This is a fairly straightforward O(N) solution:

let `sa = [s1, s2, s3.. sn]`

where `si = sum(a[0:i])`

and similar for `sb`

then `sum(a[i:j]) = sa[j]-sa[i]`

and `sum(b[i:j]) = sb[j] - sb[i]`

Note that because the sums only increase by 1 each time, we know `0 <= sb[N], sa[N] <=N`

`difference_array = [d1, d2, .. dn]`

where `di = sb[i] - sa[i] <= N`

note if `di = dj`

, then `sb[i] - sa[i] = sb[j] - sa[j]`

which means they have the same sum (rearrange to get `sum(b[i:j]) and sum(a[i:j])`

from above).

Now for each difference we need its **max position occurrence and min position occurrence**

Now for each difference di, the difference between max - min, is an i-j section of equal sum. Find the maximum max-min value and you're done.

sample code that should work:

```
a = []
b = []
sa = [0]
sb = [0]
for i in a:
sa.append(sa[-1] + i)
for i in b:
sb.append(sb[-1] + i)
diff = [sai-sbi for sai, sbi in zip(sa, sb)]
min_diff_pos = {}
max_diff_pos = {}
for pos, d in enumerate(diff):
if d in min_diff_pos:
max_diff_pos[d] = pos
else:
min_diff_pos[d] = pos
ans = min(max_diff_pos[d] - min_diff_pos[d] for d in diff)
```

`O(n)`

solution exists? – alestanis Oct 31 '12 at 9:10