2022
DOI: 10.48550/arxiv.2203.02386
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Quantum algorithms for estimating quantum entropies

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Cited by 3 publications
(4 citation statements)
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“…Proof Previous work [60] states that it is able to obtain an estimation of S α (ρ) up to precision ε, by an estimation of tr(ρ α ) within error ε ′ = |1−α| tr(ρ α ) 2 ε. Then we turn to demonstrate how to obtain tr(ρ α ) with error bounded by ε ′ .…”
Section: Supplementary Materialsmentioning
confidence: 99%
“…Proof Previous work [60] states that it is able to obtain an estimation of S α (ρ) up to precision ε, by an estimation of tr(ρ α ) within error ε ′ = |1−α| tr(ρ α ) 2 ε. Then we turn to demonstrate how to obtain tr(ρ α ) with error bounded by ε ′ .…”
Section: Supplementary Materialsmentioning
confidence: 99%
“…• For the quantum algorithms in [SH21] and [WZW22] that attempt to reduce the dependence on N , they introduce an extra dependence on κ, where κ is the reciprocal of the minimal non-zero eigenvalue of quantum states. Our quantum algorithms can be easily adapted to their settings by taking r = O(κ), but the converse seems not applicable 3 .…”
Section: • Von Neumann Entropymentioning
confidence: 99%
“…[AISW19] introduced a method of computing the von Neumann and quantum Rényi entropies of an N -dimensional quantum state using O(N 2 /ε 2 ) and O(N 2/α /ε 2/α ) copies, respectively. Recently, a new method of computing the von Neumann and quantum Rényi entropies was proposed in [WZW22] using Õ(κ 2 /ε 5 ) copies, where κ > 0 is given such that Π/κ ≤ ρ ≤ I for some projector Π. A distributed quantum algorithm for computing tr(ρσ), i.e., the fidelity of pure quantum states, was proposed in [ALL21] using O(max{ √ N /ε, 1/ε 2 }) copies.…”
Section: Introductionmentioning
confidence: 99%
“…However, the von Neumann entropy S(ρ) and its gradients are difficult to measure on real quantum hardware [18,22,23], with the cost scaling exponentially with system size, particularly in the case of Gibbs states, as eigenvalues of the target state ρ G are exponentially suppressed [24,25]. This makes the implementation of variational Gibbs state preparation too demanding for nearterm quantum processors, especially at low temperatures.…”
Section: Introductionmentioning
confidence: 99%