It is because the average number of comparisons for unsuccessful search is equal to the 'average external path length' of the tree which is given by the expression E/(n+1) , since there are (n+1) external nodes which represent all the fail cases.
You are comparing it with the average successful case which is causing you the confusion. In the case of successful search number of comparisons is equal to the number of nodes in the path from the root node to that success node. But unsuccessful search can be understood as the insertion of that particular node in the tree. ie: insertion of an element is equivalent to the unsuccessful search for that node. And we know that the number of comparisons to find a node in the tree is exactly 1 more than the number of comparisons needed to insert it.
consider the sorted array: 3,7,10,13,15
its binary search can be represented by the following binary search tree:
/ \ / \
F 7 F 15
/ \ / \
F F F F
where F denotes the fail cases.
Now this shows that if you search for 10 in this array it will take just one comparison, if you search for 3 or 13 both will take 2 comparisons each, similarly if u search for 7 or 15 it will take 3 comparisons each.
Internal path length gives the number of edges from root to a particular internal node so for each node it will be one less than the number of comparisons required to successfully search for that node. Hence we add 1 for each node to the internal path length which leads to a total of n (since there are n internal nodes) so the formula (I+n)/n is justified.
Now coming to the case of unsuccessful search, suppose in this example array you want to search for 2 (which is not present in the array) so the first comparison will be made with the mid element ie 10 , then second comparison with 3 and since the search cannot go lower than 3 our search ends here with only 2 comparisons, unlike what u stated that it would take 3 comparisons since it is on level 2 of the tree. Similarly while searching for 5 in this array you will have to make 3 comparisons and not 4. Hence we see that each fail node requires comparisons equal to its path length. And so we don not have to add an extra 1 for each external node and the average comparisons for unsuccessful search is equal to the average external path length of the binary tree. which justifies the formula E/(n+1).
I guess this should clear your doubt of why we didnt add an extra 1 for each node.