State-Space models in mvgam

The purpose of this vignette is to show how the mvgam package can be used to fit and interrogate State-Space models with nonlinear effects.

State-Space Models

Illustration of a basic State-Space model, which assumes that a latent dynamic process (X) can evolve independently from the way we take observations (Y) of that process
Illustration of a basic State-Space model, which assumes that a latent dynamic process (X) can evolve independently from the way we take observations (Y) of that process


State-Space models allow us to separately make inferences about the underlying dynamic process model that we are interested in (i.e. the evolution of a time series or a collection of time series) and the observation model (i.e. the way that we survey / measure this underlying process). This is extremely useful in ecology because our observations are always imperfect / noisy measurements of the thing we are interested in measuring. It is also helpful because we often know that some covariates will impact our ability to measure accurately (i.e. we cannot take accurate counts of rodents if there is a thunderstorm happening) while other covariate impact the underlying process (it is highly unlikely that rodent abundance responds to one storm, but instead probably responds to longer-term weather and climate variation). A State-Space model allows us to model both components in a single unified modelling framework. A major advantage of mvgam is that it can include nonlinear effects and random effects in BOTH model components while also capturing dynamic processes.

Lake Washington plankton data

The data we will use to illustrate how we can fit State-Space models in mvgam are from a long-term monitoring study of plankton counts (cells per mL) taken from Lake Washington in Washington, USA. The data are available as part of the MARSS package and can be downloaded using the following:

load(url('https://github.com/atsa-es/MARSS/raw/master/data/lakeWAplankton.rda'))

We will work with five different groups of plankton:

outcomes <- c('Greens', 'Bluegreens', 'Diatoms', 'Unicells', 'Other.algae')

As usual, preparing the data into the correct format for mvgam modelling takes a little bit of wrangling in dplyr:

# loop across each plankton group to create the long datframe
plankton_data <- do.call(rbind, lapply(outcomes, function(x){
  
  # create a group-specific dataframe with counts labelled 'y'
  # and the group name in the 'series' variable
  data.frame(year = lakeWAplanktonTrans[, 'Year'],
             month = lakeWAplanktonTrans[, 'Month'],
             y = lakeWAplanktonTrans[, x],
             series = x,
             temp = lakeWAplanktonTrans[, 'Temp'])})) %>%
  
  # change the 'series' label to a factor
  dplyr::mutate(series = factor(series)) %>%
  
  # filter to only include some years in the data
  dplyr::filter(year >= 1965 & year < 1975) %>%
  dplyr::arrange(year, month) %>%
  dplyr::group_by(series) %>%
  
  # z-score the counts so they are approximately standard normal
  dplyr::mutate(y = as.vector(scale(y))) %>%
  
  # add the time indicator
  dplyr::mutate(time = dplyr::row_number()) %>%
  dplyr::ungroup()

Inspect the data structure

head(plankton_data)
dplyr::glimpse(plankton_data)

Note that we have z-scored the counts in this example as that will make it easier to specify priors (though this is not completely necessary; it is often better to build a model that respects the properties of the actual outcome variables)

plot_mvgam_series(data = plankton_data, series = 'all')

We have some missing observations, but this isn’t an issue for modelling in mvgam. A useful property to understand about these counts is that they tend to be highly seasonal. Below are some plots of z-scored counts against the z-scored temperature measurements in the lake for each month:

plankton_data %>%
  dplyr::filter(series == 'Other.algae') %>%
  ggplot(aes(x = time, y = temp)) +
  geom_line(size = 1.1) +
  geom_line(aes(y = y), col = 'white',
            size = 1.3) +
  geom_line(aes(y = y), col = 'darkred',
            size = 1.1) +
  ylab('z-score') +
  xlab('Time') +
  ggtitle('Temperature (black) vs Other algae (red)')
plankton_data %>%
  dplyr::filter(series == 'Diatoms') %>%
  ggplot(aes(x = time, y = temp)) +
  geom_line(size = 1.1) +
  geom_line(aes(y = y), col = 'white',
            size = 1.3) +
  geom_line(aes(y = y), col = 'darkred',
            size = 1.1) +
  ylab('z-score') +
  xlab('Time') +
  ggtitle('Temperature (black) vs Diatoms (red)')

We will have to try and capture this seasonality in our process model, which should be easy to do given the flexibility of GAMs. Next we will split the data into training and testing splits:

plankton_train <- plankton_data %>%
  dplyr::filter(time <= 112)
plankton_test <- plankton_data %>%
  dplyr::filter(time > 112)

Now time to fit some models. This requires a bit of thinking about how we can best tackle the seasonal variation and the likely dependence structure in the data. These algae are interacting as part of a complex system within the same lake, so we certainly expect there to be some lagged cross-dependencies underling their dynamics. But if we do not capture the seasonal variation, our multivariate dynamic model will be forced to try and capture it, which could lead to poor convergence and unstable results (we could feasibly capture cyclic dynamics with a more complex multi-species Lotka-Volterra model, but ordinary differential equation approaches are beyond the scope of mvgam).

Capturing seasonality

First we will fit a model that does not include a dynamic component, just to see if it can reproduce the seasonal variation in the observations. This model introduces hierarchical multidimensional smooths, where all time series share a “global” tensor product of the month and temp variables, capturing our expectation that algal seasonality responds to temperature variation. But this response should depend on when in the year these temperatures are recorded (i.e. a response to warm temperatures in Spring should be different to a response to warm temperatures in Autumn). The model also fits series-specific deviation smooths (i.e. one tensor product per series) to capture how each algal group’s seasonality differs from the overall “global” seasonality. Note that we do not include series-specific intercepts in this model because each series was z-scored to have a mean of 0.

notrend_mod <- mvgam(y ~ 
                       # tensor of temp and month to capture
                       # "global" seasonality
                       te(temp, month, k = c(4, 4)) +
                       
                       # series-specific deviation tensor products
                       te(temp, month, k = c(4, 4), by = series) - 1,
                     family = gaussian(),
                     data = plankton_train,
                     newdata = plankton_test,
                     trend_model = 'None')

The “global” tensor product smooth function can be quickly visualized:

plot_mvgam_smooth(notrend_mod, smooth = 1)

On this plot, red indicates below-average linear predictors and white indicates above-average. We can then plot the deviation smooths for a few algal groups to see how they vary from the “global” pattern:

plot_mvgam_smooth(notrend_mod, smooth = 2)
plot_mvgam_smooth(notrend_mod, smooth = 3)

These multidimensional smooths have done a good job of capturing the seasonal variation in our observations:

plot(notrend_mod, type = 'forecast', series = 1)
plot(notrend_mod, type = 'forecast', series = 2)
plot(notrend_mod, type = 'forecast', series = 3)

This basic model gives us confidence that we can capture the seasonal variation in the observations. But the model has not captured the remaining temporal dynamics, which is obvious when we inspect Dunn-Smyth residuals for a few series:

plot(notrend_mod, type = 'residuals', series = 1)
plot(notrend_mod, type = 'residuals', series = 3)

Multiseries dynamics

Now it is time to get into multivariate State-Space models. We will fit two models that can both incorporate lagged cross-dependencies in the latent process models. The first model assumes that the process errors operate independently from one another, while the second assumes that there may be contemporaneous correlations in the process errors. Both models include a Vector Autoregressive component for the process means, and so both can model complex community dynamics. The models can be described mathematically as follows:

Here you can see that there are no terms in the observation model apart from the underlying process model. But we could easily add covariates into the observation model if we felt that they could explain some of the systematic observation errors. We also assume independent observation processes (there is no covariance structure in the observation errors σobs). At present, mvgam does not support multivariate observation models. But this feature will be added in future versions. However the underlying process model is multivariate, and there is a lot going on here. This component has a Vector Autoregressive part, where the process mean at time t (μprocess[t]) is a vector that evolves as a function of where the vector-valued process model was at time t − 1. The A matrix captures these dynamics with self-dependencies on the diagonal and possibly asymmetric cross-dependencies on the off-diagonals, while also incorporating the nonlinear smooth functions that capture seasonality for each series. The contemporaneous process errors are modeled by Σprocess, which can be constrained so that process errors are independent (i.e. setting the off-diagonals to 0) or can be fully parameterized using a Cholesky decomposition (using Stan’s LKJcorr distribution to place a prior on the strength of inter-species correlations). For those that are interested in the inner-workings, mvgam makes use of a recent breakthrough by Sarah Heaps to enforce stationarity of Bayesian VAR processes. This is advantageous as we often don’t expect forecast variance to increase without bound forever into the future, but many estimated VARs tend to behave this way.


Ok that was a lot to take in. Let’s fit some models to try and inspect what is going on and what they assume. But first, we need to update mvgam’s default priors for the observation and process errors. By default, mvgam uses a fairly wide Student-T prior on these parameters to avoid being overly informative. But our observations are z-scored and so we do not expect very large process or observation errors. However, we also do not expect very small observation errors either as we know these measurements are not perfect. So let’s update the priors for these parameters. In doing so, you will get to see how the formula for the latent process (i.e. trend) model is used in mvgam:

priors <- get_mvgam_priors(
  # observation formula, which has no terms in it
  y ~ -1,
  
  # process model formula, which includes the smooth functions
  trend_formula = ~ te(temp, month, k = c(4, 4)) +
    te(temp, month, k = c(4, 4), by = trend) - 1,
  
  # VAR1 model with uncorrelated process errors
  trend_model = VAR(),
  family = gaussian(),
  data = plankton_train)

Get names of all parameters whose priors can be modified:

priors[, 3]

And their default prior distributions:

priors[, 4]

Setting priors is easy in mvgam as you can use brms routines. Here we use more informative Normal priors for both error components, but we impose a lower bound of 0.2 for the observation errors:

priors <- c(prior(normal(0.5, 0.1), class = sigma_obs, lb = 0.2),
            prior(normal(0.5, 0.25), class = sigma))

You may have noticed something else unique about this model: there is no intercept term in the observation formula. This is because a shared intercept parameter can sometimes be unidentifiable with respect to the latent VAR process, particularly if our series have similar long-run averages (which they do in this case because they were z-scored). We will often get better convergence in these State-Space models if we drop this parameter. mvgam accomplishes this by fixing the coefficient for the intercept to zero. Now we can fit the first model, which assumes that process errors are contemporaneously uncorrelated

var_mod <- mvgam(  
  # observation formula, which is empty
  y ~ -1,
  
  # process model formula, which includes the smooth functions
  trend_formula = ~ te(temp, month, k = c(4, 4)) +
    te(temp, month, k = c(4, 4), by = trend) - 1,
  
  # VAR1 model with uncorrelated process errors
  trend_model = VAR(),
  family = gaussian(),
  data = plankton_train,
  newdata = plankton_test,
  
  # include the updated priors
  priors = priors,
  silent = 2)

Inspecting SS models

This model’s summary is a bit different to other mvgam summaries. It separates parameters based on whether they belong to the observation model or to the latent process model. This is because we may often have covariates that impact the observations but not the latent process, so we can have fairly complex models for each component. You will notice that some parameters have not fully converged, particularly for the VAR coefficients (called A in the output) and for the process errors (Sigma). Note that we set include_betas = FALSE to stop the summary from printing output for all of the spline coefficients, which can be dense and hard to interpret:

summary(var_mod, include_betas = FALSE)

The convergence of this model isn’t fabulous (more on this in a moment). But we can again plot the smooth functions, which this time operate on the process model. We can see the same plot using trend_effects = TRUE in the plotting functions:

plot(var_mod, 'smooths', trend_effects = TRUE)

The VAR matrix is of particular interest here, as it captures lagged dependencies and cross-dependencies in the latent process model. Unfortunately bayesplot doesn’t know this is a matrix of parameters so what we see is actually the transpose of the VAR matrix. A little bit of wrangling gives us these histograms in the correct order:

A_pars <- matrix(NA, nrow = 5, ncol = 5)
for(i in 1:5){
  for(j in 1:5){
    A_pars[i, j] <- paste0('A[', i, ',', j, ']')
  }
}
mcmc_plot(var_mod, 
          variable = as.vector(t(A_pars)), 
          type = 'hist')

There is a lot happening in this matrix. Each cell captures the lagged effect of the process in the column on the process in the row in the next timestep. So for example, the effect in cell [1,3] shows how an increase in the process for series 3 (Greens) at time t is expected to impact the process for series 1 (Bluegreens) at time t + 1. The latent process model is now capturing these effects and the smooth seasonal effects.

The process error (Σ) captures unmodelled variation in the process models. Again, we fixed the off-diagonals to 0, so the histograms for these will look like flat boxes:

Sigma_pars <- matrix(NA, nrow = 5, ncol = 5)
for(i in 1:5){
  for(j in 1:5){
    Sigma_pars[i, j] <- paste0('Sigma[', i, ',', j, ']')
  }
}
mcmc_plot(var_mod, 
          variable = as.vector(t(Sigma_pars)), 
          type = 'hist')

The observation error estimates (σobs) represent how much the model thinks we might miss the true count when we take our imperfect measurements:

mcmc_plot(var_mod, variable = 'sigma_obs', regex = TRUE, type = 'hist')

These are still a bit hard to identify overall, especially when trying to estimate both process and observation error. Often we need to make some strong assumptions about which of these is more important for determining unexplained variation in our observations.

Correlated process errors

Let’s see if these estimates improve when we allow the process errors to be correlated. Once again, we need to first update the priors for the observation errors:

priors <- c(prior(normal(0.5, 0.1), class = sigma_obs, lb = 0.2),
            prior(normal(0.5, 0.25), class = sigma))

And now we can fit the correlated process error model

varcor_mod <- mvgam(  
  # observation formula, which remains empty
  y ~ -1,
  
  # process model formula, which includes the smooth functions
  trend_formula = ~ te(temp, month, k = c(4, 4)) +
    te(temp, month, k = c(4, 4), by = trend) - 1,
  
  # VAR1 model with correlated process errors
  trend_model = VAR(cor = TRUE),
  family = gaussian(),
  data = plankton_train,
  newdata = plankton_test,
  
  # include the updated priors
  priors = priors,
  silent = 2)

The (Σ) matrix now captures any evidence of contemporaneously correlated process error:

Sigma_pars <- matrix(NA, nrow = 5, ncol = 5)
for(i in 1:5){
  for(j in 1:5){
    Sigma_pars[i, j] <- paste0('Sigma[', i, ',', j, ']')
  }
}
mcmc_plot(varcor_mod, 
          variable = as.vector(t(Sigma_pars)), 
          type = 'hist')

This symmetric matrix tells us there is support for correlated process errors, as several of the off-diagonal entries are strongly non-zero. But it is easier to interpret these estimates if we convert the covariance matrix to a correlation matrix. Here we compute the posterior median process error correlations:

Sigma_post <- as.matrix(varcor_mod, variable = 'Sigma', regex = TRUE)
median_correlations <- cov2cor(matrix(apply(Sigma_post, 2, median),
                                      nrow = 5, ncol = 5))
rownames(median_correlations) <- colnames(median_correlations) <- levels(plankton_train$series)

round(median_correlations, 2)

Impulse response functions

Because Vector Autoregressions can capture complex lagged dependencies, it is often difficult to understand how the member time series are thought to interact with one another. A method that is commonly used to directly test for possible interactions is to compute an Impulse Response Function (IRF). If h represents the simulated forecast horizon, an IRF asks how each of the remaining series might respond over times (t + 1) : h if a focal series is given an innovation “shock” at time t = 0. mvgam can compute Generalized and Orthogonalized IRFs from models that included latent VAR dynamics. We simply feed the fitted model to the irf() function and then use the S3 plot() function to view the estimated responses. By default, irf() will compute IRFs by separately imposing positive shocks of one standard deviation to each series in the VAR process. Here we compute Generalized IRFs over a horizon of 12 timesteps:

irfs <- irf(varcor_mod, h = 12)

Plot the expected responses of the remaining series to a positive shock for series 3 (Greens)

plot(irfs, series = 3)

This series of plots makes it clear that some of the other series would be expected to show both instantaneous responses to a shock for the Greens (due to their correlated process errors) as well as delayed and nonlinear responses over time (due to the complex lagged dependence structure captured by the A matrix). This hopefully makes it clear why IRFs are an important tool in the analysis of multivariate autoregressive models.

Comparing forecast scores

But which model is better? We can compute the variogram score for out of sample forecasts to get a sense of which model does a better job of capturing the dependence structure in the true evaluation set:

# create forecast objects for each model
fcvar <- forecast(var_mod)
fcvarcor <- forecast(varcor_mod)

# plot the difference in variogram scores; a negative value means the VAR1cor model is better, while a positive value means the VAR1 model is better
diff_scores <- score(fcvarcor, score = 'variogram')$all_series$score -
  score(fcvar, score = 'variogram')$all_series$score
plot(diff_scores, pch = 16, cex = 1.25, col = 'darkred', 
     ylim = c(-1*max(abs(diff_scores), na.rm = TRUE),
              max(abs(diff_scores), na.rm = TRUE)),
     bty = 'l',
     xlab = 'Forecast horizon',
     ylab = expression(variogram[VAR1cor]~-~variogram[VAR1]))
abline(h = 0, lty = 'dashed')

And we can also compute the energy score for out of sample forecasts to get a sense of which model provides forecasts that are better calibrated:

# plot the difference in energy scores; a negative value means the VAR1cor model is better, while a positive value means the VAR1 model is better
diff_scores <- score(fcvarcor, score = 'energy')$all_series$score -
  score(fcvar, score = 'energy')$all_series$score
plot(diff_scores, pch = 16, cex = 1.25, col = 'darkred', 
     ylim = c(-1*max(abs(diff_scores), na.rm = TRUE),
              max(abs(diff_scores), na.rm = TRUE)),
     bty = 'l',
     xlab = 'Forecast horizon',
     ylab = expression(energy[VAR1cor]~-~energy[VAR1]))
abline(h = 0, lty = 'dashed')

The models tend to provide similar forecasts, though the correlated error model does slightly better overall. We would probably need to use a more extensive rolling forecast evaluation exercise if we felt like we needed to only choose one for production. mvgam offers some utilities for doing this (i.e. see ?lfo_cv for guidance). Alternatively, we could use forecasts from both models by creating an evenly-weighted ensemble forecast distribution. This capability is available using the ensemble() function in mvgam (see ?ensemble for guidance).

Further reading

The following papers and resources offer a lot of useful material about multivariate State-Space models and how they can be applied in practice:

Auger‐Méthé, Marie, et al. “A guide to state–space modeling of ecological time series.Ecological Monographs 91.4 (2021): e01470.

Heaps, Sarah E. “Enforcing stationarity through the prior in vector autoregressions.Journal of Computational and Graphical Statistics 32.1 (2023): 74-83.

Hannaford, Naomi E., et al. “A sparse Bayesian hierarchical vector autoregressive model for microbial dynamics in a wastewater treatment plant.Computational Statistics & Data Analysis 179 (2023): 107659.

Holmes, Elizabeth E., Eric J. Ward, and Wills Kellie. “MARSS: multivariate autoregressive state-space models for analyzing time-series data.R Journal. 4.1 (2012): 11.

Ward, Eric J., et al. “Inferring spatial structure from time‐series data: using multivariate state‐space models to detect metapopulation structure of California sea lions in the Gulf of California, Mexico.Journal of Applied Ecology 47.1 (2010): 47-56.

Interested in contributing?

I’m actively seeking PhD students and other researchers to work in the areas of ecological forecasting, multivariate model evaluation and development of mvgam. Please reach out if you are interested (n.clark’at’uq.edu.au)