In most of the calculation analysis of running times, we have assumed that all inputs are equally likely. This is not true, because nearly sorted input, for instance, occurs much more often than is statistically expected, and this causes problems, particularly for quicksort and binary search trees.
By using a randomized algorithm, the particular input is no longer important. The random numbers are important, and we can get an expected running time, where we now average over all possible random numbers instead of over all possible inputs. Using quicksort with a random pivot gives an O(n log n)-expected-time algorithm. This means that for any input, including already-sorted input, the running time is expected to be O(n log n), based on the statistics of random numbers. An expected running time bound is somewhat stronger than an average-case bound but, of course, is weaker than the corresponding worst-case bound.
First, we will see a novel scheme for supporting the binary search tree operations in O(log n) expected time. Once again, this means that there are no bad inputs, just bad random numbers. From a theoretical point of view, this is not terribly exciting, since balanced search trees achieve this bound in the worst case. Nevertheless, the use of randomization leads to relatively simple algorithms for searching, inserting, and especially deleting.
My question on above text is
What does author mean by "An expected running time bound is somewhat stronger than an average-case bound but, of course, is weaker than the corresponding worst-case bound" ? in above text.
Regrading binary search trees what does author meant by "since balanced search trees achieve this bound in the worst case"? my understanding for binary search trees worst case is O(d), where d is depth of the node this can be "N" i.e., O(N). what does author mean by this is same as worst case above?