First, we need to consider how a local minimum is defined:
a[i] < a[i-1] and a[i] < a[i+1]
From this condition, we see that if we were to plot the array on an X/Y graph (X=index, Y = value), local minimums would be at the valleys. Therefore, to ensure there is a local minimum, we must guarantee that a change in slope sign (from decreasing to increasing) exists.
If you know the endpoint slope behavior of a range, you know if there is a local minimum within. In addition, your array must have the behavior decreasing slope sign from a to a and increasing slope sign from a[n-1] to a[n] or the problem is trivial. Consider:
a = [1,2,3,4,5] (increasing, increasing) a is an LM
a = [5,4,3,2,1] (decreasing, decreasing) a[n] is an LM
a = [1,2,2,2,1] (increasing, decreasing) a and a[n] are LMs
I think this should be enough inspiration for you to complete the method.
Note that expanding this method is good only for unique values, for example an array of all 1s, it will not have O(log n) run time unless you do some edge case detection.