87 research outputs found
Optimal continuous-variable teleportation under energy constraint
Quantum teleportation is one of the crucial protocols in quantum information
processing. It is important to accomplish an efficient teleportation under
practical conditions, aiming at a higher fidelity desirably using fewer
resources. The continuous-variable (CV) version of quantum teleportation was
first proposed using a Gaussian state as a quantum resource, while other
attempts were also made to improve performance by applying non-Gaussian
operations. We investigate the CV teleportation to find its ultimate fidelity
under energy constraint identifying an optimal quantum state. For this purpose,
we present a formalism to evaluate teleportation fidelity as an expectation
value of an operator. Using this formalism, we prove that the optimal state
must be a form of photon-number entangled states. We further show that Gaussian
states are near-optimal while non-Gaussian states make a slight improvement and
therefore are rigorously optimal, particularly in the low-energy regime.Comment: 8 pages, 4 figures, published versio
Quantum phase estimation using path-symmetric entangled states
We study the sensitivity of phase estimation using a generic class of
path-symmetric entangled states
, where an arbitrary state
occupies one of two modes in quantum superposition. This
class of states includes the previously considered states, i.e. states
and entangled coherent states, as special cases. With its generalization, we
identify the practical limit of phase estimation under energy constraint that
is characterized by the photon statistics of the component state
. We first show that quantum Cramer-Rao bound (QCRB) can be
lowered with super-Poissonianity of the state . By introducing
a component state of the form
, we particularly show
that an arbitrarily small QCRB can be achieved even with a finite energy in an
ideal situation. For practical measurement schemes, we consider a parity
measurement and a full photon-counting method to obtain phase-sensitivity.
Without photon loss, the latter scheme employing any path-symmetric states
achieves the QCRB over the
entire range of unknown phase shift whereas the former does
so in a certain confined range of . We find that the case of
provides the most
robust resource against loss among the considered entangled states over the
whole range of input energy. Finally we also propose experimental schemes to
generate these path-symmetric entangled states.Comment: 10 pages, 5 figures, published versio
Gaussian benchmark for optical communication aiming towards ultimate capacity
We establish the fundamental limit of communication capacity within Gaussian
schemes under phase-insensitive Gaussian channels, which employ multimode
Gaussian states for encoding and collective Gaussian operations and
measurements for decoding. We prove that this Gaussian capacity is additive,
i.e., its upper bound occurs with separable encoding and separable receivers so
that a single-mode communication suffices to achieve the largest capacity under
Gaussian schemes. This rigorously characterizes the gap between the ultimate
Holevo capacity and the capacity within Gaussian communication, showing that
Gaussian regime is not sufficient to achieve the Holevo bound particularly in
the low-photon regime. Furthermore the Gaussian benchmark established here can
be used to critically assess the performance of non-Gaussian protocols for
optical communication. We move on to identify non-Gaussian schemes to beat the
Gaussian capacity and show that a non-Gaussian receiver recently implemented by
Becerra et al. [Nat. Photon. 7, 147 (2013)] can achieve this aim with an
appropriately chosen encoding strategy.Comment: 9 pages, 6 figures, with supplemental materia
Continuous-variable dense coding via a general Gaussian state: Monogamy relation
We study a continuous variable (CV) dense-coding protocol, originally
proposed to employ a two-mode squeezed state, using a general two-mode Gaussian
state as a quantum channel. We particularly obtain conditions to manifest
quantum advantage by beating two well-known single-mode schemes, namely, the
squeezed-state scheme (best Gaussian scheme) and the number-state scheme
(optimal scheme achieving the Holevo bound). We then extend our study to a
multipartite Gaussian state and investigate the monogamy of operational
entanglement measured by the communication capacity under the dense-coding
protocol. We show that this operational entanglement represents a strict
monogamy relation, by means of Heisenberg's uncertainty principle among
different parties, i.e., the quantum advantage for communication can be
possible for only one pair of two-mode systems among many parties
Gaussian states under coarse-grained continuous variable measurements
The quantum-to-classical transition of a quantum state is a topic of great
interest in fundamental and practical aspects. A coarse-graining in quantum
measurement has recently been suggested as its possible account in addition to
the usual decoherence model. We here investigate the reconstruction of a
Gaussian state (single mode and two modes) by coarse-grained homodyne
measurements. To this aim, we employ two methods, the direct reconstruction of
the covariance matrix and the maximum likelihood estimation (MLE),
respectively, and examine the reconstructed state under each scheme compared to
the state interacting with a Gaussian (squeezed thermal) reservoir. We clearly
demonstrate that the coarse-graining model, though applied equally to all
quadrature amplitudes, is not compatible with the decoherence model by a
thermal (phase-insensitive) reservoir. Furthermore, we compare the performance
of the direct reconstruction and the MLE methods by investigating the fidelity
and the nonclassicality of the reconstructed states and show that the MLE
method can generally yield a more reliable reconstruction, particularly without
information on a reference frame (phase of input state).Comment: published version, 9 pages, 5 figure
Classical capacity of Gaussian communication under a single noisy channel
A long-standing problem on the classical capacity of bosonic Gaussian
channels has recently been resolved by proving the minimum output entropy
conjecture. It is also known that the ultimate capacity quantified by the
Holevo bound can be achieved asymptotically by using an infinite number of
channels. However, it is less understood to what extent the communication
capacity can be reached if one uses a finite number of channels, which is a
topic of practical importance. In this paper, we study the capacity of Gaussian
communication, i.e., employing Gaussian states and Gaussian measurements to
encode and decode information under a single-channel use. We prove that the
optimal capacity of single-channel Gaussian communication is achieved by one of
two well-known protocols, i.e., coherent-state communication or squeezed-state
communication, depending on the energy (number of photons) as well as the
characteristics of the channel. Our result suggests that the coherent-state
scheme known to achieve the ultimate information-theoretic capacity is not a
practically optimal scheme for the case of using a finite number of channels.
We find that overall the squeezed-state communication is optimal in a
small-photon-number regime whereas the coherent-state communication performs
better in a large-photon-number regime.Comment: 9 pages, 4 figures, published versio
Steering Criteria via Covariance Matrices of Local Observables in Arbitrary Dimensional Quantum Systems
We derive steerability criteria applicable for both finite and infinite
dimensional quantum systems using covariance matrices of local observables. We
show that these criteria are useful to detect a wide range of entangled states
particularly in high dimensional systems and that the Gaussian steering
criteria for general M x N-modes of continuous variables are obtained as a
special case. Extending from the approach of entanglement detection via
covariance matrices, our criteria are based on the local uncertainty principles
incorporating the asymmetric nature of steering scenario. Specifically, we
apply the formulation to the case of local orthogonal observables and obtain
some useful criteria that can be straightforwardly computable, and testable in
experiment, with no need for numerical optimization.Comment: 6 pages with further "Remarks" and "Acknowledgement" adde
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