For binary search tree type of data structures, I see the Big O notation is typically noted as O(logn). With a lowercase 'l' in log, does this imply log base e (n) as described by the natural logarithm? Sorry for the simple question but I've always had trouble distinguishing between the different implied logarithms.
Once expressed in bigO() notation, both are correct. However, during the derivation of the O() polynomial, in the case of binary search, only log_{2} is correct. I assume this distinction was the intuitive inspiration for your question to begin with. Also, as a matter of my opinion, writing O(log_{2} N) is better for your example, because it better communicates the derivation of the algorithm's runtime. In bigO() notation, constant factors are removed. Converting from one logarithm base to another involves multiplying by a constant factor. So O(log N) is equivalent to O(log_{2} N) due to a constant factor. However, if you can easily typeset log_{2} N in your answer, doing so is more pedagogical. In the case of binary tree searching, you are correct that log_{2} N is introduced during the derivation of the bigO() runtime. Before expressing the result as bigO() notation, the difference is very important. When deriving the polynomial to be communicated via bigO notation, it would be incorrect for this example to use a logarithm other than log_{2} N, prior to applying the O()notation. As soon as the polynomial is used to communicate a worstcase runtime via bigO() notation, it doesn't matter what logarithm is used. 


Big O notation is not affected by logarithmic base, because all logarithms in different bases are related by a constant factor, O(ln n) is equivalent to O(log n) 


It doesn't really matter what base it is, since bigO notation is usually written showing only the asymptotically highest order of That said, I would probably assume log base 2. 


Technically the base doesn't matter, but you can generally think of it as base2. 


Yes, when talking about bigO notation, the base does not matter. However, computationally when faced with a real search problem it does matter. When developing an intuition about tree structures, it's helpful to understand that a binary search tree can be searched in O(n log n) time because that is the height of the tree  that is, in a binary tree with n nodes, the tree depth is O(n log n) (base 2). If each node has three children, the tree can still be searched in O(n log n) time, but with a base 3 logarithm. Computationally, the number of children each node has can have a big impact on performance (see for example: link text) Enjoy! Paul 


Both are correct. Think about this



log n
he means the natural logarithm. 2. When a computer scientist writeslog n
he means basetwo. 3. When an engineer writeslog n
he means baseten. These are usually true. – jason Oct 15 '09 at 1:50