Your search keyword '"quantum graph parameters"' showing total 5 results

1. Bounds on entanglement dimensions and quantum graph parameters via noncommutative polynomial optimization

Author

Sander Gribling, Monique Laurent, David de Laat, Econometrics and Operations Research, and Research Group: Operations Research

Subjects

Optimization problem, General Mathematics, Quantum correlation, Dimension (graph theory), quantum graph parameters, FOS: Physical sciences, Quantum entanglement, 90C22, Squashed entanglement, 01 natural sciences, 90C26, 81P40, 81P45, 0103 physical sciences, polynomial optimization, FOS: Mathematics, 0101 mathematics, 010306 general physics, Mathematics - Optimization and Control, Mathematics, Discrete mathematics, Semidefinite programming, Quantum Physics, Quantum discord, Full Length Paper, quantum correlations, 010102 general mathematics, 90C30, TheoryofComputation_GENERAL, 16. Peace & justice, entanglement dimension, 05C15, Optimization and Control (math.OC), Quantum graph, Quantum Physics (quant-ph), Software

Abstract

In this paper we study bipartite quantum correlations using techniques from tracial noncommutative polynomial optimization. We construct a hierarchy of semidefinite programming lower bounds on the minimal entanglement dimension of a bipartite correlation. This hierarchy converges to a new parameter: the minimal average entanglement dimension, which measures the amount of entanglement needed to reproduce a quantum correlation when access to shared randomness is free. For synchronous correlations, we show a correspondence between the minimal entanglement dimension and the completely positive semidefinite rank of an associated matrix. We then study optimization over the set of synchronous correlations by investigating quantum graph parameters. We unify existing bounds on the quantum chromatic number and the quantum stability number by placing them in the framework of tracial optimization. In particular, we show that the projective packing number, the projective rank, and the tracial rank arise naturally when considering tracial analogues of the Lasserre hierarchy for the stability and chromatic number of a graph. We also introduce semidefinite programming hierarchies converging to the commuting quantum chromatic number and commuting quantum stability number., Comment: 26 pages

Published

2018

2. Conic Approach to Quantum Graph Parameters Using Linear Optimization Over the Completely Positive Semidefinite Cone

Author

Teresa Piovesan, Monique Laurent, Networks and Optimization, Logic and Computation (ILLC, FNWI/FGw), ILLC (FNWI), Econometrics and Operations Research, Research Group: Operations Research, and Center Ph. D. Students

Subjects

Quantum information, FOS: Physical sciences, Positive-definite matrix, Trace positive polynomials, Theoretical Computer Science, Combinatorics, Matrix (mathematics), Dual cone and polar cone, FOS: Mathematics, Operator Algebras (math.OA), Mathematics - Optimization and Control, Mathematics, Semidefinite programming, Quantum Physics, Semidefinite program- ming, Mathematics - Operator Algebras, Chromatic number, Noncommutative geometry, Quantum graph parameters, Copositive cone, Optimization and Control (math.OC), Nonlocal games, Conic section, Quantum graph, Quantum Entanglement, Quantum Physics (quant-ph), Software, Conic optimization

Abstract

We investigate the completely positive semidefinite cone $\mathcal{CS}_+^n$, a new matrix cone consisting of all $n\times n$ matrices that admit a Gram representation by positive semidefinite matrices (of any size). In particular we study relationships between this cone and the completely positive and doubly nonnegative cones, and between its dual cone and trace positive non-commutative polynomials. We use this new cone to model quantum analogues of the classical independence and chromatic graph parameters $\alpha(G)$ and $\chi(G)$, which are roughly obtained by allowing variables to be positive semidefinite matrices instead of $0/1$ scalars in the programs defining the classical parameters. We can formulate these quantum parameters as conic linear programs over the cone $\mathcal{CS}_+^n$. Using this conic approach we can recover the bounds in terms of the theta number and define further approximations by exploiting the link to trace positive polynomials., Comment: Fixed some typos

Published

2015

3. On the closure of the completely positive semidefinite cone and linear approximations to quantum colorings

Author

Burgdorf, S., Laurent, Monique, Piovesan, Teresa, Beigi, S., Koenig, R., Econometrics and Operations Research, Research Group: Operations Research, Center Ph. D. Students, Networks and Optimization, Logic and Computation (ILLC, FNWI/FGw), and ILLC (FNWI)

Subjects

Closure (topology), FOS: Physical sciences, Positive-definite matrix, 01 natural sciences, Combinatorics, Quantum entanglement, Matrix (mathematics), 0103 physical sciences, FOS: Mathematics, Symmetric matrix, 0101 mathematics, Von Neumann algebra, 010306 general physics, Operator Algebras (math.OA), Mathematics - Optimization and Control, Mathematics, Quantum Physics, Algebra and Number Theory, 000 Computer science, knowledge, general works, Trace nonnegative polynomials, 010102 general mathematics, Mathematics - Operator Algebras, Chromatic number, Ultraproduct, 16. Peace & justice, Quantum graph parameters, Copositive cone, Cone (topology), Optimization and Control (math.OC), Nonlocal games, Quantum graph, Computer Science, Quantum Physics (quant-ph), Conic optimization

Abstract

We investigate structural properties of the completely positive semidefinite cone $\mathcal{CS}_+^n$, consisting of all the $n \times n$ symmetric matrices that admit a Gram representation by positive semidefinite matrices of any size. This cone has been introduced to model quantum graph parameters as conic optimization problems. Recently it has also been used to characterize the set $\mathcal Q$ of bipartite quantum correlations, as projection of an affine section of it. We have two main results concerning the structure of the completely positive semidefinite cone, namely about its interior and about its closure. On the one hand we construct a hierarchy of polyhedral cones which covers the interior of $\mathcal{CS}_+^n$, which we use for computing some variants of the quantum chromatic number by way of a linear program. On the other hand we give an explicit description of the closure of the completely positive semidefinite cone, by showing that it consists of all matrices admitting a Gram representation in the tracial ultraproduct of matrix algebras., Comment: 20 pages

Published

2015

4. On the closure of the completely positive semidefinite cone and linear approximations to quantum colorings

Subjects

Quantum graph parameters, chromatic number, trace nonnegative polynomials, copositive cone, quantum entanglement, Von Neumann algebra, nonlocal games

Abstract

We investigate structural properties of the completely positive semidefinite cone CS^n_+ , consisting of all the n×n symmetric matrices that admit a Gram representation by positive semidefinite matrices of any size. This cone has been introduced to model quantum graph parameters as conic optimization problems. Recently it has also been used to characterize the set Q of bipartite quantum correlations, as projection of an affine section of it. We have two main results concerning the structure of the completely positive semidefinite cone, namely about its interior and about its closure. On the one hand we construct a hierarchy of polyhedral cones which covers the interior of CS^n_+ , which we use for computing some variants of the quantum chromatic number by way of a linear program. On the other hand we give an explicit description of the closure of the completely positive semidefinite cone, by showing that it consists of all matrices admitting a Gram representation in the tracial ultraproduct of matrix algebras.

Published

2015

5. Conic approach to quantum graph parameters using linear optimization over the completely positive semidefinite cone

Subjects

Quantum graph parameters, Copositive cone, Semidefinite program- ming, Quantum information, Nonlocal games, Chromatic number, Quantum Entanglement, Trace positive polynomials

Abstract

We investigate the completely positive semidefinite matrix cone CSn+, consisting of all n×n matrices that admit a Gram representation by positive semidefinite matrices (of any size). We use this new cone to model quantum analogues of the classical independence and chro- matic graph parameters α(G) and χ(G), which are roughly obtained by allowing variables to be positive semidefinite matrices instead of 0/1 scalars in the programs defining the classical parameters. We study relationships between the cone CSn+ and the completely positive and doubly nonnegative cones, and between its dual cone and trace positive non-commutative polynomials. By using the truncated tracial quadratic module as sufficient condition for trace positivity, we can define hierarchies of cones aiming to approximate the dual cone of CSn+, which we then use to construct hierarchies of semidefinite programming bounds approximating the quantum graph parameters. Finally we relate their convergence properties to Connes’ embedding conjecture in operator theory.

Published

2013