Mercurial > hg > camir-aes2014
view toolboxes/FullBNT-1.0.7/KPMtools/plotgauss2d.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
|---|---|
| date | Tue, 10 Feb 2015 15:05:51 +0000 |
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function h=plotgauss2d(mu, Sigma) % PLOTGAUSS2D Plot a 2D Gaussian as an ellipse with optional cross hairs % h=plotgauss2(mu, Sigma) % h = plotcov2(mu, Sigma); return; %%%%%%%%%%%%%%%%%%%%%%%% % PLOTCOV2 - Plots a covariance ellipse with major and minor axes % for a bivariate Gaussian distribution. % % Usage: % h = plotcov2(mu, Sigma[, OPTIONS]); % % Inputs: % mu - a 2 x 1 vector giving the mean of the distribution. % Sigma - a 2 x 2 symmetric positive semi-definite matrix giving % the covariance of the distribution (or the zero matrix). % % Options: % 'conf' - a scalar between 0 and 1 giving the confidence % interval (i.e., the fraction of probability mass to % be enclosed by the ellipse); default is 0.9. % 'num-pts' - the number of points to be used to plot the % ellipse; default is 100. % % This function also accepts options for PLOT. % % Outputs: % h - a vector of figure handles to the ellipse boundary and % its major and minor axes % % See also: PLOTCOV3 % Copyright (C) 2002 Mark A. Paskin function h = plotcov2(mu, Sigma, varargin) if size(Sigma) ~= [2 2], error('Sigma must be a 2 by 2 matrix'); end if length(mu) ~= 2, error('mu must be a 2 by 1 vector'); end [p, ... n, ... plot_opts] = process_options(varargin, 'conf', 0.9, ... 'num-pts', 100); h = []; holding = ishold; if (Sigma == zeros(2, 2)) z = mu; else % Compute the Mahalanobis radius of the ellipsoid that encloses % the desired probability mass. k = conf2mahal(p, 2); % The major and minor axes of the covariance ellipse are given by % the eigenvectors of the covariance matrix. Their lengths (for % the ellipse with unit Mahalanobis radius) are given by the % square roots of the corresponding eigenvalues. if (issparse(Sigma)) [V, D] = eigs(Sigma); else [V, D] = eig(Sigma); end % Compute the points on the surface of the ellipse. t = linspace(0, 2*pi, n); u = [cos(t); sin(t)]; w = (k * V * sqrt(D)) * u; z = repmat(mu, [1 n]) + w; % Plot the major and minor axes. L = k * sqrt(diag(D)); h = plot([mu(1); mu(1) + L(1) * V(1, 1)], ... [mu(2); mu(2) + L(1) * V(2, 1)], plot_opts{:}); hold on; h = [h; plot([mu(1); mu(1) + L(2) * V(1, 2)], ... [mu(2); mu(2) + L(2) * V(2, 2)], plot_opts{:})]; end h = [h; plot(z(1, :), z(2, :), plot_opts{:})]; if (~holding) hold off; end %%%%%%%%%%%% % CONF2MAHAL - Translates a confidence interval to a Mahalanobis % distance. Consider a multivariate Gaussian % distribution of the form % % p(x) = 1/sqrt((2 * pi)^d * det(C)) * exp((-1/2) * MD(x, m, inv(C))) % % where MD(x, m, P) is the Mahalanobis distance from x % to m under P: % % MD(x, m, P) = (x - m) * P * (x - m)' % % A particular Mahalanobis distance k identifies an % ellipsoid centered at the mean of the distribution. % The confidence interval associated with this ellipsoid % is the probability mass enclosed by it. Similarly, % a particular confidence interval uniquely determines % an ellipsoid with a fixed Mahalanobis distance. % % If X is an d dimensional Gaussian-distributed vector, % then the Mahalanobis distance of X is distributed % according to the Chi-squared distribution with d % degrees of freedom. Thus, the Mahalanobis distance is % determined by evaluating the inverse cumulative % distribution function of the chi squared distribution % up to the confidence value. % % Usage: % % m = conf2mahal(c, d); % % Inputs: % % c - the confidence interval % d - the number of dimensions of the Gaussian distribution % % Outputs: % % m - the Mahalanobis radius of the ellipsoid enclosing the % fraction c of the distribution's probability mass % % See also: MAHAL2CONF % Copyright (C) 2002 Mark A. Paskin function m = conf2mahal(c, d) m = chi2inv(c, d); % matlab stats toolbox