One of the great things about open-source software is that you can find out exactly how the software works. The code below shows Weka's source code of the `HierarchicalClusterer`

algorithm, more specifically it shows the part which implements the `COMPLETE`

and `ADJCOMPLETE`

functionality. The difference is as follows:

- Just like the
`COMPLETE`

linkage method, compute the maximum distance between one node from cluster 1 and one node from cluster 2 and store this in `fBestDist`

- Then, find the largest distance between nodes within cluster 1 or cluster 2 and store this in
`fMaxDist`

- Finally subtract
`fMaxDist`

from `fBestDist`

So the distance between two clusters calculated using `ADJCOMPLETE`

as `linkType`

corresponds to the `COMPLETE`

distance minus the largest distance between 2 nodes within either cluster 1 or cluster 2.

`Adjusted Complete-Link`

was proposed in the following paper:

Sepandar Kamvar, Dan Klein and Christopher Manning (2002). *Interpreting and Extending Classical Agglomerative Clustering Algorithms Using a Model-Based Approach*. In Proceedings of 19th International Conference on Machine Learning (ICML-2002)

According to it (section 4.2), `Adjusted Complete-Link`

is a version of `Complete-Link`

which should be used if the clusters having varying radii (see Figure 10).

```
case COMPLETE:
case ADJCOMLPETE:
// find complete link distance aka maximum link, which is the largest distance between
// any item in cluster1 and any item in cluster2
fBestDist = 0;
for (int i = 0; i < cluster1.size(); i++) {
int i1 = cluster1.elementAt(i);
for (int j = 0; j < cluster2.size(); j++) {
int i2 = cluster2.elementAt(j);
double fDist = fDistance[i1][i2];
if (fBestDist < fDist) {
fBestDist = fDist;
}
}
}
if (m_nLinkType == COMPLETE) {
break;
}
// calculate adjustment, which is the largest within cluster distance
double fMaxDist = 0;
for (int i = 0; i < cluster1.size(); i++) {
int i1 = cluster1.elementAt(i);
for (int j = i+1; j < cluster1.size(); j++) {
int i2 = cluster1.elementAt(j);
double fDist = fDistance[i1][i2];
if (fMaxDist < fDist) {
fMaxDist = fDist;
}
}
}
for (int i = 0; i < cluster2.size(); i++) {
int i1 = cluster2.elementAt(i);
for (int j = i+1; j < cluster2.size(); j++) {
int i2 = cluster2.elementAt(j);
double fDist = fDistance[i1][i2];
if (fMaxDist < fDist) {
fMaxDist = fDist;
}
}
}
fBestDist -= fMaxDist;
break;
```