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In generalisation of my previous question, how can a weighted average over cell elements (that are and shall remain arrays themselves) be performed?

I'd start by modifying gnovice's answer like this:

dim = ndims(c{1});          %# Get the number of dimensions for your arrays
M = cat(dim+1,c{:});        %# Convert to a (dim+1)-dimensional matrix
meanArray = sum(M.*weigth,dim+1)./sum(weigth,dim+1);  %# Get the weighted mean across arrays

And before that make sure weight has the correct shape. The three cases that I think need to be taken care of are

  1. weight = 1 (or any constant) => return the usual mean value
  2. numel(weight) == length(c) => weight is per cell-element c{n} (but equal for each array element for fixed n)
  3. numel(weight) == numel(cell2mat(c)) => each array-element has its own weight...

Case one is easy, and case 3 unlikely to happen so at the moment I'm interested in case 2: How can I transform weight into a array such that M.*weight has the correct dimensions in the sum above? Of course an answer that shows another way to obtain a weighted averaged is appreciated as well.

edit In fact, case 3 is even more trivial(what a tautology, apologies) than case 1 if weight has the same structure as c.

Here's an example of what I mean for case 2:

c = { [1 2 3; 1 2 3], [4 8 3; 4 2 6] };
weight = [ 2, 1 ];

should return

meanArray = [ 2 4 3; 2 2 4 ]

(e.g. for the first element (2*1 + 1*4)/(2+1) = 2)

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Have you thought of making it a function, using varargin and parsing the weight argument according to the three criteria you listed above? –  Phonon Mar 8 '11 at 15:01
For case (2), it would be interesting to look at sub2ind in order to convert both your weight vector and your c cell into linear indexing. You will lose the structure for this calculation, but you're calculating an average anyway. Just thinking out loud... –  Phonon Mar 8 '11 at 15:06
@Phonon: re 1) yes, that's the frame around it, now I only need to figure out how to reshape/repmat/...? weight correctly for each case. re 2) I think I didn't get your point about sub2int, but also to clarify what I want: the structure of meanArray shall be the same as that of c{1}, i.e. I don't want the one average over all element but for each array position individually –  Tobias Kienzler Mar 9 '11 at 9:26

1 Answer 1

up vote 1 down vote accepted

After familiarizing myself with REPMAT, now here's my solution:

function meanArray = cellMean(c, weight)
% meanArray = cellMean(c, [weight=1])
% mean over the elements of a cell c, keeping matrix structures of cell
% elements etc. Use weight if given.

% based on http://stackoverflow.com/q/5197692/321973, courtesy of gnovice
% (http://stackoverflow.com/users/52738/gnovice)
% extended to weighted averaging by Tobias Kienzler
% (see also http://stackoverflow.com/q/5231406/321973)

dim = ndims(c{1});          %# Get the number of dimensions for your arrays
if ~exist('weight', 'var') || isempty(weight); weight = 1; end;
eins = ones(size(c{1})); % that is german for "one", creative, I know...
if ~iscell(weight)
    % ignore length if all elements are equal, this is case 1
    if isequal(weight./max(weight(:)), ones(size(weight)))
        weight = repmat(eins, [size(eins)>0 length(c)]);
    elseif isequal(numel(weight), length(c)) % case 2: per cell-array weigth
        weight = repmat(shiftdim(weight, -3), [size(eins) 1]);
        error(['Weird weight dimensions: ' num2str(size(weight))]);
else % case 3, insert some dimension check here if you want
    weight = cat(dim+1,weight{:});

M = cat(dim+1,c{:});        %# Convert to a (dim+1)-dimensional matrix
sumc = sum(M.*weight,dim+1);
sumw = sum(weight,dim+1);
meanArray = sumc./sumw;  %# Get the weighted mean across arrays
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