Gaussian beam launching for 3D physical modeling of propagation channels

Anca Fluerasu; Christine Letrou

doi:10.1007/s12243-009-0121-2

Gaussian beam launching for 3D physical modeling of propagation channels

Anca Fluerasu
, Christine Letrou

CNRS SAMOVAR UMR 5157

Research output: Contribution to journal › Article › peer-review

Abstract

Gaussian beam launching is proposed as an alternative to ray-based techniques for propagation channel modeling, and it is implemented and validated in the context of indoor propagation. A rigorous Gabor frame decomposition of source fields is used to represent a radiated field as a superposition of shifted and rotated Gaussian beams, conveniently expressed as complex rays. Beam tracking through multiple reflections and transmissions is straightforward, and fields can then be evaluated by summation of closed form expressions. The parameters of a given transformed Gaussian beam have to be calculated only once for all observation points, leading to easy implementation, and computationally efficient algorithms. Simulations of amplitude-delay profiles, mean excess delay, and RMS delay spread are performed in an indoor environment at 60 GHz and compared to measured and published results.

Original language	English
Pages (from-to)	763-776
Number of pages	14
Journal	Annales des Telecommunications/Annals of Telecommunications
Volume	64
Issue number	11-12
DOIs	https://doi.org/10.1007/s12243-009-0121-2
Publication status	Published - 1 Dec 2009

Keywords

Amplitude-delay profile
Channel characterization
Channel measurements
Delay spread
Gabor frame
Gaussian beam
Indoor multipath propagation
Millimeter-wave

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10.1007/s12243-009-0121-2

Cite this

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title = "Gaussian beam launching for 3D physical modeling of propagation channels",

abstract = "Gaussian beam launching is proposed as an alternative to ray-based techniques for propagation channel modeling, and it is implemented and validated in the context of indoor propagation. A rigorous Gabor frame decomposition of source fields is used to represent a radiated field as a superposition of shifted and rotated Gaussian beams, conveniently expressed as complex rays. Beam tracking through multiple reflections and transmissions is straightforward, and fields can then be evaluated by summation of closed form expressions. The parameters of a given transformed Gaussian beam have to be calculated only once for all observation points, leading to easy implementation, and computationally efficient algorithms. Simulations of amplitude-delay profiles, mean excess delay, and RMS delay spread are performed in an indoor environment at 60 GHz and compared to measured and published results.",

keywords = "Amplitude-delay profile, Channel characterization, Channel measurements, Delay spread, Gabor frame, Gaussian beam, Indoor multipath propagation, Millimeter-wave",

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AU - Letrou, Christine

PY - 2009/12/1

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N2 - Gaussian beam launching is proposed as an alternative to ray-based techniques for propagation channel modeling, and it is implemented and validated in the context of indoor propagation. A rigorous Gabor frame decomposition of source fields is used to represent a radiated field as a superposition of shifted and rotated Gaussian beams, conveniently expressed as complex rays. Beam tracking through multiple reflections and transmissions is straightforward, and fields can then be evaluated by summation of closed form expressions. The parameters of a given transformed Gaussian beam have to be calculated only once for all observation points, leading to easy implementation, and computationally efficient algorithms. Simulations of amplitude-delay profiles, mean excess delay, and RMS delay spread are performed in an indoor environment at 60 GHz and compared to measured and published results.

AB - Gaussian beam launching is proposed as an alternative to ray-based techniques for propagation channel modeling, and it is implemented and validated in the context of indoor propagation. A rigorous Gabor frame decomposition of source fields is used to represent a radiated field as a superposition of shifted and rotated Gaussian beams, conveniently expressed as complex rays. Beam tracking through multiple reflections and transmissions is straightforward, and fields can then be evaluated by summation of closed form expressions. The parameters of a given transformed Gaussian beam have to be calculated only once for all observation points, leading to easy implementation, and computationally efficient algorithms. Simulations of amplitude-delay profiles, mean excess delay, and RMS delay spread are performed in an indoor environment at 60 GHz and compared to measured and published results.

KW - Amplitude-delay profile

KW - Channel characterization

KW - Channel measurements

KW - Delay spread

KW - Gabor frame

KW - Gaussian beam

KW - Indoor multipath propagation

KW - Millimeter-wave

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M3 - Article

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SN - 0003-4347

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SP - 763

EP - 776

JO - Annales des Telecommunications/Annals of Telecommunications

JF - Annales des Telecommunications/Annals of Telecommunications

IS - 11-12

ER -

Gaussian beam launching for 3D physical modeling of propagation channels

Abstract

Keywords

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