To find overlapping intervals, you need to check if the start-time or the end-time of one interval falls within the boundaries of another. To do that with for all intervals at once, you could use `bsxfun`

:

```
ovlp = @(x, y)bsxfun(@ge, x(:, 1), y(:, 1)') & bsxfun(@le, x(:, 1), y(:, 2)');
idx = ovlp(intervals_a, intervals_b) | ovlp(intervals_b, intervals_a)';
[row, col] = ind2sub(size(idx), find(idx));
output = [row, col];
```

### Example

Let's see how this works for your example:

```
intervals_a = [0 1; 1 4; 4 7; 7 9]
intervals_b = [0 2; 2 3; 3 5; 5 8]
```

The anonymous function `ovlp`

checks if the start-times in `x`

(that is, `x(:, 1)`

) fall inside the intervals given in `y`

. Therefore, `ovlp(intervals_a, intervals_b)`

yields:

```
ans =
1 0 0 0
1 0 0 0
0 0 1 0
0 0 0 1
```

The '1's indicate where start-time of interval_a falls inside interval_b. The row number is the index of the interval in `intervals_a`

, and the column number is the index of the interval in `intervals_b`

.

We need to do the same process for the start-times of `intervals_b`

to find all the overlapping intervals, and we do a logical OR between the two results:

```
idx = ovlp(intervals_a, intervals_b) | ovlp(intervals_b, intervals_a)'
```

Notice that the second result is transposed, to keep the rows corresponding with `intervals_a`

and not `intervals_b`

. The resulting matrix `idx`

is:

```
idx =
1 0 0 0
1 1 1 0
0 0 1 1
0 0 0 1
```

The final step is to translate the matrix `idx`

into indices in `intervals_a`

and `intervals_b`

, so we obtain the row and column numbers of the '1's and concatenate them:

```
[row, col] = ind2sub(size(idx), find(idx));
output = [row, col];
```

The final result is:

```
output =
1 1
2 1
2 2
2 3
3 3
3 4
4 4
```