11,984 research outputs found
Real-Time Dispersion Code Multiple Access (DCMA) for High-Speed Wireless Communications
We model, demonstrate and characterize Dispersion Code Multiple Access (DCMA)
and hence show the applicability of this purely analog and real-time multiple
access scheme to high-speed wireless communications. We first mathematically
describe DCMA and show the appropriateness of Chebyshev dispersion coding in
this technology. We next provide an experimental proof-of-concept in a 2 X 2
DCMA system. Finally,we statistically characterize DCMA in terms of bandwidth,
dispersive group delay swing, system dimension and signal-to-noise ratio
Time-Reversal Routing for Dispersion Code Multiple Access (DCMA) Communications
We present the modeling and characterization of a time-reversal routing
dispersion code multiple access (TR-DCMA) system. We show that this system
maintains the low complexity advantage of DCMA transceivers while offering
dynamic adaptivity for practial communication scenarios. We first derive the
mathematical model and explain operation principles of the system, and then
characterize its interference, signal to interference ratio, and bit error
probability characteristics
A universal space-time architecture for multiple-antenna aided systems
In this tutorial, we first review the family of conventional multiple-antenna techniques, and then we provide a general overview of the recent concept of the powerful Multiple-Input Multiple-Output (MIMO) family based on a universal Space-Time Shift Keying (STSK) philosophy. When appropriately configured, the proposed STSK scheme has the potential of outperforming conventional MIMO arrangements
Temporal and spatial combining for 5G mmWave small cells
This chapter proposes the combination of temporal processing through Rake combining based on direct sequence-spread spectrum (DS-SS), and multiple antenna beamforming or antenna spatial diversity as a possible physical layer access technique for fifth generation (5G) small cell base stations (SBS) operating in the millimetre wave (mmWave) frequencies. Unlike earlier works in the literature aimed at previous generation wireless, the use of the beamforming is presented as operating in the radio frequency (RF) domain, rather than the baseband domain, to minimise power expenditure as a more suitable method for 5G small cells. Some potential limitations associated with massive multiple input-multiple output (MIMO) for small cells are discussed relating to the likely limitation on available antennas and resultant beamwidth. Rather than relying, solely, on expensive and potentially power hungry massive MIMO (which in the case of a SBS for indoor use will be limited by a physically small form factor) the use of a limited number of antennas, complimented with Rake combining, or antenna diversity is given consideration for short distance indoor communications for both the SBS) and user equipment (UE). The proposal’s aim is twofold: to solve eroded path loss due to the effective antenna aperture reduction and to satisfy sensitivity to blockages and multipath dispersion in indoor, small coverage area base stations. Two candidate architectures are proposed. With higher data rates, more rigorous analysis of circuit power and its effect on energy efficiency (EE) is provided. A detailed investigation is provided into the likely design and signal processing requirements. Finally, the proposed architectures are compared to current fourth generation long term evolution (LTE) MIMO technologies for their anticipated power consumption and EE
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