Suppose I have a case like
T(n)=2T(n/4)+log(n). a=2, b=4, f(n)=log(n)
That should be case 1 because n^(1/2)>log(n)
. There is also a lambda in case 1. f(n)=O(n^((1/2)lambda)
. Is this correct? And how can I find this lambda?
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Suppose I have a case like
That should be case 1 because 


The constant lambda is important: its purpose is to avoid considering the bizarre cases that lie between Case 1 and Case 2. Since bigO is an upper bound only and not a lower bound, smaller choices of lambda are "better" in the sense that they cover more functions. Since lambda must be positive, however, there is no "best" choice of lambda. Lambda = 10^3 should get you through enough examples to see why most treatments of the Master Theorem do not make a production out of choosing lambda. 


f(n)=logn Epsilon can be 1/4 since n^{(logbaepsilon)}=n^{(log421/4)}=n^{(1/21/4)}=n^{(1/4)}. f(n)=O(n^{(1/4)}). So by case 1 of the master theorem T(n)=Θ(n^{logba})=Θ(n^{(1/2)}). 

