Skip to content

Self organizing Kohonen map in Python with periodic boundary conditions

License

Notifications You must be signed in to change notification settings

alexarnimueller/som

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

som-pbc README

pypi version Documentation Status

A simple self-organizing map implementation in Python with periodic boundary conditions.

Self-organizing maps are also called Kohonen maps and were invented by Teuvo Kohonen.[1] They are an unsupervised machine learning technique to efficiently create spatially organized internal representations of various types of data. For example, SOMs are well-suited for the visualization of high-dimensional data.

This is a simple implementation of SOMs in Python. This SOM has periodic boundary conditions and therefore can be imagined as a "donut". The implementation uses numpy, scipy, scikit-learn and matplotlib.

Installation

som-pbc can be installed from pypi using pip:

pip install som-pbc

To upgrade som-pbc to the latest version, run:

pip install --upgrade som-pbc

Usage

Then you can import and use the SOM class as follows:

import numpy as np
from som import SOM

# generate some random data with 36 features
data1 = np.random.normal(loc=-.25, scale=0.5, size=(500, 36))
data2 = np.random.normal(loc=.25, scale=0.5, size=(500, 36))
data = np.vstack((data1, data2))

som = SOM(10, 10)  # initialize a 10 by 10 SOM
som.fit(data, 10000, save_e=True, interval=100)  # fit the SOM for 10000 epochs, save the error every 100 steps
som.plot_error_history(filename='images/som_error.png')  # plot the training error history

targets = np.array(500 * [0] + 500 * [1])  # create some dummy target values

# now visualize the learned representation with the class labels
som.plot_point_map(data, targets, ['Class 0', 'Class 1'], filename='images/som.png')
som.plot_class_density(data, targets, t=0, name='Class 0', colormap='Greens', filename='images/class_0.png')
som.plot_distance_map(colormap='Blues', filename='images/distance_map.png')  # plot the distance map after training

# predicting the class of a new, unknown datapoint
datapoint = np.random.normal(loc=.25, scale=0.5, size=(1, 36))
print("Labels of neighboring datapoints: ", som.get_neighbors(datapoint, data, targets, d=0))

# transform data into the SOM space
newdata = np.random.normal(loc=.25, scale=0.5, size=(10, 36))
transformed = som.transform(newdata)
print("Old shape of the data:", newdata.shape)
print("New shape of the data:", transformed.shape)

Training Error:

Training Error

Point Map:

Point Map

Class Density:

Class Density Map

Distance Map:

Distance Map

The same way you can handle your own data.

Methods / Functions

The SOM class has the following methods:

  • initialize(data, how='pca'): initialize the SOM, either via Eigenvalues (pca) or randomly (random)
  • winner(vector): compute the winner neuron closest to a given data point in vector (Euclidean distance)
  • cycle(vector): perform one iteration in adapting the SOM towards the chosen data point in vector
  • fit(data, epochs=0, save_e=False, interval=1000, decay='hill'): train the SOM on the given data for several epochs
  • transform(data): transform given data in to the SOM space
  • distance_map(metric='euclidean'): get a map of every neuron and its distances to all neighbors based on the neuron weights
  • winner_map(data): get the number of times, a certain neuron in the trained SOM is winner for the given data
  • winner_neurons(data): for every data point, get the winner neuron coordinates
  • som_error(data): calculates the overall error as the average difference between the winning neurons and the data
  • get_neighbors(datapoint, data, labels, d=0): get the labels of all data examples that are d neurons away from datapoint on the map
  • save(filename): save the whole SOM instance into a pickle file
  • load(filename): load a SOM instance from a pickle file
  • plot_point_map(data, targets, targetnames, filename=None, colors=None, markers=None, density=True): visualize the som with all data as points around the neurons
  • plot_density_map(data, filename=None, internal=False): visualize the data density in different areas of the SOM.
  • plot_class_density(data, targets, t, name, colormap='Oranges', filename=None): plot a density map only for the given class
  • plot_distance_map(colormap='Oranges', filename=None): visualize the disance of the neurons in the trained SOM
  • plot_error_history(color='orange', filename=None): visualize the training error history after training (fit with save_e=True)

References:

[1] Kohonen, T. Self-Organized Formation of Topologically Correct Feature Maps. Biol. Cybern. 1982, 43 (1), 59–69.

This work was partially inspired by ramalina's som implementation and JustGlowing's minisom.

Documentation:

Documentation for som-pbc is hosted on readthedocs.io.

About

Self organizing Kohonen map in Python with periodic boundary conditions

Topics

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages