Near Field Radiation Patterns for an Ultra-Wide-Band Antenna

Jonathan Blackledge; Bazar Babajanov

doi:10.21427/d7rj8k

Near Field Radiation Patterns for an Ultra-Wide-Band Antenna

Jonathan Blackledge
, Bazar Babajanov

Technological University Dublin

Research output: Contribution to conference › Paper › peer-review

Abstract

We present a three-dimensional time dependent model for simulating the electromagnetic radiation field patterns generated by Ultra-Wide- Band (UWB) antennas. UWB antennas are pulsed mode radiators used to communicate information at high bit rates over short distance. This affects the spatial characteristics of the field patterns assumed to be generated when a Continuous Wave (CW) model is used and this paper investigates the difference between the near field intensity patterns generated when a pulse and CW mode is used. The purpose of this is to develop a numerical simulation that provides information on the three-dimensional electromagnetic field subject to a known (integrated) antenna geometry. The context of the approach considered is the design of integrated antennas that extend the performance of UWB systems in terms of range (in the near field) subject to emission standards.

Original language	English
DOIs	https://doi.org/10.21427/d7rj8k
Publication status	Published - 2013
Event	ISSC13 - Letterkenny, Ireland Duration: 20 Jun 2013 → 21 Jun 2013

Conference

Conference	ISSC13
Country/Territory	Ireland
City	Letterkenny
Period	20/06/13 → 21/06/13
Other	ISSC13

Keywords

three-dimensional
time dependent model
electromagnetic radiation
Ultra-Wide-Band
UWB antennas
pulsed mode radiators
high bit rates
short distance
spatial characteristics
Continuous Wave
CW model
near field intensity patterns
pulse mode
numerical simulation
integrated antenna geometry
design of integrated antennas
UWB systems
range
emission standards

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10.21427/d7rj8kLicence: CC BY-NC-SA

Cite this

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abstract = "We present a three-dimensional time dependent model for simulating the electromagnetic radiation field patterns generated by Ultra-Wide- Band (UWB) antennas. UWB antennas are pulsed mode radiators used to communicate information at high bit rates over short distance. This affects the spatial characteristics of the field patterns assumed to be generated when a Continuous Wave (CW) model is used and this paper investigates the difference between the near field intensity patterns generated when a pulse and CW mode is used. The purpose of this is to develop a numerical simulation that provides information on the three-dimensional electromagnetic field subject to a known (integrated) antenna geometry. The context of the approach considered is the design of integrated antennas that extend the performance of UWB systems in terms of range (in the near field) subject to emission standards.",

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author = "Jonathan Blackledge and Bazar Babajanov",

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doi = "10.21427/d7rj8k",

language = "English",

note = "ISSC13 ; Conference date: 20-06-2013 Through 21-06-2013",

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AU - Babajanov, Bazar

PY - 2013

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N2 - We present a three-dimensional time dependent model for simulating the electromagnetic radiation field patterns generated by Ultra-Wide- Band (UWB) antennas. UWB antennas are pulsed mode radiators used to communicate information at high bit rates over short distance. This affects the spatial characteristics of the field patterns assumed to be generated when a Continuous Wave (CW) model is used and this paper investigates the difference between the near field intensity patterns generated when a pulse and CW mode is used. The purpose of this is to develop a numerical simulation that provides information on the three-dimensional electromagnetic field subject to a known (integrated) antenna geometry. The context of the approach considered is the design of integrated antennas that extend the performance of UWB systems in terms of range (in the near field) subject to emission standards.

AB - We present a three-dimensional time dependent model for simulating the electromagnetic radiation field patterns generated by Ultra-Wide- Band (UWB) antennas. UWB antennas are pulsed mode radiators used to communicate information at high bit rates over short distance. This affects the spatial characteristics of the field patterns assumed to be generated when a Continuous Wave (CW) model is used and this paper investigates the difference between the near field intensity patterns generated when a pulse and CW mode is used. The purpose of this is to develop a numerical simulation that provides information on the three-dimensional electromagnetic field subject to a known (integrated) antenna geometry. The context of the approach considered is the design of integrated antennas that extend the performance of UWB systems in terms of range (in the near field) subject to emission standards.

KW - three-dimensional

KW - time dependent model

KW - electromagnetic radiation

KW - Ultra-Wide-Band

KW - UWB antennas

KW - pulsed mode radiators

KW - high bit rates

KW - short distance

KW - spatial characteristics

KW - Continuous Wave

KW - CW model

KW - near field intensity patterns

KW - pulse mode

KW - numerical simulation

KW - integrated antenna geometry

KW - design of integrated antennas

KW - UWB systems

KW - range

KW - emission standards

U2 - 10.21427/d7rj8k

DO - 10.21427/d7rj8k

M3 - Paper

T2 - ISSC13

Y2 - 20 June 2013 through 21 June 2013

ER -

Near Field Radiation Patterns for an Ultra-Wide-Band Antenna

Abstract

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Keywords

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