131 research outputs found
A miniaturized 3 dimensional bandpass frequency selective surface
A planar bandpass frequency selective surface
(FSS) is proposed along with an alternative 3D element design
with the intent of miniaturizing the unit cell. The two structures
are simulated in CST and compared. Such techniques show the
potential of using 3D elements in FSS design to miniaturize the
structure for space constrained applications
Modifying conventional microwave antenna designs using fine scale structures and nanomaterials
This paper investigates the possibility of designing and fabricating microwave antennas using metallic nanomaterials. Specifically, we will consider modifying the structure of conventional designs including dipoles, loops and apertures. FDTD simulations are used to examine these modified structures. Due to the prohibitive computational requirements of modelling nanoscale objects on a millimetre scale, the structures are approximated using larger scale objects. However, cell sizes down to 2¿m have been considered. The results show that the frequency can be decreased. However, typically the bandwidth decreases
Microwave aperture antennas using nanomaterials
In this paper, computer simulations are used to
investigate the concept of designing microwave aperture
antennas, potentially fabricated using metallic nanomaterials.
Nanomaterials are considered as they facilitate fabrication and
electromagnetic advantages. Aperture radiating structures have
been excited by a plane wave in a microstrip line. The aperture
was modified with the addition of fine scale structures; vertical
strips shorter than the height of the aperture. These initial
simulation results have shown that these fine structures inside
the aperture can decrease the resonance frequency at the expense
of the bandwidth
Nano-metamaterial antennas at microwave frequencies
This paper examines the possibility of creating novel microwave frequency antennas by suitably arranging
metallic / dielectric nanoparticles. Simulation results show that the antenna must be composed of ≥ 99% metal (<1 % gaps)
Optically reconfigurable balanced dipole antenna
In this paper, a new design for an optically
reconfigurable printed dipole antenna is presented. A
wideband coplanar waveguide (CPW) to coplanar strip
(CPS) transition is used to feed the printed dipole. Two
optically activated silicon switches, controlled using
fibre optic cables and near infra-red laser diodes, are
placed on small gaps in the dipole arms. The switches
enable the dipole length to be optically controlled, thus
facilitating frequency switching. Measured return loss
results that compare well to the simulated values are
also presented, showing a frequency shift of 10.5%
Reconfigurable antenna using photoconducting switches
This paper presents a design for an optically reconfigurable printed dipole antenna. A wideband coplanar
waveguide (CPW) to coplanar stripline (CPS) transition is used to feed the balanced printed dipole. Two silicon
photo switches are placed on small gaps in both dipole arms equidistant from the centre feed. Light from two
infra-red laser diodes channelled through fibre optic cables is applied to the switches. With the gaps in the
dipole bridged, the antenna resonates at a lower frequency. Measured return loss results that compare well to the
simulated values are also presented, showing a frequency shift of nearly 40%. The change in bore-sight gain
along with radiation patterns are also presented
Antenna performance on quasi synthetic media
While we seem to be experiencing a material evolution by applying unique properties of metamaterials,
such as negative constitutive parameters and to some extent cloaking phenomena, not much attention has been paid in
the practical suitability of synthetic materials towards antenna designs. The antenna designer is often faced with a
judicious choice of:- complexity in the conducting/radiating shape, substrate and radome parameters, cost as well as
ever increasing environmental effects both in the construction but also in the disposal of the antenna as part of a
recycling process. This paper will outline some of the hypotheses and processes that underpin our terminology of quasi
synthetic media and will proceed to illustrate how one can obtain a variety of dielectric (and magnetic) effective
contrasts from 3-D structures containing either dielectric or conducting micro particles. Some representative patch
designs are considered to indicate how one could replace cumbersome conventional design and manufacturing
processes by using nanotechnology and additive manufacturing
Additively manufactured profiled conical horn antenna with dielectric loading
The world's first additively manufactured dielectric loaded profiled conical horn antenna is presented in this letter. With a smooth profiled flare and two loaded dielectric core materials, this horn offers symmetrical patterns, wideband gain, low sidelobe level, and low cross polarization. Additive manufacturing, including electroplating, has been employed to address the fabrication challenges. The measurement results show that the fabrication process produces a horn antenna with reduced mass and volume (<;200 g with three-dimensional-printed flange) and high antenna performance with realized gain 16-20 dBi, sidelobe level -22 to -19 dB across the frequency range from 9 to 15 GHz
Additively manufactured artificial materials with metallic meta-atoms
The paper presents the analysis and fabrication of artificial materials with metallic cuboid inclusions (termed here as meta-atoms) in a dielectric host material. These synthetic materials or metamaterials have been additively manufactured with a fused deposition modelling (FDM) 3D-printer. The effective permittivity and permeability have been numerically analyzed using the Maxwell-Garnett and Lewin’s approximation. Simulations and measurements have shown good agreement with analytical calculations. The anisotropy of the heterogeneous mixture due to the orientation of the meta-atoms has been demonstrated. The effective permittivity has been increased by the presence of the meta-atoms, which has the potential of producing 3D-printing metamaterials with tailored electromagnetic properties
Designing microwave patch antennas using heterogeneous substrates
This paper introduces the concept of designing
microwave patch antennas by creating synthetic heterogeneous
substrates with small scale inclusions. These inclusions embedded
in a host dielectric can be used to control the dielectric properties
and create bespoke effective permittivity values. Heterogeneous
patch antennas at 2.4GHz are simulated in this paper. By
deliberately mapping the permittivity values to the electric fields,
the antenna behavior can be controlled and a dual band
frequency was introduced. The local regions with micro-scale
inclusions showed good agreement with a homogeneous substrate
section with the same predicted permittivity. These
heterogeneous substrates can be potentially created using
nanomaterials
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