Because the Ohm Law is linear, the principle of superposition is applicable.
Consider two special cases and superpose one on another.
Case1:
Apply a votage between A and infinite, assume the current flows into A is I,and V(A)=votage of A, V(∞)=votage of infinite, the votage difference between A and infinite is V(A)-V(∞).
The current on the resistance between A and B is I/4.
Case2:
Apply the same votage between infinite and B, assume the current flows out from B is I,and V(B)=votage of B, V(∞)=votage of infinite, the votage between B and infinite is V(∞)-V(B).
The current on the resistance between A and B is I/4.
Then, consider the two cases occurring at the same time.
That is, V(A) and V(B) are applied at A and B at the same time and current I flows into A out from B:
V(A) - V(B) = I×R'
where R' is the equvalent between A and B.
The principle of superposition tells us that we can superpose Case1 on Case2.
Consider the resistance between A and B :
V(A) - V(B) = [ I/4 + I/4 ]×R
where R = 1 Ω, and
I/4 and I/4 are the currents in Case1 and Case2 on the resistance respectively.
With the two equations, one can solve R' = R/2 = 1/2 (Ω)
My apologies, my English is quite poor and the description is lengthy.
