8,063 research outputs found
Optimal low-complexity detection for space division multiple access wireless systems
A symbol detector for wireless systems using space division multiple access (SDMA) and orthogonal frequency division multiplexing (OFDM) is derived. The detector uses a sphere decoder (SD) and has much less computational complexity than the naive maximum likelihood (ML) detector. We also show how to detect non-constant modulus signals with constrained least squares (CLS) receiver, which is designed for constant modulus (unitary) signals. The new detector outperforms existing suboptimal detectors for both uncoded and coded systems
Ultrastrong coupling few-photon scattering theory
We study the scattering of photons by a two-level system ultrastrongly
coupled to a one-dimensional waveguide. Using a combination of the polaron
transformation with scattering theory we can compute the one-photon scattering
properties of the qubit for a broad range of coupling strengths, estimating
resonance frequencies, lineshapes and linewidths. We validate numerically and
analytically the accuracy of this technique up to , close to the
Toulouse point , where inelastic scattering becomes relevant. These
methods model recent experiments with superconducting circuits [P.
Forn-D{\'\i}az et al., Nat. Phys. (2016)]
Regularized linearization for quantum nonlinear optical cavities: Application to Degenerate Optical Parametric Oscillators
Nonlinear optical cavities are crucial both in classical and quantum optics;
in particular, nowadays optical parametric oscillators are one of the most
versatile and tunable sources of coherent light, as well as the sources of the
highest quality quantum-correlated light in the continuous variable regime.
Being nonlinear systems, they can be driven through critical points in which a
solution ceases to exist in favour of a new one, and it is close to these
points where quantum correlations are the strongest. The simplest description
of such systems consists in writing the quantum fields as the classical part
plus some quantum fluctuations, linearizing then the dynamical equations with
respect to the latter; however, such an approach breaks down close to critical
points, where it provides unphysical predictions such as infinite photon
numbers. On the other hand, techniques going beyond the simple linear
description become too complicated especially regarding the evaluation of
two-time correlators, which are of major importance to compute observables
outside the cavity. In this article we provide a regularized linear description
of nonlinear cavities, that is, a linearization procedure yielding physical
results, taking the degenerate optical parametric oscillator as the guiding
example. The method, which we call self-consistent linearization, is shown to
be equivalent to a general Gaussian ansatz for the state of the system, and we
compare its predictions with those obtained with available exact (or
quasi-exact) methods.Comment: Comments and suggestions are welcom
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