For the general case where you have `N`

different strings and each of these strings occurs a different number of times `M_i`

, then each corresponding set of values in `B`

will have a different length and you won't be able to concatenate the sets together into a numeric array. You will instead have to store the sets in an `N`

-element cell array, and you can do this using the functions UNIQUE and ACCUMARRAY:

```
>> A = {'a' 'b' 'b' 'c' 'a' 'a' 'a' 'c' 'd' 'b'}; %# Sample array A
>> B = 1:10; %# Sample array B
>> [uniqueStrings,~,index] = unique(A)
>> associatedValues = accumarray(index(:),B,[],@(x) {x})
associatedValues =
[4x1 double] %# The values 1, 5, 6, and 7
[3x1 double] %# The values 2, 3, and 10
[2x1 double] %# The values 4 and 8
[ 9] %# The value 9
```

In the specific case where each string occurs the same number of times the above code will still work just fine, and you will have the option of converting the output from a cell array to the desired numeric array like so:

```
associatedValues = [associatedValues{:}];
```

**NOTE:** Since ACCUMARRAY is not guaranteed to maintain the relative order of items it accumulates, the order of items within the cells of `associatedValues`

may not match the relative order they had in the vector `B`

. One way to ensure that the original relative order in `B`

is maintained is to modify the call to ACCUMARRAY as follows:

```
associatedValues = accumarray(index(:),1:numel(B),[],@(x) {B(sort(x))});
```

Or you could sort the inputs to ACCUMARRAY to get the same effect:

```
[index,sortIndex] = sort(index);
associatedValues = accumarray(index(:),B(sortIndex),[],@(x) {x});
```