Improved local models and new Bell inequalities via Frank-Wolfe algorithms

Abstract: ∞ 1979 Lower bounds 0.5 Werner [4] ∞ 1989 Table I. Successive refinements of the bounds on v Wer c , the nonlocality threshold of the two-qubit Werner states under projective measurements. Using m measurements to simulate all projective ones is denoted by m ∼ ∞.

“…Let us now recall the Grothendieck constant of order 3 22 , 25 , 26 , 32 , 33 , which is given by where the maximization is taken over real matrices M of arbitrary dimensions , q ( M ) is defined by ( 8 ) and L ( M ) is defined as follows where the maximum is taken over all . The value of in ( 16 ), according to the recent work of Designolle et al 34 , is bounded by where the lower bound is an improved version of that given in Ref. 35 and the upper bound is an improved version of that given in Refs.…”

Certification of qubits in the prepare-and-measure scenario with large input alphabet and connections with the Grothendieck constant

“…Let us now recall the Grothendieck constant of order 3 22 , 25 , 26 , 32 , 33 , which is given by where the maximization is taken over real matrices M of arbitrary dimensions , q ( M ) is defined by ( 8 ) and L ( M ) is defined as follows where the maximum is taken over all . The value of in ( 16 ), according to the recent work of Designolle et al 34 , is bounded by where the lower bound is an improved version of that given in Ref. 35 and the upper bound is an improved version of that given in Refs.…”

Certification of qubits in the prepare-and-measure scenario with large input alphabet and connections with the Grothendieck constant