2.1. Model parameters

The model parameters requiring calibration are the degree-day factor of snow (f _snow, mm w.e. d⁻¹°C⁻¹), precipitation factor (k _p, -), and temperature bias (T _bias, °C). The precipitation factor and temperature bias are a multiplier and additive correction that are used to correct the precipitation and air temperature data from ERA-Interim, respectively. These adjustment factors are needed to account for any biases in the climate data and downscale the data from its coarse resolution to each glacier. Additionally, these model parameters are used to account for any processes (e.g., debris cover, firn densification) that are not explicitly included in the glacier evolution model.

For the other model parameters, we either assume reasonable values or estimate them from climate data in order to reduce the number of model parameters. Specifically, the degree-day factor of snow is assumed to be 70% of the degree-day factor of ice, and the degree-day factor of firn is assumed to be the mean of the degree-day factor of snow and ice. We assume the precipitation gradient is 0.01% m⁻¹ and the temperature threshold for the snow–rain transition is 1°C (Huss and Hock, Reference Huss and Hock2015).

2.2. Calibration data

Geodetic mass-balance observations of 95,086 glaciers (99.6% of the total glacier area) (Shean and others, Reference Shean2020) in High Mountain Asia were used to calibrate the glacier evolution model. These observations were derived from trends fit to at least five, and sometimes more than 50, digital elevation models per glacier derived from all available cloud-free Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) and DigitalGlobe WorldView-1, WorldView-2, WorldView-3 and GeoEye-1 stereo images between 2000 and 2018 (Shean and others, Reference Shean2016). Given the nearly complete coverage of glaciers in High Mountain Asia, the specific glacier-wide mass balances were computed as the mean elevation change rate for each glacier polygon, which was converted to mass balance using a density of 850 kg m⁻³ (Shean and others, Reference Shean2020).

We quality controlled these mass balances by removing outliers using a 3-sigma filter. For 22 subregions defined by Bolch and others (Reference Bolch, Wester, Mishra, Mukherji and Shrestha2019), 954 glaciers (0.4% of the total glacier area) were identified as outliers based on a comparison of individual glacier mass-balance estimates and the regional mean. Additionally, the uncertainty associated with the mass-balance estimates of individual glaciers ranged from 0.02 to 13.2 m w.e. a⁻¹. Again, a 3-sigma filter was used to identify and remove 1401 glaciers (0.5% of the total glacier area) based on a comparison of the uncertainty associated with the individual glacier mass balance and the mean uncertainty of all the glaciers in High Mountain Asia. Glaciers that were not measured or removed as outliers were assumed to have a specific mass balance and uncertainty equal to the regional specific mass balance and the mean uncertainty associated with all the glaciers in their respective region.

The mean specific mass balance for all glaciers in High Mountain Asia from 2000 to 2018 was −0.20 ± 0.21 m w.e. a⁻¹, but varied greatly by region ranging from −0.65 ± 0.41 m w.e. a⁻¹ in Hengduan Shan to 0.05 ± 0.18 m w.e. a⁻¹ in Western Kunlun Shan. The uncertainty associated with the individual glacier mass-balance estimates ranged from 0.02 to 1.31 m w.e. a⁻¹ with a median of 0.31 m w.e. a⁻¹. These results are consistent with Brun and others (Reference Brun, Berthier, Wagnon, Kääb and Treichler2017) and emphasize the importance of using subregional data to calibrate large-scale glacier evolution models.

3.1. Inversion

Given the non-linear data-generating process:

(11)$$B_{{\rm obs}} = F\lpar {\bi \theta} \rpar + \; \varepsilon, $$

where B _obs is the observed specific mass balance, F(θ) is our forward model (PyGEM, see Section 2), θ are the three model parameters: precipitation factor (k _p), temperature bias (T _bias), and degree-day factor of snow (f _snow), and ɛ is the error associated with the observation; we seek to determine the distribution of parameters, θ, consistent with observations. The error, ɛ, is assumed to be normally distributed with a mean of zero and a standard deviation, σ, derived from the processing of the geodetic mass-balance observations (Shean and others, Reference Shean2020). Note that ɛ does not account for any uncertainty associated with how well the glacier evolution model actually represents reality as quantifying uncertainty associated with the model physics and input data is beyond the scope of this study.

The likelihood function, p(y|θ), can therefore be described as:

(12)$$p\lpar {y{\rm \vert} {\bi \theta}} \rpar \propto \psi _1\lpar {\bi \theta} \rpar \; \psi _2({\bi \theta} )\; \displaystyle{1 \over {\sigma \sqrt {2\pi}}} {\rm e}^{-{\lpar {B-F\lpar {\bi \theta} \rpar } \rpar }^2/2\sigma ^2},$$

where ψ ₁ and ψ ₂ are potential functions (Jordan, Reference Jordan2004) that impose two physical constraints. The first potential function, ψ ₁, ensures the modeled mass balance is not less than the mass balance associated with completely melting the glacier, B _{max_loss}:

(13)$$ \psi _1\lpar {\bi \theta} \rpar = \left\{ {\matrix{ {0\; \; \; \; \; {\rm if}\; F\lpar {\bi \theta} \rpar \lt B_{{\rm max}\_{\rm loss}}} \cr {1\; \; \; \; \; {\rm if}\; F\lpar {\bi \theta} \rpar \ge B_{{\rm max}\_{\rm loss}}} \cr}} \right..$$

The second potential function, ψ ₂, ensures the climatic mass balance of the lowermost bin, $b_{{\rm clim,bi}{\rm n}_{{\rm lowest}}}$, is negative for at least 1 year, i.e., the glacier has an ablation area:

(14)$$\psi _2\lpar {\bi \theta} \rpar = \left\{\matrix{0\; \; \; \hfill &b_{{\rm clim,bi}{\rm n}_{\rm lowest}}\lpar {\bi \theta} \rpar \ge 0\; {\rm for\; every\; year}\hfill\cr 1\hfill & b_{{\rm clim,bi}{\rm n}_{{\rm lowest}}}\lpar {\bi \theta} \rpar \lt 0\; {\rm for\; at\; least\; one\; year}}\hfill \right..$$

The constraints ensure the proposed sets of non-physical model parameters are rejected.

3.2. Empirical Bayes and prior distributions

A preferable solution would be to employ a hierarchical model that jointly models glaciers in a (sub)region, which allows for the borrowing of information from nearby glaciers. Such a model would assume that the observations of each glacier are conditionally independent, but the parameters themselves would be assumed, through their prior distribution, to be drawn from a common underlying population (Carlin and Louis, Reference Carlin and Louis2008; Chapter 5). This hierarchical model could be applied to each of the 22 subregions (Bolch and others, Reference Bolch, Wester, Mishra, Mukherji and Shrestha2019) as follows:

(15)$$\eqalignb{p\lpar {{\bi \theta}, {\bi \varphi} {\rm \vert} y} \rpar &\propto p\lpar {y{\rm \vert} {\bi \theta}, {\bi \varphi}} \rpar p({\bi \theta}, {\bi \varphi} )\cr &\propto \mathop \prod \limits_{i = 1}^{n_y} [\,p\lpar {y_i{\rm \vert} {\bi \theta}_i} \rpar p({\bi \theta} _i \vert {\bi \varphi} )]p({\bi \varphi} ),}$$

where θ_i is the set of model parameters for glacier i, y _i is the observation for glacier i, φ represents the regional prior parameters, and p(φ) is therefore the regional joint prior distribution. Unfortunately, simultaneous inference over all glaciers is intractable.

We therefore approximate p(φ) as p(φ|y) by computing a priori estimates for each glacier in each region (detailed below, Fig. 1), which is computationally cheap, and then fit normal and gamma distributions to the resulting histograms. This procedure is commonly used in mixed-effects models (such as the one in this study), where it is referred to as empirical Bayes (Efron, Reference Efron2010).

Fig. 1. Flow chart of the simple calibration scheme used to initially calibrate every glacier in order to generate the regional marginal prior distributions for the temperature bias (T _bias) and precipitation factor (k _p). The prior distribution for the degree-day factor of snow (f_snow) is based on Braithwaite (Reference Braithwaite2008). B _obs refers to the observed mass balance.

The joint prior distribution reflects our knowledge of each parameter prior to any observations. Independent prior information for the degree-day factor of snow is available from glaciers from various regions around the world. Braithwaite (Reference Braithwaite2008) compiled these data and found a mean ± standard deviation of 4.1 ± 1.5 mm w.e. d⁻¹°C⁻¹. Based on these data, we assume the prior distribution for the degree-day factor of snow is a truncated normal distribution with the given mean, μ, and standard deviation, σ, truncated at 0 and ∞ to ensure positivity:

(16)$$p\lpar {\,f_{{\rm snow}}} \rpar = N_{\rm T}(\mu, \sigma, 0,\infty ).$$

For the temperature bias and precipitation factor, no independent data are available due to a lack of meteorological observations, especially at high altitudes where the glaciers reside. In Central Asia, a comparison of air temperature observations with various reanalysis datasets, including ERA-Interim, found the air temperature agreed well with local observations (average absolute error between −0.6 and 1.6°C), but also identified minor differences between datasets in the air temperature trends from 1980 to 2011 in select subregions (Hu and others, Reference Hu, Zhang, Hu and Tian2014). Conversely, precipitation has been a great source of uncertainty in High Mountain Asia with many studies concluding that precipitation at high altitudes is highly inaccurate and that some regions need to be corrected by up to a factor of 10 (Immerzeel and others, Reference Immerzeel, Wanders, Lutz, Shea and Bierkens2015; Dahri and others, Reference Dahri2016; Wortmann and others, Reference Wortmann, Bolch, Menz, Tong and Krysanova2018).

Given this information, we first use a simple optimization scheme to fit the precipitation factor and temperature bias to the observed specific mass balance of every glacier in High Mountain Asia based on a modified version of Huss and Hock (Reference Huss and Hock2015) (Fig. 1). This initial optimization enables us to approximate the regional joint prior distribution, p(φ), of the temperature bias and precipitation factor for each subregion. The optimizations are performed using the sequential least-squares minimization function from the open-source SciPy statistical package (Jones and others, Reference Jones2001). Since precipitation is considered to be more uncertain than the temperature data, the scheme first attempts to optimize only the precipitation factor, and then incrementally adjusts the temperature bias bounds to ensure the precipitation factor remains within its bounds.

The optimized parameters are then regionally aggregated by the 22 subregions (Bolch and others, Reference Bolch, Wester, Mishra, Mukherji and Shrestha2019) to develop prior distributions for each region. Specifically, the prior distribution for the temperature bias is assumed to be a normal distribution with a mean and standard deviation based on the regional mean, $\mu _{{\rm reg},T_{{\rm bias}}}$, and regional standard deviation, $\sigma _{{\rm reg},T_{{\rm bias}}}$, derived from the initial optimization of the temperature bias (Fig. S1):

(17)$$p\lpar {T_{{\rm bias}}} \rpar = {\rm {\cal N}}(\mu _{{\rm reg},T_{{\rm bias}}},\sigma _{{\rm reg},T_{{\rm bias}}}).$$

The prior distribution for the precipitation factor is assumed to be a gamma distribution, which ensures positivity, that has a shape parameter, α, and rate parameter, β, estimated from the regional mean, $\mu _{{\rm reg},k_{\rm p}}$, and standard deviation, $\sigma _{{\rm reg},k_{\rm p}}$, of the initial optimization of the precipitation factor (Fig. S2):

(18)$$\beta = \displaystyle{{\mu _{{\rm reg},k_{\rm p}}} \over {\sigma _{{\rm reg},k_{\rm p}}}}$$

(19)$$\alpha = \beta \mu _{{\rm reg},k{\rm p}}$$

(20)$$p\lpar {k_{\rm p}} \rpar = {\rm \Gamma} (\alpha, \beta ).$$

3.3. Markov chain Monte Carlo implementation

In practice, properties or characteristics of the posterior distribution p(θ|y) are difficult to evaluate analytically. MCMC methods circumvent this issue by producing samples of the joint posterior distribution that can be used to estimate the center, shape, and spread of the marginal posterior distributions. Specifically, MCMC methods are based on theorems that prove if the Markov chain is run for enough steps, the chain converges to a unique stationary distribution, and the resulting samples are from the joint posterior distribution (Carlin and Louis, Reference Carlin and Louis2008).

The MCMC methods are implemented using the open source PyMC 2.3.7 statistical package (Fonnesbeck and others, Reference Fonnesbeck, Patil, Huard and Salvatier2014). Specifically, these methods are implemented using an adaptive Metropolis-Hastings sampling algorithm, which uses normal proposal distributions and single-component updating. To ensure the Markov chain mixes well, the chain can be tuned throughout. This is done by using a multiplicative factor to adjust the standard deviation associated with the proposal distribution of each parameter with the goal of adjusting the proposal distribution such that the acceptance rate is between 20 and 50% (Fonnesbeck and others, Reference Fonnesbeck, Patil, Huard and Salvatier2014). For our model, the Markov chains were tuned every 1,000 steps. Note these methods are computationally expensive because the likelihood function requires the forward model to be evaluated many times.

3.4. Identifiability

Each glacier has one observation and a corresponding estimate of uncertainty (i.e., mean and standard deviation of the glacier-wide specific mass balance), and three model parameters (precipitation factor, temperature bias, and degree-day factor of snow). Given how each model parameter affects the forward model (Fig. 2), the lack of observations results in there being an infinite number of parameter sets that will produce an exact match between the modeled and observed mass balance, i.e., the model is over-parameterized. For example, for glacier RGI60-13.26360, the modeled and observed mass balance agree if the temperature bias, precipitation factor, and degree-day factor of snow are −2°C, 1, 4.1 mm w.e. d⁻¹°C⁻¹; 0°C, 3.1, 2.6 mm w.e. d⁻¹°C⁻¹; or 0°C, 7.4, 5.6 mm w.e. d⁻¹°C⁻¹, respectively. Given our over-parameterized problem, we must consider identifiability and its implications for large-scale glacier evolution modeling.

Fig. 2. The modeled mass balance for glacier RGI60-13.26360 as a function of the temperature bias (°C), using three different precipitation factors (k _p, -) and degree-day factors of snow (f _snow, mm w.e. d⁻¹°C⁻¹). The observed mass balance ± 3 standard deviations is shown by the horizontal gray line and shading, respectively.

Identifiability refers to how much information is gained about the individual components of θ given the data y. Gelfand and Sahu (Reference Gelfand and Sahu1999) provide a formal definition of identifiability for a simple Bayesian model with a likelihood function p(y|θ), where θ is partitioned into θ₁ and θ₂. θ₂ is said to be non-identifiable if

(21)$$p({\bi \theta} _2 \vert {\bi \theta} _1,y) = p({\bi \theta} _2 \vert {\bi \theta} _1).$$

In other words, θ₂ is non-identifiable if ‘observing data y does not increase our prior knowledge about θ₂ given θ₁’ (Gelfand and Sahu, Reference Gelfand and Sahu1999). Mathematically one can prove that θ₂ is non-identifiable if the likelihood function can be reparameterized such that the likelihood function is free of θ₂. In practice, analytically proving a parameter in a complex model is non-identifiable is difficult, sometimes nearly impossible, and instead non-identifiability may be detected intuitively (Eberly and Carlin, Reference Eberly and Carlin2000) or empirically (Renard and others, Reference Renard, Kavetski, Kuczera, Thyer and Franks2010).

Note that identifiability relies only on the likelihood function and is independent of the joint prior distribution (Renard and others, Reference Renard, Kavetski, Kuczera, Thyer and Franks2010). For our likelihood function, which includes the glacier mass balance computed using PyGEM, each model parameter clearly affects the mass balance (Fig. 2). Given that we only have a single mass-balance observation that provides no information as to which model parameters need to be modified, i.e., any model parameter or combination of model parameters can be adjusted such that the modeled mass balance agrees with the observation, we can intuitively determine that each model parameter is clearly non-identifiable (Renard and others, Reference Renard, Kavetski, Kuczera, Thyer and Franks2010).

3.5. Chain length and convergence diagnostics

One of the limitations of MCMC methods is the inability to know when the chain has converged. Therefore, we rely on three diagnostics (Gelman–Rubin statistic, Monte Carlo error, and effective sample size) to provide us with confidence that the chain has likely converged to its stationary distribution. This enables us to confidently sample from the joint posterior distribution and use ordinary estimators to evaluate the model parameters and their respective uncertainty. In an ideal setting, multiple long chains would be run for each glacier such that chain convergence could be assessed using a suite of diagnostics. However, this quickly becomes computationally prohibitive since each step in the chain requires the mass balance to be computed by PyGEM. Therefore, we need to determine the acceptable number of steps required for us to be confident that the chain has converged while using our computational resources efficiently.

For each of the three RGI regions in High Mountain Asia, 1,000 glaciers were randomly selected to determine the appropriate number of steps required for the Markov chain to converge. For each of these glaciers, three chains of 25,000 steps using overdispersed starting points (one at the center and one at each of the end points of the 95% confidence interval) were generated. The overdispersed starting points helped determine if the chains converged to the unique stationary distribution. The amount of burn-in, i.e., the number of steps discarded at the start of the chain, was also investigated.

The Gelman–Rubin statistic uses multiple chains to compare the variance within each chain to the variance between chains for each parameter (Gelman and others, Reference Gelman2014). If the within-chain and between-chain variances are significantly different, the chain has likely not converged; while if they are similar, the chain has potentially converged. An upper threshold of 1.1 is used to assess possible convergence (Flegal and others, Reference Flegal, Haran and Jones2008; Gelman and others, Reference Gelman2014). Since successive steps from the Metropolis-Hastings algorithm are inherently correlated, the effective sample size is used to estimate the number of independent samples generated for each parameter. A threshold of 100 is used to ensure enough independent samples have been generated (Gelman and others, Reference Gelman2014) such that we can be confident in estimating 95% confidence intervals for the model output.

The Monte Carlo error is an estimate of the simulation error, which does not indicate chain convergence, but rather provides information regarding the quality of the reported ordinary estimators such as the mean and standard deviation (Flegal and others, Reference Flegal, Haran and Jones2008). We normalize the Monte Carlo error by the standard deviation of the posterior predictive distribution for the mass balance or the marginal posterior distribution for each model parameter. A high value indicates the uncertainty associated with the ordinary estimator is dominated by simulation error, while a low value indicates the uncertainty associated with the ordinary estimator is informed by the data and priors. We set a target threshold of 10%, but acknowledge that a high value is not necessarily cause for concern since it could reflect that the spread in the posterior is very small. The Monte Carlo error is computed using overlapping batch means with a batch size equal to the square root of the chain length.

The acceptable chain length is considered to be the value at which 90% of the glaciers pass the threshold associated with each diagnostic. A single chain with this acceptable number of steps is then run for each glacier in High Mountain Asia. These single chains are evaluated using only the Monte Carlo error and the effective sample size, since the Gelman–Rubin statistic requires multiple chains. This ensures that the subset of glaciers used to estimate the chain length is representative of the greater region.