Suppose we have a matrix of size NxN of numbers where all the rows and columns are in increasing order, and we want to find if it contains a value v. One algorithm is to perform a binary search on the middle row, to find the elements closest in value to v: M[row,col] < v < M[row,col+1] (if we find v exactly, the search is complete). Since the matrix is sorted we know that v is larger than all elements in the sub-matrix M[0..row, 0..col] (the top-left quadrant of the matrix), and similarly it's smaller than all elements in the sub-matrix M[row..N-1, col+1..N-1] (the bottom right quadrant). So we can recursively search the top right quadrant M[0..row-1, col+1..N-1] and the bottom left quadrant M[row+1..N-1, 0..col].

The question is what is the complexity of this algorithm ?

Example: Suppose we have the 5x5 matrix shown below and we are searching for the number 25:

```
0 10 20 30 40
1 11 21 31 41
2 12 22 32 42
3 13 23 33 43
4 14 24 34 44
```

In the first iteration we perform binary search on the middle row and find the closest element which is smaller than 25 is 22 (at row=2 col=2). So now we know 25 is larger than all items in the top-left 3x3 quadrant:

```
0 10 20
1 11 21
2 12 22
```

Similary we know 25 is smaller than all elements in the bottom right 3x2 quadrant:

```
32 42
33 43
34 44
```

So, we recursively search the remaining quadrants - the top right 2x2:

```
30 40
31 41
```

and the bottom left 2x3:

```
3 13 23
4 14 24
```

And so on. We essentially divided the matrix into 4 quadrants (which might be of different sizes depending on the result of the binary search on the middle row), and then we recursively search two of the quadrants.