530 research outputs found
A predefined channel coefficients library for vehicle-to-vehicle communications
It is noticeable that most of VANETs communications tests are assessed through simulation. In a majority of simulation results, the physical layer is often affected by an apparent lack of realism. Therefore, vehicular channel model has become a critical issue in the field of intelligent transport systems (ITS). To overcome the lack of realism problem, a more robust channel model is needed to reflect the reality. This paper provides an open access, predefined channel coefficients library. The library is based on 2x2 and 4x4 Multiple – Input – Multiple – Output (MIMO) systems in V2V communications, using a spatial channel model extended SCME which will help to reduce the overall simulation time. In addition, it provides a more realistic channel model for V2V communications; considering: over ranges of speeds, distances, multipath signals, sub-path signals, different angle of arrivals, different angle departures, no line of sight and line of sight. An intensive evaluation process has taken place to validate the library and acceptance results are produced. Having an open access predefined library, enables the researcher at relevant communities to test and evaluate several complicated vehicular communications scenarios in a wider manners with less time and efforts
A Mixed-Bouncing Based Non-Stationarity and Consistency 6G V2V Channel Model with Continuously Arbitrary Trajectory
In this paper, a novel three-dimensional (3D) irregularshaped geometry-based stochastic model (IS-GBSM) is proposedfor sixth-generation (6G) millimeter wave (mmWave) massivemultiple-input multiple-output (MIMO) vehicle-to-vehicle(V2V) channels. To investigate the impact of vehicular trafficdensity (VTD) on channel statistics, clusters are divided into staticclusters and dynamic clusters, which are further distinguishedinto static/dynamic single/twin-clusters to capture the mixed bouncingpropagation. A new method, which integrates thevisibility region and birth-death process methods, is developedto model space-time-frequency (S-T-F) non-stationarity of V2Vchannels with time-space (T-S) consistency. The continuouslyarbitrary vehicular movement trajectory (VMT) and soft clusterpower handover are modeled to further ensure channel T-Sconsistency. From the proposed model, key channel statistics arederived. Simulation results show that S-T-F non-stationarity ofchannels with T-S consistency is modeled and the impacts of VTDand VMT on channel statistics are analyzed. The generality ofthe proposed model is validated by comparing simulation resultsand measurement/ray-tracing (RT)-based results
A Non-Stationary MIMO Vehicle-to-Vehicle Channel Model Derived From the Geometrical T-Junction Model
Realistic geometry-based stochastic channel models for advanced wireless MIMO systems
The employment of multiple antennas at both the Transmitter (Tx) and Receiver (Rx)
enables the so-called Multiple-Input Multiple-Output (MIMO) technologies to greatly
improve the link reliability and increase the overall system capacity. MIMO has been
recommended to be employed in various advanced wireless communication systems,
e.g., the Fourth Generation (4G) wireless systems and beyond. For the successful
design, performance test, and simulation of MIMO wireless communication systems, a
thorough understanding of the underlying MIMO channels and corresponding models
are indispensable. The approach of geometry-based stochastic modelling has widely
been used due to its advantages, such as convenience for theoretical analysis and
mathematical tractability.
In addition, wireless Vehicle-to-Vehicle (V2V) communications play an important role
in mobile relay-based cellular networks, vehicular ad hoc networks, and intelligent
transportation systems. In V2V communication systems, both the Tx and Rx are
in motion and equipped with low elevation antennas. This is di erent from conventional
Fixed-to-Mobile (F2M) cellular systems, where only one terminal moves. This
PhD project is therefore devoted to the modelling and simulation of wireless MIMO
channels for both V2V and F2M communication systems.
In this thesis, we rst propose a novel narrowband Three Dimensional (3D) theoretical
Regular-Shape Geometry Based Stochastic Model (RS-GBSM) and the corresponding
Sum-of-Sinusoids (SoS) simulation model for non-isotropic MIMO V2V Ricean fading
channels. The proposed RS-GBSM has the ability to study the impact of the Vehicular
Tra c Density (VTD) on channel statistics and jointly considers the azimuth
and elevation angles by using the von Mises-Fisher (VMF) distribution. Moreover, a
novel parameter computation method is proposed for jointly calculating the azimuth
and elevation angles in the SoS channel simulator. Based on the proposed 3D theoretical
RS-GBSM and its SoS simulation model, statistical properties are derived
and thoroughly investigated. The impact of the elevation angle in the 3D model on
key statistical properties is investigated by comparing with those of the corresponding
Two Dimensional (2D) model. It is demonstrated that the 3D model is more practical
to characterise real V2V channels, in particular for pico-cell scenarios.
Secondly, actual V2V channel measurements have shown that the modelling assumption
of Wide Sense Stationary (WSS) is valid only for very short time intervals. This fact inspires the requirement of non-WSS V2V channel models. Therefore, we propose
a novel 3D theoretical wideband MIMO non-WSS V2V RS-GBSM and corresponding
SoS simulation model. Due to the dynamic movement of both the Tx and Rx,
the Angle of Departure (AoD) and Angle of Arrival (AoA) are time-variant, which
makes our model non-stationary. The proposed RS-GBSMs are su ciently generic
and adaptable to mimic various V2V scenarios. Furthermore, important local channel
statistical properties are derived and thoroughly investigated. The impact of
non-stationarity on these channel statistical properties is investigated by comparing
with those of the corresponding WSS model. The proposed non-WSS RS-GBSMs are
validated by measurements in terms of the channel stationary time.
Thirdly, realistic MIMO channel models with a proper trade-o between accuracy
and complexity are indispensable for the practical application. By comparing the
accuracy and complexity of two latest F2M standardised channel models (i.e., LTE-A
and IMT-A channel models), we employ some channel statistical properties as the
accuracy metrics and the number of Real Operations (ROs) as the complexity metric.
It is shown that the LTE-A MIMO channel model is simple but has signi cant
aws
in terms of the accuracy. The IMT-A channel model is complicated but has better
accuracy. Therefore, we focus on investigating various complexity reduction methods
to simplify the IMT-A channel model. The results have shown that the proposed
methods do not degrade much the accuracy of the IMT-A channel model, whereas
they can signi cantly reduce the complexity in terms of the number of ROs and
channel coe cients computing time.
Finally, to investigate the non-stationarity of the IMT-A MIMO channel model, we
further propose a non-WSS channel model with time-varying AoDs and AoAs. The
proposed time-varying functions can be applied to various scenarios according to moving
features of Moving Clusters (MCs) and a Mobile Station (MS). Moreover, the impacts
of time-varying AoDs and AoAs on local statistical properties are investigated
thoroughly. Simulation results prove that statistical properties are varied with time
due to the non-stationarity of the proposed channel model.
In summary, the proposed reference models and channel simulators are useful for
the design, testing, and performance evaluation of advanced wireless V2V and F2M
MIMO communication systems
A Non-Stationary IMT-Advanced MIMO Channel Model for High-Mobility Wireless Communication Systems
The file attached to this record is the author's final peer reviewed version. The Publisher's final version can be found by following the DOI link.With the recent developments of high-mobility wireless communication systems, e.g., high-speed train (HST) and vehicle-to-vehicle (V2V) communication systems, the ability of conventional stationary channel models to mimic the underlying channel characteristics has widely been challenged. Measurements have demonstrated that the current standardized channel models, like IMT-Advanced (IMT-A) and WINNER II channel models, offer stationary intervals that are noticeably longer than those in measured HST channels. In this paper, we propose a non-stationary channel model with time-varying parameters including the number of clusters, the powers and the delays of the clusters, the angles of departure (AoDs), and the angles of arrival (AoAs). Based on the proposed non-stationary IMT-A channel model, important statistical properties, i.e., the local spatial cross-correlation function (CCF) and local temporal autocorrelation function (ACF) are derived and analyzed. Simulation results demonstrate that the statistical properties vary with time due to the non-stationarity of the proposed channel model. An excellent agreement is achieved between the stationary interval of the developed non-stationary IMT-A channel model and that of relevant HST measurement data, demonstrating the utility of the proposed channel model
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