47 research outputs found
Parallel State Transfer and Efficient Quantum Routing on Quantum Networks
We study the routing of quantum information in parallel on multi-dimensional
networks of tunable qubits and oscillators. These theoretical models are
inspired by recent experiments in superconducting circuits using Josephson
junctions and resonators. We show that perfect parallel state transfer is
possible for certain networks of harmonic oscillator modes. We further extend
this to the distribution of entanglement between every pair of nodes in the
network, finding that the routing efficiency of hypercube networks is both
optimal and robust in the presence of dissipation and finite bandwidth.Comment: 5 pages, 3 figure
A combinatorial identity for studying Sato-Tate type problems
We derive a combinatorial identity which is useful in studying the
distribution of Fourier coefficients of L-functions by allowing us to pass from
knowledge of moments of the coefficients to the distribution of the
coefficients.Comment: This paper contains the proof of a combinatorial identity used to
study effective equidistribution laws for the Fourier coefficients of
elliptic curve L-functions investigated by the first two authors in
http://arxiv.org/abs/1004.275
Comparing resolved-sideband cooling and measurement-based feedback cooling on an equal footing: analytical results in the regime of ground-state cooling
We show that in the regime of ground-state cooling, simple expressions can be
derived for the performance of resolved-sideband cooling --- an example of
coherent feedback control --- and optimal linear measurement-based feedback
cooling for a harmonic oscillator. These results are valid to leading order in
the small parameters that define this regime. They provide insight into the
origins of the limitations of coherent and measurement-based feedback for
linear systems, and the relationship between them. These limitations are not
fundamental bounds imposed by quantum mechanics, but are due to the fact that
both cooling methods are restricted to use only a linear interaction with the
resonator. We compare the performance of the two methods on an equal footing
--- that is, for the same interaction strength --- and confirm that coherent
feedback is able to make much better use of the linear interaction than
measurement-based feedback. We find that this performance gap is caused not by
the back-action noise of the measurement but by the projection noise. We also
obtain simple expressions for the maximal cooling that can be obtained by both
methods in this regime, optimized over the interaction strength.Comment: 14 pages, 2 png figures; v2: revised for publicatio
Tunneling phase gate for neutral atoms in a double-well lattice
We propose a new two--qubit phase gate for ultra--cold atoms confined in an
experimentally realized tilted double--well optical lattice [Sebby--Strabley et
al., Phys. Rev. A {\bf 73} 033605 (2006)]. Such a lattice is capable of
confining pairs of atoms in a two--dimensional array of double--well potentials
where control can be exercised over the barrier height and the energy
difference of the minima of the two wells (known as the ``tilt''). The four
lowest single--particle motional states consist of two pairs of motional states
in which each pair is localized on one side of the central barrier, allowing
for two atoms confined in such a lattice to be spatially separated qubits. We
present a time--dependent scheme to manipulate the tilt to induce tunneling
oscillations which produce a collisional phase gate. Numerical simulations
demonstrate that this gate can be performed with high fidelity.Comment: 5 pages, 4 figure
Connecting the discrete and continuous-time quantum walks
Recently, quantized versions of random walks have been explored as effective
elements for quantum algorithms. In the simplest case of one dimension, the
theory has remained divided into the discrete-time quantum walk and the
continuous-time quantum walk. Though the properties of these two walks have
shown similarities, it has remained an open problem to find the exact relation
between the two. The precise connection of these two processes, both quantally
and classically, is presented. Extension to higher dimensions is also
discussed.Comment: 5 pages, 1 figur
Quantum logic gates for superconducting resonator qudits
We study quantum information processing using superpositions of Fock states
in superconducting resonators, as quantum -level systems (qudits). A
universal set of single and coupled logic gates is theoretically proposed for
resonators coupled by superconducting circuits of Josephson juctions. These
gates use experimentally demonstrated interactions, and provide an attractive
route to quantum information processing using harmonic oscillator modes.Comment: 10 pages, 14 figures, decoherence calculations adde