You know how to compute maximum sum sub-array on a 1D array using Kadane's algorithm. Now we want to extend this algorithm for the 2D array. For an O(N^3) algorithm, we have an intuition. If we somehow create N^2 sub problems and then try to run our O(N) Kadane's algorithm, we can solve the maximum sub array problem.

So basically how we create the N^2 sub problems is by iterating over all the top and bottom rows of the matrix. Then we try to find the optimal columns between which the sub array exists by applying kadane's 1D algorithm. We thus sum the numbers between these two rows column wise and then apply kadane's 1D algorithm on this newly formed 1D array.

But we have a problem here. Computing the sums for all the O(n^2) ranges of the top and bottom rows will itself be O(n^4). This bottle neck can be overcome by modifying our matrix by replacing each element with the sum of all the numbers that are above it in that element's column. Thus, now we can find out the sum of numbers between any two rows in O(n) time by subtracting the appropriate arrays in the matrix.

The java pseudo code -

```
int kadane2D(int array[N+1][N+1]){
// Modify the array's elements to now hold the sum
// of all the numbers that are above that element in its column
for (int i = 1; i <= N; i++) {
for (int j = 1; j <= M; j++){
array[i][j] += array[i-1][j];
}
}
int ans = 0; // Holds the maximum sum matrix found till now
for(int top=1; top<=N; top++){
for(int bottom=top; bottom<=N; bottom++){
// loop over all the N^2 sub problems
int[] sums = new int[N+1];
// store the sum of numbers between the two rows
// in the sums array
for(int i=0; i<=N; i++){
sums[i] = array[bottom] - array[top-1];
}
// O(n) time to run 1D kadane's on this sums array
ans = Math.max(ans, kadane1d(sums));
}
}
return ans;
}
```