Mobile to mobile channel modelling for wireless communications

dc.contributor.authorSamarasinghe, Prasad Talpawila Kankanamge Don Arunaen_AU
dc.date.accessioned2019-02-18T23:45:17Z
dc.date.available2019-02-18T23:45:17Z
dc.date.copyright2014
dc.date.issued2014
dc.date.updated2019-01-10T08:24:43Z
dc.description.abstractWireless communication has been experiencing many recent advances in mobile to mobile (M2M) applications. M2M communication systems differ from conventional fixed to mobile systems by having both transmitter and receiver in low elevation and in motion. This raises the need to come up with new channel models and perform statistical analysis on M2M communication channels looking from a different perspective. This need motivated us to perform the research outlined in this thesis. In reviewing the literature we found that though in general the M2M channel models are sparse, a major gap exists in the non geometrical stochastic based mathematical channel models. In filling this gap, we develop a novel mathematical non geometrical stochastic multiple input multiple output (MIMO) M2M channel model for two dimensional (2D) and three dimensional (3D) scattering environments. This model is based on the underlying physics of free space wave propagation and can be used as a framework for any environment by selecting suitable complex scattering gain functions. In addition, we extend this novel model to multicarrier M2M which is the first multicarrier channel model in the non geometrical stochastic M2M category. Based on our novel M2M channel model, we carry out an extensive analysis in space-time correlation, space-frequency correlation and second order channel statistics. With the choice of suitable parameters, this analysis and channel model can be used for any wireless environment. Thus, we claim that our novel channel model together with the analysis performed in this thesis can be taken as a generalized framework. A significant contribution of our analysis is the consideration of the impact of transmitter and receiver speed to space-time and space-frequency correlation, which is not available in the literature. Using a von Mises-Fisher distribution as the angular power distribution, the usefulness of the derived temporal correlation function is discussed. The simulation results corroborate the fact that both space-time and space-frequency correlations are reduced when transmitter or receiver speed increases. The rate of reduction of space-time correlation in von Mises-Fisher distribution scattering environment is more than in the isotropic environment. Under second order channel statistics, we consider Rice, Rayleigh and Nakagami fading channels in four different non-isotropic scattering environments with angle of departure (AoD) and angle of arrival (AoA) distributions given by (i) separable Truncated Gaussian, (ii) separable von-Mises, (iii) truncated Gaussian bivariate and (iv) truncated Laplacian bivariate distributions. We show that the major second order statistics, namely, the level crossing rate (LCR) and the average fade duration (AFD), in different fading channels can be expressed in terms of known scattering coefficients of the AoD and AoA distributions. As the channel models and their respective measurements provide reliable knowledge of the channel for the design and analysis of M2M systems, the proposed channel model and the corresponding analysis will be useful for the design, testing and performance evaluation of future M2M communication systems.
dc.format.extentxxii, 157 leaves.
dc.identifier.otherb3579062
dc.identifier.urihttp://hdl.handle.net/1885/156305
dc.subject.lcshWireless communication systems
dc.subject.lcshWireless communication systems Design
dc.subject.lcshMobile communication systems Computer simulation.
dc.subject.lcshSignals and signaling Mathematical models
dc.titleMobile to mobile channel modelling for wireless communications
dc.typeThesis (PhD)en-AU
local.contributor.affiliationAustralian National University. Research School of Engineering
local.contributor.supervisorKennedy, Rodney A.
local.description.notesThesis (Ph.D.)--Australian National University, 2014.
local.identifier.doi10.25911/5d51416f5968e
local.mintdoimint

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