Spawning & Random effects

This vignette walks through a script that will generate a gadget3 model, explaining concepts along the way.

Spawning

In vignette("introduction-single-stock") we introduced g3a_renewal_normalparam() as a means of adding recruitment into the model.

An alternative action is g3a_spawn(). The main difference here is the existing state of the stock is used to inform the rate of recruitment.

To improve our model fit, we shall define the rate of spawning using a random walk.

Firstly, we define our immature stock. There’s no real difference here, apart from g3a_renewal_normalparam() no longer being present:

actions_st_imm <- list(
  g3a_growmature(st_imm,
    g3a_grow_impl_bbinom(
      maxlengthgroupgrowth = 4L ),
    # Add maturation
    maturity_f = g3a_mature_continuous(),
    output_stocks = list(st_mat),
    transition_f = ~TRUE ),
  g3a_naturalmortality(st_imm),
  g3a_initialconditions_normalcv(st_imm),
  # NB: g3a_renewal_normalparam() no longer here
  g3a_age(st_imm, output_stocks = list(st_mat)),
  NULL)
actions <- c(actions, actions_st_imm)

Next, we need to define the set of parameters that will constitute our random walk:

# Configure our random walk for mu
st_spawn_mu <- g3_parameterized('spawn_mu',
    by_year = TRUE,
    scale = g3_parameterized('spawn_mu_seasonal', by_step = TRUE, value = 1, optimise = FALSE),
    random = TRUE)

As we saw in vignette('multiple-substocks'), by_year will give us a series of parameters for spawn_mu, one per year. random = TRUE will ensure that these parameters have TRUE in the random column in the parameter template.

The scale parameter adds seasonal variation parameters, spawn_mu_seasonal.1..spawn_mu_seasonal.4, which can be used to control when spawning happens.

We store this as a separate variable as we need to use it in 2 places. First, when we configure our spawning action:

actions_st_mat <- list(
  g3a_growmature(st_mat,
    g3a_grow_impl_bbinom(
      maxlengthgroupgrowth = 4L )),
  g3a_naturalmortality(st_mat),
  g3a_initialconditions_normalcv(st_mat),
  g3a_spawn(
      st_mat,
      recruitment_f = g3a_spawn_recruitment_bevertonholt(
          mu = st_spawn_mu,
          lambda = g3_parameterized("spawn_lambda", by_stock = TRUE) ),
      proportion_f = g3_suitability_exponentiall50(),
      output_stocks = list(st_imm) ),
  g3a_age(st_mat),
  NULL)
actions <- c(actions, actions_st_mat)

Mature stocks spawn, their output going into the immature stock. We use suitability functions to define proportion_f, the proportion of stock ready to spawn, by_step meaning this proportion is seasonal. Our random walk is used as the rate of recruitment, mu.

Next we use a likelihood action to constrain the values in the random walk during optimisation:

actions_likelihood_st <- list(
  g3l_understocking(stocks, nll_breakdown = TRUE),
  g3l_random_walk('rwalk_st_spawn_mu',
      param_f = st_spawn_mu,
      sigma_f = g3_parameterized('spawn_mu.sigma', value = 5, optimise = FALSE),
      log_f = FALSE ),
  g3l_random_dnorm('rwalk_st_spawn_mu',
      param_f = st_spawn_mu,
      mean_f = g3_parameterized('spawn_mu.mean', value = 78, optimise = FALSE),
      sigma_f = g3_parameterized('spawn_mu.sigma', value = 1, optimise = FALSE),
      log_f = FALSE ),
  NULL)
actions <- c(actions, actions_likelihood_st)

For random effects to be useful, they have to be constrained to sensible bounds. There are 2 likelihood actions that help with this, g3l_random_dnorm() & g3l_random_walk(). The former penalises random values that stray outside given normal distribution, the latter constrains along a random walk; the current year’s value should not vary significantly from the previous.

# Fleet data for f_surv #################################

# Landings data: For each year/step/area
expand.grid(year = 1980:2000, step = 2, area = 'IXa') |>
    # Generate a random total landings by weight
    mutate(weight = rnorm(n(), mean = 1000, sd = 100)) |>
    # Assign result to landings_f_surv
    identity() -> landings_f_surv

# Length distribution data: Generate 100 random samples in each year/step/area
expand.grid(year = 1980:2000, step = 2, area = 'IXa', length = rep(NA, 100)) |>
  # Generate random lengths for these samples
  mutate(length = rnorm(n(), mean = 50, sd = 20)) |>
  # Save unagggregated data into ldist_f_surv.raw
  identity() -> ldist_f_surv.raw

# Aggregate .raw data
ldist_f_surv.raw |>
  # Group into length bins
  group_by(
      year = year,
      step = step,
      length = cut(length, breaks = c(seq(0, 80, 20), Inf), right = FALSE) ) |>
  # Report count in each length bin
  summarise(number = n(), .groups = 'keep') |>
  # Save into ldist_f_surv
  identity() -> ldist_f_surv

# Assume 5 * 5 samples in each year/step/area
expand.grid(year = 1980:2000, step = 2, area = 'IXa', age = rep(NA, 5), length = rep(NA, 5)) |>
  # Generate random lengths/ages for these samples
  mutate(length = rnorm(n(), mean = 50, sd = 20)) |>
  # Generate random whole numbers for age
  mutate(age = floor(runif(n(), min = 1, max = 5))) |>
  # Group into length/age bins
  group_by(
      year = year,
      step = step,
      age = age,
      length = cut(length, breaks = c(seq(0, 80, 20), Inf), right = FALSE) ) |>
  # Report count in each length bin
  summarise(number = n(), .groups = 'keep') ->
  aldist_f_surv

# Create fleet definition for f_surv ####################
f_surv <- g3_fleet("f_surv") |> g3s_livesonareas(area_names["IXa"])

actions_f_surv <- list(
  g3a_predate_fleet(
    f_surv,
    stocks,
    suitabilities = g3_suitability_exponentiall50(by_stock = 'species'),
    catchability_f = g3a_predate_catchability_totalfleet(
      g3_timeareadata("landings_f_surv", landings_f_surv, "weight", areas = area_names))),
  NULL)
actions_likelihood_f_surv <- list(
  g3l_catchdistribution(
    "ldist_f_surv",
    obs_data = ldist_f_surv,
    fleets = list(f_surv),
    stocks = stocks,
    function_f = g3l_distribution_sumofsquares(),
    area_group = area_names,
    report = TRUE,
    nll_breakdown = TRUE),
  g3l_catchdistribution(
    "aldist_f_surv",
    obs_data = aldist_f_surv,
    fleets = list(f_surv),
    stocks = stocks,
    function_f = g3l_distribution_sumofsquares(),
    area_group = area_names,
    report = TRUE,
    nll_breakdown = TRUE),
  NULL)

actions <- c(actions, actions_f_surv, actions_likelihood_f_surv)

# Create abundance index for si_cpue ########################

# Generate random data
expand.grid(year = 1980:2000, step = 3, area = 'IXa') |>
    # Fill in a weight column with total biomass for the year/step/area combination
    mutate(weight = runif(n(), min = 10000, max = 100000)) ->
    dist_si_cpue

actions_likelihood_si_cpue <- list(

  g3l_abundancedistribution(
    "dist_si_cpue",
    dist_si_cpue,

    stocks = stocks,
    function_f = g3l_distribution_surveyindices_log(alpha = NULL, beta = 1),
    area_group = area_names,
    report = TRUE,
    nll_breakdown = TRUE),
  NULL)

actions <- c(actions, actions_likelihood_si_cpue)

Creating model functions and Parameterization

At this point, we are ready to convert our model into code:

# Create model objective function ####################

model_code <- g3_to_tmb(c(actions, list(
    g3a_report_detail(actions),
    g3l_bounds_penalty(actions) )))

# Guess l50 / linf based on stock sizes
estimate_l50 <- g3_stock_def(st_imm, "midlen")[[length(g3_stock_def(st_imm, "midlen")) / 2]]
estimate_linf <- max(g3_stock_def(st_imm, "midlen"))
estimate_t0 <- g3_stock_def(st_imm, "minage") - 0.8

attr(model_code, "parameter_template") |>
  g3_init_val("*.rec|init.scalar", 10, lower = 0.001, upper = 200) |>
  g3_init_val("*.init.#", 10, lower = 0.001, upper = 200) |>
  g3_init_val("*.M.#", 0.15, lower = 0.001, upper = 1) |>
  g3_init_val("init.F", 0.5, lower = 0.1, upper = 1) |>
  g3_init_val("*.Linf", estimate_linf, spread = 0.2) |>
  g3_init_val("*.K", 0.3, lower = 0.04, upper = 1.2) |>
  g3_init_val("*.t0", estimate_t0, spread = 2) |>
  g3_init_val("*.walpha", 0.01, optimise = FALSE) |>
  g3_init_val("*.wbeta", 3, optimise = FALSE) |>
  g3_init_val("*.*.alpha", 0.07, lower = 0.01, upper = 0.2) |>
  g3_init_val("*.*.l50", estimate_l50, spread = 0.25) |>
  g3_init_val("*.bbin", 100, lower = 1e-05, upper = 1000) |>

  g3_init_val("spawn_mu.#", value = 78) |>
  #g3_init_val("spawn_mu.1980", value = 78, random = FALSE) |>
  #g3_init_val("spawn_lambda", value = 1e-6, optimise = TRUE) |>

  identity() -> params.in

# Uncomment this to temporarily disable random effects
#params.in[params.in$random, 'optimise'] <- TRUE
#params.in[params.in$random, 'random'] <- FALSE

Finally we are ready for optimisation runs. g3_tmb_adfun() is a wrapper around TMB::MakeADFun() and TMB::compile, producing a TMB objective function. gadgetutils::g3_iterative() then optimises based on iterative reweighting

# Optimise model ################################
obj.fn <- g3_tmb_adfun(model_code, params.in, inner.control = list(trace = 3, maxit = 100))

#obj.fn$env$tracepar <- TRUE
#obj.fn$env$tracemgc <- TRUE
out <- optim(par = obj.fn$par, fn = obj.fn$fn, gr = obj.fn$gr, method = 'BFGS', control = list(
    maxit = 1000,
    trace = 1,
    reltol = .Machine$double.eps^2 ))
params.out <- g3_tmb_relist(params.in, out$par)
fit <- gadgetutils::g3_fit(model_code, params.out)

Spawning & Random effects

Spawning

Creating model functions and Parameterization

Appendix: Full model script