dc.description.abstract |
The size and complexity of wireless communication networks have grown
tremendously over the last few decades. Analysis of a wireless communication system
requires computer simulations of the entire communication network, spanning multiple
cells with a large number of base stations and mobile terminals. This normally involves
complex physical layer computations in order to evaluate the receiver performance with
the transmitted signals subjected to interference, multipath propagation, and
shadowing. Link to system (L2S) interfacing reduces the computational complexity
associated with the physical layer performance evaluation of multiple communication
links by predicting the receiver behavior under different channel conditions using precalculated lookup tables (LUTs).
This thesis investigates the L2S interfacing for different advanced receiver strategies
using various nonlinear mapping functions. Different transmission scenarios such as
single input single output, single input multiple output, and multiple input multiple
output are considered. Besides using the conventional AWGN channel performance as
the reference LUT, the mean of different channel frame error performance is also
suggested as reference and the prediction accuracy of both have been compared. L2S
framework has been implemented using the post detection signal to noise ratio (SNR)
values as the received signal quality measure. The existing L2S work for SISO, linear
MIMO systems has been extended to iterative and maximum likelihood receivers,
where finding an accurate estimate of the received signal quality which is highly
correlated to the receiver output is an open problem and needs to be fully explored.
Algorithms for the post detection SNR value estimation for iterative and maximum
likelihood receivers have been proposed and their prediction performance is validated
for diverse communication channels. It is shown that, the post detection SNR value is
an accurate measure of the quality of the received signal. However, for MIMO system
with single stream encoding, the accurate estimation of the post detection SNR value
for each individual link is not essential, but rather an accurate average value over
multiple links is found to be sufficient. The other main contribution of this thesis is the formulation of a Artificial
Neural Network (ANN) framework for the receiver performance prediction. ANN has
been applied extensively to diverse applications due to its fast processing in real time
scenarios. This is due to its ability to learn different tasks and to make decisions without
being explicitly programmed. ANN has been used in this thesis for L2S interfacing in
order to reduce the extensive training required for generating the reference curves in
the classical L2S interfacing without having to compromise the quality of the prediction
process. It has been shown that the quality features extracted from the received signal
can be used in the machine learning algorithms for accurate prediction of the link level
performances. An ANN based L2S interfacing has been implemented for different
linear and nonlinear MIMO receiver strategies. The ANN based technique gives good
link level performance prediction accuracy while doing away with the need for
computing the pre-estimated LUTs required in classical L2S interfacing. Additionally,
the ANN model when imported into the communication system simulation chain gives
an independent frame error decision for each transmitted frame. |
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