I'm not sure if this is exactly what you wanted, cause it results in 31626x2092 data points, but since you said to take the difference of the columns...

```
data=ceil(rand(7,5)*10); % some sample data, works with any matrix(at least 2 columns of course)
N = size(data,2);
%b=cell(N-1,1);
c=NaN(size(data,1),N*(N-1)/2); % preallocate result matrix
kk=0;
for ii=1:N-1
%b{ii} = bsxfun(@minus,data(:,ii),data(:,ii+1:end));
c(:,kk+(1:N-ii)) = bsxfun(@minus,data(:,ii),data(:,ii+1:end));
kk=kk+N-ii;
end
```

Key here is that in each looping step, you select just the part of the matrix you want to perform the `minus`

operation on, ie: `data(:,ii)`

(= the ii'th column) and `data(:,ii+1:end)`

(= all remaining columns, from the ii'th up to the end of the matrix)

The bsxfun function description says:

*Apply element-by-element binary operation to two arrays with singleton expansion enabled*

That singleton expansion is what I'm using up here, bsxfun sees the two input being one column and a matrix with same sized columns, and expands the column to be same size as the matrix (=singleton expansion (row dimension gets expanded) )

So if you want the rows to be subtracted from each other, you can just provide a row and the same matrix as before, and it'll also know what to do, ie expand the row vector along the column dimension:

```
N = size(data,1);
%b=cell(N-1,1);
c=NaN(N*(N-1)/2,size(data,2)); % preallocate result matrix
kk=0;
for ii=1:N-1
%b{ii} = bsxfun(@minus,data(ii,:),data(ii+1:end,:));
c(kk+(1:N-ii),:) = bsxfun(@minus,data(ii,:),data(ii+1:end,:));
kk=kk+N-ii;
end
```

As you can see, the indexing of all the matrices switched places: `A(i,j)`

changed to `A(j,i)`

.

Using cells for the result matrices in each step in the loop would allow easier access to the result, but since you wanted the result in one variable (matrix I assume), I commented those out.

**EDIT**

on preallocating: http://www.mathworks.nl/help/techdoc/matlab_prog/f8-784135.html

```
c(:,kk+(1:N-ii));
kk=kk+N-ii
```

is the indexing, which was the most tricky:

When ii=1 you have 251 columns to insert: that'll be column 1->251 in the output variable

ii=2 -> 250 columns, column 252->501 in the output

ii=3 -> 249 columns, column 502->750 in the output

ii=4 => 248 columns, column 751->999 in the output

etc.

The `kk+(1:N-ii)`

is essentially doing that: selecting the appropriate columns for the output of `bsxfun`

.

The variable `kk`

is the number of columns already saved into the output variable `c`

, so obviously it starts at zero. If you change it to another value, say `kk_init`

, the first `kk_init`

columns of `c`

would remain empty and the resulting `c`

matrix will have `N*(N-1)/2+kk_init`

columns instead of `N*(N-1)/2`

.