A simple proof of the strong subadditivity inequality

Arguably the deepest fact known about the von~Neumann entropy, the strong subadditivity inequality is a potent hammer in the quantum information theorist's toolkit. This short tutorial describes a simple proof of strong subadditivity due to Petz [Rep. on Math. Phys. \textbf{23} (1), 57--65 (1986)]. It assumes only knowledge of elementary linear algebra and quantum mechanics.

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THE UNREASONABLE EFFECTIVENESS OF EXPONENTIALLY SUPPRESSED CORRECTIONS IN PRESERVING INFORMATION

International Journal of Modern Physics D ◽

10.1142/s0218271813420303 ◽

2013 ◽

Vol 22 (12) ◽

pp. 1342030 ◽

Cited By ~ 9

Author(s):

KYRIAKOS PAPADODIMAS ◽

SUVRAT RAJU

Keyword(s):

Hilbert Space ◽

Black Hole ◽

Quantum Mechanics ◽

Nonperturbative Effects ◽

Von Neumann Entropy ◽

Von Neumann ◽

Information Theoretic ◽

Black Hole Evaporation ◽

Strong Subadditivity ◽

Unreasonable Effectiveness

We point out that nonperturbative effects in quantum gravity are sufficient to reconcile the process of black hole evaporation with quantum mechanics. In ordinary processes, these corrections are unimportant because they are suppressed by e-S. However, they gain relevance in information-theoretic considerations because their small size is offset by the corresponding largeness of the Hilbert space. In particular, we show how such corrections can cause the von Neumann entropy of the emitted Hawking quanta to decrease after the Page time, without modifying the thermal nature of each emitted quantum. Second, we show that exponentially suppressed commutators between operators inside and outside the black hole are sufficient to resolve paradoxes associated with the strong subadditivity of entropy without any dramatic modifications of the geometry near the horizon.

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Quantum Algorithmic Complexities and Entropy

Open Systems & Information Dynamics ◽

10.1142/s1230161209000025 ◽

2009 ◽

Vol 16 (01) ◽

pp. 1-28 ◽

Cited By ~ 3

Author(s):

Fabio Benatti

Keyword(s):

Quantum Computing ◽

Quantum Information ◽

Complexity Theory ◽

Information Sources ◽

Algorithmic Complexity ◽

Entropy Rate ◽

Von Neumann Entropy ◽

Von Neumann

We review the basics of classical algorithmic complexity theory and two of its quantum extensions that have been prompted by the foreseeable existence of quantum computing devices. In particular, we will examine the relations between these extensions and the von Neumann entropy rate of generic quantum information sources of ergodic type.

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From linear algebra to quantum information

Annals of Mathematics and Physics ◽

10.17352/amp.000023 ◽

2021 ◽

pp. 032-047

Author(s):

Yu LW ◽

Wang NL ◽

Kanemitsu S

Keyword(s):

Functional Analysis ◽

Hilbert Space ◽

Quantum Mechanics ◽

Quantum Information ◽

Linear Algebra ◽

Smooth Transition ◽

Quantum Computers ◽

Hermite Operator ◽

Hermite Matrix ◽

Hermite Operators

Anticipating the realization of quantum computers, we propose the most reader-friendly exposition of quantum information and qubits theory. Although the latter lies within framework of linear algebra, it has some fl avor of quantum mechanics and it would be easier to get used to special symbols and terminologies. Quantum mechanics is described in the language of functional analysis: the state space (the totality of all states) of a quantum system is a Hilbert space over the complex numbers and all mechanical quantities are taken as Hermite operators. Hence some basics of functional analysis is necessary. We make a smooth transition from linear algebra to functional analysis by comparing the elements in these theories: Hilbert space vs. fi nite dimensional vector space, Hermite operator vs. linear map given by a Hermite matrix. Then from Newtonian mechanics to quantum mechanics and then to the theory of qubits. We elucidate qubits theory a bit by accommodating it into linear algebra framework under these precursors.

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Randomized Linear Algebra Approaches to Estimate the von Neumann Entropy of Density Matrices

IEEE Transactions on Information Theory ◽

10.1109/tit.2020.2971991 ◽

2020 ◽

Vol 66 (8) ◽

pp. 5003-5021

Author(s):

Eugenia-Maria Kontopoulou ◽

Gregory-Paul Dexter ◽

Wojciech Szpankowski ◽

Ananth Grama ◽

Petros Drineas

Keyword(s):

Linear Algebra ◽

Von Neumann Entropy ◽

Density Matrices ◽

Von Neumann

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Information entropy of multi-qubit Rabi system

International Journal of Quantum Information ◽

10.1142/s0219749915500422 ◽

2015 ◽

Vol 13 (06) ◽

pp. 1550042 ◽

Cited By ~ 3

Author(s):

D. A. M. Abo-Kahla ◽

M. Abdel-Aty

Keyword(s):

Population Dynamics ◽

Quantum Information ◽

Information Entropy ◽

Time Development ◽

Von Neumann Entropy ◽

Frequency Detuning ◽

Coupling Constant ◽

Von Neumann

We consider quantum information entropy phenomenon for multi-qubit Rabi system. By introducing different measurements schemes, we establish the relation between information entropy approach and Von Neumann entropy. It is shown that the information entropy is more sensitive to the time development than the Von Neumann entropy. Furthermore, the suggested protocol exhibits excellent scaling of relevant characteristics, with respect to population dynamics, such that more accurate dynamical results may be obtained using information entropy due to variation of the frequency detuning and the coupling constant.

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Interaction of quantum systems with environment in QCD

EPJ Web of Conferences ◽

10.1051/epjconf/201920401002 ◽

2019 ◽

Vol 204 ◽

pp. 01002

Author(s):

Viatcheslav Kuvshinov ◽

Valery Shaparau ◽

Eugene Bagashov

Keyword(s):

Quantum Information ◽

Von Neumann Entropy ◽

Asymptotic Freedom ◽

Squeezed States ◽

Time Intervals ◽

Von Neumann ◽

Confinement Region ◽

Photon States ◽

Short Time ◽

Good Agreement

It is shown that the interaction of quark with the stochastic vacuum of QCD (considered as an environment) leads to the decoherence of quark colour state, associated with the loss of information on the initial quark colour. We propose to consider this process as a reason of the confinement of the quark colour. Asymptotically this leads to confined quarks (fully mixed colourless quark states) in the limit of large distances and time intervals (confinement region) and free coloured quarks in the limit of small distances and time intervals (asymptotic freedom). We propose quantitative characteristics that allow to describe the process of interaction: purity, fidelity, von Neumann entropy, quantum information measure. The cases of two and arbitrary number of quarks are considered, and it is shown that the entanglement in such system disappears in the limit of large distances and time intervals. The process is in good agreement with the known theorems in quantum information theory (no-cloning and no-hiding). We study non-perturbative evolution of the gluon colour states during short time. Fluctuations of gluons are less than those for coherent states. This fact suggests that there gluon squeezed states can arise. Theoretical justification for the occurrence both singe- and two-mode gluon squeezing effects in QCD is given. We show that gluon entangled states which are closely related with two-mode squeezed states of gluon fields can appear at short time non-perturbative evolution by analogy with corresponding photon states in quantum optics.

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NO-CLONING THEOREM IN THERMOFIELD DYNAMICS

International Journal of Quantum Information ◽

10.1142/s021974991230001x ◽

2012 ◽

Vol 10 (02) ◽

pp. 1230001 ◽

Cited By ~ 3

Author(s):

T. PRUDÊNCIO

Keyword(s):

Quantum Information ◽

Von Neumann Entropy ◽

Mixed States ◽

Von Neumann

We discuss the relation between the no-cloning theorem from quantum information and the doubling procedure used in the formalism of thermofield dynamics (TFD). We also discuss how to apply the no-cloning theorem in the context of thermofield states defined in TFD. Consequences associated to mixed states, von Neumann entropy and thermofield vacuum are also addressed.

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Switching and Swapping of Quantum Information: Entropy and Entanglement Level

Entropy ◽

10.3390/e23060717 ◽

2021 ◽

Vol 23 (6) ◽

pp. 717

Author(s):

Marek Sawerwain ◽

Joanna Wiśniewska ◽

Roman Gielerak

Keyword(s):

Quantum Information ◽

Quantum Systems ◽

Von Neumann Entropy ◽

Crucial Issue ◽

Schmidt Decomposition ◽

Intrinsic Decoherence ◽

Von Neumann ◽

Local Quantum ◽

Definition Of ◽

Moriya Interaction

Information switching and swapping seem to be fundamental elements of quantum communication protocols. Another crucial issue is the presence of entanglement and its level in inspected quantum systems. In this article, a formal definition of the operation of the swapping local quantum information and its existence proof, together with some elementary properties analysed through the prism of the concept of the entropy, are presented. As an example of the local information swapping usage, we demonstrate a certain realisation of the quantum switch. Entanglement levels, during the work of the switch, are calculated with the Negativity measure and a separability criterion based on the von Neumann entropy, spectral decomposition and Schmidt decomposition. Results of numerical experiments, during which the entanglement levels are estimated for systems under consideration with and without distortions, are presented. The noise is generated by the Dzyaloshinskii-Moriya interaction and the intrinsic decoherence is modelled by the Milburn equation. This work contains a switch realisation in a circuit form—built out of elementary quantum gates, and a scheme of the circuit which estimates levels of entanglement during the switch’s operating.

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QUANTUM MEASUREMENT SCHEMES RELATED TO FLAVOR-WEIGHTED ENERGIES

International Journal of Modern Physics A ◽

10.1142/s0217751x13500656 ◽

2013 ◽

Vol 28 (15) ◽

pp. 1350065 ◽

Cited By ~ 1

Author(s):

A. E. BERNARDINI

Keyword(s):

Quantum Mechanics ◽

Quantum System ◽

Quantum Measurement ◽

Single Particle ◽

Neutrino Energy ◽

Von Neumann Entropy ◽

System Framework ◽

Von Neumann ◽

Mass Eigenstates ◽

The Right

The framework of the generalized theory of quantum measurement provides some theoretical tools for computing flavor associated energies correlated to the von-Neumann entropy of a composed system. After defining flavor-averaged and flavor-weighted energies, that are respectively supported by nonselective (selective) quantum measurement schemes, the right correlation between the energies of flavor eigenstates and their measurement probabilities can be obtained. Our results from the composed quantum system framework show that the nonselective measurement scheme for computing flavor-weighted energies is consistent with predictions from single-particle quantum mechanics. As an application of our results, through the expressions for neutrino effective mass values, it is straightforwardly verified that cosmological background neutrino energy densities could be obtained from the coherent superposition of mass eigenstates.

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Order-Stability in Complex Biological, Social, and AI-Systems from Quantum Information Theory

Entropy ◽

10.3390/e23030355 ◽

2021 ◽

Vol 23 (3) ◽

pp. 355

Author(s):

Andrei Khrennikov ◽

Noboru Watanabe

Keyword(s):

Information Theory ◽

Quantum Information ◽

Quantum Information Theory ◽

Von Neumann Entropy ◽

Order Structure ◽

Compound System ◽

Von Neumann ◽

Local Disorder ◽

Low Entropy ◽

The Brain

This paper is our attempt, on the basis of physical theory, to bring more clarification on the question “What is life?” formulated in the well-known book of Schrödinger in 1944. According to Schrödinger, the main distinguishing feature of a biosystem’s functioning is the ability to preserve its order structure or, in mathematical terms, to prevent increasing of entropy. However, Schrödinger’s analysis shows that the classical theory is not able to adequately describe the order-stability in a biosystem. Schrödinger also appealed to the ambiguous notion of negative entropy. We apply quantum theory. As is well-known, behaviour of the quantum von Neumann entropy crucially differs from behaviour of classical entropy. We consider a complex biosystem S composed of many subsystems, say proteins, cells, or neural networks in the brain, that is, S=(Si). We study the following problem: whether the compound system S can maintain “global order” in the situation of an increase of local disorder and if S can preserve the low entropy while other Si increase their entropies (may be essentially). We show that the entropy of a system as a whole can be constant, while the entropies of its parts rising. For classical systems, this is impossible, because the entropy of S cannot be less than the entropy of its subsystem Si. And if a subsystems’s entropy increases, then a system’s entropy should also increase, by at least the same amount. However, within the quantum information theory, the answer is positive. The significant role is played by the entanglement of a subsystems’ states. In the absence of entanglement, the increasing of local disorder implies an increasing disorder in the compound system S (as in the classical regime). In this note, we proceed within a quantum-like approach to mathematical modeling of information processing by biosystems—respecting the quantum laws need not be based on genuine quantum physical processes in biosystems. Recently, such modeling found numerous applications in molecular biology, genetics, evolution theory, cognition, psychology and decision making. The quantum-like model of order stability can be applied not only in biology, but also in social science and artificial intelligence.

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