How to get the upper bound of the following equation, thanks!
2log(mn/2) + 4log(mn/4) + ... + mlog(mn/m)
How to get the upper bound of the following equation, thanks!
2log(mn/2) + 4log(mn/4) + ... + mlog(mn/m)
This sum works out to Θ(m log n).
Let's start by rewriting
2^{k} log (mn / 2^{k}) = 2^{k}(log mn - k)
Now, we have the sum
Σ_{k=1}^{log m} 2^{k} (log mn - k)
= Σ_{k=1}^{log m} (2^{k} log mn - k 2^{k})
= log mn Σ_{k=1}^{log m} 2^{k} - Σ_{k=1}^{log m} k 2^{k}
That first sum is the sum of a geometric series. It simplifies to 2^{1 + log m} - 2 = 2m - 2. That means that we're left with
2m log mn - 2log mn - Σ_{k=1}^{log m} k 2^{k}
That leaves us with the task of simplifying the sum k2^{k} over some range. This is an arithmetico-geometric sum. If we imagine this sum ranging from 2 (inclusive) to some upper bound q, then the sum works out to q2^{q+1}.
(q+1)2^{q+1} - 2 + 2(2 - 2^{q+1})
= (q+1)2^{q+1} - 2 + 4 - 2·2^{q+1}
= (q - 1)2^{q+1} + 2
You can check that this formula is correct by plugging in different values of q.
In our case, q = log m, so the sum we want works out to
(log m - 1)2^{1 + log m} + 2
= (log m - 1)(2m) + 2
= 2m log m - 2m + 2
So our overall sum works out to
2m log mn - 2log mn - Σ_{k=1}^{log mn} k 2^{k}
= 2m log mn - 2log mn - (2m log m - 2m + 2)
= 2m log mn - 2log mn - 2m log m + 2m - 2
= 2m (log mn - log m + 1) - 2log mn - 2
= 2m (log n + 1) - 2 log mn - 2
Θ(m log n).
Hope this helps!
O(mlog(mn))
andOmega(mlogn)
, if that help. But I am unsure how to pinpoint the tight bound though.