Prove that
1 + 1/2 + 1/3 + ... + 1/n is O(log n).
Assume n = 2^k
I put the series into the summation, but I have no idea how to tackle this problem. Any help is appreciated
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3 Answers
This follows easily from a simple fact in Calculus:
and we have the following inequality:
Here we can conclude that S = 1 + 1/2 + ... + 1/n is both Ω(log(n)) and O(log(n)), thus it is Ɵ(log(n)), the bound is actually tight.
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Thanks! My professor said we shouldn't use calculus for this one. Any tips on how to solve it using discrete math? Sep 18, 2014 at 6:29
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4For your purpose (i.e. proving the
O(log(n))upper bound), you only need to argue the leftmost inequality holds (i.e.1/2 + 1/3 + ... + 1/(n+1) <= ln(n)), you can argue this by mathematical induction. (Hint: argue that we have1/(n+1) <= log(n+1) - log(n) = log(1+1/n)using Taylor's expansion or otherwise)– chiwangcSep 18, 2014 at 9:17
Here's a formulation using Discrete Mathematics:
So, H(n) = O(log n)
answered Sep 15, 2016 at 13:46
If the problem was changed to :
1 + 1/2 + 1/4 + ... + 1/n
series can now be written as:
1/2^0 + 1/2^1 + 1/2^2 + ... + 1/2^(k)
How many times loop will run? 0 to k = k + 1 times.From both series, we can see 2^k = n. Hence k = log (n). So, the number of times it runs = log(n) + 1 = O(log n).
