Quantum Dynamical Entropy, Chaotic Unitaries and Complex Hadamard Matrices

Słomczyński, Wojciech; Szczepanek, Anna

doi:10.1109/tit.2017.2751507

Cited by 11 publications

(16 citation statements)

References 47 publications

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“…to(8) results in(5) and concludes the proof of Theorem 2.A Financial support by the Polish National Science Centre under Project No. DEC-2015/18/A/ST2/00274 is gratefully acknowledged.…”

supporting

confidence: 63%

“…with p jl := P l U z j 2 = | z l , U z j | 2 for j, l ∈ {0, 1} being the probability that we obtain l as the measurement outcome, provided that the preceding measurement yielded the result j. The combined evolution of states (and of measurement outcomes) is then Markovian with two states: z 0 , z 1 , the initial distribution concentrated at z 0 , and the transition bistochastic matrix P := (p jl ) j,l=0,1 [7,8,9]. In particular,…”

Section: Arxiv:200513658v1 [Quant-ph] 26 May 2020mentioning

confidence: 99%

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Orthogonal projections on hyperplanes intertwined with unitaries

Słomczyński

Szczepanek²

2021

J. Phys. A: Math. Theor.

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Fix a point in a finite-dimensional complex vector space and consider the sequence of iterates of this point under the composition of a unitary map with the orthogonal projection on the hyperplane orthogonal to the starting point. We prove that, generically, the series of the squared norms of these iterates sums to the dimension of the underlying space. This leads us to construct a (device-dependent) dimension witness for quantum systems which involves the probabilities of obtaining certain strings of outcomes in a sequential yes-no measurement. The exact formula for this series in non-generic cases is provided as well as its analogue in the real case.

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“…to(8) results in(5) and concludes the proof of Theorem 2.A Financial support by the Polish National Science Centre under Project No. DEC-2015/18/A/ST2/00274 is gratefully acknowledged.…”

supporting

confidence: 63%

Section: Arxiv:200513658v1 [Quant-ph] 26 May 2020mentioning

confidence: 99%

Orthogonal projections on hyperplanes intertwined with unitaries

Słomczyński

Szczepanek²

2021

J. Phys. A: Math. Theor.

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“…In [20] the authors establish a class of instruments which have positive dynamical SZ entropy and we give further such examples in Section 6. Therefore Proposition 4.8 does establish the nonlinearity of dynamical SZ entropy in time.…”

Section: Quantum Dynamical Entropymentioning

confidence: 99%

“…Next we split the SZ entropy of (Θ, T , u) with respect to C into two different causes for randomness. The first cause of randomness is that caused by the choice of instrument, is referred to as the measurement SZ entropy and is given by (20) h SZ meas (T , u, C) := h SZ (½, T , u, C). The second cause of randomness is given by the dynamics; i.e.…”

Section: Quantum Dynamical Entropymentioning

confidence: 99%

On the nonlinearity of quantum dynamical entropy

Androulakis

Wright

2019

Journal of Mathematical Physics

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Linearity of a dynamical entropy means that the dynamical entropy of the n-fold composition of a dynamical map with itself is equal to n times the dynamical entropy of the map for every positive integer n. We show that the quantum dynamical entropy introduced by S lomczyński andŻyczkowski is nonlinear in the time interval between successive measurements of a quantum dynamical system. This is in contrast to Kolmogorov-Sinai dynamical entropy for classical dynamical systems, which is linear in time. We also compute the exact values of quantum dynamical entropy for the Hadamard walk with varying Lüders-von Neumann instruments and partitions.2000 Mathematics Subject Classification. Primary: 46L55, 94A17 ; Secondary: 37M25, 60G99, 82C10.

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“…A different approach appears in [26] and [27] where the authors present their own definition of quantum dynamical entropy (see also [4]).…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic Formalism for Quantum Channels: Entropy, Pressure, Gibbs channels and generic properties

Brasil¹,

Knorst²,

Lopes³

2019

Preprint

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Denote M k the set of complex k by k matrices. We will analyze here quantum channels φ L of the following kind: given a measurable function L : M k → M k and the measure µ on M k we define the linear operatorA recent paper by T. Benoist, M. Fraas, Y. Pautrat, and C. Pellegrini is our starting point. They considered the case where L was the identity.Under some mild assumptions on the quantum channel φ L we analyze the eigenvalue property for φ L and we define entropy for such channel. For a fixed µ (the a priori measure) and for a given an Hamiltonian H : M k → M k we present a variational principle of pressure (associated to such H) and relate it to the eigenvalue problem. We introduce the concept of Gibbs channel.We also show that for a fixed µ (with more than one point in the support) the set of L such that it is Φ-Erg (also irreducible) for µ is a generic set.We describe a related process X n , n ∈ N, taking values on the projective space P (C k ) and analyze the question of existence of invariant probabilities.We also consider an associated process ρ n , n ∈ N, with values on D k (D k is the set of density operators). Via the barycenter we associate the invariant probabilities mentioned above with the density operator fixed for φ L .

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Quantum Dynamical Entropy, Chaotic Unitaries and Complex Hadamard Matrices

Cited by 11 publications

References 47 publications

Orthogonal projections on hyperplanes intertwined with unitaries

Orthogonal projections on hyperplanes intertwined with unitaries

On the nonlinearity of quantum dynamical entropy

Thermodynamic Formalism for Quantum Channels: Entropy, Pressure, Gibbs channels and generic properties

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