nageshsinghc4/DBSCAN_sklearn_implementation.py

## DBSCAN_sklearn_implementation.py
import numpy as np
from sklearn.cluster import DBSCAN
from sklearn import metrics
from sklearn.datasets import make_blobs
from sklearn.preprocessing import StandardScaler

# Generate sample data
centers = [[1, 1], [-1, -1], [1, -1]]
X, labels_true = make_blobs(n_samples=750, centers=centers, cluster_std=0.4,
                            random_state=0)

X = StandardScaler().fit_transform(X)

# Compute DBSCAN
db = DBSCAN(eps=0.3, min_samples=10).fit(X)
core_samples_mask = np.zeros_like(db.labels_, dtype=bool)
core_samples_mask[db.core_sample_indices_] = True
labels = db.labels_

# Number of clusters in labels, ignoring noise if present.
n_clusters_ = len(set(labels)) - (1 if -1 in labels else 0)
n_noise_ = list(labels).count(-1)

print('Estimated number of clusters: %d' % n_clusters_)
print('Estimated number of noise points: %d' % n_noise_)
print("Homogeneity: %0.3f" % metrics.homogeneity_score(labels_true, labels))
print("Completeness: %0.3f" % metrics.completeness_score(labels_true, labels))
print("V-measure: %0.3f" % metrics.v_measure_score(labels_true, labels))
print("Adjusted Rand Index: %0.3f"
      % metrics.adjusted_rand_score(labels_true, labels))
print("Adjusted Mutual Information: %0.3f"
      % metrics.adjusted_mutual_info_score(labels_true, labels))
print("Silhouette Coefficient: %0.3f"
      % metrics.silhouette_score(X, labels))

# Plot result
import matplotlib.pyplot as plt
%matplotlib inline

# Black removed and is used for noise instead.
unique_labels = set(labels)
colors = [plt.cm.Spectral(each)
          for each in np.linspace(0, 1, len(unique_labels))]
for k, col in zip(unique_labels, colors):
    if k == -1:
        # Black used for noise.
        col = [0, 0, 0, 1]

    class_member_mask = (labels == k)

    xy = X[class_member_mask & core_samples_mask]
    plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
             markeredgecolor='k', markersize=14)

    xy = X[class_member_mask & ~core_samples_mask]
    plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
             markeredgecolor='k', markersize=6)

plt.title('Estimated number of clusters: %d' % n_clusters_)
plt.show()
	import numpy as np
	from sklearn.cluster import DBSCAN
	from sklearn import metrics
	from sklearn.datasets import make_blobs
	from sklearn.preprocessing import StandardScaler

	# Generate sample data
	centers = [[1, 1], [-1, -1], [1, -1]]
	X, labels_true = make_blobs(n_samples=750, centers=centers, cluster_std=0.4,
	random_state=0)

	X = StandardScaler().fit_transform(X)

	# Compute DBSCAN
	db = DBSCAN(eps=0.3, min_samples=10).fit(X)
	core_samples_mask = np.zeros_like(db.labels_, dtype=bool)
	core_samples_mask[db.core_sample_indices_] = True
	labels = db.labels_

	# Number of clusters in labels, ignoring noise if present.
	n_clusters_ = len(set(labels)) - (1 if -1 in labels else 0)
	n_noise_ = list(labels).count(-1)

	print('Estimated number of clusters: %d' % n_clusters_)
	print('Estimated number of noise points: %d' % n_noise_)
	print("Homogeneity: %0.3f" % metrics.homogeneity_score(labels_true, labels))
	print("Completeness: %0.3f" % metrics.completeness_score(labels_true, labels))
	print("V-measure: %0.3f" % metrics.v_measure_score(labels_true, labels))
	print("Adjusted Rand Index: %0.3f"
	% metrics.adjusted_rand_score(labels_true, labels))
	print("Adjusted Mutual Information: %0.3f"
	% metrics.adjusted_mutual_info_score(labels_true, labels))
	print("Silhouette Coefficient: %0.3f"
	% metrics.silhouette_score(X, labels))

	# Plot result
	import matplotlib.pyplot as plt
	%matplotlib inline

	# Black removed and is used for noise instead.
	unique_labels = set(labels)
	colors = [plt.cm.Spectral(each)
	for each in np.linspace(0, 1, len(unique_labels))]
	for k, col in zip(unique_labels, colors):
	if k == -1:
	# Black used for noise.
	col = [0, 0, 0, 1]

	class_member_mask = (labels == k)

	xy = X[class_member_mask & core_samples_mask]
	plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
	markeredgecolor='k', markersize=14)

	xy = X[class_member_mask & ~core_samples_mask]
	plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
	markeredgecolor='k', markersize=6)

	plt.title('Estimated number of clusters: %d' % n_clusters_)
	plt.show()