Clustergram - visualization and diagnostics for cluster analysis
Project description
Clustergram
Visualization and diagnostics for cluster analysis
Clustergram is a diagram proposed by Matthias Schonlau in his paper The clustergram: A graph for visualizing hierarchical and nonhierarchical cluster analyses.
In hierarchical cluster analysis, dendrograms are used to visualize how clusters are formed. I propose an alternative graph called a “clustergram” to examine how cluster members are assigned to clusters as the number of clusters increases. This graph is useful in exploratory analysis for nonhierarchical clustering algorithms such as k-means and for hierarchical cluster algorithms when the number of observations is large enough to make dendrograms impractical.
The clustergram was later implemented in R by Tal Galili, who also gives a thorough explanation of the concept.
This is a Python translation of Tal's script written for scikit-learn
and RAPIDS cuML
implementations of K-Means, Mini Batch K-Means and Gaussian Mixture Model (scikit-learn only) clustering, plus hierarchical/agglomerative clustering using SciPy
. Alternatively, you can create clustergram using from_*
constructors based on alternative clustering algorithms.
Getting started
You can install clustergram from conda
or pip
:
conda install clustergram -c conda-forge
pip install clustergram
In any case, you still need to install your selected backend
(scikit-learn
and scipy
or cuML
).
The example of clustergram on Palmer penguins dataset:
import seaborn
df = seaborn.load_dataset('penguins')
First we have to select numerical data and scale them.
from sklearn.preprocessing import scale
data = scale(df.drop(columns=['species', 'island', 'sex']).dropna())
And then we can simply pass the data to clustergram
.
from clustergram import Clustergram
cgram = Clustergram(range(1, 8))
cgram.fit(data)
cgram.plot()
Styling
Clustergram.plot()
returns matplotlib axis and can be fully customised as any other matplotlib plot.
seaborn.set(style='whitegrid')
cgram.plot(
ax=ax,
size=0.5,
linewidth=0.5,
cluster_style={"color": "lightblue", "edgecolor": "black"},
line_style={"color": "red", "linestyle": "-."},
figsize=(12, 8)
)
Mean options
On the y
axis, a clustergram can use mean values as in the original paper by Matthias Schonlau or PCA weighted mean values as in the implementation by Tal Galili.
cgram = Clustergram(range(1, 8))
cgram.fit(data)
cgram.plot(figsize=(12, 8), pca_weighted=True)
cgram = Clustergram(range(1, 8))
cgram.fit(data)
cgram.plot(figsize=(12, 8), pca_weighted=False)
Scikit-learn, SciPy and RAPIDS cuML backends
Clustergram offers three backends for the computation - scikit-learn
and scipy
which use CPU and RAPIDS.AI cuML
, which uses GPU. Note that all are optional dependencies but you will need at least one of them to generate clustergram.
Using scikit-learn
(default):
cgram = Clustergram(range(1, 8), backend='sklearn')
cgram.fit(data)
cgram.plot()
Using cuML
:
cgram = Clustergram(range(1, 8), backend='cuML')
cgram.fit(data)
cgram.plot()
data
can be all data types supported by the selected backend (including cudf.DataFrame
with cuML
backend).
Supported methods
Clustergram currently supports K-Means, Mini Batch K-Means, Gaussian Mixture Model and SciPy's hierarchical clustering methods. Note tha GMM and Mini Batch K-Means are supported only for scikit-learn
backend and hierarchical methods are supported only for scipy
backend.
Using K-Means (default):
cgram = Clustergram(range(1, 8), method='kmeans')
cgram.fit(data)
cgram.plot()
Using Mini Batch K-Means, which can provide significant speedup over K-Means:
cgram = Clustergram(range(1, 8), method='minibatchkmeans', batch_size=100)
cgram.fit(data)
cgram.plot()
Using Gaussian Mixture Model:
cgram = Clustergram(range(1, 8), method='gmm')
cgram.fit(data)
cgram.plot()
Using Ward's hierarchical clustering:
cgram = Clustergram(range(1, 8), method='hierarchical', linkage='ward')
cgram.fit(data)
cgram.plot()
Manual input
Alternatively, you can create clustergram using from_data
or from_centers
methods based on alternative clustering algorithms.
Using Clustergram.from_data
which creates cluster centers as mean or median values:
data = numpy.array([[-1, -1, 0, 10], [1, 1, 10, 2], [0, 0, 20, 4]])
labels = pandas.DataFrame({1: [0, 0, 0], 2: [0, 0, 1], 3: [0, 2, 1]})
cgram = Clustergram.from_data(data, labels)
cgram.plot()
Using Clustergram.from_centers
based on explicit cluster centers.:
labels = pandas.DataFrame({1: [0, 0, 0], 2: [0, 0, 1], 3: [0, 2, 1]})
centers = {
1: np.array([[0, 0]]),
2: np.array([[-1, -1], [1, 1]]),
3: np.array([[-1, -1], [1, 1], [0, 0]]),
}
cgram = Clustergram.from_centers(centers, labels)
cgram.plot(pca_weighted=False)
To support PCA weighted plots you also need to pass data:
cgram = Clustergram.from_centers(centers, labels, data=data)
cgram.plot()
Partial plot
Clustergram.plot()
can also plot only a part of the diagram, if you want to focus on a limited range of k
.
cgram = Clustergram(range(1, 20))
cgram.fit(data)
cgram.plot(figsize=(12, 8))
cgram.plot(k_range=range(3, 10), figsize=(12, 8))
Additional clustering performance evaluation
Clustergam includes handy wrappers around a selection of clustering performance metrics offered by
scikit-learn
. Data which were originally computed on GPU are converted to numpy on the fly.
Silhouette score
Compute the mean Silhouette Coefficient of all samples. See scikit-learn
documentation for details.
>>> cgram.silhouette_score()
2 0.531540
3 0.447219
4 0.400154
5 0.377720
6 0.372128
7 0.331575
Name: silhouette_score, dtype: float64
Once computed, resulting Series is available as cgram.silhouette
. Calling the original method will recompute the score.
Calinski and Harabasz score
Compute the Calinski and Harabasz score, also known as the Variance Ratio Criterion. See scikit-learn
documentation for details.
>>> cgram.calinski_harabasz_score()
2 482.191469
3 441.677075
4 400.392131
5 411.175066
6 382.731416
7 352.447569
Name: calinski_harabasz_score, dtype: float64
Once computed, resulting Series is available as cgram.calinski_harabasz
. Calling the original method will recompute the score.
Davies-Bouldin score
Compute the Davies-Bouldin score. See scikit-learn
documentation for details.
>>> cgram.davies_bouldin_score()
2 0.714064
3 0.943553
4 0.943320
5 0.973248
6 0.950910
7 1.074937
Name: davies_bouldin_score, dtype: float64
Once computed, resulting Series is available as cgram.davies_bouldin
. Calling the original method will recompute the score.
Acessing labels
Clustergram
stores resulting labels for each of the tested options, which can be accessed as:
>>> cgram.labels
1 2 3 4 5 6 7
0 0 0 2 2 3 2 1
1 0 0 2 2 3 2 1
2 0 0 2 2 3 2 1
3 0 0 2 2 3 2 1
4 0 0 2 2 0 0 3
.. .. .. .. .. .. .. ..
337 0 1 1 3 2 5 0
338 0 1 1 3 2 5 0
339 0 1 1 1 1 1 4
340 0 1 1 3 2 5 5
341 0 1 1 1 1 1 5
Saving clustergram
You can save both plot and clustergram.Clustergram
to a disk.
Saving plot
Clustergram.plot()
returns matplotlib axis object and as such can be saved as any other plot:
import matplotlib.pyplot as plt
cgram.plot()
plt.savefig('clustergram.svg')
Saving object
If you want to save your computed clustergram.Clustergram
object to a disk, you can use pickle
library:
import pickle
with open('clustergram.pickle','wb') as f:
pickle.dump(cgram, f)
Then loading is equally simple:
with open('clustergram.pickle','rb') as f:
loaded = pickle.load(f)
References
Schonlau M. The clustergram: a graph for visualizing hierarchical and non-hierarchical cluster analyses. The Stata Journal, 2002; 2 (4):391-402.
Schonlau M. Visualizing Hierarchical and Non-Hierarchical Cluster Analyses with Clustergrams. Computational Statistics: 2004; 19(1):95-111.
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