Non-WSSUS vehicular channel characterization at 5.2 GHz-spectral divergence and time-variant coherence parameters

Laura Bernadó; Thomas Zemen; Alexander Paier; Gerald Matz; Johan Karedal; Nicolai Czink; Charlotte Dumard; Fredrik Tufvesson; Martin Hagenauer; Andreas F Molisch; Christoph F. Mecklenbräuker

Non-WSSUS vehicular channel characterization at 5.2 GHz-spectral divergence and time-variant coherence parameters

Laura Bernadó, Thomas Zemen, Alexander Paier, Gerald Matz, Johan Karedal, Nicolai Czink, Charlotte Dumard, Fredrik Tufvesson, Martin Hagenauer, Andreas F Molisch, Christoph F. Mecklenbräuker

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Abstract

The scattering environment in vehicle-to-vehicle communication channels at 5.2 GHz changes rapidly. Hence the wide-sense stationary (WSS) uncorrelated scattering (US) assumption for the fading process is valid for short time intervals only. We characterize the spectral divergence of the local scattering function (LSF) sequence in order to assess the non-WSSUS characteristics in different scenarios. We find that the vehicle-to-vehicle channels violate the wide-sense stationarity much stronger than the US assumption. Additionally, we use the LSF to quantify the time dependence of the channel coherence time and bandwidth. Both parameters vary strongly over time depending on the chosen scenario. Furthermore the effect of the antenna radiation pattern on the fading process is quantified, which can cause the strength of a multipath component to change by more than 40 dB in drive-by experiments.

Original language	English
Pages (from-to)	1-4
Journal	XXIXth URSI General Assembly
Volume	2008
Publication status	Published - 2008

Research Field

Enabling Digital Technologies

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https://citeseerx.ist.psu.edu/document?repid=rep1&type=pdf&doi=12520394c04c888d83ae821ed07f4061364efb0e

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Bernadó, L., Zemen, T., Paier, A., Matz, G., Karedal, J., Czink, N., Dumard, C., Tufvesson, F., Hagenauer, M., Molisch, A. F., & Mecklenbräuker, C. F. (2008). Non-WSSUS vehicular channel characterization at 5.2 GHz-spectral divergence and time-variant coherence parameters. XXIXth URSI General Assembly, 2008, 1-4. https://citeseerx.ist.psu.edu/document?repid=rep1&type=pdf&doi=12520394c04c888d83ae821ed07f4061364efb0e

@article{20365d83ae1c4e96b4996ba5e256dc67,

title = "Non-WSSUS vehicular channel characterization at 5.2 GHz-spectral divergence and time-variant coherence parameters",

abstract = "The scattering environment in vehicle-to-vehicle communication channels at 5.2 GHz changes rapidly. Hence the wide-sense stationary (WSS) uncorrelated scattering (US) assumption for the fading process is valid for short time intervals only. We characterize the spectral divergence of the local scattering function (LSF) sequence in order to assess the non-WSSUS characteristics in different scenarios. We find that the vehicle-to-vehicle channels violate the wide-sense stationarity much stronger than the US assumption. Additionally, we use the LSF to quantify the time dependence of the channel coherence time and bandwidth. Both parameters vary strongly over time depending on the chosen scenario. Furthermore the effect of the antenna radiation pattern on the fading process is quantified, which can cause the strength of a multipath component to change by more than 40 dB in drive-by experiments.",

author = "Laura Bernad{\'o} and Thomas Zemen and Alexander Paier and Gerald Matz and Johan Karedal and Nicolai Czink and Charlotte Dumard and Fredrik Tufvesson and Martin Hagenauer and Molisch, {Andreas F} and Mecklenbr{\"a}uker, {Christoph F.}",

year = "2008",

language = "English",

volume = "2008",

pages = "1--4",

}

Bernadó, L , Zemen, T, Paier, A, Matz, G, Karedal, J, Czink, N, Dumard, C, Tufvesson, F, Hagenauer, M, Molisch, AF & Mecklenbräuker, CF 2008, 'Non-WSSUS vehicular channel characterization at 5.2 GHz-spectral divergence and time-variant coherence parameters', XXIXth URSI General Assembly, vol. 2008, pp. 1-4. <https://citeseerx.ist.psu.edu/document?repid=rep1&type=pdf&doi=12520394c04c888d83ae821ed07f4061364efb0e>

TY - JOUR

T1 - Non-WSSUS vehicular channel characterization at 5.2 GHz-spectral divergence and time-variant coherence parameters

AU - Bernadó, Laura

AU - Zemen, Thomas

AU - Paier, Alexander

AU - Matz, Gerald

AU - Karedal, Johan

AU - Czink, Nicolai

AU - Dumard, Charlotte

AU - Tufvesson, Fredrik

AU - Hagenauer, Martin

AU - Molisch, Andreas F

AU - Mecklenbräuker, Christoph F.

PY - 2008

Y1 - 2008

N2 - The scattering environment in vehicle-to-vehicle communication channels at 5.2 GHz changes rapidly. Hence the wide-sense stationary (WSS) uncorrelated scattering (US) assumption for the fading process is valid for short time intervals only. We characterize the spectral divergence of the local scattering function (LSF) sequence in order to assess the non-WSSUS characteristics in different scenarios. We find that the vehicle-to-vehicle channels violate the wide-sense stationarity much stronger than the US assumption. Additionally, we use the LSF to quantify the time dependence of the channel coherence time and bandwidth. Both parameters vary strongly over time depending on the chosen scenario. Furthermore the effect of the antenna radiation pattern on the fading process is quantified, which can cause the strength of a multipath component to change by more than 40 dB in drive-by experiments.

AB - The scattering environment in vehicle-to-vehicle communication channels at 5.2 GHz changes rapidly. Hence the wide-sense stationary (WSS) uncorrelated scattering (US) assumption for the fading process is valid for short time intervals only. We characterize the spectral divergence of the local scattering function (LSF) sequence in order to assess the non-WSSUS characteristics in different scenarios. We find that the vehicle-to-vehicle channels violate the wide-sense stationarity much stronger than the US assumption. Additionally, we use the LSF to quantify the time dependence of the channel coherence time and bandwidth. Both parameters vary strongly over time depending on the chosen scenario. Furthermore the effect of the antenna radiation pattern on the fading process is quantified, which can cause the strength of a multipath component to change by more than 40 dB in drive-by experiments.

M3 - Article

VL - 2008

SP - 1

EP - 4

JO - XXIXth URSI General Assembly

JF - XXIXth URSI General Assembly

ER -

Non-WSSUS vehicular channel characterization at 5.2 GHz-spectral divergence and time-variant coherence parameters

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