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Full-Diversity QO-STBC Technique for Large-Antenna MIMO SystemsAnoh, Kelvin O.O., Okorafor, G., Adebisi, B., Alabdullah, A., Jones, Steven M.R., Abd-Alhameed, Raed 05 May 2017 (has links)
Yes / The need to achieve high data rates in modern telecommunication systems, such as 5G standard, motivates the study and development of large antenna and multiple-input multiple-output (MIMO) systems. This study introduces a large antenna-order design of MIMO quasi-orthogonal space-time block code (QO-STBC) system that achieves better signal-to-noise ratio (SNR) and bit-error ratio (BER) performances than the conventional QO-STBCs with the potential for massive MIMO (mMIMO) configurations. Although some earlier MIMO standards were built on orthogonal space-time block codes (O-STBCs), which are limited to two transmit antennas and data rates, the need for higher data rates motivates the exploration of higher antenna configurations using different QO-STBC schemes. The standard QO-STBC offers a higher number of antennas than the O-STBC with the full spatial rate. Unfortunately, also, the standard QO-STBCs are not able to achieve full diversity due to self-interference within their detection matrices; this diminishes the BER performance of the QO-STBC scheme. The detection also involves nonlinear processing, which further complicates the system. To solve these problems, we propose a linear processing design technique (which eliminates the system complexity) for constructing interference-free QO-STBCs and that also achieves full diversity using Hadamard modal matrices with the potential for mMIMO design. Since the modal matrices that orthogonalize QO-STBC are not sparse, our proposal also supports O-STBCs with a well-behaved peak-to-average power ratio (PAPR) and better BER. The results of the proposed QO-STBC outperform other full diversity techniques including Givens-rotation and the eigenvalue decomposition (EVD) techniques by 15 dB for both MIMO and multiple-input single-output (MISO) antenna configurations at 10−3 BER. The proposed interference-free QO-STBC is also implemented for 16×NR and 32×NR MIMO systems, where NR≤2. We demonstrate 8 x 16 and 32 transmit antenna-enabled MIMO systems with the potential for mMIMO design applications with attractive BER and PAPR performance characteristics.
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Adaptive and Robust Multi-Gigabit Techniques Based MmWave Massive MU-MIMO Beamforming For 5G Wireless and Mobile Communications Systems. A Road Map for Simple and Robust Beamforming Scheme and Algorithms Based Wideband MmWave Massive MU-MIMO for 5G Wireless and Mobile Communications SystemsAlabdullah, Ali AbdulMohsin S. January 2021 (has links)
Over recent years, the research and studies have focused on innovative solutions in various aspects
and phases related to the high demands on data rate and energy for fifth-generation and beyond
(B5G). This thesis aims to improve the energy efficiency, error rates, low-resolution
ADCs/DACs, antenna array structures and sum-rate performances of a single cell downlink
broadband millimetre-wave (mmWave) systems with orthogonal frequency division multiplexing
(OFDM) modulation and deploying multi-user massive multiple inputs multiple outputs (MU mMIMO) by applying robust beamforming techniques and detection algorithms that support
multiple streams per user (UE) in various environments and scenarios to achieve low complexity
system design with reliable performance and significant improvement in users perceived quality
of service (QoS).
The performance of the four 5G candidate mmWave frequencies, 28 GHz, 39 GHz, 60 GHz, and
73 GHz, are investigated for indoor/outdoor propagation scenarios, including path loss models
and multipath delay spread values. Results are compared to confirm that the received power and
delay spread is decreased with increasing frequency. The results were also validated with the
measurement findings for 60 GHz.
Then several proposed design models of beamforming are studied and implemented modified
algorithms of Hybrid Beamforming (HBF) approaches in indoor/outdoor scenarios over large
scale fading wideband mmWave /Raleigh channels. Firstly, three beamforming based diagonalize
the Equivalent Virtual Channel Matrix (EVCM) schemes with the optimal linear combining
methods are presented to overcoming the self-interference problems in Quasi-Orthogonal-Space
Time Block Code (QO-STBC) systems over narrowband mmWave Single-User mMIMO (SU mMIMO). The evaluated results show that the proposed beamforming based- Single Value
Decomposition (SVD) outperforms the conventional beamforming and standard QO-STBC
techniques in terms of BER and spectrum efficiency.
Next, the proposed HBF algorithm approaches with the fully/ partially connected structures are
developed and applied for sum-rate and symbol error rate (SER) performance maximization MU mMIMO-OFDM system, including HBF based on block diagonalization (BD) method Constraint/Unconstraint RF Power, Codebook, Kalman schemes. In addition, the modified near optimal linear HBF-Zero Forcing (HBF-ZF) and HBF-Minimum Mean Square Error (HBF MMSE) schemes, considering both fully-connected and partially-connected structures.
Finally, Simulation results using MATLAB platform, demonstrate that the proposed HBF based codebook and most likely HBF based-unconstraint RF power algorithms achieve significant
performance gains in terms SER and sum-rate efficiency as well as show high immunity against
the deformities and disturbances in the system compared with other HBF algorithm schemes. / Ministry of Higher Education and Scientific Research, the Republic of Iraq
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