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1 %DEMGMM4 Demonstrate density modelling with a Gaussian mixture model.
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2 %
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3 % Description
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4 % The problem consists of modelling data generated by a mixture of
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5 % three Gaussians in 2 dimensions with a mixture model using full
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6 % covariance matrices. The priors are 0.3, 0.5 and 0.2; the centres
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7 % are (2, 3.5), (0, 0) and (0,2); the variances are (0.16, 0.64) axis
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8 % aligned, (0.25, 1) rotated by 30 degrees and the identity matrix. The
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9 % first figure contains a scatter plot of the data.
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10 %
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11 % A Gaussian mixture model with three components is trained using EM.
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12 % The parameter vector is printed before training and after training.
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13 % The user should press any key to continue at these points. The
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14 % parameter vector consists of priors (the column), and centres (given
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15 % as (x, y) pairs as the next two columns). The covariance matrices
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16 % are printed separately.
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17 %
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18 % The second figure is a 3 dimensional view of the density function,
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19 % while the third shows the axes of the 1-standard deviation ellipses
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20 % for the three components of the mixture model.
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21 %
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22 % See also
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23 % GMM, GMMINIT, GMMEM, GMMPROB, GMMUNPAK
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24 %
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25
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26 % Copyright (c) Ian T Nabney (1996-2001)
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27
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28
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29 % Generate the data
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30
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31 ndata = 500;
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32
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33 % Fix the seeds for reproducible results
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34 randn('state', 42);
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35 rand('state', 42);
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36 data = randn(ndata, 2);
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37 prior = [0.3 0.5 0.2];
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38 % Mixture model swaps clusters 1 and 3
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39 datap = [0.2 0.5 0.3];
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40 datac = [0 2; 0 0; 2 3.5];
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41 datacov = repmat(eye(2), [1 1 3]);
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42 data1 = data(1:prior(1)*ndata,:);
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43 data2 = data(prior(1)*ndata+1:(prior(2)+prior(1))*ndata, :);
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44 data3 = data((prior(1)+prior(2))*ndata +1:ndata, :);
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45
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46 % First cluster has axis aligned variance and centre (2, 3.5)
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47 data1(:, 1) = data1(:, 1)*0.4 + 2.0;
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48 data1(:, 2) = data1(:, 2)*0.8 + 3.5;
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49 datacov(:, :, 3) = [0.4*0.4 0; 0 0.8*0.8];
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50
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51 % Second cluster has variance axes rotated by 30 degrees and centre (0, 0)
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52 rotn = [cos(pi/6) -sin(pi/6); sin(pi/6) cos(pi/6)];
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53 data2(:,1) = data2(:, 1)*0.5;
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54 data2 = data2*rotn;
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55 datacov(:, :, 2) = rotn' * [0.25 0; 0 1] * rotn;
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56
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57 % Third cluster is at (0,2)
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58 data3 = data3 + repmat([0 2], prior(3)*ndata, 1);
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59
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60 % Put the dataset together again
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61 data = [data1; data2; data3];
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62
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63 clc
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64 disp('This demonstration illustrates the use of a Gaussian mixture model')
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65 disp('with full covariance matrices to approximate the unconditional ')
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66 disp('probability density of data in a two-dimensional space.')
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67 disp('We begin by generating the data from a mixture of three Gaussians and')
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68 disp('plotting it.')
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69 disp(' ')
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70 disp('The first cluster has axis aligned variance and centre (0, 2).')
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71 disp('The second cluster has variance axes rotated by 30 degrees')
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72 disp('and centre (0, 0). The third cluster has unit variance and centre')
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73 disp('(2, 3.5).')
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74 disp(' ')
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75 disp('Press any key to continue.')
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76 pause
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77
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78 fh1 = figure;
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79 plot(data(:, 1), data(:, 2), 'o')
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80 set(gca, 'Box', 'on')
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81
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82 % Set up mixture model
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83 ncentres = 3;
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84 input_dim = 2;
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85 mix = gmm(input_dim, ncentres, 'full');
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86
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87 % Initialise the model parameters from the data
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88 options = foptions;
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89 options(14) = 5; % Just use 5 iterations of k-means in initialisation
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90 mix = gmminit(mix, data, options);
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91
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92 % Print out model
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93 clc
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94 disp('The mixture model has three components and full covariance')
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95 disp('matrices. The model parameters after initialisation using the')
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96 disp('k-means algorithm are as follows')
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97 disp(' Priors Centres')
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98 disp([mix.priors' mix.centres])
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99 disp('Covariance matrices are')
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100 disp(mix.covars)
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101 disp('Press any key to continue.')
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102 pause
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103
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104 % Set up vector of options for EM trainer
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105 options = zeros(1, 18);
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106 options(1) = 1; % Prints out error values.
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107 options(14) = 50; % Number of iterations.
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108
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109 disp('We now train the model using the EM algorithm for 50 iterations.')
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110 disp(' ')
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111 disp('Press any key to continue.')
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112 pause
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113 [mix, options, errlog] = gmmem(mix, data, options);
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114
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115 % Print out model
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116 disp(' ')
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117 disp('The trained model has priors and centres:')
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118 disp(' Priors Centres')
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119 disp([mix.priors' mix.centres])
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120 disp('The data generator has priors and centres')
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121 disp(' Priors Centres')
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122 disp([datap' datac])
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123 disp('Model covariance matrices are')
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124 disp(mix.covars(:, :, 1))
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125 disp(mix.covars(:, :, 2))
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126 disp(mix.covars(:, :, 3))
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127 disp('Data generator covariance matrices are')
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128 disp(datacov(:, :, 1))
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129 disp(datacov(:, :, 2))
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130 disp(datacov(:, :, 3))
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131 disp('Note the close correspondence between these parameters and those')
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132 disp('of the distribution used to generate the data. The match for')
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133 disp('covariance matrices is not that close, but would be improved with')
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134 disp('more iterations of the training algorithm.')
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135 disp(' ')
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136 disp('Press any key to continue.')
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137 pause
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138
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139 clc
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140 disp('We now plot the density given by the mixture model as a surface plot.')
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141 disp(' ')
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142 disp('Press any key to continue.')
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143 pause
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144
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145 % Plot the result
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146 x = -4.0:0.2:5.0;
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147 y = -4.0:0.2:5.0;
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148 [X, Y] = meshgrid(x,y);
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149 X = X(:);
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150 Y = Y(:);
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151 grid = [X Y];
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152 Z = gmmprob(mix, grid);
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153 Z = reshape(Z, length(x), length(y));
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154 c = mesh(x, y, Z);
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155 hold on
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156 title('Surface plot of probability density')
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157 hold off
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158 drawnow
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159
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160 clc
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161 disp('The final plot shows the centres and widths, given by one standard')
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162 disp('deviation, of the three components of the mixture model. The axes')
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163 disp('of the ellipses of constant density are shown.')
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164 disp(' ')
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165 disp('Press any key to continue.')
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166 pause
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167
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168 % Try to calculate a sensible position for the second figure, below the first
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169 fig1_pos = get(fh1, 'Position');
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170 fig2_pos = fig1_pos;
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171 fig2_pos(2) = fig2_pos(2) - fig1_pos(4) - 30;
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172 fh2 = figure('Position', fig2_pos);
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173
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174 h3 = plot(data(:, 1), data(:, 2), 'bo');
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175 axis equal;
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176 hold on
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177 title('Plot of data and covariances')
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178 for i = 1:ncentres
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179 [v,d] = eig(mix.covars(:,:,i));
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180 for j = 1:2
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181 % Ensure that eigenvector has unit length
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182 v(:,j) = v(:,j)/norm(v(:,j));
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183 start=mix.centres(i,:)-sqrt(d(j,j))*(v(:,j)');
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184 endpt=mix.centres(i,:)+sqrt(d(j,j))*(v(:,j)');
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185 linex = [start(1) endpt(1)];
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186 liney = [start(2) endpt(2)];
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187 line(linex, liney, 'Color', 'k', 'LineWidth', 3)
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188 end
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189 % Plot ellipses of one standard deviation
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190 theta = 0:0.02:2*pi;
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191 x = sqrt(d(1,1))*cos(theta);
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192 y = sqrt(d(2,2))*sin(theta);
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193 % Rotate ellipse axes
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194 ellipse = (v*([x; y]))';
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195 % Adjust centre
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196 ellipse = ellipse + ones(length(theta), 1)*mix.centres(i,:);
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197 plot(ellipse(:,1), ellipse(:,2), 'r-');
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198 end
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199 hold off
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200
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201 disp('Note how the data cluster positions and widths are captured by')
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202 disp('the mixture model.')
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203 disp(' ')
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204 disp('Press any key to end.')
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205 pause
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206
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207 close(fh1);
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208 close(fh2);
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209 clear all;
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210
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