Index modulation for next generation wireless communications.
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Date
2018
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Abstract
A multicarrier index modulation technique in the form of quadrature spatial modulation (QSM)
orthogonal frequency division multiplexing (QSM-OFDM) is proposed, in which transmit antenna
indices are employed to transmit additional bits. Monte Carlo simulation results demonstrates a 5 dB
gain in signal-to-noise ratio (SNR) over other OFDM schemes. Furthermore, an analysis of the
receiver computational complexity is presented.
A low-complexity near-ML detector for space-time block coded (STBC) spatial modulation
(STBC-SM) with cyclic structure (STBC-CSM), which demonstrate near-ML error performance and
yields significant reduction in computational complexity is proposed. In addition, the union-bound
theoretical framework to quantify the average bit-error probability (ABEP) of STBC-CSM is
formulated and validates the Monte Carlo simulation results.
The application of media-based modulation (MBM), to STBC-SM and STBC-CSM employing radio
frequency (RF) mirrors, in the form of MBSTBC-SM and MBSTBC-CSM is proposed to improve
the error performance. Numerical results of the proposed schemes demonstrate significant
improvement in error performance when compared with STBC-CSM and STBC-SM. In addition, the
analytical framework of the union-bound on the ABEP of MBSTBC-SM and MBSTBC-CSM for the
ML detector is formulated and agrees well with Monte Carlo simulations. Furthermore, a
low-complexity near-ML detector for MBSTBC-SM and MBSTBC-CSM is proposed, and achieves a
near-ML error performance. Monte Carlo simulation results demonstrate a trade-off between the
error performance and the resolution of the detector that is employed.
Finally, the application of MBM, an index modulated system to spatial modulation, in the form of
spatial MBM (SMBM) is investigated. SMBM employs RF mirrors located around the transmit
antenna units to create distinct channel paths to the receiver. This thesis presents an easy to evaluate
theoretical bound for the error performance of SMBM, which is validated by Monte Carlo simulation
results. Lastly, two low-complexity suboptimal mirror activation pattern (MAP) optimization
techniques are proposed, which improve the error performance of SMBM significantly.
Description
Doctoral Degree. University of KwaZulu-Natal, Durban.