English

Mapping the space of quantum expectation values

Quantum Physics 2023-10-23 v1 High Energy Physics - Theory

Abstract

For a quantum system with Hilbert space H{\cal H} of dimension NN and a set SS of nn Hermitian operators Oi{\cal O}_i, a basic question is to understand the set ESRnE_S \subset \mathbb{R}^n of points e\vec{e} where ei=tr(ρOi)e_i = {\rm tr}(\rho {\cal O}_i) for an allowed state ρ\rho. A related question is to determine whether a given set of expectation values e\vec{e} lies in ESE_S and in this case to describe the most general state with these expectation values. In this paper, we describe various ways to characterize ESE_S, reviewing basic results that are perhaps not widely known and adding new ones. One important result (originally due to E. Wichmann) is that for a set SS of linearly independent traceless operators, every set of expectation values e\vec{e} in the interior of ESE_S is achieved uniquely by a state of the form ρ(β)=eiβiOi/tr(eiβiOi)\rho({\vec{\beta}}) = e^{-\sum_i \beta_i {\cal O}_i}/{\rm tr}(e^{-\sum_i \beta_i {\cal O}_i}) for OiS{\cal O}_i \in S. In fact, the map βE(β)=tr(Oρ(β))\vec{\beta} \to \vec{E}(\vec{\beta}) = {\rm tr}(\vec{\cal O} \rho({\vec{\beta}})) is a diffeomorphism from Rn\mathbb{R}^n to the interior of ESE_S with symmetric, positive Jacobian; using this fact, we provide an algorithm to invert E(β)\vec{E}(\vec{\beta}) and thus determine a state ρ(β(e))\rho({\vec{\beta}(\vec{e})}) with specified expectation values e\vec{e} provided that these lie in ESE_S. The algorithm is based on defining a first order differential equation in the space of parameters β\vec{\beta} that is guaranteed to converge to β(e)\vec{\beta}(\vec{e}) in a precise way, with E(β(t))e=Cet|\vec{E}(\vec{\beta}(t)) - \vec{e}| = C e^{-t}.

Keywords

Cite

@article{arxiv.2310.13111,
  title  = {Mapping the space of quantum expectation values},
  author = {Seraphim Jarov and Mark Van Raamsdonk},
  journal= {arXiv preprint arXiv:2310.13111},
  year   = {2023}
}

Comments

35 pages, LaTeX

R2 v1 2026-06-28T12:56:10.554Z