Beam division multiple access transmission for massive MIMO communications

We study multicarrier multiuser multiple-input multiple-output (MU-MIMO) systems, in which the base station employs an asymptotically large number of antennas. We analyze a fully correlated channel matrix and provide a beam domain channel model, where the channel gains are independent of sub-carriers. For this model, we first derive a closed-form upper bound on the achievable ergodic sum-rate, based on which, we develop asymptotically necessary and sufficient conditions for optimal downlink transmission that require only statistical channel state information at the transmitter. Furthermore, we propose a beam division multiple access (BDMA) transmission scheme that simultaneously serves multiple users via different beams. By selecting users within non-overlapping beams, the MU-MIMO channels can be equivalently decomposed into multiple single-user MIMO channels; this scheme significantly reduces the overhead of channel estimation, as well as, the processing complexity at transceivers. For BDMA transmission, we work out an optimal pilot design criterion to minimize the mean square error (MSE) and provide optimal pilot sequences by utilizing the Zadoff-Chu sequences. Simulations demonstrate the near-optimal performance of BDMA transmission and the advantages of the proposed pilot sequences.

FPGA-based Tabu Search for Detection in Large-Scale MIMO Systems

The increasing scale of Multiple-Input Multiple- Output (MIMO) topologies employed in forthcoming wireless communications standards presents a substantial implementation challenge to designers of embedded baseband signal processing architectures for MIMO transceivers. Specifically the increased scale of such systems has a substantial impact on the perfor- mance/cost balance of detection algorithms for these systems. Whilst in small-scale systems Sphere Decoding (SD) algorithms offer the best quasi-ML performance/cost balance, in larger systems heuristic detectors, such Tabu-Search (TS) detectors are superior. This paper addresses a dearth of research in architectures for TS-based MIMO detection, presenting the first known realisations of TS detectors for 4 × 4 and 10 × 10 MIMO systems. To the best of the authors’ knowledge, these are the largest single-chip detectors on record.

Channel modelling for MIMO systems

Systems equipped with multiple antennas at the transmitter and at the receiver, known as MIMO (Multiple Input Multiple Output) systems, offer higher capacities, allowing an efficient exploitation of the available spectrum and/or the employment of more demanding applications. It is well known that the radio channel is characterized by multipath propagation, a phenomenon deemed problematic and whose mitigation has been achieved through techniques such as diversity, beamforming or adaptive antennas. By exploring conveniently the spatial domain MIMO systems turn the characteristics of the multipath channel into an advantage and allow creating multiple parallel and independent virtual channels. However, the achievable benefits are constrained by the propagation channel’s characteristics, which may not always be ideal. This work focuses on the characterization of the MIMO radio channel. It begins with the presentation of the fundamental results from information theory that triggered the interest on these systems, including the discussion of some of their potential benefits and a review of the existing channel models for MIMO systems. The characterization of the MIMO channel developed in this work is based on experimental measurements of the double-directional channel. The measurement system is based on a vector network analyzer and a two-dimensional positioning platform, both controlled by a computer, allowing the measurement of the channel’s frequency response at the locations of a synthetic array. Data is then processed using the SAGE (Space-Alternating Expectation-Maximization) algorithm to obtain the parameters (delay, direction of arrival and complex amplitude) of the channel’s most relevant multipath components. Afterwards, using a clustering algorithm these data are grouped into clusters. Finally, statistical information is extracted allowing the characterization of the channel’s multipath components. The information about the multipath characteristics of the channel, induced by existing scatterers in the propagation scenario, enables the characterization of MIMO channel and thus to evaluate its performance. The method was finally validated using MIMO measurements.

Sistemas de antenas MIMO

Os sistemas de rádio comunicação com múltiplas antenas transmissoras (Tx) e receptoras (Rx), também conhecidos como sistemas MIMO (Multiple Input-Multiple Output), são um dos mais importantes avanços nos sistemas de telecomunicações. Estes sistemas tiram vantagem do uso de várias antenas transmissoras e várias antenas receptoras para explorar as propriedades espaciais do canal rádio. O crescimento dramático da capacidade dos canais que os sistemas MIMO vêm acrescentar, faz com que esta tecnologia seja promissora para os futuros serviços de Internet Wireless. Estes sistemas MIMO utilizam diversidade espacial, ou seja, tiram partido da natureza aleatória da propagação das ondas através do multipercurso e na qual réplicas de um sinal são combinadas no receptor com o intuito de se obter maior fiabilidade na detecção desse sinal. Assim sendo, um canal MIMO é o meio por onde se propaga a informação transmitida por este conjunto de antenas. O conceito inerente aos sistemas MIMO passa por combinar os sinais emitidos e recebidos de modo que seja possível melhorar a performance do sistema. Esta melhoria de desempenho irá reflectir-se na maximização dos ritmos de transmissão associados e na melhoria da qualidade de serviço oferecida ao cliente final. Esta tecnologia tem sido aprofundada com o objectivo de se resolver o problema de estrangulamento da capacidade de tráfego nas futuras redes de telecomunicações sem fios. Isto é extremamente importante em sistemas onde a capacidade é bastante limitada devido às características do ambiente de propagação. Existe portanto, um grande interesse em comparar o comportamento, características, vantagens e desvantagens dos vários tipos de sistemas existentes (SISO - Single Input - Single Output, SIMO - Single Input - Multiple Output, MISO - Multiple Input - Single Output, MIMO - Multiple Input - Multiple Output). Torna-se então necessário o estudo dos sistemas de antenas Multiple Input - Multiple Output (MIMO) e as suas vantagens/desvantagens na transmissão de informação relativamente aos sistemas Single Input - Single Output (SISO). Este estudo vem comprovar que a tecnologia MIMO é uma evolução natural para as tecnologias sem fios, visto que existe uma crescente demanda de serviços multimédia e um esforço constante para se aumentar as taxas de transmissão nas redes sem fios. Os sistemas MIMO vêm também dar um enorme contributo à investigação nesta área das telecomunicações.

Compensation of undesired effects in MIMO wireless transceivers

This paper presents compensation of all undesired effects (Power Amplifier (PA) nonlinearity, transmitter and receiver antenna crosstalk, before-PA nonlinear crosstalk, Multiple Input Multiple Output (MIMO) channel fading and crosstalk) in MIMO Orthogonal Frequency Division Multiplex (OFDM) wireless systems. It has been demonstrated that reduced-complexity Crossover Digital Predistortion (CO-DPD) algorithm on transmitter side and Matrix Inversion algorithm on receiver side can suppress almost all undesired effects introduced by transmitter, channel and receiver in 4×4 MIMO OFDM System that can be used in modern wireless system applications. A significant complexity reduction is achieved due to the fact that Digital Signal Processing (DSP) during CO-DPD process on transmitter side is done with real instead of complex numbers.

Evaluation of nonlinear distortion in MIMO transmitters

In this paper, an evaluation of unwanted effects in Multiple Input Multiple Output (MIMO) transmitters is described. Complete 2×2 and 4×4 MIMO Orthogonal Frequency Division Multiplex (OFDM) transmitters are simulated for the purpose of quantifying all potential unwanted effects such as Power Amplifiers' (PAs) nonlinearity, linear and nonlinear crosstalk, and IQ modulator imperfections. An experimental analysis of a 2×2 MIMO transmitter using two-tones and WCDMA signal is presented.