# How to calculate KNN Variable Importance in R

I implemented an Authorship attribution project where I was able to train my KNN model with articles from two authors using KNN. Then, I classify the author of a new article to be either author A or author B. I use knn() function to generate the model. The output of the model is the table below.

``````   Word1 Word2 Word3  Author
11    1     48    8      A
2     2     0     0      B
29    1     45    9      A
1     2     0     0      B
4     0     0     0      B
28    3     1     1      B
``````

As seen from the model, it is obvious to see that Word2 and Word3 are the most significant variables that cause the classification between Author A and Author B.

My question is how can I identify this using R.

• Why kNN, and not e.g. decision trees? Decision trees (and random forests) are much easier to use if you want to know about variable importance. Commented Apr 25, 2015 at 15:00

Basically, your question boils down to having some variables (Word1, Word2, and Word3 in your example) and a binary outcome (Author in your example) and wanting to know the importance of different variables in determining that outcome. A natural approach would be training a regression model to predict the outcome using the variables and to check the variable importance in that model. I'll include two approaches (logistic regression and random forest) here, but many others could be used.

Let's start with a slightly larger example, in which the outcome only depends on Word2 and Word3, and Word2 has a much larger effect than Word3:

``````set.seed(144)
dat <- data.frame(Word1=rnorm(10000), Word2=rnorm(10000), Word3=rnorm(10000))
dat\$Author <- ifelse(runif(10000) < 1/(1+exp(-10*dat\$Word2+dat\$Word3)), "A", "B")
``````

We can use the summary of the logistic regression model predicting Author to determine the most important variables:

``````summary(glm(I(Author=="A")~., data=dat, family="binomial"))
# [snip]
# Coefficients:
#             Estimate Std. Error z value Pr(>|z|)
# (Intercept)  0.05117    0.04935   1.037    0.300
# Word1       -0.02123    0.04926  -0.431    0.666
# Word2        9.52679    0.26895  35.422   <2e-16 ***
# Word3       -0.97022    0.05629 -17.236   <2e-16 ***
``````

From the p-values, we can see that Word2 has a large positive effect and Word3 has a large negative effect. From the coefficients we can see that Word2 has a higher magnitude of effect on the outcome (since by construction we know all the variables are on the same scale).

We can use the variable importance from a random forest predicting the Author outcome similarly:

``````library(randomForest)
rf <- randomForest(as.factor(Author)~., data=dat)
rf\$importance
#       MeanDecreaseGini
# Word1         294.9039
# Word2        4353.2107
# Word3         351.3268
``````

We can identify Word2 as by far the most important variable. This tells us something else that's interesting -- given that we know Word2, Word3 actually isn't too much more useful than Word1 in predicting the outcome (and Word1 shouldn't be too useful because it wasn't used to compute the outcome).

• Note that randomForest ist pretty much unrelated to `knn` classification. Commented Apr 25, 2015 at 14:59
• @Anony-Mousse as I understand it, the labels A and B came from knn, and the author now wants to better understand the relationship between independent variables and label. Therefore there's no need to further use knn to assess the variable importance. Commented Apr 25, 2015 at 16:15
• @Anony-Mousse Thanks for the explanation. Can you further elaborate on the p-value? you said Word2 has a large positive effect and Word3 has a large negative effect. How did you see that from Pr(>|z|)? Commented Apr 26, 2015 at 9:27
• @alandalusi a small p-value indicates that the coefficient differs from 0 with high probability. Yes, Pr(>|z|) is the p-value. Commented Apr 26, 2015 at 12:50
• The positive and negative effects can be seen from the sign of the z value Commented Jun 21, 2021 at 17:10