Suppose i have a case like T(n)=2T(n/4)+1. f(n)=1 a=2 and b=4. Thus n^(1/2)>1. That should be case 1. However there is also a lambda in case 1, so that f(n)=O(n^((1/2)-lambda)) for some lambda >0. In this case lambda would be 1/2?
Yes, that's correct. Note that, in this case, we have that a = 2 and b = 4. The function f(n) in this case is 1, and we do have that 1 = Θ(n1/2 - ε) for some ε > 0, where in this case ε = 1/2. Consequently, by the Master Theorem, you would get that T(n) = Θ(n1/2).
The point of this ε is that if the amount of work done per level is sufficiently small (below logb a), then the work is dominating primarily by the splitting rather than the work per level. The fact that you can subtract ε > 0 from the exponent indicates that the work per level must grow strictly asymptotically slower than the splitting rate, and must do so by some polynomial amount.
Hope this helps!