9,763 research outputs found
The Long and Large Decline in U.S. Output Volatility
output volatility, macroeconomics, decline, U.S. output
Panel of resonators with variable resonance frequency for noise control
The article focuses on acoustic resonators made of perforated sheets bonded onto honeycomb cavities. This kind of resonators can be used in adverse conditions such as high temperature, dirt and mechanical constraints. For all these reasons, they are, for example, widely used in aeronautic applications. The acoustic properties are directly linked to the size, shape and porosity of holes and to the thickness of air gaps. Unfortunately, the acoustic absorption of these resonators is selective in frequency and conventional acoustic resonators are only well adapted to tonal noises. In case of variable tonal noise, the efficiency is limited if the resonators are not tunable. One common solution is to control the depth of cavities based on the noise to be attenuated. This article proposes another technology of tunable resonators with only a very small mass and size increase. It consists of two superposed and identically perforated plates associated with cavities. One plate is fixed and bonded to the cavities and the other plate is mobile. The present concept enables to change the internal shapes of the holes of the perforated layers. The article describes this system and gives a theoretical model of the normal incidence acoustic impedance that allows to predict the acoustic behavior, in particular the resonance frequency. The model shows that the resonance frequency varies with hole profiles and that the absorption peak moves towards the lower frequencies. The proposed model is validated by measurements on various configurations of resonators tested in an impedance tube. The perspectives of this work are to adapt the hole profiles using an actuator in order to perform active control of impedance
Laser Doppler Velocimetry for Joint Measurements of Acoustic and Mean Flow Velocities : LMS-based Algorithm and CRB Calculation
This paper presents a least mean square (LMS) algorithm for the joint
estimation of acoustic and mean flow velocities from laser doppler velocimetry
(LDV) measurements. The usual algorithms used for measuring with LDV purely
acoustic velocity or mean flow velocity may not be used when the acoustic field
is disturbed by a mean flow component. The LMS-based algorithm allows accurate
estimations of both acoustic and mean flow velocities. The Cram\'er-Rao bound
(CRB) of the associated problem is determined. The variance of the estimators
of both acoustic and mean flow velocities is also given. Simulation results of
this algorithm are compared with the CRB and the comparison leads to validate
this estimator
Gaugid inflation
The spectrum of primordial gravitational waves is one of the most robust
inflationary observables, often thought of as a direct probe of the energy
scale of inflation. We present a simple model, where the dynamics controlling
this observable is very different than in the standard paradigm of inflation.
The model is based on a peculiar finite density phase---the magnetic
gaugid---which stems from a highly non-linear effective theory of a triplet of
abelian gauge fields. The gaugid extends the notion of homogeneous isotropic
solid, in that its spectrum of fluctuations includes helicity-2 phonons. We
show how, upon implementing the gaugid to drive inflation, the helicity-2
phonon mixes with the graviton, significantly affecting the size of the
primordial tensor spectrum. The rest of the features of the theory, in
particular the vector and scalar perturbations, closely resemble those of solid
inflation.Comment: 35+8 page
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