If the true label is not known in advance(as in your case), then `K-Means clustering`

can be evaluated using either Elbow Criterion or Silhouette Coefficient.

**Elbow Criterion Method:**

The idea behind elbow method is to run k-means clustering on a given dataset for a range of values of k (`num_clusters`

, e.g k=1 to 10), and for each value of k, calculate sum of squared errors (SSE).

After that, plot a line graph of the SSE for each value of k. If the line graph looks like an arm - a red circle in below line graph (like angle), the "elbow" on the arm is the value of optimal k (number of cluster).
Here, we want to minimize SSE. SSE tends to decrease toward 0 as we increase k (and SSE is 0 when k is equal to the number of data points in the dataset, because then each data point is its own cluster, and there is no error between it and the center of its cluster).

So the goal is to choose a `small value of k`

that still has a low SSE, and the elbow usually represents where we start to have diminishing returns by increasing k.

Let's consider iris datasets,

```
import pandas as pd
from sklearn.datasets import load_iris
from sklearn.cluster import KMeans
import matplotlib.pyplot as plt
iris = load_iris()
X = pd.DataFrame(iris.data, columns=iris['feature_names'])
#print(X)
data = X[['sepal length (cm)', 'sepal width (cm)', 'petal length (cm)']]
sse = {}
for k in range(1, 10):
kmeans = KMeans(n_clusters=k, max_iter=1000).fit(data)
data["clusters"] = kmeans.labels_
#print(data["clusters"])
sse[k] = kmeans.inertia_ # Inertia: Sum of distances of samples to their closest cluster center
plt.figure()
plt.plot(list(sse.keys()), list(sse.values()))
plt.xlabel("Number of cluster")
plt.ylabel("SSE")
plt.show()
```

Plot for above code:

We can see in plot, 3 is the optimal number of clusters (encircled red) for iris dataset, which is indeed correct.

**Silhouette Coefficient Method:**

From sklearn documentation,

A higher Silhouette Coefficient score relates to a model with better-defined clusters. The Silhouette Coefficient is defined for each sample and is composed of two scores:
`

a: The mean distance between a sample and all other points in the same class.

b: The mean distance between a sample and all other points in the next
nearest cluster.

The Silhouette Coefficient is for a single sample is then given as:

Now, to find the optimal value of `k`

for `KMeans`

, loop through 1..n for n_clusters in `KMeans`

and calculate Silhouette Coefficient for each sample.

A higher Silhouette Coefficient indicates that the object is well matched to its own cluster and poorly matched to neighboring clusters.

```
from sklearn.metrics import silhouette_score
from sklearn.datasets import load_iris
from sklearn.cluster import KMeans
X = load_iris().data
y = load_iris().target
for n_cluster in range(2, 11):
kmeans = KMeans(n_clusters=n_cluster).fit(X)
label = kmeans.labels_
sil_coeff = silhouette_score(X, label, metric='euclidean')
print("For n_clusters={}, The Silhouette Coefficient is {}".format(n_cluster, sil_coeff))
```

**Output -**

For n_clusters=2, The Silhouette Coefficient is 0.680813620271

**For n_clusters=3, The Silhouette Coefficient is 0.552591944521**

For n_clusters=4, The Silhouette Coefficient is 0.496992849949

For n_clusters=5, The Silhouette Coefficient is 0.488517550854

For n_clusters=6, The Silhouette Coefficient is 0.370380309351

For n_clusters=7, The Silhouette Coefficient is 0.356303270516

For n_clusters=8, The Silhouette Coefficient is 0.365164535737

For n_clusters=9, The Silhouette Coefficient is 0.346583642095

For n_clusters=10, The Silhouette Coefficient is 0.328266088778

As we can see, *n_clusters=2* has highest Silhouette Coefficient. This means that 2 should be the optimal number of cluster, Right?

But here's the catch.

Iris dataset has 3 species of flower, which contradicts the 2 as an optimal number of cluster. So despite *n_clusters=2* having highest Silhouette Coefficient, We would consider *n_clusters=3* as optimal number of cluster due to -

- Iris dataset has 3 species.
**(Most Important)**
*n_clusters=2* has a 2nd highest value of Silhouette Coefficient.

So choosing *n_clusters=3* is the optimal no. of cluster for iris dataset.

Choosing optimal no. of the cluster will depend on the type of datasets and the problem we are trying to solve. But most of the cases, taking highest Silhouette Coefficient will yield an optimal number of cluster.

Hope it helps!