{ \matrix { x_{{\rm start}_{i}} & \!\!\!\!\!\!\!\!\!\!\!\!\!\!\!= P ( x_{{\rm start}_{i}} \in [ x_{\min_{1}},\; x_{\max_{1}}] ) x_{{\rm start}_{1}} + \cr & \,\,\,( 1-P ( x_{{\rm start}_{i}} \in [ x_{\min_{2}},\; x_{\max_{2}}] ) ) x_{{\rm start}_{2}},\; \cr & \!\!\!\!\!\!\! P ( x_{{\rm start}_{i}} \in [ x_{\min_{1}},\; x_{\max_{1}}] ) \sim B (p)}}$$

Since normalization is a requirement when dealing with the Beta distribution, normalized release abscissas are calculated and considered in the model as follows:

(6)$$\matrix{&x_{{\rm start}_{norm_{1}}} = {x_{{\rm start}_{1}}-x_{\min_{1}}\over x_{\max_{1}}- x_{\min_{1}}} \mathbbm{1}( x_{{\rm start}_{1}} \in [ x_{\min_{1}},\; x_{\max_{1}}] ) \sim Beta( \alpha_{1},\; \beta_{1}) ,\; \cr &x_{{\rm start}_{norm_{2}}} = {x_{{\rm start}_{2}}-x_{\min_{2}}\over x_{\max_{2}}- x_{\min_{2}}} \mathbbm{1}( x_{{\rm start}_{2}} \in [ x_{\min_{2}},\; x_{\max_{2}}] ) \sim Beta( \alpha_{2},\; \beta_{2}) ,\; }$$

where $x_{\min _{1}}$, $x_{\max _{1}}$, $x_{\min _{2}}$ and $x_{\max _{2}}$ are the minimal and maximal abscissas delimiting release zones I and II estimated for the case study using topographical thresholds (Figs 1, 2), and α ₁, α ₂, β ₁ and β ₂ the parameters of the corresponding Beta distributions, and $\mathbbm {1}(.)$ the indicator function.

The mean release depth h _start is assumed to be Gamma-distributed with parameters b ₁ and b ₂ reflecting its dependency on release abscissa and a constant dispersion around the mean σ _h (Eckert and others, Reference Eckert, Naaim and Parent2010b). Here and in what follows the conditioning by $x_{\min _{1}}$, $x_{\min _{2}}$, $x_{\max _{1}}$ and $x_{\max _{2}}$ is dropped for simplicity:

(7)$$ \eqalign{ & h_{\rm start}\vert b_{1},\; b_{2},\; \sigma_{h},\; x_{\rm start} \sim \cr & Gamma\left({1\over \sigma_{h^{2}}}( b_{1} + b_{2}x_{{\rm start}_{\rm norm}}) ^{2},\; {1\over \sigma_{h^{2}}}( b_{1} + b_{2}x_{{\rm start}_{\rm norm}}) \right),\;}$$

where $x_{{\rm start}_{\rm norm}} = ( {x_{\rm start}-x_{\min _{1}}}) /( {x_{\max _{2}}-x_{\min _{1}}})$ is the normalized release abscissa evaluated all over the different release areas.

Given the normalized release abscissa $x_{{\rm start}_{\rm norm}}$ and the mean release depth h _start, the friction coefficient μ is modeled as a latent variable describing the random effects from one avalanche to another and it is assumed normally distributed (Eckert and others, Reference Eckert, Naaim and Parent2010b):

(8)$$\mu\vert c,\; d,\; e,\; \sigma,\; x_{\rm start},\; h_{\rm start} \sim N( c + {\rm d} x_{{\rm start}_{\rm norm}} + eh_{\rm start},\; \sigma) .$$

The parameters c, d and e represent the dependency of μ on the release abscissa and mean release depth, with a constant dispersion σ around the mean. Parameters b ₂, d and e indirectly translate the impact of the altitude, and hence, of prevailing climate and snow conditions on the release depth and μ. Therefore the distribution of the μ and h _start varies according to the release altitude. Alternatively, the velocity-dependent friction coefficient ξ is modeled as a parameter in the strict statistical sense of the term. Both ξ and μ _i, i ∈ [1,  n] where n is the data sample size of fully documented events are estimated from the data.

Small Gaussian differences between the observed runout distances $x_{\rm stop_{\rm data}}$ and computed runout distances x _stop are postulated:

(9)$$x_{\rm stop_{\rm data}}\vert \sigma_{\rm num},\; x_{\rm stop} \sim N( x_{\rm stop},\; \sigma_{\rm num}) .$$

These differences can result from numerical errors due to the imperfection of the propagation model, and/or from observation errors. The SD of these numerical errors σ _num is set to 15 m to grant model identifiability.

Inference of the full model is a difficult problem which is solved by splitting it in simpler tasks. As stated before, the frequency and magnitude models are inferred separately. For the frequency model inference, all 21 avalanche events recorded since 1934 are used. For the magnitude model inference, only the n = 17 fully documented events are used. Avalanche events are assumed mutually independent. This implies that the joint likelihood of all events is the product of their individual marginal likelihood.

For the frequency model, Bayesian inference is analytical. With the chosen Gamma(a _λ,  b _λ) prior for the parameter λ, the posterior distribution of λ remains Gamma-distributed: Gamma(a _λ + T _obs,  b _λ + N _obs), where the pair (a _λ,  b _λ) represents the prior knowledge concerning the distribution of avalanche occurrences. N _obs is the total number of avalanches recorded on the study site (i.e. 21 events) during T _obs years of observation.

The parameters of the binomial Beta mixture model of x _start, α ₁, α ₂, β ₁ and β ₂, are estimated using the method of moments, a frequentist approach for parameter estimation (Appendix B).

The rest of the magnitude model is inferred using Bayesian methods, resulting in the joint posterior distribution of remaining parameters and latent variables:

(10)$$ \eqalign{ \matrix{\,p & \!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\!\! ( \theta,\; \mu,\; x_{\rm stop}\vert {data},\; \sigma_{\rm num}) \propto \pi( \theta) \cr & \times\, p( h_{\rm start},\; x_{\rm stop_{\rm data}}\vert \theta,\; \mu,\; x_{\rm start},\; x_{\rm stop},\; \sigma_{\rm num}) \cr & \times\, p( \mu,\; x_{\rm stop}\vert \theta,\; h_{\rm start},\; x_{\rm start},\; x_{\rm stop_{\rm data}},\; \sigma_{\rm num}) }}$$

where θ = (b ₁, b ₂, σ _h, c, d, e, σ, ξ), π(θ) is the joint prior distribution for the related parameters and data represents all observations. Numerical computation was achieved using the Metropolis Hasting algorithm within a Markov chain Monte Carlo scheme detailed in Eckert and others (Reference Eckert, Naaim and Parent2010b). Convergence was checked using several chains starting at different points of the space parameter. For each unknown various point estimates can be computed from the joint posterior distribution. We classically chose the posterior mean and summed-up the related uncertainty with the posterior SD and the 95% credible interval (Table 1).

Table 1.

Parameter estimates of the statistical dynamical model

When Bayesian inference is used, for each parameter, the marginal prior distribution used is given, as well as summary statistics of the posterior distribution (the posterior mean is retained as point estimate). The mixture model for the release position (Eqn (5)) is calibrated separately using the method of moments (Appendix B).

Simulation of avalanche hazard conditional to local calibration

To evaluate avalanche hazard conditional to local calibration, 10 000 predictive simulations (Eckert and others, Reference Eckert, Parent and Richard2007, Reference Eckert, Naaim and Parent2010b; Fischer and others, Reference Fischer, Kofler, Fellin, Granig and Kleemayr2015, Reference Fischer2020) were performed with all parameters set to their Bayesian or frequentist point estimates (Table 1). In detail, for each simulation, x _start is evaluated according to the mixture model (Eqn (5)) that allows reconstructing a binomial mixture of two Beta distributions. Then, the normalized release abscissa injected in the simulation model is $x_{{\rm start}_{\rm norm}} = ( {x_{\rm start}-x_{\min {1}}}) /( {x_{\max _{2}}-x_{\min _{1}}})$, where x _start is the simulated release abscissa depending on its location on the path, $x_{\max _{2}}$ the maximal abscissa of zone II and $x_{\min _{1}}$ the minimal abscissa of zone I. A statistical–dynamical Monte Carlo approach is necessary to obtain the full joint distribution of the outputs of the numerical avalanche model knowing the distribution of the inputs. It involves integration over the distribution of the latent friction coefficient μ and writes as follows:

(11)$$ \eqalign{ & p( y \vert \,{ \hat {\! \theta} _{M}}) = \cr& \int p( x_{\rm start}\vert \hat {\alpha_{1}},\; \hat{\alpha_{2}},\; \hat{\beta_{1}},\; \hat{\beta_{2}},\; \hat{\,p}) \cr& p( h_{\rm start}\vert {\hat b_{1}},\; { \hat b_{2}},\; { \hat \sigma_{h}},\; x_{\rm start}) p( x_{\rm stop}\vert x_{\rm start},\; h_{\rm start},\; \mu,\; \hat{\xi}) {\rm d}\mu,\;}$$

where ‘$\hat {.}$’ classically denotes a statistical estimate. This simulation strategy leads, for instance, the joint distribution of the input variables $( x_{\rm start},\; \, h_{\rm start},\; \, \mu \vert { { \hat \theta} _{M}})$ and of the output variables $p( x_{\rm stop},\; \, v_{xt},\; \, h_{xt}\vert { \hat \theta _{M}})$ of the avalanche propagation model, where v _xt and h _xt represent, for each avalanche simulation, the velocity and flow depth computed for each abscissa and time step (Fig. 4).

Fig. 4.

Avalanche hazard at Ravin de Côte-Belle: statistical–dynamical simulations according to local calibration and mean forest fraction f _k = 0.35 (as in 1980). Distribution of (a) release abscissa, (b) release depth, (c) runout abscissa, (d) friction coefficient μ, (e) maximal flow depth at abscissa position corresponding to a return period of T = 10 years and (f) maximal velocity at abscissa position corresponding to a return period of T = 10 years.

Subsequently, the return period $T_{x_{\rm stop}}$ associated with the runout distance x _stop, is estimated by combining $\hat {\lambda }$ and the cumulative distribution function (cdf) of runout distances $\hat {F}( x_{\rm stop}) = P( X_{\rm stop}\leq x_{\rm stop})$ as follows:

(12)$$T_{x_{\rm stop}} = {1\over \hat{\lambda}( 1-\hat {F}( x_{\rm stop}) ) }.$$

The inverse problem is then solved, to evaluate the runout distance quantile corresponding to the return period T as:

(13)$$x_{{\rm stop}_{T}} = \hat {F}^{-1}_{x_{\rm stop}}\left(1-{1\over \hat{\lambda}T}\right).$$

A Monte Carlo confidence interval is computed for the non-exceedance probability associated with a given runout distance. It allows checking if the sample size is large enough to give reliable estimates:

(14)$$CI_{\alpha} = \hat{F}( x_{\rm stop}) \pm q_{N_{\alpha_{c}}} \sqrt{{\hat {F}( x_{\rm stop}) ( 1-\hat {F}( x_{\rm stop}) ) \over n}},\; $$

where n is the sample size (in our case 10 000) and $q_{N_{\alpha _c}}$ is the quantile of the standard normal distribution corresponding to the desired confidence level α _c.

The runout return period obtained were used to extract the distribution of maximal velocities $v_{x}^{\max }$ (Fig. 4f) and maximal flow depths $h_{x}^{\max }$ (Fig. 4e) at abscissas corresponding to different return periods, notably 10 years.

Eventually, the distribution of impact pressures is classically calculated by transforming velocities into pressures as follows:

(15)$$P = C_{x}{1\over 2}\rho v^{2},\; $$

where C _x is the dimensionless coefficient of resistance i.e. drag coefficient, ρ is the snow density and v is the flow velocity. Studies like Sovilla and others (Reference Sovilla, Schaer, Kern and Bartelt2008) and Naaim and others (Reference Naaim2008) link velocity to pressure in a comprehensive but complex way that involves semi-empirical relationships between the drag coefficient C _x and the Froude number. For simplicity, we stick here to a value of C _x = 2, an approximation usable for wide, wall like structures, and ρ = 300 kg m⁻³ all along the analysis. Associated Monte Carlo confidence intervals are computed similar to Eqn (14).

Integration of forest cover changes within avalanche hazard assessment

The model calibrated using the above considers avalanche events as mutually independent, i.e. the result of the calibration is independent of the order of the events (except that each event is associated with the snow depth data in the release zone that prevailed at the date at which it occurred). Therefore, it is implicitly assumed that all events have occurred for the same path configuration and forest cover. This configuration corresponds to the average forest fraction over the period during which the events used for the calibration of the magnitude model occurred, namely 1950–2018. According (1) to the quasi-linear increase of forest fraction between 1948 and 2017 inferred from the aerial photographs, and (2) the slightly uneven temporal distribution of avalanche events within the EPA record over the 1950–2018 period, this mean forest fraction $\bar {f}$ arguably coincides with the forest fraction digitized from the 1980 aerial photograph, namely $\bar {f} = 0.35$.

Here, we seek at showing how the distribution of hazard and subsequent risk levels can be impacted by forest cover changes by introducing the forest fraction into the modeling in a robust way. Six values of f _k are considered, among which four represent the actual chronic of forest fractions digitized for the period 1825–2017 at the study site, and two extreme cases. In detail, f _k values considered are 0 (no forest, deforestation), 0.16 (forest fraction in 1825), 0.24 (forest fraction in 1948), $\bar {f} = f_{k} = 0.35$ (equal to the forest fraction in 1980), 0.46 (forest fraction in 2017) and 1 (the path is fully covered by forests).

As explained in the Introduction, in frictional approaches, forest–avalanche interaction is often modeled by decreasing the value of ξ significantly, and increasing the value of μ only slightly in the forested section of the path. However, it is known for long that the runout distance is mostly controlled by the static friction coefficient μ (e.g. Dent and Lang, Reference Dent and Lang1980; Borstad and McClung, Reference Borstad and McClung2009), which has been recently confirmed by more systematic sensitivity analyses by Heredia and others (Reference Heredia, Prieur and Eckert2021, Reference Heredia, Prieur and Eckert2022). Similarly, Teich and others (Reference Teich2012b) showed that focusing on the turbulent friction ξ only when investigating how forest cover impacts avalanche dynamics is not enough since the effects on runout distances of sole slight decrease of ξ remain too limited. Hence, we consider that changes in land cover can affect both ξ and μ and consider the three following cases, corresponding to the different possible relationships between forest fraction and friction coefficients: Case I: It is assumed that the dependability of the friction coefficient μ on land cover, particularly forests, can be modeled by adding a term $g( f_{k}-\bar {f})$ that increases/decreases the mean of the distribution of the static friction coefficient μ based on the value of the forest fraction f _k relative to $\bar {f}$. This uses the fact that μ is a latent variable in our statistical–dynamical model. A linear dependency between the mean of the distribution of μ and f _k is chosen, similar to the one between the mean of μ, release abscissa and mean release depth. To avoid the small number of unphysical negative values of μ that may result from this formulation with low values of f _k, we simply add a positivity constraint and sample the static friction coefficient μ from the truncated normal distribution (see Section ‘Dependence of the Voellmy friction coefficients on the forest fraction’ for discussion and Appendix D for the influence of the truncation on the case study):

(16)$$\mu \sim N( c + {\rm d} x_{{\rm start}_{\rm norm}} + eh + g( f_{k}-\bar{f}) ,\; \sigma) \mathbbm{1}( \mu > 0) ,\; $$

where the parameters c, d and e remain set to their posterior estimates (Table 1) resulting from the model calibration. Choosing a suitable value for g is a difficult task. To this aim, we use the fact that, when the effects of the variables x _start and h are neglected, the minimal value of the mean of μ, obtained for f _k = 0, is ${\bar \mu} _{\min } = c-g\bar {f}$. Physical knowledge and repeated calibrations in various avalanche terrains using deterministic or stochastic methods (Salm and others, Reference Salm, Burkard and Gubler1990; Ancey and others, Reference Ancey, Gervasoni and Meunier2004; Naaim and others, Reference Naaim, Durand, Eckert and Chambon2013) indicate that classical very low values of μ are ~0.15. Within the equation $\bar {\rm \mu _{\min }} = c-g\bar {f}$, this corresponds to g = 0.6. Given that this remains, however, a strong assumption, we performed a sensitivity analysis with values of g spanning the full g = 0.4–0.8 range. Case II: It is assumed that the turbulent coefficient ξ decays as a power law with an increasing forest fraction:

(17)$$\xi = \hat{\xi}b^{( f_{k}-\bar{\,f}) }$$

where $\hat {\xi }$ is the posterior estimate resulting from the calibration step. This relationship uses the fact that ξ is a parameter in the strict statistical sense of the term. It is considered that, moving from deforested to forested terrain, ξ decreases by ~60% (~1000 to 400 m s⁻²) (Feistl, Reference Feistl2015). This corresponds to b = 0.5. However, just like in the previous case, the sensitivity of the results to this parameter is tested by spanning the range between b = 0.2 and b = 0.8. Eventually, the choice of a power law relationship stems from the rather limited protection offered by forests against natural hazard during the primary steps of forest colonization (Wohlgemuth and others, Reference Wohlgemuth, Schwitter, Bebi, Sutter and Brang2017) versus the maximum protection offered when reforestation of the avalanche path is complete. Case III: It is assumed that both μ and ξ depend on the forest fraction, combining the models corresponding to cases I and II. Results are analyzed and discussed for g = 0.6 and b = 0.5.

Note that, due to the specification of cases I–III, for $f_{k} = \bar {f} = 0.35$, friction coefficient models, and, hence, results of the previous section remain unchanged, so that no further simulation campaign is necessary. For all other forest fractions and in each case, 10 000 avalanches were simulated to reconstruct the joint distribution of model inputs–outputs according to Eqn (11). Subsequently, return periods, confidence intervals and impact pressures were computed based on Eqns (12–15).

Avalanche risk evaluation

Risk in the natural hazard field is defined as the expected damage resulting from the interaction between a damageable phenomenon and a vulnerable exposed entity. According to Eckert and others (Reference Eckert2012), the specific (dimensionless) avalanche risk r _z for an element at risk z is:

(18)$$r_{z} = \lambda\int p( y) V_{z}( y) {\rm d}y,\; $$

where V _z(y) is the vulnerability of the element z to the avalanche magnitude y. Favier and others (Reference Favier, Eckert, Bertrand and Naaim2014b) further show that this generic expression can be rewritten at abscissa x _b as:

(19)$$r_{z}( x_{b}) = \lambda\int p( P\vert x_{b}\leq x_{\rm stop}) p( x_{b}\leq x_{\rm stop}) \times V_{z}( P) {\rm d}P.$$

Here, the avalanche magnitude distribution corresponds to the joint distribution of runout distances x _stop and pressures P i.e. p(P,  x _stop) = p(P|x _b ≤ x _stop)p(x _b ≤ x _stop) where p(P|x _b ≤ x _stop) is the pressure distribution at abscissa x _b knowing that x _b has been reached by an avalanche and p(x _b ≤ x _stop) is the probability for an element at x _b to be reached by an avalanche.

To assess the evolution of avalanche risk to settlements, we consider at x = 1840 m a typical mountainous dwelling house. Its overall vulnerability is determined by the failure probability of its most vulnerable part, i.e. the wall facing the avalanche (Favier and others, Reference Favier, Bertrand, Eckert and Naaim2014a). Within a reliability framework, Favier and others (Reference Favier, Bertrand, Eckert and Naaim2014a) evaluated vulnerability curves for such typical buildings impacted by snow avalanches. This was done by modeling the response of an RC wall impacted by a uniform dense avalanche flow under the assumption of a quasi-static loading. These curves were obtained for various building types and for different limit state definitions: the elastic limit state (ELS), the ultimate limit state (ULS), the accidental limit state (ALS) and collapse (YLT: yield line theory). The ELS represents the upper limit of the elastic phase beyond which cracks begin to form and the concrete develops a non-linear behavior (Bertrand and others, Reference Bertrand, Naaim and Brun2010). At this point, the structure can still carry loads and the damage is considered low. Under continuously increasing pressure, the tensile crack will grow until the concrete or the steel reach respectively the ultimate compression strain and ultimate tensile strain (Favier and others, Reference Favier, Bertrand, Eckert and Naaim2014a), thus announcing the reach of the ULSand the onset of steel yield (plastic (permanent) deformation inside the steel). The ALS is considered to ensure that the structure can withstand accidental events (statistically less likely to occur) e.g. explosions. Finally, yield lines or macro-crack form through the member leading to the collapse of the structure (YLT). For more details refer to Appendix C and Favier and others (Reference Favier, Bertrand, Eckert and Naaim2014a). In this study, we consider ten building types and the four limit state definitions. This results in a large set of 40 vulnerability relationships (Appendix C) providing the probability for the considered building type to surpass the considered limit state (i.e. the failure probability) when subjected to a given avalanche impact pressure. This large set allows studying in a robust way how risk to buildings varies with forest cover within the path, and, notably, how different combinations of building types and forest fractions can result in given risk levels.