Position-Specific Statistics of 60 GHz Vehicular Channels During Overtaking

Zöchmann, Erich; Hofer, Markus; Lerch, Martin; Pratschner, Stefan; Bernadó, Laura; Blumenstein, Jiří; Caban, Sebastian; Sangodoyin, Seun; Groll, Herbert; Zemen, Thomas; Prokeš, Aleš; Rupp, Markus; Molisch, Andreas F.; Mecklenbräuker, Christoph F.

doi:10.1109/access.2019.2893136

Cited by 45 publications

(31 citation statements)

References 54 publications

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“…If we also consider the center frequency of the channel model f 0 = 60 GHz and 10 GHz channel bandwidth, we can assume that the channel model is frequency selective and represents the small-scale fading case. This assumption is valid for mmWave bands [13,14]. Such a channel can be described by CIR as:…”

Section: Channel Model and Parameter Estimation Methodsmentioning

confidence: 99%

“…It also serves to obtain an approximate estimate of the range of suitable S-G filter cut-off frequencies f c for application to noisy |H(jω)| and illustrate whether it adds some improvement to the basic τ RMS estimation method described by Witrisal [2]. If we relate the used two-ray channel model to the current widely utilized and discussed two-wave channel model with diffuse power fading (TWDP), which assumess an interference of two strong signals (specular components) and a number of diffuse signals, then the ratio of specular-to-diffuse power K TWDP → ∞ (only specular components are considered) and the ratio of the specular components ∆ TWDP equals 1 [13]. The examination of a number of combinations of the channel model parameters and the channel model types goes beyond the scope of this work.…”

Section: S-g Filtermentioning

confidence: 99%

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Improved RMS Delay Spread Estimation for mmWave Channels Using Savitzky–Golay Filters

et al. 2019

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In this paper, a novel method for improving the estimation accuracy of the root mean square (RMS) delay spread from the magnitude of the Channel Transfer Function (CTF) is presented. We utilize the level crossing rate metric in the frequency domain, which is based on scalar power measurement. The Savitzky–Golay (S-G) filtering method is used to improve the fidelity of the channel delay spread estimator. The presented concept is simple to implement and inexpensive. The proposed method is tested on the CTF magnitude data measured in the mmWave frequency band at low Signal-to-Noise Ratio (SNR).

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Section: Channel Model and Parameter Estimation Methodsmentioning

confidence: 99%

Section: S-g Filtermentioning

confidence: 99%

Improved RMS Delay Spread Estimation for mmWave Channels Using Savitzky–Golay Filters

et al. 2019

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“…In this section, by comparing the results obtained from the measurement campaign in [38] and the simulation results obtained through the RT simulator under the same environments, the accuracy of the RT simulator is verified.…”

Section: Channel Measurement and Rt Simulationmentioning

confidence: 99%

Channel Characterization for Vehicle-to-Infrastructure Communications in Millimeter-Wave Band

Yan

Guan

et al. 2020

IEEE Access

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In recent years, the intelligent transport system (ITS) has been developed rapidly because of global urbanization and industrialization, which is considered as the key enabling technology to improve road safety, traffic efficiency, and driving experience. To achieve these goals, vehicles need to be equipped with a large number of sensors to enable the generation and exchange of high-rate data streams. Recently, millimeter-wave (mmWave) technology has been introduced as a means of meeting such a high data rate requirement. In this paper, a comprehensive study on the channel characteristics for vehicle-toinfrastructure (V2I) link in mmWave band (22.1-23.1 GHz) for various road environments and deployment configurations is conducted. The self-developed ray-tracing (RT) simulator is employed with the calibrated electromagnetic (EM) parameters. The three-dimensional (3D) environment models are reconstructed from the OpenStreetMap (OSM). In the simulations, not only the vehicle user equipment (UE) moves, but also the other vehicles such as cars, delivery vans, and buses move around the vehicle UE. Moreover, the impacts of the receiver (Rx) multiple antennas and beam switching technologies at the vehicle UE are evaluated as well. The channel parameters of the V2I link in mmWave band, including received power, Rician K-factor, rootmean-square delay spread, and angular spreads are explored in the target scenarios under different simulation deployments. This work aims to help the researchers understand the channel characteristics of the V2I links in mmWave band and support the link-level and system-level design for future vehicular communications.

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“…Nowadays, thanks to the advance of integrated circuits used in mmWave bands [11][12][13], low-cost devices become possible and hence the study on mmWave V2X networks is reinvigorated. Recently, several research efforts have been devoted to exploring such networks [14][15][16][17]. During overtaking, the actual V2V propagation channel for the frequency range from 59.75 to 60.25 GHz was measured in [14].…”

Section: A Related Work and Motivationsmentioning

confidence: 99%

“…Recently, several research efforts have been devoted to exploring such networks [14][15][16][17]. During overtaking, the actual V2V propagation channel for the frequency range from 59.75 to 60.25 GHz was measured in [14]. Since vehicular radars are also operated in mmWave bands, the authors in [15] proposed an adaptive cruise control mode to enhance mmWave V2X communications by incorporating radar sensing capabilities.…”

Section: A Related Work and Motivationsmentioning

confidence: 99%