bistaumanga · September 26, 2024 10:00 · romaresccoa · Jan 18, 2018 · yashk2810 · Feb 11, 2018
diff --git a/gmm.py b/gmm.py
 # -*- coding: utf-8 -*-
 """
 Created on Sat May  3 10:21:21 2014

 @author: umb
 """

 import numpy as np
    
 class GMM:
    
    def __init__(self, k = 3, eps = 0.0001):
        self.k = k ## number of clusters
        self.eps = eps ## threshold to stop `epsilon`
        
        # All parameters from fitting/learning are kept in a named tuple
        from collections import namedtuple
    
    def fit_EM(self, X, max_iters = 1000):
        
        # n = number of data-points, d = dimension of data points        
        n, d = X.shape
        
        # randomly choose the starting centroids/means 
        ## as 3 of the points from datasets        
        mu = X[np.random.choice(n, self.k, False), :]
        
        # initialize the covariance matrices for each gaussians
        Sigma= [np.eye(d)] * self.k
        
        # initialize the probabilities/weights for each gaussians
        w = [1./self.k] * self.k
        
        # responsibility matrix is initialized to all zeros
        # we have responsibility for each of n points for eack of k gaussians
        R = np.zeros((n, self.k))
        
        ### log_likelihoods
        log_likelihoods = []
        
        P = lambda mu, s: np.linalg.det(s) ** -.5 ** (2 * np.pi) ** (-X.shape[1]/2.) \
                * np.exp(-.5 * np.einsum('ij, ij -> i',\
                        X - mu, np.dot(np.linalg.inv(s) , (X - mu).T).T ) ) 
                        
        # Iterate till max_iters iterations        
        while len(log_likelihoods) < max_iters:
            
            # E - Step
            
            ## Vectorized implementation of e-step equation to calculate the 
            ## membership for each of k -gaussians
            for k in range(self.k):
                R[:, k] = w[k] * P(mu[k], Sigma[k])

            ### Likelihood computation
            log_likelihood = np.sum(np.log(np.sum(R, axis = 1)))
            
            log_likelihoods.append(log_likelihood)
            
            ## Normalize so that the responsibility matrix is row stochastic
            R = (R.T / np.sum(R, axis = 1)).T
            
            ## The number of datapoints belonging to each gaussian            
            N_ks = np.sum(R, axis = 0)
            
            
            # M Step
            ## calculate the new mean and covariance for each gaussian by 
            ## utilizing the new responsibilities
            for k in range(self.k):
                
                ## means
                mu[k] = 1. / N_ks[k] * np.sum(R[:, k] * X.T, axis = 1).T
                x_mu = np.matrix(X - mu[k])
                
                ## covariances
                Sigma[k] = np.array(1 / N_ks[k] * np.dot(np.multiply(x_mu.T,  R[:, k]), x_mu))
                
                ## and finally the probabilities
                w[k] = 1. / n * N_ks[k]
            # check for onvergence
            if len(log_likelihoods) < 2 : continue
            if np.abs(log_likelihood - log_likelihoods[-2]) < self.eps: break
        
        ## bind all results together
        from collections import namedtuple
        self.params = namedtuple('params', ['mu', 'Sigma', 'w', 'log_likelihoods', 'num_iters'])
        self.params.mu = mu
        self.params.Sigma = Sigma
        self.params.w = w
        self.params.log_likelihoods = log_likelihoods
        self.params.num_iters = len(log_likelihoods)       
        
        return self.params
    
    def plot_log_likelihood(self):
        import pylab as plt
        plt.plot(self.params.log_likelihoods)
        plt.title('Log Likelihood vs iteration plot')
        plt.xlabel('Iterations')
        plt.ylabel('log likelihood')
        plt.show()
    
    def predict(self, x):
        p = lambda mu, s : np.linalg.det(s) ** - 0.5 * (2 * np.pi) **\
                (-len(x)/2) * np.exp( -0.5 * np.dot(x - mu , \
                        np.dot(np.linalg.inv(s) , x - mu)))
        probs = np.array([w * p(mu, s) for mu, s, w in \
            zip(self.params.mu, self.params.Sigma, self.params.w)])
        return probs/np.sum(probs)
        
        
 def demo_2d():
    
    # Load data
    #X = np.genfromtxt('data1.csv', delimiter=',')
    ### generate the random data     
    np.random.seed(3)
    m1, cov1 = [9, 8], [[.5, 1], [.25, 1]] ## first gaussian
    data1 = np.random.multivariate_normal(m1, cov1, 90)
    
    m2, cov2 = [6, 13], [[.5, -.5], [-.5, .1]] ## second gaussian
    data2 = np.random.multivariate_normal(m2, cov2, 45)
    
    m3, cov3 = [4, 7], [[0.25, 0.5], [-0.1, 0.5]] ## third gaussian
    data3 = np.random.multivariate_normal(m3, cov3, 65)
    X = np.vstack((data1,np.vstack((data2,data3))))
    np.random.shuffle(X)
 #    np.savetxt('sample.csv', X, fmt = "%.4f",  delimiter = ",")
    ####
    gmm = GMM(3, 0.000001)
    params = gmm.fit_EM(X, max_iters= 100)
    print params.log_likelihoods
    import pylab as plt    
    from matplotlib.patches import Ellipse
    
    def plot_ellipse(pos, cov, nstd=2, ax=None, **kwargs):
        def eigsorted(cov):
            vals, vecs = np.linalg.eigh(cov)
            order = vals.argsort()[::-1]
            return vals[order], vecs[:,order]
    
        if ax is None:
            ax = plt.gca()
    
        vals, vecs = eigsorted(cov)
        theta = np.degrees(np.arctan2(*vecs[:,0][::-1]))
    
        # Width and height are "full" widths, not radius
        width, height = 2 * nstd * np.sqrt(abs(vals))
        ellip = Ellipse(xy=pos, width=width, height=height, angle=theta, **kwargs)
    
        ax.add_artist(ellip)
        return ellip    
    
    def show(X, mu, cov):

        plt.cla()
        K = len(mu) # number of clusters
        colors = ['b', 'k', 'g', 'c', 'm', 'y', 'r']
        plt.plot(X.T[0], X.T[1], 'm*')
        for k in range(K):
          plot_ellipse(mu[k], cov[k],  alpha=0.6, color = colors[k % len(colors)])  

    
    fig = plt.figure(figsize = (13, 6))
    fig.add_subplot(121)
    show(X, params.mu, params.Sigma)
    fig.add_subplot(122)
    plt.plot(np.array(params.log_likelihoods))
    plt.title('Log Likelihood vs iteration plot')
    plt.xlabel('Iterations')
    plt.ylabel('log likelihood')
    plt.show()
    print gmm.predict(np.array([1, 2]))
       

 if __name__ == "__main__":

    demo_2d()    
    from optparse import OptionParser

    parser = OptionParser()
    parser.add_option("-f", "--file", dest="filepath", help="File path for data")
    parser.add_option("-k", "--clusters", dest="clusters", help="No. of gaussians")    
    parser.add_option("-e", "--eps", dest="epsilon", help="Epsilon to stop")    
    parser.add_option("-m", "--maxiters", dest="max_iters", help="Maximum no. of iteration")        
    options, args = parser.parse_args()
    
    if not options.filepath : raise('File not provided')
    
    if not options.clusters :
        print("Used default number of clusters = 3" )
        k = 3
    else: k = int(options.clusters)
    
    if not options.epsilon :
        print("Used default eps = 0.0001" )
        eps = 0.0001
    else: eps = float(options.epsilon)
    
    if not options.max_iters :
        print("Used default maxiters = 1000" )
        max_iters = 1000
    else: eps = int(options.maxiters)
    
    X = np.genfromtxt(options.filepath, delimiter=',')
    gmm = GMM(k, eps)
    params = gmm.fit_EM(X, max_iters)
    print params.log_likelihoods
    gmm.plot_log_likelihood()
    print gmm.predict(np.array([1, 2]))
	# -- coding: utf-8 --
	"""
	Created on Sat May 3 10:21:21 2014

	@author: umb
	"""

	import numpy as np

	class GMM:

	def __init__(self, k = 3, eps = 0.0001):
	self.k = k ## number of clusters
	self.eps = eps ## threshold to stop `epsilon`

	# All parameters from fitting/learning are kept in a named tuple
	from collections import namedtuple

	def fit_EM(self, X, max_iters = 1000):

	# n = number of data-points, d = dimension of data points
	n, d = X.shape

	# randomly choose the starting centroids/means
	## as 3 of the points from datasets
	mu = X[np.random.choice(n, self.k, False), :]

	# initialize the covariance matrices for each gaussians
	Sigma= [np.eye(d)] * self.k

	# initialize the probabilities/weights for each gaussians
	w = [1./self.k] * self.k

	# responsibility matrix is initialized to all zeros
	# we have responsibility for each of n points for eack of k gaussians
	R = np.zeros((n, self.k))

	### log_likelihoods
	log_likelihoods = []

	P = lambda mu, s: np.linalg.det(s) -.5 (2 * np.pi) ** (-X.shape[1]/2.) \
	* np.exp(-.5 * np.einsum('ij, ij -> i',\
	X - mu, np.dot(np.linalg.inv(s) , (X - mu).T).T ) )

	# Iterate till max_iters iterations
	while len(log_likelihoods) < max_iters:

	# E - Step

	## Vectorized implementation of e-step equation to calculate the
	## membership for each of k -gaussians
	for k in range(self.k):
	R[:, k] = w[k] * P(mu[k], Sigma[k])

	### Likelihood computation
	log_likelihood = np.sum(np.log(np.sum(R, axis = 1)))

	log_likelihoods.append(log_likelihood)

	## Normalize so that the responsibility matrix is row stochastic
	R = (R.T / np.sum(R, axis = 1)).T

	## The number of datapoints belonging to each gaussian
	N_ks = np.sum(R, axis = 0)


	# M Step
	## calculate the new mean and covariance for each gaussian by
	## utilizing the new responsibilities
	for k in range(self.k):

	## means
	mu[k] = 1. / N_ks[k] * np.sum(R[:, k] * X.T, axis = 1).T
	x_mu = np.matrix(X - mu[k])

	## covariances
	Sigma[k] = np.array(1 / N_ks[k] * np.dot(np.multiply(x_mu.T, R[:, k]), x_mu))

	## and finally the probabilities
	w[k] = 1. / n * N_ks[k]
	# check for onvergence
	if len(log_likelihoods) < 2 : continue
	if np.abs(log_likelihood - log_likelihoods[-2]) < self.eps: break

	## bind all results together
	from collections import namedtuple
	self.params = namedtuple('params', ['mu', 'Sigma', 'w', 'log_likelihoods', 'num_iters'])
	self.params.mu = mu
	self.params.Sigma = Sigma
	self.params.w = w
	self.params.log_likelihoods = log_likelihoods
	self.params.num_iters = len(log_likelihoods)

	return self.params

	def plot_log_likelihood(self):
	import pylab as plt
	plt.plot(self.params.log_likelihoods)
	plt.title('Log Likelihood vs iteration plot')
	plt.xlabel('Iterations')
	plt.ylabel('log likelihood')
	plt.show()

	def predict(self, x):
	p = lambda mu, s : np.linalg.det(s) ** - 0.5 * (2 * np.pi) **\
	(-len(x)/2) * np.exp( -0.5 * np.dot(x - mu , \
	np.dot(np.linalg.inv(s) , x - mu)))
	probs = np.array([w * p(mu, s) for mu, s, w in \
	zip(self.params.mu, self.params.Sigma, self.params.w)])
	return probs/np.sum(probs)


	def demo_2d():

	# Load data
	#X = np.genfromtxt('data1.csv', delimiter=',')
	### generate the random data
	np.random.seed(3)
	m1, cov1 = [9, 8], [[.5, 1], [.25, 1]] ## first gaussian
	data1 = np.random.multivariate_normal(m1, cov1, 90)

	m2, cov2 = [6, 13], [[.5, -.5], [-.5, .1]] ## second gaussian
	data2 = np.random.multivariate_normal(m2, cov2, 45)

	m3, cov3 = [4, 7], [[0.25, 0.5], [-0.1, 0.5]] ## third gaussian
	data3 = np.random.multivariate_normal(m3, cov3, 65)
	X = np.vstack((data1,np.vstack((data2,data3))))
	np.random.shuffle(X)
	# np.savetxt('sample.csv', X, fmt = "%.4f", delimiter = ",")
	####
	gmm = GMM(3, 0.000001)
	params = gmm.fit_EM(X, max_iters= 100)
	print params.log_likelihoods
	import pylab as plt
	from matplotlib.patches import Ellipse

	def plot_ellipse(pos, cov, nstd=2, ax=None, **kwargs):
	def eigsorted(cov):
	vals, vecs = np.linalg.eigh(cov)
	order = vals.argsort()[::-1]
	return vals[order], vecs[:,order]

	if ax is None:
	ax = plt.gca()

	vals, vecs = eigsorted(cov)
	theta = np.degrees(np.arctan2(*vecs[:,0][::-1]))

	# Width and height are "full" widths, not radius
	width, height = 2 * nstd * np.sqrt(abs(vals))
	ellip = Ellipse(xy=pos, width=width, height=height, angle=theta, **kwargs)

	ax.add_artist(ellip)
	return ellip

	def show(X, mu, cov):

	plt.cla()
	K = len(mu) # number of clusters
	colors = ['b', 'k', 'g', 'c', 'm', 'y', 'r']
	plt.plot(X.T[0], X.T[1], 'm*')
	for k in range(K):
	plot_ellipse(mu[k], cov[k], alpha=0.6, color = colors[k % len(colors)])


	fig = plt.figure(figsize = (13, 6))
	fig.add_subplot(121)
	show(X, params.mu, params.Sigma)
	fig.add_subplot(122)
	plt.plot(np.array(params.log_likelihoods))
	plt.title('Log Likelihood vs iteration plot')
	plt.xlabel('Iterations')
	plt.ylabel('log likelihood')
	plt.show()
	print gmm.predict(np.array([1, 2]))


	if __name__ == "__main__":

	demo_2d()
	from optparse import OptionParser

	parser = OptionParser()
	parser.add_option("-f", "--file", dest="filepath", help="File path for data")
	parser.add_option("-k", "--clusters", dest="clusters", help="No. of gaussians")
	parser.add_option("-e", "--eps", dest="epsilon", help="Epsilon to stop")
	parser.add_option("-m", "--maxiters", dest="max_iters", help="Maximum no. of iteration")
	options, args = parser.parse_args()

	if not options.filepath : raise('File not provided')

	if not options.clusters :
	print("Used default number of clusters = 3" )
	k = 3
	else: k = int(options.clusters)

	if not options.epsilon :
	print("Used default eps = 0.0001" )
	eps = 0.0001
	else: eps = float(options.epsilon)

	if not options.max_iters :
	print("Used default maxiters = 1000" )
	max_iters = 1000
	else: eps = int(options.maxiters)

	X = np.genfromtxt(options.filepath, delimiter=',')
	gmm = GMM(k, eps)
	params = gmm.fit_EM(X, max_iters)
	print params.log_likelihoods
	gmm.plot_log_likelihood()
	print gmm.predict(np.array([1, 2]))