Gaussian quantum information

Weedbrook, Christian; Pirandola, Stefano; García−Patrón, Raúl; Cerf, Nicolas J.; Ralph, T. C.; Shapiro, Jeffrey H.; Lloyd, Seth

doi:10.1103/revmodphys.84.621

Cited by 3,035 publications

(3,774 citation statements)

References 388 publications

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“…For many quantum communication protocols, Gaussian channels describe the decoherence introduced by the environment to a quantum state and represent the basic models of communication lines such as optical fibers [19]. Let us assume that a single mode of a two-mode squeezed vacuum state, i.e., a = b = 1+χ 2 1−χ 2 and c 1 = −c 2 = 2χ 1−χ 2 , with χ = tanh r ∈ [0,1), is sent through a Gaussian channel.…”

Section: Entanglement Of Formation: Lower Boundmentioning

confidence: 99%

“…Let us assume that a single mode of a two-mode squeezed vacuum state, i.e., a = b = 1+χ 2 1−χ 2 and c 1 = −c 2 = 2χ 1−χ 2 , with χ = tanh r ∈ [0,1), is sent through a Gaussian channel. One-mode Gaussian channels can be defined as the transformation of the covariance matrix of the mode γ , i.e., γ → Uγ U T + V [19]. Typically, these channels are phase invariant and so produce states with balanced correlations that saturate the lower bound, i.e., r − = r o .…”

Section: Entanglement Of Formation: Lower Boundmentioning

confidence: 99%

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Quantifying entanglement in two-mode Gaussian states

Tserkis

Ralph

2017

Phys. Rev. A

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Entangled two-mode Gaussian states are a key resource for quantum information technologies such as teleportation, quantum cryptography, and quantum computation, so quantification of Gaussian entanglement is an important problem. Entanglement of formation is unanimously considered a proper measure of quantum correlations, but for arbitrary two-mode Gaussian states no analytical form is currently known. In contrast, logarithmic negativity is a measure that is straightforward to calculate and so has been adopted by most researchers, even though it is a less faithful quantifier. In this work, we derive an analytical lower bound for entanglement of formation of generic two-mode Gaussian states, which becomes tight for symmetric states and for states with balanced correlations. We define simple expressions for entanglement of formation in physically relevant situations and use these to illustrate the problematic behavior of logarithmic negativity, which can lead to spurious conclusions.

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Section: Entanglement Of Formation: Lower Boundmentioning

confidence: 99%

Section: Entanglement Of Formation: Lower Boundmentioning

confidence: 99%

Quantifying entanglement in two-mode Gaussian states

Tserkis

Ralph

2017

Phys. Rev. A

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“…The criteria of CV cloning and teleportation are studied in (Grosshans and Grangier, 2001). We remark again that the reviews of CV quantum information can be found in (Braunstein and van Loock, 2005;Wang et al, 2007;Weedbrook et al, 2012).…”

Section: E Other Developments and Related Topicsmentioning

confidence: 99%

“…Most schemes and protocols of quantum computation and quantum information can be realized and demonstrated by photonic state of CV, it may possesses unique advantage other than other systems. The reviews of CV quantum information can be found in (Braunstein and van Loock, 2005;Wang et al, 2007;Weedbrook et al, 2012), see spin squeezing in (Ma et al, 2011). An example of continuous systems is simply to consider the position and momentum of a particle, or the two quadratures of a quantized electromagnetic field.…”

Section: Quantum Cloning For Continuous Variable Systemsmentioning

confidence: 99%

Quantum cloning machines and the applications

et al. 2014

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No-cloning theorem is fundamental for quantum mechanics and for quantum information science that states an unknown quantum state cannot be cloned perfectly. However, we can try to clone a quantum state approximately with the optimal fidelity, or instead, we can try to clone it perfectly with the largest probability. Thus various quantum cloning machines have been designed for different quantum information protocols. Specifically, quantum cloning machines can be designed to analyze the security of quantum key distribution protocols such as BB84 protocol, six-state protocol, B92 protocol and their generalizations. Some well-known quantum cloning machines include universal quantum cloning machine, phase-covariant cloning machine, the asymmetric quantum cloning machine and the probabilistic quantum cloning machine etc. In the past years, much progress has been made in studying quantum cloning machines and their applications and implementations, both theoretically and experimentally. In this review, we will give a complete description of those important developments about quantum cloning and some related topics. On the other hand, this review is self-consistent, and in particular, we try to present some detailed formulations so that further study can be taken based on those results.

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“…Quantum informationmeasured in units known as quantum bits, or qubits -can be encoded either by the discrete properties of a pulse of light, such as its polarization state, or by the continuous aspects of an electromagnetic wave, such as the intensity and phase of the wave's electric field 4 . To teleport this information, both the sender and receiver must own one of a pair of entangled quantum systems (see 'Quantum teleportation').…”

Section: Two Approachesmentioning

confidence: 99%