Here's a way how to do this. Basically, your array is a hankel matrix plus vectors of 1:m, where m is the number of elements in each diagonal. Maybe someone else has a neat idea on how to create the diagonal arrays that have to be added to the flipped hankel array without a loop.
I think this should be generalizeable to a non-square array.
% for a 3x3 array
numElementsPerDiagonal = [1:n,n-1:-1:1];
hadaRC = cumsum([0,numElementsPerDiagonal(1:end-1)]);
array2add = fliplr(hankel(hadaRC(1:n),hadaRC(end-n+1:n)));
% loop through the hankel array and add numbers counting either up or down
% if they are even or odd
for d = 1:(2*n-1)
% even, count down
array2add = array2add + diag(1:numElementsPerDiagonal(d),d-n);
% odd, count up
array2add = array2add + diag(numElementsPerDiagonal(d):-1:1,d-n);
% now flip to get the result
indexMatrix = fliplr(array2add)
1 2 6
3 5 7
4 8 9
Afterward, you just call
reshape(image(indexMatrix),,1) to get the vector of reordered elements.
Ok, from your comment it looks like you need to use
sort like Marc suggested.
indexMatrixT = indexMatrix'; % ' SO formatting
[dummy,sortedIdx] = sort(indexMatrixT(:));
1 2 4 7 5 3 6 8 9
Note that you'd need to transpose your input matrix first before you index, because Matlab counts first down, then right.