Via Resonance Amplitude Control

Given the interference avoidance capacity, high gain, and dynamical reconfigurability, phased array antennas (PAAs) have emerged as a key enabling technology for future broadband mobile applications. This is especially important at millimeter-wave (mm-wave) frequencies, where the high power consumption and significant path loss impose serious range constraints. However, at mm-wave frequencies the phase and amplitude control of the feeding currents of the PAA elements is not a trivial issue because electrical beamforming requires bulky devices and exhibits relatively narrow bandwidth. In order to overcome these limitations, different optical beamforming architectures have been presented. In this paper we review the basic principles of phased arrays and identify the main challenges, that is, integration of high-speed photodetectors with antenna elements and the efficient optical control of both amplitude and phase of the feeding current. After presenting the most important solutions found in the literature, we analyze the impact of the different noise sources on the PAA performance, giving some guidelines for the design of optically fed PAAs.

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Noise contributors in a 7.2 GHz low-power VCO with automatic amplitude control

RFIC) Symposium, 2005. Digest of Papers. 2005 IEEE Radio Frequency integrated Circuits ◽

10.1109/rfic.2005.1489826 ◽

2005 ◽

Cited By ~ 3

Author(s):

R. Murji ◽

M.J. Deen

Keyword(s):

Low Power ◽

Amplitude Control ◽

Automatic Amplitude Control ◽

Automatic Amplitude

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Manipulating flow separation: sensitivity of stagnation points, separatrix angles and recirculation area to steady actuation

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2014.0365 ◽

2014 ◽

Vol 470 (2170) ◽

pp. 20140365 ◽

Cited By ~ 5

Author(s):

E. Boujo ◽

F. Gallaire

Keyword(s):

Flow Separation ◽

Separation Point ◽

Navier Stokes ◽

Reattachment Point ◽

Amplitude Control ◽

Geometric Quantity ◽

Stagnation Points ◽

Recirculation Area ◽

Layer Flow ◽

Analytical Expressions

A variational technique is used to derive analytical expressions for the sensitivity of several geometric indicators of flow separation to steady actuation. Considering the boundary layer flow above a wall-mounted bump, the six following representative quantities are considered: the locations of the separation point and reattachment point connected by the separatrix, the separation angles at these stagnation points, the backflow area and the recirculation area. For each geometric quantity, linear sensitivity analysis allows us to identify regions which are the most sensitive to volume forcing and wall blowing/suction. Validations against full nonlinear Navier−Stokes calculations show excellent agreement for small-amplitude control for all considered indicators. With very resemblant sensitivity maps, the reattachment point, the backflow and recirculation areas are seen to be easily manipulated. By contrast, the upstream separation point and the separatrix angles are seen to remain extremely robust with respect to external steady actuation.

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Arbitrary polarization conversion for pure vortex generation with a single metasurface

Nanophotonics ◽

10.1515/nanoph-2020-0332 ◽

2020 ◽

Vol 10 (1) ◽

pp. 727-732

Author(s):

Marco Piccardo ◽

Antonio Ambrosio

Keyword(s):

Angular Momentum ◽

Polarization Conversion ◽

Vortex Beam ◽

Vortex Generation ◽

Optical Elements ◽

Amplitude Control ◽

Cavity Resonators ◽

Vortex Beams ◽

Topological Charges ◽

Selection Of

AbstractThe purity of an optical vortex beam depends on the spread of its energy among different azimuthal and radial modes, also known as $\ell $- and p-modes. The smaller the spread, the higher the vortex purity and more efficient its creation and detection. There are several methods to generate vortex beams with well-defined orbital angular momentum, but only few exist allowing selection of a pure radial mode. These typically consist of many optical elements with rather complex arrangements, including active cavity resonators. Here, we show that it is possible to generate pure vortex beams using a single metasurface plate—called p-plate as it controls radial modes—in combination with a polarizer. We generalize an existing theory of independent phase and amplitude control with birefringent nanopillars considering arbitrary input polarization states. The high purity, sizeable creation efficiency, and impassable compactness make the presented approach a powerful complex amplitude modulation tool for pure vortex generation, even in the case of large topological charges.

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Problems of Nonlinear Multiple-Mode Vibrations of Thin Elastic Shells of Revolution

10.1115/imece2000-1014 ◽

2000 ◽

Author(s):

Veniamin D. Kubenko ◽

Piotr S. Kovalchuk

Keyword(s):

Degrees Of Freedom ◽

Asymptotic Methods ◽

Nonlinear Resonance ◽

Shells Of Revolution ◽

Elastic Shells ◽

Resonance Amplitude ◽

Multiple Degrees Of Freedom ◽

Free And Forced Vibrations ◽

Multiple Mode ◽

Averaged Equations

Abstract A method is suggested for the calculation of nonlinear free and forced vibrations of thin elastic shells of revolution, which are modeled as dynamic systems of multiple degrees of freedom. Cases are investigated in which the shells are characterized by two or more closely-spaced eigenfrequencies. Based on an analysis of averaged equations, obtained by making use of asymptotic methods of nonlinear mechanics, a number of new first integrals is obtained, which state a regular energy exchange among various modes of cylindrical shells under conditions of nonlinear resonance. Amplitude-frequency characteristics of multiple-mode vibrations are obtained for shells subjected to radial oscillating pressure.

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