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I want to normalise each column of a matrix in Matlab. I have tried two implementations:

Option A:

mx=max(x);
mn=min(x);
mmd=mx-mn;
for i=1:size(x,1)
    xn(i,:)=((x(i,:)-mn+(mmd==0))./(mmd+(mmd==0)*2))*2-1; 
end

Option B:

mn=mean(x);
sdx=std(x);
for i=1:size(x,1)
    xn(i,:)=(x(i,:)-mn)./(sdx+(sdx==0));
end

However, these options take too much time for my data, e.g. 3-4 seconds on a 5000x53 matrix. Thus, is there any better solution?

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4 Answers 4

up vote 3 down vote accepted

Remember, in matlab, vectorizing = speed.

If A is an M x N matrix,

A = rand(m,n)
normA = max(A) - min(A);               % this is a vector
normA = repmat(normA, [length(a) 1]);  % this makes it a matrix
                                       % of the same size as A
normalizedA = A./normA;  % your normalized matrix
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3  
You may want to subtract the minimum from A before you divide in order to normalize it to [0...1] –  Jonas Dec 23 '10 at 21:10
4  
Why was this marked as the solution? It doesn't normalize each column. –  erikb85 May 20 '12 at 13:22

Use bsxfun instead of the loop. This may be a bit faster; however, it may also use more memory (which may be an issue in your case; if you're paging, everything'll be really slow).

To normalize with mean and std, you'd write

mn = mean(x);
sd = std(x);
sd(sd==0) = 1;

xn = bsxfun(@minus,x,mn);
xn = bsxfun(@rdivide,xn,sd);
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@gnovice: Thanks! –  Jonas Dec 24 '10 at 13:42
    
Why do you use sd(sd==0) = 1; instead of sd(sd==0) = eps; ? –  tashuhka Jul 9 at 11:02
    
@tashuhka: because I divide by the value of sd later. If I divide by 1, the result is unchanged; if I divide by eps, the result is multiplied by a large number. –  Jonas Jul 28 at 7:55
    
thank you for your reply. I guess this is a matter of preference. The operation 0/eps returns always zero, so there is not problem with the division. However, if I want to keep the sd matrix for further analysis, the eps value gives a better representation of the actual variability than zero. –  tashuhka Jul 31 at 10:31

Let X be a mxn matrix and you want to normalize collumn wise.

The following matlab code does it

XMean = repmat(mean(X),m,1);
XVariance = repmat(var(X),m,1);
X_norm = (X - XMean)./(XVariance);

The element wise ./ operator is explained here: http://www.mathworks.in/help/matlab/ref/arithmeticoperators.html

Note: As op mentioned, this is simply a faster solution and performs the same task as looping through the matrix. The underlying implementation of this inbuilt function makes it work faster

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Note: I am not providing a freshly new answer, but I am comparing the proposed answers.

Option A: Using bsxfun()

function xn = normalizeBsxfun(x)

    mn = mean(x);
    sd = std(x);
    sd(sd==0) = eps;

    xn = bsxfun(@minus,x,mn);
    xn = bsxfun(@rdivide,xn,sd);

end

Option B: Using a for-loop

function xn = normalizeLoop(x)

    xn = zeros(size(x));

    for ii=1:size(x,2)
        xaux = x(:,ii);
        xn(:,ii) = (xaux - mean(xaux))./mean(xaux);
    end

end

We compare both implementations for different matrix sizes:

expList = 2:0.5:5;
for ii=1:numel(expList)
    expNum = round(10^expList(ii));
    x = rand(expNum,expNum); 
    tic;
    xn = normalizeBsxfun(x);
    ts(ii) = toc; 
    tic;
    xn = normalizeLoop(x);
    tl(ii) = toc; 
end

figure;
hold on;
plot(round(10.^expList),ts,'b');
plot(round(10.^expList),tl,'r');
legend('bsxfun','loop');
set(gca,'YScale','log') 

The results show that for small matrices, the bsxfun is faster. But, the difference is neglect able for higher dimensions, as it was also found in other post.

enter image description here

The x-axis is the squared root number of matrix elements, while the y-axis is the computation time in seconds.

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