It looks like this can be solved using Dynamic Programming. Without loss of generality i can re-phrase the question as:

Given search space `S = {s1, s2, ..., sn}`

, a needle pair `(si, sj)`

, we have to find position pair `(k, l)`

such that:

`(sk, sl) == (si, sj)`

`distance(k, l)`

is minimum.

A recursive solution for the problem can be formulated by:

`Cost(m) =`

`LARGEST_NUMBER, if m = 0`

`Min (Cost(m-1), distance(S[m], Latest_si)), if m > 0 and S[m] == sj`

`Min (Cost(m-1), distance(S[m], Latest_sj)), if m > 0 and S[m] == si`

`Cost(m-1), if m > 0 and S[m] != (si, sj)`

Where,

`Cost(m)`

is the optimization function. It represents minimum distance between `(si, sj)`

in search space `S[1:m]`

.
`Latest_si`

is the latest position of `si`

.
`Latest_sj`

is the latest position of `sj`

.

This can be converted into an `O(n)`

bottoms up loop with space complexity of `O(n)`

to store `Cost`

.

Here is an implementation of above algorithm in Python:

```
def min_phrase (S, si, sj):
Cost = []
for i in S:
Cost.append([len(S), [-1, -1]])
latest_si = -1
latest_sj = -1
for idx, v in enumerate(S):
if v == si:
if latest_sj >=0:
cost = idx - latest_sj
if cost < Cost[idx - 1][0]:
Cost[idx] = [cost, [latest_sj, idx]]
else:
Cost[idx] = Cost[idx - 1]
else:
Cost[idx] = Cost[idx - 1]
latest_si = idx
elif v == sj:
if latest_si >=0:
cost = idx - latest_si
if cost < Cost[idx - 1][0]:
Cost[idx] = [cost, [latest_si, idx]]
else:
Cost[idx] = Cost[idx - 1]
else:
Cost[idx] = Cost[idx - 1]
latest_sj = idx
else:
Cost[idx] = Cost[idx - 1]
return Cost[len(S) - 1]
if __name__ == '__main__':
S = ("one", "two", "three", "four", "five", "four", "six", "one")
si = "one"
sj = "four"
result = min_phrase(S, si, sj)
if result[1][0] == -1 or result[1][1] == -1:
print "No solution found"
else:
print "Cost: {0}".format(result[0])
print "Phrase: {0}".format(" ".join(S[result[1][0] : result[1][1] + 1]))
```