A Variational Quantum Algorithm For Approximating Convex Roofs

Abstract

Many entanglement measures are first defined for pure states of a bipartite Hilbert space, and then extended to mixed states via the convex roof extension. In this article we alter the convex roof extension of an entanglement measure, to produce a sequence of extensions that we call f-d extensions, for d ∈ N, where f:[0,1] [0, ∞) is a fixed continuous function which vanishes only at zero. We prove that for any such function f, and any continuous, faithful, non-negative function, (such as an entanglement measure), μ on the set of pure states of a finite dimensional bipartite Hilbert space, the collection of f-d extensions of μ detects entanglement, i.e. a mixed state on a finite dimensional bipartite Hilbert space is separable, if and only if there exists d ∈ N such that the f-d extension of μ applied to is equal to zero. We introduce a quantum variational algorithm which aims to approximate the f-d extensions of entanglement measures defined on pure states. However, the algorithm does have its drawbacks. We show that this algorithm exhibits barren plateaus when used to approximate the family of f-d extensions of the Tsallis entanglement entropy for a certain function f and unitary ansatz U(θ) of sufficient depth. In practice, if additional information about the state is known, then one needs to avoid using the suggested ansatz for long depth of circuits.