12,244 research outputs found
Gravitational wave detection with single-laser atom interferometers
We present a new general design approach of a broad-band detector of
gravitational radiation that relies on two atom interferometers separated by a
distance L. In this scheme, only one arm and one laser will be used for
operating the two atom interferometers. We consider atoms in the atom
interferometers not only as perfect inertial reference sensors, but also as
highly stable clocks. Atomic coherence is intrinsically stable and can be many
orders of magnitude more stable than a laser. The unique one-laser
configuration allows us to then apply time-delay interferometry to the
responses of the two atom interferometers, thereby canceling the laser phase
fluctuations while preserving the gravitational wave signal in the resulting
data set. Our approach appears very promising. We plan to investigate further
its practicality and detailed sensitivity analysis.Comment: Paper submitted to General Relativity and Gravitation as part of the
prceedings of the International Workshop on Gravitational Waves Detection
with Atom Interferometry (Florence, February 2009)
Searching for stochastic background of ultra-light fields with atomic sensors
We propose a cross-correlation method for the searches of ultra-light fields,
in particular, with a space network of atomic sensors. The main motivation of
the approach is cancellation of uncorrelated noises in the observation data and
unique pattern the fields leave on the cross-spectrum, depending on their
nature (i.e., scalar, vector or tensor). In particular, we analytically derive
a dependence of the cross-spectrum on the angle between two pairs of detectors.
We then confirm obtained angular curves with a numerical simulation. We imply
application of the method to the detection of dark matter and gravitational
waves.Comment: 16 pages. Minor revision. Submitted to the Universe journa
Generation of optical combs in a whispering gallery mode resonator from a bichromatic pump
An optical comb is shown to arise from a whispering gallery mode resonator
pumped by two optical frequencies. Two externally excited modes couple due to
Kerr nonlinearity to initially empty modes and give rise to new frequency
components. This thresholdles process is much more efficient than the
previously reported single-pump four-wave mixing. As a result, a few milliwatt
pump is sufficient to generate strong secondary fields, that efficiently
generate higher-order frequency components and so on, in a cascade process
leading to an optical comb.Comment: 4 pages, 6 figure
A taxonomy of asymmetric requirements aspects
The early aspects community has received increasing attention among researchers and practitioners, and has grown a set of meaningful terminology and concepts in recent years, including the notion of requirements aspects. Aspects at the requirements level present stakeholder concerns that crosscut the problem domain, with the potential for a broad impact on questions of scoping, prioritization, and architectural design. Although many existing requirements engineering approaches advocate and advertise an integral support of early aspects analysis, one challenge is that the notion of a requirements aspect is not yet well established to efficaciously serve the community. Instead of defining the term once and for all in a normally arduous and unproductive conceptual unification stage, we present a preliminary taxonomy based on the literature survey to show the different features of an asymmetric requirements aspect. Existing approaches that handle requirements aspects are compared and classified according to the proposed taxonomy. In addition,we study crosscutting security requirements to exemplify the taxonomy's use, substantiate its value, and explore its future directions
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