library(knitr) opts_chunk$set(message = FALSE, fig.width = 7.1, fig.height = 5)
multimput
packageThe multimput
package was originally intended to provide the data and code to replicate the results of @Onkelinx2016.
This paper is freely available at http://dx.doi.org/10.1007/s10336-016-1404-9.
The functions were all rewritten to make them more user-friendly and more generic.
In order to make the package more compact, we removed the original code and data starting for version 0.2.6.
However both the original code and data remain available in the older releases.
The imputations are based on a model $Y \sim X \beta^*$ which the user has to specify. For a missing value $i$ with covariates $x_i$, we draw a random value $y_i$ from the distribution of $\hat{y}_i$. In case of a linear model, we sample a normal distribution $y_i \sim N(\hat{y}_i, \sigma_i)$. An imputation set $l$ holds an impute value $y_i$ for each missing value.
With the missing values replaced by imputation set $l$, the dataset is complete. So we can apply the analysis that we wanted to do in the first place. This can, but don't has to, include aggregating the dataset prior to analysis. The analysis results in a set of coefficients ${\gamma_a}_l$ and their standard error ${\sigma_a}_l$. Of course, this set will depend on the imputed values of the imputation set $l$. Another imputation set has different imputed values and will hence lead to different coefficients.
Therefore the imputation, aggregation and analysis is repeated for $L$ different imputation sets, resulting in $L$ sets of coefficients and their standard errors. They are aggregated by the formulas below. The coefficient will be the average of the coefficient in all imputation sets. The standard error of a coefficient is the square root of a sum of two parts. The first part is the average of the squared standard error in all imputation sets. The second part is the variance of the coefficient among the imputation sets, multiplied by a correction factor $1 + \frac{1}{L}$.
$$\bar{\gamma}a = \frac{\sum{l = 1}^L{\gamma_a}_l}{L}$$
$$\bar{\sigma}a = \sqrt{\frac{\sum{l = 1}^J {{\sigma_a^2}l}}{L} + (1 + \frac{1}{L}) \frac{\sum{l = 1}^L({\gamma_a}_l - \bar{\gamma}_a) ^ 2}{L - 1}}$$
First, let's generate a dataset and set some observations missing.
generateData()
creates a balanced dataset with repeated visits of a number of sites.
Each site is visited several years and multiple times per year.
Have a look at the help-file of generateData()
for more details on the model.
library(multimput) set.seed(123) prop_missing <- 0.5 dataset <- generate_data(n_year = 10, n_period = 6, n_site = 50, n_run = 1) dataset$Observed <- dataset$Count which_missing <- sample(nrow(dataset), size = nrow(dataset) * prop_missing) dataset$Observed[which_missing] <- NA dataset$fYear <- factor(dataset$Year) dataset$fPeriod <- factor(dataset$Period) dataset$fSite <- factor(dataset$Site) str(dataset)
Variables in dataset
Year
~ The year of the observation as an integer
fYear
~ The year of the observation as a factor
Period
~ The period of the observation as an integer
fPeriod
~ The period of the observation as a factor
Site
~ The ID of the site as an integer
fSite
~ The ID of the site as a factor
Mu
~ The expected value of a negative binomial distribution
Count
~ A realisation of a negative binomial distribution with expected value Mu
Observed
~ The Count
variable with missing data
library(ggplot2) ggplot(dataset, aes(x = Year, y = Mu, group = Site)) + geom_line() + facet_wrap(~Period) + scale_y_log10()
We will create several models, mainly to illustrate the capabilities of the multimput
package.
Hence several of the models are not good for a real life application.
# a simple linear model imp_lm <- lm(Observed ~ fYear + fPeriod + fSite, data = dataset) # a mixed model with Poisson distribution # fYear and fPeriod are the fixed effects # Site are independent and identically distributed random intercepts library(lme4) imp_glmm <- glmer( Observed ~ fYear + fPeriod + (1 | fSite), data = dataset, family = poisson )
inla_available <- requireNamespace("INLA") cat("**_This vignette requires the INLA package. It was build on a system without the INLA package. Please have look at the vignette on the [website](https://inbo.github.io/multimput/articles/impute.html)._**")
library(INLA) # a mixed model with Poisson distribution # fYear and fPeriod are the fixed effects # Site are independent and identically distributed random intercepts # the same model as imp_glmm imp_inla_p <- inla( Observed ~ fYear + fPeriod + f(Site, model = "iid"), data = dataset, family = "poisson", control.compute = list(config = TRUE), control.predictor = list(compute = TRUE, link = 1) ) # the same model as imp_inla_p but with negative binomial distribution imp_inla_nb <- inla( Observed ~ fYear + fPeriod + f(fSite, model = "iid"), data = dataset, family = "nbinomial", control.compute = list(config = TRUE), control.predictor = list(compute = TRUE, link = 1) ) # a mixed model with negative binomial distribution # fPeriod is a fixed effect # f(Year, model = "rw1") is a global temporal trend # modelled as a first order random walk # delta_i = Year_i - Year_{i-1} with delta_i \sim N(0, \sigma_{rw1}) # f(YearCopy, model = "ar1", replicate = Site) is a temporal trend per Site # modelled as an first order autoregressive model # Year_i_k = \rho Year_{i-1}_k + \epsilon_i_k with # \epsilon_i_k \sim N(0, \sigma_{ar1}) dataset$YearCopy <- dataset$Year imp_better <- inla( Observed ~ f(Year, model = "rw1") + f(YearCopy, model = "ar1", replicate = Site) + fPeriod, data = dataset, family = "nbinomial", control.compute = list(config = TRUE), control.predictor = list(compute = TRUE, link = 1) )
Most models have a predict
method.
In such a case impute()
requires both a model
and a data
argument.
Note that this implies that one can apply an imputation on any dataset as long as the dataset contains the necessary variables.
inla
do the prediction simultaneously with the model fitting.
Hence the model contains all required information and the data
is not used.
n_imp
is the number of imputations.
The default is n_imp = 19
.
raw_lm <- impute(imp_lm, data = dataset) raw_glmm <- impute(imp_glmm, data = dataset)
# setting `parallel_configs = FALSE` was required to pass R CMD Check # in practice you can use the default `parallel_configs = TRUE` raw_inla_p <- impute(imp_inla_p, parallel_configs = FALSE) raw_inla_nb <- impute(imp_inla_nb, parallel_configs = FALSE) raw_better <- impute(imp_better, parallel_configs = FALSE) raw_better_9 <- impute(imp_better, n_imp = 9, parallel_configs = FALSE)
Suppose that we are interested in the sum of the counts over all sites for each combination of year and period.
Then we must aggregate the imputations on year and period.
The resulting object will only contain the imputed response and the grouping variables.
The easiest way to have a variable like year both a continuous and factor is to add both Year
and fYear
to the grouping
.
aggr_lm <- aggregate_impute(raw_lm, grouping = c("fYear", "fPeriod"), fun = sum) aggr_glmm <- aggregate_impute( raw_glmm, grouping = c("fYear", "fPeriod"), fun = sum )
aggr_inla_p <- aggregate_impute( raw_inla_p, grouping = c("fYear", "fPeriod"), fun = sum ) aggr_inla_nb <- aggregate_impute( raw_inla_nb, grouping = c("fYear", "fPeriod"), fun = sum ) aggr_better <- aggregate_impute( raw_better, grouping = c("fYear", "fPeriod"), fun = sum ) aggr_better_9 <- aggregate_impute( raw_better_9, grouping = c("fYear", "fPeriod"), fun = sum )
model_impute()
will apply the model_fun
to each imputation set.
The covariates are defined in the rhs
argument.
So model_fun = lm
in combination with rhs = "0 + fYear + fPeriod"
is equivalent to lm(ImputedResponse ~ 0 + fYear + fPeriod, data = ImputedData)
.
The tricky part of this function the extractor
argument.
This is a user defined function which must have an argument called model
.
The function should return a data.frame
or matrix
with two columns.
The first column hold the estimate of a parameter of the model
, the second column their standard error.
Each row represents a parameter.
extractor_lm <- function(model) { summary(model)$coefficients[, c("Estimate", "Std. Error")] } model_impute( aggr_lm, model_fun = lm, rhs = "0 + fYear + fPeriod", extractor = extractor_lm )
fYear
The extractor
function requires more work from the user.
This cost is compensated by the high degree of flexibility.
The user doesn't depend on the predefined extractor functions.
This is illustrated by the following examples.
extractor_lm2 <- function(model) { cf <- summary(model)$coefficients cf[grepl("fYear", rownames(cf)), c("Estimate", "Std. Error")] } model_impute( aggr_lm, model_fun = lm, rhs = "0 + fYear + fPeriod", extractor = extractor_lm2 )
Note that we pass extra arguments to the extractor
function through the extractor_args
argument.
This has to be a list.
We recommend to use a named list to avoid confusion.
library(mgcv) new_set <- expand.grid( Year = pretty(dataset$Year, 20), fPeriod = dataset$fPeriod[1] ) extractor_lm3 <- function(model, newdata) { predictions <- predict(model, newdata = newdata, se.fit = TRUE) cbind(predictions$fit, predictions$se.fit) } model_gam <- model_impute( aggr_lm, model_fun = gam, rhs = "s(Year) + fPeriod", extractor = extractor_lm3, extractor_args = list(newdata = new_set), mutate = list(Year = ~as.integer(levels(fYear))[fYear]) ) model_gam <- cbind(new_set, model_gam) ggplot(model_gam, aes(x = Year, y = Estimate, ymin = LCL, ymax = UCL)) + geom_ribbon(alpha = 0.1) + geom_line()
glm.nb
Suppose that we are interested in a yearly relative index taking into account the average seasonal pattern.
With a complete dataset (without missing values) we could model it like the example below: a generalised linear model with negative binomial distribution because we have counts that are likely overdispersed.
fYear
models the yearly index and fPeriod
the average seasonal pattern.
The 0 +
part removes the intercept for the model.
This simple trick gives direct estimates for the effect of fYear
.
Only the effects of fYear
are needed for the index.
Therefore the extractor functions selects only the parameters who's row name contains fYear
.
In case that we want the first year to be used as a reference (index year 1 = 100%), we can subtract the estimate for this year from all estimates.
The result are the indices relative to the first year, but still in the log scale.
Note that the estimated index for year 1 will be 0 and $log(100\%) = 0$.
library(MASS) aggr_complete <- aggregate( dataset[, "Count", drop = FALSE], dataset[, c("fYear", "fPeriod")], FUN = sum ) model_complete <- glm.nb(Count ~ 0 + fYear + fPeriod, data = aggr_complete) summary(model_complete) extractor_logindex <- function(model) { coef <- summary(model)$coefficients log_index <- coef[grepl("fYear", rownames(coef)), c("Estimate", "Std. Error")] log_index[, "Estimate"] <- log_index[, "Estimate"] - log_index["fYear1", "Estimate"] log_index }
Now that we have a relevant model and extractor function, we can apply them to the aggregate imputed datasets.
model_glmm <- model_impute( object = aggr_glmm, model_fun = glm.nb, rhs = "0 + fYear + fPeriod", extractor = extractor_logindex )
model_p <- model_impute( object = aggr_inla_p, model_fun = glm.nb, rhs = "0 + fYear + fPeriod", extractor = extractor_logindex ) model_nb <- model_impute( object = aggr_inla_nb, model_fun = glm.nb, rhs = "0 + fYear + fPeriod", extractor = extractor_logindex ) model_better <- model_impute( object = aggr_better, model_fun = glm.nb, rhs = "0 + fYear + fPeriod", extractor = extractor_logindex )
model_complete <- extractor_logindex(model_complete) colnames(model_complete) <- c("Estimate", "SE") library(dplyr) model_complete <- model_complete |> as.data.frame() |> mutate( LCL = qnorm(0.025, Estimate, SE), UCL = qnorm(0.975, Estimate, SE), Parameter = paste0("fYear", sort(unique(dataset$Year))) ) covar <- data.frame( Year = sort(unique(dataset$Year)) )
# combine all results and add the Year parameters <- rbind( cbind(covar, model_glmm, Model = "glmm"), cbind(covar, model_p, Model = "poisson"), cbind(covar, model_nb, Model = "negative binomial"), cbind(covar, model_better, Model = "better"), cbind(covar, model_complete, Model = "complete") )
# combine all results and add the Year parameters <- cbind(covar, model_glmm, Model = "glmm")
# convert estimate and confidence interval to the original scale parameters[, c("Estimate", "LCL", "UCL")] <- exp( parameters[, c("Estimate", "LCL", "UCL")] ) ggplot(parameters, aes(x = Year, y = Estimate, ymin = LCL, ymax = UCL)) + geom_hline(yintercept = 1, linetype = 3) + geom_ribbon(alpha = 0.2) + geom_line() + facet_wrap(~Model)
inla
The example below does something similar.
Two things are different: 1) instead of glm.nb
we use inla
to model the imputed totals.
2) we model the seasonal pattern as a random intercept instead of a fixed effect.
extractor_inla <- function(model) { fe <- model$summary.fixed[, c("mean", "sd")] log_index <- fe[grepl("fYear", rownames(fe)), ] log_index[, "mean"] <- log_index[, "mean"] - log_index["fYear1", "mean"] log_index } model_p <- model_impute( object = aggr_glmm, model_fun = inla, rhs = "0 + fYear + f(fPeriod, model = 'iid')", model_args = list(family = "nbinomial"), extractor = extractor_inla ) model_nb <- model_impute( object = aggr_inla_nb, model_fun = inla, rhs = "0 + fYear + f(fPeriod, model = 'iid')", model_args = list(family = "nbinomial"), extractor = extractor_inla ) model_better <- model_impute( object = aggr_better, model_fun = inla, rhs = "0 + fYear + f(fPeriod, model = 'iid')", model_args = list(family = "nbinomial"), extractor = extractor_inla ) m_complete <- inla( Count ~ 0 + fYear + f(fPeriod, model = "iid"), data = aggr_complete, family = "nbinomial" ) model_complete <- extractor_inla(m_complete) colnames(model_complete) <- c("Estimate", "SE") model_complete <- model_complete |> as.data.frame() |> mutate( LCL = qnorm(0.025, Estimate, SE), UCL = qnorm(0.975, Estimate, SE), Parameter = paste0("fYear", sort(unique(dataset$Year))) ) # combine all results and add the Year parameters <- rbind( cbind(covar, model_glmm, Model = "glmm"), cbind(covar, model_p, Model = "poisson"), cbind(covar, model_nb, Model = "negative binomial"), cbind(covar, model_better, Model = "better"), cbind(covar, model_complete, Model = "complete") ) # convert estimate and confidence interval to the original scale parameters[, c("Estimate", "LCL", "UCL")] <- exp( parameters[, c("Estimate", "LCL", "UCL")] ) ggplot(parameters, aes(x = Year, y = Estimate, ymin = LCL, ymax = UCL)) + geom_hline(yintercept = 1, linetype = 3) + geom_ribbon(alpha = 0.2) + geom_line() + facet_wrap(~Model)
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