The maximum number of comparisons to decide whether the array is sorted is N-1, because there are N-1 adjacent number pairs to compare. But for simplicity, we'll say N as it does not matter if we look at N or N+1 numbers.

Furthermore, it is unimportant where you start, so let's just start at the beginning.
Comparison #1 (A[0] vs. A[1]). If it fails, the array is unsorted. If it succeeds, good.

As we only compare, we can reduce this to the neighbors and whether the left one is smaller or equal (1) or not (0). So we can treat the array as a sequence of 0's and 1's, indicating whether two adjacent numbers are in order or not.

Calculating the error rate or the propability (correct spelling?) we will have to look at all combinations of our 0/1 sequence.
I would look at it like this: We have 2^n combinations of an array (i.e. the order of the pairs, of which only one is sorted (all elements are 1 indicating that each A[i] is less or equal to A[i+1]).

Now this seems to be simple:
initially the error is 1/2^N. After the first comparison half of the possible combinations (all unsorted) get eliminated. So the error rate should be 1/2^n + 1/2^(n-1).

I'm not a mathematician, but it should be quite easy to calculate how many elements are needed to reach the error rate (find x such that ERROR >= sum of 1/2^n + 1/2^(n-1)... 1/^(2-x) )

Sorry for the confusing english. I come from germany..