Detail publikace

Frequency-Domain In-Vehicle Channel Modelling in mmW Band

Originální název

Frequency-Domain In-Vehicle Channel Modelling in mmW Band

Anglický název

Frequency-Domain In-Vehicle Channel Modelling in mmW Band

Jazyk

en

Originální abstrakt

The goal of this paper is to characterize frequency domain channel transfer function of intra vehicular millimeter wave links in the 60 GHz band. It is found that the complex transfer function may be decomposed into two terms, the first one being a real valued long term trend that characterizes frequency dependency with a power law, and the second term forms a complex correlative discrete series which may be represented via an autoregressive model. The proposed model is validated by comparing the simulated transfer function with the measured data. Simulated values for the coherence bandwidth, power delay profile, and the root mean square delay spread are also in good agreement with the experimental values.

Anglický abstrakt

The goal of this paper is to characterize frequency domain channel transfer function of intra vehicular millimeter wave links in the 60 GHz band. It is found that the complex transfer function may be decomposed into two terms, the first one being a real valued long term trend that characterizes frequency dependency with a power law, and the second term forms a complex correlative discrete series which may be represented via an autoregressive model. The proposed model is validated by comparing the simulated transfer function with the measured data. Simulated values for the coherence bandwidth, power delay profile, and the root mean square delay spread are also in good agreement with the experimental values.

BibTex


@inproceedings{BUT118198,
  author="Aniruddha {Chandra} and Pavel {Kukolev} and Tomáš {Mikulášek} and Aleš {Prokeš}",
  title="Frequency-Domain In-Vehicle Channel Modelling in mmW Band",
  annote="The goal of this paper is to characterize frequency
domain channel transfer function of intra vehicular millimeter
wave links in the 60 GHz band. It is found that the complex
transfer function may be decomposed into two terms, the first one
being a real valued long term trend that characterizes frequency
dependency with a power law, and the second term forms a
complex correlative discrete series which may be represented
via an autoregressive model. The proposed model is validated
by comparing the simulated transfer function with the measured
data. Simulated values for the coherence bandwidth, power delay
profile, and the root mean square delay spread are also in good
agreement with the experimental values.",
  booktitle="In 1st International Forum on Research and Technologies for Society and Industry (RTSI 2015)",
  chapter="118198",
  doi="10.1109/RTSI.2015.7325079",
  howpublished="electronic, physical medium",
  year="2015",
  month="september",
  pages="1--5",
  type="conference paper"
}