As already mentioned, you can use a classifier such as class :: knn, to determine which cluster a new individual belongs to.

The KNN or k-nearest neighbors algorithm is one of the simplest machine learning algorithms and is an example of instance-based learning, where new data are classified based on stored, labeled instances. More specifically, the distance between the stored data and the new instance is calculated by means of some kind of a similarity measure. This similarity measure is typically expressed by a distance measure such as the Euclidean distance.

Next I leave a code as an example for the iris data.

```
library(scorecard)
library(factoextra)
library(class)
df_iris <- split_df(iris, ratio = 0.75, seed = 123)
d_iris <- dist(scale(df_iris$train[,-5]))
hc_iris <- hclust(d_iris, method = "ward.D2")
fviz_dend(hc_iris, k = 3,cex = 0.5,k_colors = c("#00AFBB","#E7B800","#FC4E07"),
color_labels_by_k = TRUE, ggtheme = theme_minimal())
groups <- cutree(hc_iris, k = 3)
table(groups)
```

**Predict new data**

```
knnClust <- knn(train = df_iris$train[,-5], test = df_iris$test[,-5] , k = 1, cl = groups)
knnClust
[1] 1 1 1 1 1 1 1 1 1 1 1 1 1 1 2 3 2 3 3 3 2 2 2 2 2 3 3 2 2 3 2 2 2 2 2 2 2 2 2
Levels: 1 2 3
# p1 <- fviz_cluster(list(data = df_iris$train[,-5], cluster = groups), stand = F) + xlim(-11.2,-4.8) + ylim(-3,3) + ggtitle("train")
# p2 <- fviz_cluster(list(data = df_iris$test[,-5], cluster = knnClust),stand = F) + xlim(-11.2,-4.8) + ylim(-3,3) + ggtitle("test")
# gridExtra::grid.arrange(p1,p2,nrow = 2)
pca1 <- data.frame(prcomp(df_iris$train[,-5], scale. = T)$x[,1:2], cluster = as.factor(groups), factor = "train")
pca2 <- data.frame(prcomp(df_iris$test[,-5], scale. = T)$x[,1:2], cluster = as.factor(knnClust), factor = "test")
pca <- as.data.frame(rbind(pca1,pca2))
```

**Plot train and test data**

```
ggplot(pca, aes(x = PC1, y = PC2, color = cluster, size = 1, alpha = factor)) +
geom_point(shape = 19) + theme_bw()
```

`knn(...)`

function in package class.