I did some digging into how the gbm package calculates importance and it is based on the ErrorReduction which is contained in the trees element of the result and can be accessed with `pretty.gbm.trees()`

. Relative influence is obtained by taking the sum of this ErrorReduction over all trees for each variable. For a multiclass problem there are actually `n.trees*num.classes`

trees in the model. So if there are 3 classes you can calculate the sum of the ErrorReduction for each variable over every third tree to get the importance for one class. I have written the following functions to implement this and then plot the results:

**Get Variable Importance By Class**

```
RelInf_ByClass <- function(object, n.trees, n.classes, Scale = TRUE){
library(dplyr)
library(purrr)
library(gbm)
Ext_ErrRed<- function(ptree){
ErrRed <- ptree %>% filter(SplitVar != -1) %>% group_by(SplitVar) %>%
summarise(Sum_ErrRed = sum(ErrorReduction))
}
trees_ErrRed <- map(1:n.trees, ~pretty.gbm.tree(object, .)) %>%
map(Ext_ErrRed)
trees_by_class <- split(trees_ErrRed, rep(1:n.classes, n.trees/n.classes)) %>%
map(~bind_rows(.) %>% group_by(SplitVar) %>%
summarise(rel_inf = sum(Sum_ErrRed)))
varnames <- data.frame(Num = 0:(length(object$var.names)-1),
Name = object$var.names)
classnames <- data.frame(Num = 1:object$num.classes,
Name = object$classes)
out <- trees_by_class %>% bind_rows(.id = "Class") %>%
mutate(Class = classnames$Name[match(Class,classnames$Num)],
SplitVar = varnames$Name[match(SplitVar,varnames$Num)]) %>%
group_by(Class)
if(Scale == FALSE){
return(out)
} else {
out <- out %>% mutate(Scaled_inf = rel_inf/max(rel_inf)*100)
}
}
```

## Plot Variable Importance By Class

In my real use for this I have over 40 features so I give an option to specify the number of features to plot. I also couldn't use faceting if I wanted the plots to be sorted separately for each class, which is why I used `gridExtra`

.

```
plot_imp_byclass <- function(df, n) {
library(ggplot2)
library(gridExtra)
plot_imp_class <- function(df){
df %>% arrange(rel_inf) %>%
mutate(SplitVar = factor(SplitVar, levels = .$SplitVar)) %>%
ggplot(aes(SplitVar, rel_inf))+
geom_segment(aes(x = SplitVar,
xend = SplitVar,
y = 0,
yend = rel_inf))+
geom_point(size=3, col = "cyan") +
coord_flip()+
labs(title = df$Class[[1]], x = "Variable", y = "Importance")+
theme_classic()+
theme(plot.title = element_text(hjust = 0.5))
}
df %>% top_n(n, rel_inf) %>% split(.$Class) %>%
map(plot_imp_class) %>% map(ggplotGrob) %>%
{grid.arrange(grobs = .)}
}
```

## Try It

```
gbm_iris <- gbm(Species~., data = iris)
imp_byclass <- RelInf_ByClass(gbm_iris, length(gbm_iris$trees),
gbm_iris$num.classes, Scale = F)
plot_imp_byclass(imp_byclass, 4)
```

Seems to give the same results as the built in `relative.influence`

function if you sum the results over all the classes.

```
relative.influence(gbm_iris)
# n.trees not given. Using 100 trees.
# Sepal.Length Sepal.Width Petal.Length Petal.Width
# 0.00000 51.88684 2226.88017 868.71085
imp_byclass %>% group_by(SplitVar) %>% summarise(Overall_rel_inf = sum(rel_inf))
# A tibble: 3 x 2
# SplitVar Overall_rel_inf
# <fct> <dbl>
# 1 Petal.Length 2227.
# 2 Petal.Width 869.
# 3 Sepal.Width 51.9
```