Bounding Polynomial Entanglement Measures for Mixed States

Abstract

We generalize the notion of the best separable approximation (BSA) and best W-class approximation (BWA) to arbitrary pure state entanglement measures, defining the best zero-E approximation (BEA). We show that for any polynomial entanglement measure E, any mixed state admits at least one "S-decomposition," i.e., a decomposition in terms of a mixed state on which E is equal to zero, and a single additional pure state with (possibly) non-zero E. We show that the BEA is not in general the optimal S-decomposition from the point of view of bounding the entanglement of , and describe an algorithm to construct the entanglement-minimizing S-decomposition for and place an upper bound on E(). When applied to the three-tangle, the cost of the algorithm is linear in the rank d of the density matrix and has accuracy comparable to a steepest descent algorithm whose cost scales as d8 d. We compare the upper bound to a lower bound algorithm given by Eltschka and Siewert for the three-tangle, and find that on random rank-two three-qubit density matrices, the difference between the upper and lower bounds is 0.14 on average. We also find that the three-tangle of random full-rank three qubit density matrices is less than 0.023 on average.