A Generalized Modified Suzuki Model with Sectored and Inhomogeneous Diffuse Scattering Component
Wireless Personal Communications: An International Journal
A Novel Isotropic Scatter Distribution Wideband MIMO M2M Fading Channel Model
CNSR '09 Proceedings of the 2009 Seventh Annual Communication Networks and Services Research Conference
A geometry-based stochastic MIMO model for vehicle-to-vehicle communications
IEEE Transactions on Wireless Communications
Propagation aspects of vehicle-to-vehicle communications - an overview
RWS'09 Proceedings of the 4th international conference on Radio and wireless symposium
An adaptive geometry-based stochastic model for non-isotropic MIMO mobile-to-mobile channels
IEEE Transactions on Wireless Communications
A geometry-based stochastic model for wideband MIMO mobile-to-mobile channels
GLOBECOM'09 Proceedings of the 28th IEEE conference on Global telecommunications
IEEE Transactions on Wireless Communications
Design of wideband MIMO car-to-car channel models based on the geometrical street scattering model
Modelling and Simulation in Engineering - Special issue on Modeling and Simulation of Mobile Radio Channels
3D Ellipsoidal Model for Mobile-to-Mobile Radio Propagation Environments
Wireless Personal Communications: An International Journal
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This paper' deals with the modeling, analysis, and simulation of multiple-input multiple-output (MIMO) narrowband fading channels for mobile-to-mobile communications. A stochastic MIMO mobile-to-mobile reference channel model is derived from the geometrical two-ring scattering model under the assumption that both the transmitter and the receiver are surrounded by an infinite number of local scatterers. Using a wave propagation model, the complex channel gains are derived and their statistical properties are studied. General analytical solutions are provided for the three-dimensional (3-D) space-time cross-correlation function (CCF). We show that this function can be expressed as the product of two 2D space-time cross-correlation function (CFs), called the transmit and receive CF. From the non-realizable reference model, a stochastic and a deterministic simulation model are derived using a double sum of complex exponential functions. It is shown how the parameters of the simulation model can be determined for any given distribution of the angle of departure (AOD) and angle of arrival (AOA). In case of isotropic scattering, we present a closed-form solution for the parameter computation problem and illustrate some numerical results concerning the transmit CF. The proposed procedure provides an important framework for designers of future mobile-to-mobile communication systems to verify new transmission concepts employing MIMO techniques under realistic propagation conditions.