### Problem #1

The most Matlab-like way for doing this I can think of is two-dimensional convolution (`conv2`

) (as I now see was commented by @rahnema1):

```
M = randi(9, 5, 5); % input: square matrix, arbitrary size
N = 3; % block size, assumed square, not larger than M
result = conv2(M, ones(N), 'valid');
```

Equivalently, you can use the recently introduced `movsum`

function, twice (once for each dimension):

```
result = movsum(movsum(M, N, 1, 'Endpoints', 'discard'), N, 2, 'Endpoints', 'discard');
```

Example:

```
M =
4 4 3 1 2
2 8 7 1 6
3 6 7 5 5
6 5 4 8 1
5 9 6 9 4
result =
44 42 37
48 51 44
51 59 49
```

### Problem #2

The simplest way (not the most efficient one) is to use convolution again with a logical matrix containing `true`

at the desired position and `false`

otherwise, and checking where the convolution is not zero:

```
in_coords = [3 4]; % example input coordinates
T = false(size(M)); % initiallize matrix containing false, same size as M
T(in_coords(1), in_coords(2)) = true; % true at the desired coordinates
C = conv2(T, ones(N), 'valid'); % this gives 1 for blocks affected by in_coords
[ii, jj] = find(C); % row and column indices of nonzero values
out_coords = [ii jj]; % build result
```

In this example,

```
out_coords =
1 2
2 2
3 2
1 3
2 3
3 3
```

`result = conv2(A, ones(10), 'valid');`