## 1. K-medoid is more flexible

First of all, you can use k-medoids with *any* similarity measure. K-means however, may fail to converge - it really must only be used with distances that are consistent with the *mean*. So e.g. Absolute Pearson Correlation must not be used with k-means, but it works well with k-medoids.

## 2. Robustness of medoid

Secondly, the medoid as used by k-medoids is roughly comparable to the *median* (in fact, there also is k-medians, which is like K-means but for Manhattan distance). If you look up literature on the median, you will see plenty of explanations and examples why **the median is more robust to outliers than the arithmetic mean**. Essentially, these explanations and examples will also hold for the medoid. It is a more *robust* estimate of a representative point than the mean as used in k-means.

Consider this 1-dimensional example:

```
[1, 2, 3, 4, 100000]
```

Both the median and medoid of this set are *3*. The mean is 20002.

Which do you think is more representative of the data set? The mean has the lower squared error, but assuming that there might be a measurement error in this data set ...

Technically, the notion of **breakdown point** is used in statistics. The median has a breakdown point of 50% (i.e. half of the data points can be incorrect, and the result is still unaffected), whereas the mean has a breakdown point of 0 (i.e. a single large observation can yield a bad estimate).

I do not have a proof, but I assume the medoid will have a similar breakdown point as the median.

## 3. k-medoids is much more expensive

That's the main drawback. Usually, PAM takes much longer to run than k-means. As it involves computing all pairwise distances, it is `O(n^2*k*i)`

; whereas k-means runs in `O(n*k*i)`

where usually, k times the number of iterations is `k*i << n`

.

breakdown pointfrom robust statistics. The medoid is likely arobuststatistic, the mean is not at all robust.