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<source lang="lisp">
 
  
x=1:n
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for j=1:100
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==Function to compute Bayes error (based on Monte-Carlo method)==
j=j+1
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<source lang="matlab">
 +
 
 +
function [ e ] = BayesErrorMonteCarlo( n, P1, M1, Sigma1, P2, M2, Sigma2, N )
 +
%Compute Bayes Error using Monte-Carlo method
 +
%J. Zhou
 +
 
 +
% ....Input Parameters
 +
% n --- data dimension
 +
% P1 --- prior probability of class 1
 +
% M1 --- mean of class 1 data
 +
% Sigma1 --- covariance of class 1 data
 +
% p2 --- prior probability of class 2
 +
% M2 --- mean of class 2 data
 +
% Sigma2 --- covariance of class 2 data
 +
% N --- number of samples using in Monte-Carlo
 +
 
 +
%....Output Parameters
 +
% e --- Bayes Error
 +
 
 +
x1 = randn(n,N);
 +
y1 = discFunc(x1, P1, M1, Sigma1, P2, M2, Sigma2, 1);
 +
e1 = y1/N;
 +
 
 +
 
 +
temp = randn(n,N);
 +
x2 = sqrt(Sigma2)*temp + repmat(M2, 1, N);
 +
y2 = discFunc(x2, P1, M1, Sigma1, P2, M2, Sigma2, 2);
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e2 = y2/N;
 +
 
 +
% Bayes Error e
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e = P1*e1+P2*e2;
 +
 
 +
 
 
end
 
end
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</source>
 +
 +
==Function #1 used in previous code==
 +
<source lang="matlab">
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function [ z ] = discFunc(x,P1,M1,Sigma1,P2,M2,Sigma2, CFlag)
 +
%compute 3.119 and return number of samples that are misclassified
 +
%J. Zhou
 +
 +
[N,M] = size(x); %M samples
 +
 +
invSigma1 = inv(Sigma1);
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invSigma2 = inv(Sigma2);
 +
temp = 0.5*log(det(Sigma1)/det(Sigma2)) - log(P1/P2);
 +
 +
y = zeros(1,M);
 +
 +
for i = 1:M         
 +
   
 +
        if  0.5*(x(:,i)-M1)'*invSigma1*(x(:,i)-M1) - ...
 +
                0.5*(x(:,i)-M2)'*invSigma2*(x(:,i)-M2) + temp > 0 
 +
            if CFlag == 1
 +
                y(i) = 1;
 +
            else
 +
                y(i) = 0;
 +
            end
 +
        else
 +
            if CFlag == 1
 +
                y(i) = 0;
 +
            else
 +
                y(i) = 1;
 +
            end
 +
        end
 +
       
 +
end
 +
 +
z = sum(y);
 +
 +
end
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</source>
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----
 +
==Test Function ==
 +
<source lang="matlab">
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%% ECE662
 +
% This code tests BayesErrorMonteCarlo.m using a data set with known
 +
% Bayes Error
 +
% J. Zhou
 +
 +
close all;
 +
clear all;
 +
 +
% test data using Data I-^ ; Fukunaga page 45
 +
n = 8;  %data dimension
 +
 +
P1 = 0.5; % prior probability for class 1
 +
M1 = zeros(n, 1);  %mean of class 1 data
 +
Sigma1 = eye(n,n);  %covariance of class 1 data
 +
 +
P2 = 0.5; % prior probability for class 2
 +
M2 = [3.86, 3.10, 0.84, 0.84, 1.64, 1.08, 0.26, 0.01]';
 +
Sigma2 = diag([8.41, 12.06, 0.12, 0.22, 1.49, 1.77, 0.35, 2.73]);
 +
 +
 +
%Number of samples for Monte-Carlo, start with 1 million, run a few times
 +
%to see how much computed Bayes error vary, if it varies quite bit, then
 +
%increase the number of samples, do this until Bayes error become
 +
%relatively stable.
 +
N = 1000000; 
 +
 +
e = BayesErrorMonteCarlo(n, P1, M1, Sigma1, P2, M2, Sigma2, N );
 +
 +
% Bayes Error in this case should 1.46%
 +
sprintf('Bayes Error in this case should be %.3f', 0.018)
  
 +
sprintf('Bayes Error computed is %.3f', e)
 
</source>
 
</source>

Revision as of 18:46, 4 February 2016


Function to compute Bayes error (based on Monte-Carlo method)

function [ e ] = BayesErrorMonteCarlo( n, P1, M1, Sigma1, P2, M2, Sigma2, N )
%Compute Bayes Error using Monte-Carlo method
%J. Zhou
 
% ....Input Parameters
% n --- data dimension
% P1 --- prior probability of class 1
% M1 --- mean of class 1 data
% Sigma1 --- covariance of class 1 data
% p2 --- prior probability of class 2
% M2 --- mean of class 2 data
% Sigma2 --- covariance of class 2 data
% N --- number of samples using in Monte-Carlo
 
%....Output Parameters
% e --- Bayes Error
 
x1 = randn(n,N);
y1 = discFunc(x1, P1, M1, Sigma1, P2, M2, Sigma2, 1); 
e1 = y1/N;
 
 
temp = randn(n,N);
x2 = sqrt(Sigma2)*temp + repmat(M2, 1, N);
y2 = discFunc(x2, P1, M1, Sigma1, P2, M2, Sigma2, 2);
e2 = y2/N;
 
% Bayes Error e
e = P1*e1+P2*e2;
 
 
end

Function #1 used in previous code

function [ z ] = discFunc(x,P1,M1,Sigma1,P2,M2,Sigma2, CFlag)
%compute 3.119 and return number of samples that are misclassified
%J. Zhou
 
[N,M] = size(x); %M samples
 
invSigma1 = inv(Sigma1);
invSigma2 = inv(Sigma2);
temp = 0.5*log(det(Sigma1)/det(Sigma2)) - log(P1/P2);
 
y = zeros(1,M);
 
for i = 1:M          
 
        if  0.5*(x(:,i)-M1)'*invSigma1*(x(:,i)-M1) - ...
                0.5*(x(:,i)-M2)'*invSigma2*(x(:,i)-M2) + temp > 0   
            if CFlag == 1
                y(i) = 1;
            else
                y(i) = 0;
            end
        else
            if CFlag == 1
                y(i) = 0;
            else
                y(i) = 1;
            end
        end
 
end
 
z = sum(y);
 
end

Test Function

%% ECE662 
% This code tests BayesErrorMonteCarlo.m using a data set with known
% Bayes Error
% J. Zhou
 
close all;
clear all;
 
% test data using Data I-^ ; Fukunaga page 45
n = 8;   %data dimension
 
P1 = 0.5; % prior probability for class 1
M1 = zeros(n, 1);  %mean of class 1 data
Sigma1 = eye(n,n);  %covariance of class 1 data
 
P2 = 0.5; % prior probability for class 2
M2 = [3.86, 3.10, 0.84, 0.84, 1.64, 1.08, 0.26, 0.01]';
Sigma2 = diag([8.41, 12.06, 0.12, 0.22, 1.49, 1.77, 0.35, 2.73]);
 
 
%Number of samples for Monte-Carlo, start with 1 million, run a few times
%to see how much computed Bayes error vary, if it varies quite bit, then
%increase the number of samples, do this until Bayes error become
%relatively stable. 
N = 1000000;  
 
e = BayesErrorMonteCarlo(n, P1, M1, Sigma1, P2, M2, Sigma2, N );
 
% Bayes Error in this case should 1.46%
sprintf('Bayes Error in this case should be %.3f', 0.018)
 
sprintf('Bayes Error computed is %.3f', e)

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