Robust Interior Point Method for Quantum Key Distribution Rate
Computation
- URL: http://arxiv.org/abs/2104.03847v2
- Date: Thu, 1 Sep 2022 14:16:44 GMT
- Title: Robust Interior Point Method for Quantum Key Distribution Rate
Computation
- Authors: Hao Hu, Jiyoung Im, Jie Lin, Norbert L\"utkenhaus and Henry Wolkowicz
- Abstract summary: We derive a stable reformulation of the convex nonlinear semidefinite programming, SDP, model for the key rate calculation problems.
We report on empirical results that dramatically improve on speed and accuracy, as well as solving previously intractable problems.
- Score: 5.43684033059546
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Security proof methods for quantum key distribution, QKD, that are based on
the numerical key rate calculation problem, are powerful in principle. However,
the practicality of the methods are limited by computational resources and the
efficiency and accuracy of the underlying algorithms for convex optimization.
We derive a stable reformulation of the convex nonlinear semidefinite
programming, SDP, model for the key rate calculation problems. We use this to
develop an efficient, accurate algorithm. The stable reformulation is based on
novel forms of facial reduction, FR, for both the linear constraints and
nonlinear quantum relative entropy objective function. This allows for a
Gauss-Newton type interior-point approach that avoids the need for
perturbations to obtain strict feasibility, a technique currently used in the
literature. The result is high accuracy solutions with theoretically proven
lower bounds for the original QKD from the FR stable reformulation. This
provides novel contributions for FR for general SDP. We report on empirical
results that dramatically improve on speed and accuracy, as well as solving
previously intractable problems.
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