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Thursday, November 7, 2024

Dynamic linear fashions with tfprobability


Welcome to the world of state area fashions. On this world, there’s a latent course of, hidden from our eyes; and there are observations we make in regards to the issues it produces. The method evolves on account of some hidden logic (transition mannequin); and the way in which it produces the observations follows some hidden logic (remark mannequin). There’s noise in course of evolution, and there may be noise in remark. If the transition and remark fashions each are linear, and the method in addition to remark noise are Gaussian, we now have a linear-Gaussian state area mannequin (SSM). The duty is to deduce the latent state from the observations. Essentially the most well-known approach is the Kálmán filter.

In sensible functions, two traits of linear-Gaussian SSMs are particularly engaging.

For one, they allow us to estimate dynamically altering parameters. In regression, the parameters could be seen as a hidden state; we might thus have a slope and an intercept that adjust over time. When parameters can fluctuate, we communicate of dynamic linear fashions (DLMs). That is the time period we’ll use all through this publish when referring to this class of fashions.

Second, linear-Gaussian SSMs are helpful in time-series forecasting as a result of Gaussian processes could be added. A time collection can thus be framed as, e.g. the sum of a linear pattern and a course of that varies seasonally.

Utilizing tfprobability, the R wrapper to TensorFlow Likelihood, we illustrate each elements right here. Our first instance might be on dynamic linear regression. In an in depth walkthrough, we present on how one can match such a mannequin, how one can get hold of filtered, in addition to smoothed, estimates of the coefficients, and how one can get hold of forecasts.
Our second instance then illustrates course of additivity. This instance will construct on the primary, and might also function a fast recap of the general process.

Let’s bounce in.

Dynamic linear regression instance: Capital Asset Pricing Mannequin (CAPM)

Our code builds on the just lately launched variations of TensorFlow and TensorFlow Likelihood: 1.14 and 0.7, respectively.

Be aware how there’s one factor we used to do recently that we’re not doing right here: We’re not enabling keen execution. We are saying why in a minute.

Our instance is taken from Petris et al.(2009)(Petris, Petrone, and Campagnoli 2009), chapter 3.2.7.
Moreover introducing the dlm bundle, this e book supplies a pleasant introduction to the concepts behind DLMs basically.

As an example dynamic linear regression, the authors function a dataset, initially from Berndt(1991)(Berndt 1991) that has month-to-month returns, collected from January 1978 to December 1987, for 4 totally different shares, the 30-day Treasury Invoice – standing in for a risk-free asset –, and the value-weighted common returns for all shares listed on the New York and American Inventory Exchanges, representing the general market returns.

Let’s have a look.

# As the info doesn't appear to be obtainable on the tackle given in Petris et al. any extra,
# we put it on the weblog for obtain
# obtain from: 
# https://github.com/rstudio/tensorflow-blog/blob/grasp/docs/posts/2019-06-25-dynamic_linear_models_tfprobability/information/capm.txt"
df <- read_table(
  "capm.txt",
  col_types = listing(X1 = col_date(format = "%Y.%m"))) %>%
  rename(month = X1)
df %>% glimpse()
Observations: 120
Variables: 7
$ month  <date> 1978-01-01, 1978-02-01, 1978-03-01, 1978-04-01, 1978-05-01, 19…
$ MOBIL  <dbl> -0.046, -0.017, 0.049, 0.077, -0.011, -0.043, 0.028, 0.056, 0.0…
$ IBM    <dbl> -0.029, -0.043, -0.063, 0.130, -0.018, -0.004, 0.092, 0.049, -0…
$ WEYER  <dbl> -0.116, -0.135, 0.084, 0.144, -0.031, 0.005, 0.164, 0.039, -0.0…
$ CITCRP <dbl> -0.115, -0.019, 0.059, 0.127, 0.005, 0.007, 0.032, 0.088, 0.011…
$ MARKET <dbl> -0.045, 0.010, 0.050, 0.063, 0.067, 0.007, 0.071, 0.079, 0.002,…
$ RKFREE <dbl> 0.00487, 0.00494, 0.00526, 0.00491, 0.00513, 0.00527, 0.00528, …
df %>% collect(key = "image", worth = "return", -month) %>%
  ggplot(aes(x = month, y = return, coloration = image)) +
  geom_line() +
  facet_grid(rows = vars(image), scales = "free")

Monthly returns for selected stocks; data from Berndt (1991).

Determine 1: Month-to-month returns for chosen shares; information from Berndt (1991).

The Capital Asset Pricing Mannequin then assumes a linear relationship between the surplus returns of an asset underneath examine and the surplus returns of the market. For each, extra returns are obtained by subtracting the returns of the chosen risk-free asset; then, the scaling coefficient between them reveals the asset to both be an “aggressive” funding (slope > 1: modifications available in the market are amplified), or a conservative one (slope < 1: modifications are damped).

Assuming this relationship doesn’t change over time, we are able to simply use lm as an example this. Following Petris et al. in zooming in on IBM because the asset underneath examine, we now have

# extra returns of the asset underneath examine
ibm <- df$IBM - df$RKFREE
# market extra returns
x <- df$MARKET - df$RKFREE

match <- lm(ibm ~ x)
abstract(match)
Name:
lm(components = ibm ~ x)

Residuals:
     Min       1Q   Median       3Q      Max 
-0.11850 -0.03327 -0.00263  0.03332  0.15042 

Coefficients:
              Estimate Std. Error t worth Pr(>|t|)    
(Intercept) -0.0004896  0.0046400  -0.106    0.916    
x            0.4568208  0.0675477   6.763 5.49e-10 ***
---
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1

Residual commonplace error: 0.05055 on 118 levels of freedom
A number of R-squared:  0.2793,    Adjusted R-squared:  0.2732 
F-statistic: 45.74 on 1 and 118 DF,  p-value: 5.489e-10

So IBM is discovered to be a conservative funding, the slope being ~ 0.5. However is that this relationship secure over time?

Let’s flip to tfprobability to research.

We wish to use this instance to reveal two important functions of DLMs: acquiring smoothing and/or filtering estimates of the coefficients, in addition to forecasting future values. So in contrast to Petris et al., we divide the dataset right into a coaching and a testing half:.

# zoom in on ibm
ts <- ibm %>% matrix()
# forecast 12 months
n_forecast_steps <- 12
ts_train <- ts[1:(length(ts) - n_forecast_steps), 1, drop = FALSE]

# be certain we work with float32 right here
ts_train <- tf$solid(ts_train, tf$float32)
ts <- tf$solid(ts, tf$float32)

We now assemble the mannequin. sts_dynamic_linear_regression() does what we wish:

# outline the mannequin on the entire collection
linreg <- ts %>%
  sts_dynamic_linear_regression(
    design_matrix = cbind(rep(1, size(x)), x) %>% tf$solid(tf$float32)
  )

We move it the column of extra market returns, plus a column of ones, following Petris et al.. Alternatively, we may heart the one predictor – this is able to work simply as properly.

How are we going to coach this mannequin? Technique-wise, we now have a alternative between variational inference (VI) and Hamiltonian Monte Carlo (HMC). We’ll see each. The second query is: Are we going to make use of graph mode or keen mode? As of at this time, for each VI and HMC, it’s most secure – and quickest – to run in graph mode, so that is the one approach we present. In a couple of weeks, or months, we must always be capable to prune a whole lot of sess$run()s from the code!

Usually in posts, when presenting code we optimize for straightforward experimentation (that means: line-by-line executability), not modularity. This time although, with an vital variety of analysis statements concerned, it’s best to pack not simply the becoming, however the smoothing and forecasting as properly right into a perform (which you might nonetheless step by if you happen to wished). For VI, we’ll have a match _with_vi perform that does all of it. So once we now begin explaining what it does, don’t sort within the code simply but – it’ll all reappear properly packed into that perform, so that you can copy and execute as an entire.

Becoming a time collection with variational inference

Becoming with VI just about appears to be like like coaching historically used to look in graph-mode TensorFlow. You outline a loss – right here it’s executed utilizing sts_build_factored_variational_loss() –, an optimizer, and an operation for the optimizer to cut back that loss:

optimizer <- tf$compat$v1$practice$AdamOptimizer(0.1)

# solely practice on the coaching set!    
loss_and_dists <- ts_train %>% sts_build_factored_variational_loss(mannequin = mannequin)
variational_loss <- loss_and_dists[[1]]

train_op <- optimizer$reduce(variational_loss)

Be aware how the loss is outlined on the coaching set solely, not the entire collection.

Now to truly practice the mannequin, we create a session and run that operation:

 with (tf$Session() %as% sess,  {
      
      sess$run(tf$compat$v1$global_variables_initializer())
   
      for (step in 1:n_iterations) {
        res <- sess$run(train_op)
        loss <- sess$run(variational_loss)
        if (step %% 10 == 0)
          cat("Loss: ", as.numeric(loss), "n")
      }
 })

Given we now have that session, let’s make use of it and compute all of the estimates we want.
Once more, – the next snippets will find yourself within the fit_with_vi perform, so don’t run them in isolation simply but.

Acquiring forecasts

The very first thing we wish for the mannequin to provide us are forecasts. In an effort to create them, it wants samples from the posterior. Fortunately we have already got the posterior distributions, returned from sts_build_factored_variational_loss, so let’s pattern from them and move them to sts_forecast:

variational_distributions <- loss_and_dists[[2]]
posterior_samples <-
  Map(
    perform(d) d %>% tfd_sample(n_param_samples),
    variational_distributions %>% reticulate::py_to_r() %>% unname()
  )
forecast_dists <- ts_train %>% sts_forecast(mannequin, posterior_samples, n_forecast_steps)

sts_forecast() returns distributions, so we name tfd_mean() to get the posterior predictions and tfd_stddev() for the corresponding commonplace deviations:

fc_means <- forecast_dists %>% tfd_mean()
fc_sds <- forecast_dists %>% tfd_stddev()

By the way in which – as we now have the total posterior distributions, we’re on no account restricted to abstract statistics! We may simply use tfd_sample() to acquire particular person forecasts.

Smoothing and filtering (Kálmán filter)

Now, the second (and final, for this instance) factor we are going to need are the smoothed and filtered regression coefficients. The well-known Kálmán Filter is a Bayesian-in-spirit technique the place at every time step, predictions are corrected by how a lot they differ from an incoming remark. Filtering estimates are primarily based on observations we’ve seen to date; smoothing estimates are computed “in hindsight,” making use of the entire time collection.

We first create a state area mannequin from our time collection definition:

# solely do that on the coaching set
# returns an occasion of tfd_linear_gaussian_state_space_model()
ssm <- mannequin$make_state_space_model(size(ts_train), param_vals = posterior_samples)

tfd_linear_gaussian_state_space_model(), technically a distribution, supplies the Kálmán filter functionalities of smoothing and filtering.

To acquire the smoothed estimates:

c(smoothed_means, smoothed_covs) %<-% ssm$posterior_marginals(ts_train)

And the filtered ones:

c(., filtered_means, filtered_covs, ., ., ., .) %<-% ssm$forward_filter(ts_train)

Lastly, we have to consider all these.

c(posterior_samples, fc_means, fc_sds, smoothed_means, smoothed_covs, filtered_means, filtered_covs) %<-%
  sess$run(listing(posterior_samples, fc_means, fc_sds, smoothed_means, smoothed_covs, filtered_means, filtered_covs))

Placing all of it collectively (the VI version)

So right here’s the entire perform, fit_with_vi, prepared for us to name.

fit_with_vi <-
  perform(ts,
           ts_train,
           mannequin,
           n_iterations,
           n_param_samples,
           n_forecast_steps,
           n_forecast_samples) {
    
    optimizer <- tf$compat$v1$practice$AdamOptimizer(0.1)
    
    loss_and_dists <-
      ts_train %>% sts_build_factored_variational_loss(mannequin = mannequin)
    variational_loss <- loss_and_dists[[1]]
    train_op <- optimizer$reduce(variational_loss)
    
    with (tf$Session() %as% sess,  {
      
      sess$run(tf$compat$v1$global_variables_initializer())
      for (step in 1:n_iterations) {
        sess$run(train_op)
        loss <- sess$run(variational_loss)
        if (step %% 1 == 0)
          cat("Loss: ", as.numeric(loss), "n")
      }
      variational_distributions <- loss_and_dists[[2]]
      posterior_samples <-
        Map(
          perform(d)
            d %>% tfd_sample(n_param_samples),
          variational_distributions %>% reticulate::py_to_r() %>% unname()
        )
      forecast_dists <-
        ts_train %>% sts_forecast(mannequin, posterior_samples, n_forecast_steps)
      fc_means <- forecast_dists %>% tfd_mean()
      fc_sds <- forecast_dists %>% tfd_stddev()
      
      ssm <- mannequin$make_state_space_model(size(ts_train), param_vals = posterior_samples)
      c(smoothed_means, smoothed_covs) %<-% ssm$posterior_marginals(ts_train)
      c(., filtered_means, filtered_covs, ., ., ., .) %<-% ssm$forward_filter(ts_train)
   
      c(posterior_samples, fc_means, fc_sds, smoothed_means, smoothed_covs, filtered_means, filtered_covs) %<-%
        sess$run(listing(posterior_samples, fc_means, fc_sds, smoothed_means, smoothed_covs, filtered_means, filtered_covs))
      
    })
    
    listing(
      variational_distributions,
      posterior_samples,
      fc_means[, 1],
      fc_sds[, 1],
      smoothed_means,
      smoothed_covs,
      filtered_means,
      filtered_covs
    )
  }

And that is how we name it.

# variety of VI steps
n_iterations <- 300
# pattern dimension for posterior samples
n_param_samples <- 50
# pattern dimension to attract from the forecast distribution
n_forecast_samples <- 50

# this is the mannequin once more
mannequin <- ts %>%
  sts_dynamic_linear_regression(design_matrix = cbind(rep(1, size(x)), x) %>% tf$solid(tf$float32))

# name fit_vi outlined above
c(
  param_distributions,
  param_samples,
  fc_means,
  fc_sds,
  smoothed_means,
  smoothed_covs,
  filtered_means,
  filtered_covs
) %<-% fit_vi(
  ts,
  ts_train,
  mannequin,
  n_iterations,
  n_param_samples,
  n_forecast_steps,
  n_forecast_samples
)

Curious in regards to the outcomes? We’ll see them in a second, however earlier than let’s simply rapidly look on the various coaching technique: HMC.

Placing all of it collectively (the HMC version)

tfprobability supplies sts_fit_with_hmc to suit a DLM utilizing Hamiltonian Monte Carlo. Latest posts (e.g., Hierarchical partial pooling, continued: Various slopes fashions with TensorFlow Likelihood) confirmed how one can arrange HMC to suit hierarchical fashions; right here a single perform does all of it.

Right here is fit_with_hmc, wrapping sts_fit_with_hmc in addition to the (unchanged) methods for acquiring forecasts and smoothed/filtered parameters:

num_results <- 200
num_warmup_steps <- 100

fit_hmc <- perform(ts,
                    ts_train,
                    mannequin,
                    num_results,
                    num_warmup_steps,
                    n_forecast,
                    n_forecast_samples) {
  
  states_and_results <-
    ts_train %>% sts_fit_with_hmc(
      mannequin,
      num_results = num_results,
      num_warmup_steps = num_warmup_steps,
      num_variational_steps = num_results + num_warmup_steps
    )
  
  posterior_samples <- states_and_results[[1]]
  forecast_dists <-
    ts_train %>% sts_forecast(mannequin, posterior_samples, n_forecast_steps)
  fc_means <- forecast_dists %>% tfd_mean()
  fc_sds <- forecast_dists %>% tfd_stddev()
  
  ssm <-
    mannequin$make_state_space_model(size(ts_train), param_vals = posterior_samples)
  c(smoothed_means, smoothed_covs) %<-% ssm$posterior_marginals(ts_train)
  c(., filtered_means, filtered_covs, ., ., ., .) %<-% ssm$forward_filter(ts_train)
  
  with (tf$Session() %as% sess,  {
    sess$run(tf$compat$v1$global_variables_initializer())
    c(
      posterior_samples,
      fc_means,
      fc_sds,
      smoothed_means,
      smoothed_covs,
      filtered_means,
      filtered_covs
    ) %<-%
      sess$run(
        listing(
          posterior_samples,
          fc_means,
          fc_sds,
          smoothed_means,
          smoothed_covs,
          filtered_means,
          filtered_covs
        )
      )
  })
  
  listing(
    posterior_samples,
    fc_means[, 1],
    fc_sds[, 1],
    smoothed_means,
    smoothed_covs,
    filtered_means,
    filtered_covs
  )
}

c(
  param_samples,
  fc_means,
  fc_sds,
  smoothed_means,
  smoothed_covs,
  filtered_means,
  filtered_covs
) %<-% fit_hmc(ts,
               ts_train,
               mannequin,
               num_results,
               num_warmup_steps,
               n_forecast,
               n_forecast_samples)

Now lastly, let’s check out the forecasts and filtering resp. smoothing estimates.

Forecasts

Placing all we’d like into one dataframe, we now have

smoothed_means_intercept <- smoothed_means[, , 1] %>% colMeans()
smoothed_means_slope <- smoothed_means[, , 2] %>% colMeans()

smoothed_sds_intercept <- smoothed_covs[, , 1, 1] %>% colMeans() %>% sqrt()
smoothed_sds_slope <- smoothed_covs[, , 2, 2] %>% colMeans() %>% sqrt()

filtered_means_intercept <- filtered_means[, , 1] %>% colMeans()
filtered_means_slope <- filtered_means[, , 2] %>% colMeans()

filtered_sds_intercept <- filtered_covs[, , 1, 1] %>% colMeans() %>% sqrt()
filtered_sds_slope <- filtered_covs[, , 2, 2] %>% colMeans() %>% sqrt()

forecast_df <- df %>%
  choose(month, IBM) %>%
  add_column(pred_mean = c(rep(NA, size(ts_train)), fc_means)) %>%
  add_column(pred_sd = c(rep(NA, size(ts_train)), fc_sds)) %>%
  add_column(smoothed_means_intercept = c(smoothed_means_intercept, rep(NA, n_forecast_steps))) %>%
  add_column(smoothed_means_slope = c(smoothed_means_slope, rep(NA, n_forecast_steps))) %>%
  add_column(smoothed_sds_intercept = c(smoothed_sds_intercept, rep(NA, n_forecast_steps))) %>%
  add_column(smoothed_sds_slope = c(smoothed_sds_slope, rep(NA, n_forecast_steps))) %>%
  add_column(filtered_means_intercept = c(filtered_means_intercept, rep(NA, n_forecast_steps))) %>%
  add_column(filtered_means_slope = c(filtered_means_slope, rep(NA, n_forecast_steps))) %>%
  add_column(filtered_sds_intercept = c(filtered_sds_intercept, rep(NA, n_forecast_steps))) %>%
  add_column(filtered_sds_slope = c(filtered_sds_slope, rep(NA, n_forecast_steps)))

So right here first are the forecasts. We’re utilizing the estimates returned from VI, however we may simply as properly have used these from HMC – they’re practically indistinguishable. The identical goes for the filtering and smoothing estimates displayed under.

ggplot(forecast_df, aes(x = month, y = IBM)) +
  geom_line(coloration = "gray") +
  geom_line(aes(y = pred_mean), coloration = "cyan") +
  geom_ribbon(
    aes(ymin = pred_mean - 2 * pred_sd, ymax = pred_mean + 2 * pred_sd),
    alpha = 0.2,
    fill = "cyan"
  ) +
  theme(axis.title = element_blank())

12-point-ahead forecasts for IBM; posterior means +/- 2 standard deviations.

Determine 2: 12-point-ahead forecasts for IBM; posterior means +/- 2 commonplace deviations.

Smoothing estimates

Listed here are the smoothing estimates. The intercept (proven in orange) stays fairly secure over time, however we do see a pattern within the slope (displayed in inexperienced).

ggplot(forecast_df, aes(x = month, y = smoothed_means_intercept)) +
  geom_line(coloration = "orange") +
  geom_line(aes(y = smoothed_means_slope),
            coloration = "inexperienced") +
  geom_ribbon(
    aes(
      ymin = smoothed_means_intercept - 2 * smoothed_sds_intercept,
      ymax = smoothed_means_intercept + 2 * smoothed_sds_intercept
    ),
    alpha = 0.3,
    fill = "orange"
  ) +
  geom_ribbon(
    aes(
      ymin = smoothed_means_slope - 2 * smoothed_sds_slope,
      ymax = smoothed_means_slope + 2 * smoothed_sds_slope
    ),
    alpha = 0.1,
    fill = "inexperienced"
  ) +
  coord_cartesian(xlim = c(forecast_df$month[1], forecast_df$month[length(ts) - n_forecast_steps]))  +
  theme(axis.title = element_blank())

Smoothing estimates from the Kálmán filter. Green: coefficient for dependence on excess market returns (slope), orange: vector of ones (intercept).

Determine 3: Smoothing estimates from the Kálmán filter. Inexperienced: coefficient for dependence on extra market returns (slope), orange: vector of ones (intercept).

Filtering estimates

For comparability, listed here are the filtering estimates. Be aware that the y-axis extends additional up and down, so we are able to seize uncertainty higher:

ggplot(forecast_df, aes(x = month, y = filtered_means_intercept)) +
  geom_line(coloration = "orange") +
  geom_line(aes(y = filtered_means_slope),
            coloration = "inexperienced") +
  geom_ribbon(
    aes(
      ymin = filtered_means_intercept - 2 * filtered_sds_intercept,
      ymax = filtered_means_intercept + 2 * filtered_sds_intercept
    ),
    alpha = 0.3,
    fill = "orange"
  ) +
  geom_ribbon(
    aes(
      ymin = filtered_means_slope - 2 * filtered_sds_slope,
      ymax = filtered_means_slope + 2 * filtered_sds_slope
    ),
    alpha = 0.1,
    fill = "inexperienced"
  ) +
  coord_cartesian(ylim = c(-2, 2),
                  xlim = c(forecast_df$month[1], forecast_df$month[length(ts) - n_forecast_steps])) +
  theme(axis.title = element_blank())

Filtering estimates from the Kálmán filter. Green: coefficient for dependence on excess market returns (slope), orange: vector of ones (intercept).

Determine 4: Filtering estimates from the Kálmán filter. Inexperienced: coefficient for dependence on extra market returns (slope), orange: vector of ones (intercept).

Thus far, we’ve seen a full instance of time-series becoming, forecasting, and smoothing/filtering, in an thrilling setting one doesn’t encounter too typically: dynamic linear regression. What we haven’t seen as but is the additivity function of DLMs, and the way it permits us to decompose a time collection into its (theorized) constituents.
Let’s do that subsequent, in our second instance, anti-climactically making use of the iris of time collection, AirPassengers. Any guesses what parts the mannequin may presuppose?


AirPassengers.

Determine 5: AirPassengers.

Composition instance: AirPassengers

Libraries loaded, we put together the info for tfprobability:

The mannequin is a sum – cf. sts_sum – of a linear pattern and a seasonal element:

linear_trend <- ts %>% sts_local_linear_trend()
month-to-month <- ts %>% sts_seasonal(num_seasons = 12)
mannequin <- ts %>% sts_sum(parts = listing(month-to-month, linear_trend))

Once more, we may use VI in addition to MCMC to coach the mannequin. Right here’s the VI means:

n_iterations <- 100
n_param_samples <- 50
n_forecast_samples <- 50

optimizer <- tf$compat$v1$practice$AdamOptimizer(0.1)

fit_vi <-
  perform(ts,
           ts_train,
           mannequin,
           n_iterations,
           n_param_samples,
           n_forecast_steps,
           n_forecast_samples) {
    loss_and_dists <-
      ts_train %>% sts_build_factored_variational_loss(mannequin = mannequin)
    variational_loss <- loss_and_dists[[1]]
    train_op <- optimizer$reduce(variational_loss)
    
    with (tf$Session() %as% sess,  {
      sess$run(tf$compat$v1$global_variables_initializer())
      for (step in 1:n_iterations) {
        res <- sess$run(train_op)
        loss <- sess$run(variational_loss)
        if (step %% 1 == 0)
          cat("Loss: ", as.numeric(loss), "n")
      }
      variational_distributions <- loss_and_dists[[2]]
      posterior_samples <-
        Map(
          perform(d)
            d %>% tfd_sample(n_param_samples),
          variational_distributions %>% reticulate::py_to_r() %>% unname()
        )
      forecast_dists <-
        ts_train %>% sts_forecast(mannequin, posterior_samples, n_forecast_steps)
      fc_means <- forecast_dists %>% tfd_mean()
      fc_sds <- forecast_dists %>% tfd_stddev()
      
      c(posterior_samples,
        fc_means,
        fc_sds) %<-%
        sess$run(listing(posterior_samples,
                      fc_means,
                      fc_sds))
    })
    
    listing(variational_distributions,
         posterior_samples,
         fc_means[, 1],
         fc_sds[, 1])
  }

c(param_distributions,
  param_samples,
  fc_means,
  fc_sds) %<-% fit_vi(
    ts,
    ts_train,
    mannequin,
    n_iterations,
    n_param_samples,
    n_forecast_steps,
    n_forecast_samples
  )

For brevity, we haven’t computed smoothed and/or filtered estimates for the general mannequin. On this instance, this being a sum mannequin, we wish to present one thing else as a substitute: the way in which it decomposes into parts.

However first, the forecasts:

forecast_df <- df %>%
  add_column(pred_mean = c(rep(NA, size(ts_train)), fc_means)) %>%
  add_column(pred_sd = c(rep(NA, size(ts_train)), fc_sds))


ggplot(forecast_df, aes(x = month, y = n)) +
  geom_line(coloration = "gray") +
  geom_line(aes(y = pred_mean), coloration = "cyan") +
  geom_ribbon(
    aes(ymin = pred_mean - 2 * pred_sd, ymax = pred_mean + 2 * pred_sd),
    alpha = 0.2,
    fill = "cyan"
  ) +
  theme(axis.title = element_blank())

AirPassengers, 12-months-ahead forecast.

Determine 6: AirPassengers, 12-months-ahead forecast.

A name to sts_decompose_by_component yields the (centered) parts, a linear pattern and a seasonal issue:

component_dists <-
  ts_train %>% sts_decompose_by_component(mannequin = mannequin, parameter_samples = param_samples)

seasonal_effect_means <- component_dists[[1]] %>% tfd_mean()
seasonal_effect_sds <- component_dists[[1]] %>% tfd_stddev()
linear_effect_means <- component_dists[[2]] %>% tfd_mean()
linear_effect_sds <- component_dists[[2]] %>% tfd_stddev()

with(tf$Session() %as% sess, {
  c(
    seasonal_effect_means,
    seasonal_effect_sds,
    linear_effect_means,
    linear_effect_sds
  ) %<-% sess$run(
    listing(
      seasonal_effect_means,
      seasonal_effect_sds,
      linear_effect_means,
      linear_effect_sds
    )
  )
})

components_df <- forecast_df %>%
  add_column(seasonal_effect_means = c(seasonal_effect_means, rep(NA, n_forecast_steps))) %>%
  add_column(seasonal_effect_sds = c(seasonal_effect_sds, rep(NA, n_forecast_steps))) %>%
  add_column(linear_effect_means = c(linear_effect_means, rep(NA, n_forecast_steps))) %>%
  add_column(linear_effect_sds = c(linear_effect_sds, rep(NA, n_forecast_steps)))

ggplot(components_df, aes(x = month, y = n)) +
  geom_line(aes(y = seasonal_effect_means), coloration = "orange") +
  geom_ribbon(
    aes(
      ymin = seasonal_effect_means - 2 * seasonal_effect_sds,
      ymax = seasonal_effect_means + 2 * seasonal_effect_sds
    ),
    alpha = 0.2,
    fill = "orange"
  ) +
  theme(axis.title = element_blank()) +
  geom_line(aes(y = linear_effect_means), coloration = "inexperienced") +
  geom_ribbon(
    aes(
      ymin = linear_effect_means - 2 * linear_effect_sds,
      ymax = linear_effect_means + 2 * linear_effect_sds
    ),
    alpha = 0.2,
    fill = "inexperienced"
  ) +
  theme(axis.title = element_blank())

AirPassengers, decomposition into a linear trend and a seasonal component (both centered).

Determine 7: AirPassengers, decomposition right into a linear pattern and a seasonal element (each centered).

Wrapping up

We’ve seen how with DLMs, there’s a bunch of fascinating stuff you are able to do – aside from acquiring forecasts, which in all probability would be the final aim in most functions – : You’ll be able to examine the smoothed and the filtered estimates from the Kálmán filter, and you’ll decompose a mannequin into its posterior parts. A very engaging mannequin is dynamic linear regression, featured in our first instance, which permits us to acquire regression coefficients that adjust over time.

This publish confirmed how one can accomplish this with tfprobability. As of at this time, TensorFlow (and thus, TensorFlow Likelihood) is in a state of considerable inner modifications, with desirous to turn into the default execution mode very quickly. Concurrently, the superior TensorFlow Likelihood improvement workforce are including new and thrilling options daily. Consequently, this publish is snapshot capturing how one can greatest accomplish these targets now: If you happen to’re studying this a couple of months from now, chances are high that what’s work in progress now may have turn into a mature technique by then, and there could also be sooner methods to realize the identical targets. On the charge TFP is evolving, we’re excited for the issues to return!

Berndt, R. 1991. The Observe of Econometrics. Addison-Wesley.

Murphy, Kevin. 2012. Machine Studying: A Probabilistic Perspective. MIT Press.

Petris, Giovanni, sonia Petrone, and Patrizia Campagnoli. 2009. Dynamic Linear Fashions with r. Springer.

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