I think you can do it in O(n) using these three tricks:
Precompute an array C[k] that stores sum(A[0:k]).
This can be done recursively via C[k]=C[k-1]+A[k] in time O(n).
The benefit of this array is that you can then compute sum(A[a:b]) via C[b]-C[a-1].
Because your elements are sorted, then it is easy to compute the best i to minimise the sum of absolute values. In fact, the best i will always be given by the middle entry.
If the length of the list is even, then all values of i between the two central elements will always give the minimum absolute value.
e.g. for your list 10,10,12,14 the central elements are 10 and 12, so any value for i between 10 and 12 will minimise the sum.
You can now scan over the elements a single time to find the best value.
1. Init s=0,e=0
2. if the score for A[s:e] is less than B increase e by 1
3. else increase s by 1
4. if e<n return to step 2
Keep track of the largest value for e-s seen which has a score < B and this is your answer.
This loop can go around at most 2n times so it is O(n).
The score for A[s:e] is given by sum |A[s:e]-A[(s+e)/2]|.
score = sum |A[s:e]-A[(s+e)/2]|
= sum |A[s:e]-A[m]|
= sum (A[m]-A[s:m]) + sum (A[m+1:e]-A[m])
= (m-s+1)*A[m]-sum(A[s:m]) + sum(A[m+1:e])-(e-m)*A[m]
and we can compute the sums in this expression using the precomputed array C[k].
If the endpoint must always be n, then you can use this alternative algorithm:
1. Init s=0,e=n
2. while the score for A[s:e] is greater than B, increase s by 1
Here is a python implementation of the algorithm:
for a in A:
# this returns 4, as the 4 elements 10,10,12,14 can be chosen