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Mobile-to-mobile (M2M) and xed-to-mobile (F2M) communication technology
has shown astonishing intrusion in battle- elds, cellular and vehicular networks,
intelligent transportation systems and internet of things. Mobile nodes involved
in these infrastructures demand a high data rate connectivity over radio fading
links.
This dissertation concentrates on the geometrical modeling of the spatial characteristics
of two-dimensional (2D) and three-dimensional (3D) radio fading channel
for multiple-input-multiple-output (MIMO) M2M and MIMO F2M communication
scenarios. Closed-form expressions for the joint and marginal space-time
correlation functions among MIMO antenna array elements and probability density
function (PDF) of angle-of-arrival (AoA) of the multipaths in nonisotropic
environments are presented.
Initially, the emphasis has been on the 2D propagation scenario; where, mobile
subscribers are equipped with low elevated multiple antenna array structures and
they intend to communicate on the move without any base station (BS). These
mobile subscribers usually reside on structured-bounded highways or in the \long
and narrow" streets and canyons; where, the distribution of scattering objects
along the roadside regions are non-isotropic in nature. It is observed that elliptical
geometry is an appropriate shape, which correlates more accurately the layout
of such propagation environments than the circular shape. In the proposed model,
it is assumed that the mobile stations reside at the centers of two di erent ellipses
and the scatterers are distributed uniformly along the boundaries of the ellipses.
The ellipses are independently rotatable along the horizontal plane corresponding
to the direction of mobile stations. The lengths of major and minor axes and the
eccentricities of the ellipses are assumed to be dependant on the physical measurement
of the propagation environments. Using the proposed geometrical model, the
closed-form expression of PDF of AoA/AoD is obtained for non-isotropic scattering
environments. Based on this AoA/AoD, mathematical expression of joint and
marginal PDFs of space-time correlations among the MIMO antenna elements are
derived. The 2D eccentricity based channel model is then extended to 3D ellipticalbased
cylindrical channel model to accommodate the high-rise structures present
along the roadside premises of highways, streets or canyons. In this model, the
scattering objects are assumed to be placed on the surfaces of the elliptical-based
x
cylinders around both transmitter and receiver nodes. The horizontal dimension
of the physical propagation medium is modeled by eccentricity and height of the
scatterers are modeled by the height of cylinders. Mobile stations are placed at
the centers of the cylinders equipped with multiple antenna arrays. The dimension
of cylinders are independently adjustable and rotatable according to the physical
dimension of the propagation medium and the direction of motion of MS's. Here
again the mathematical expressions for correlations among MIMO M2M links are
formulated and the obtained theoretical results are simulated and compared with
the measured data. In the last part of thesis, a 3D elliptical based geometrical
channel model is proposed to model umbrella-cell in a cellular communication environment,
which provides trustworthy communication links for speedy vehicles on
the highways. In the proposed model, mobile subscriber is assumed to be located
at the center of the elliptical cylinder equipped with low-rise antenna array and the
scatterers are assumed to be uniformly distributed on the surface of the cylinder;
whereas, the BS is on the top of high-rise tower with multiple antenna structure
and is assumed to be scatter-free. Using the proposed model an expression for
space-time correlation among antenna elements is derived. |
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