Multi-Step Knowledge-Aided Iterative ESPRIT for Direction Finding

In this work, we propose a subspace-based algorithm for DOA estimation which iteratively reduces the disturbance factors of the estimated data covariance matrix and incorporates prior knowledge which is gradually obtained on line. An analysis of the MSE of the reshaped data covariance matrix is carried out along with comparisons between computational complexities of the proposed and existing algorithms. Simulations focusing on closely-spaced sources, where they are uncorrelated and correlated, illustrate the improvements achieved.Comment: 7 figures. arXiv admin note: text overlap with arXiv:1703.1052

DOA Estimation in the Uplink of Multicarrier CDMA Systems

We consider the uplink of a multicarrier code-division multiple-access (MC-CDMA) network and assume that the base station is endowed with a uniform linear array. Transmission takes place over a multipath channel and the goal is the estimation of the directions of arrival (DOAs) of the signal from the active users. In a multiuser scenario, difficulties are primarily due to the large number of parameters involved in the estimation of the DOAs which makes this problem much more challenging than in single-user transmissions. The solution we propose allows estimating the DOAs of different users independently, thereby leading to a significant reduction in the system complexity. In the presence of multipath propagation, however, estimating the DOAs of a given user through maximum-likelihood methods remains a formidable task since it involves a search over a multidimensional domain. Therefore, we look for simpler solutions and discuss two alternative schemes based on the SAGE and ESPRIT algorithms

Advanced array processing techniques and systems

Research and development on smart antennas, which are recognized as a promising technique to improve the performance of mobile communications, have been extensive in the recent years. Smart antennas combine multiple antenna elements with a signal processing capability in both space and time to optimize its radiation and reception pattern automatically in response to the signal environment. This paper concentrates on the signal processing aspects of smart antenna systems. Smart antennas are often classified as either switched-beam or adaptive-array systems, for which a variety of algorithms have been developed to enhance the signal of interest and reject the interference. The antenna systems need to differentiate the desired signal from the interference, and normally requires either a priori knowledge or the signal direction to achieve its goal. There exists a variety of methods for direction of arrival (DOA) estimation with conflicting demands of accuracy and computation. Similarly, there are many algorithms to compute array weights to direct the maximum radiation of the array pattern toward the signal and place nulls toward the interference, each with its convergence property and computational complexity. This paper discusses some of the typical algorithms for DOA estimation and beamforming. The concept and details of each algorithm are provided. Smart antennas can significantly help in improving the performance of communication systems by increasing channel capacity and spectrum efficiency, extending range coverage, multiplexing channels with spatial division multiple access (SDMA), and compensating electronically for aperture distortion. They also reduce delay spread, multipath fading, co-channel interference, system complexity, bit error rates, and outage probability. In addition, smart antennas can locate mobile units or assist the location determination through DOA and range estimation. This capability can support and benefit many location-based services including emergency assistance, tracking services, safety services, billing services, and information services such as navigation, weather, traffic, and directory assistance

Space time transceiver design over multipath fading channels

Imperial Users onl

Cyclic Prefix-Free MC-CDMA Arrayed MIMO Communication Systems

The objective of this thesis is to investigate MC-CDMA MIMO systems where the antenna array geometry is taken into consideration. In most MC-CDMA systems, cyclic pre xes, which reduce the spectral e¢ ciency, are used. In order to improve the spectral efficiency, this research study is focused on cyclic pre x- free MC-CDMA MIMO architectures. Initially, space-time wireless channel models are developed by considering the spatio-temporal mechanisms of the radio channel, such as multipath propaga- tion. The spatio-temporal channel models are based on the concept of the array manifold vector, which enables the parametric modelling of the channel. The array manifold vector is extended to the multi-carrier space-time array (MC-STAR) manifold matrix which enables the use of spatio-temporal signal processing techniques. Based on the modelling, a new cyclic pre x-free MC- CDMA arrayed MIMO communication system is proposed and its performance is compared with a representative existing system. Furthermore, a MUSIC-type algorithm is then developed for the estimation of the channel parameters of the received signal. This proposed cyclic pre x-free MC-CDMA arrayed MIMO system is then extended to consider the effects of spatial diffusion in the wireless channel. Spatial diffusion is an important channel impairment which is often ignored and the failure to consider such effects leads to less than satisfactory performance. A subspace-based approach is proposed for the estimation of the channel parameters and spatial spread and reception of the desired signal. Finally, the problem of joint optimization of the transmit and receive beam- forming weights in the downlink of a cyclic pre x-free MC-CDMA arrayed MIMO communication system is investigated. A subcarrier-cooperative approach is used for the transmit beamforming so that there is greater flexibility in the allocation of channel symbols. The resulting optimization problem, with a per-antenna transmit power constraint, is solved by the Lagrange multiplier method and an iterative algorithm is proposed

Studies on DOA estimation in the presence of multipath in a frequency hopping system

Master'sMASTER OF ENGINEERIN

Tensor-based tracking schemes for time-delay estimation in GNSS multi-antenna receivers

Trabalho de Conclusão de Curso (graduação)—Universidade de Brasília, Faculdade de Tecnologia, Departamento de Engenharia Elétrica, 2017.Embora os receptores GNSS (Global Navigation Satellite Systems) alcancem atualmente alta precisão ao processar sua localização geográfica sob condições de Linha de Visão (Line of Sight), erros devido a interferência por componentes multipercurso e ruído são as fontes mais degradantes desse sistema. A fim de resolver a interferência multipercurso, receptores baseados em múltiplas antenas tornaram-se o foco de pesquisa e desenvolvimento tecnológico devido ao fato de que podem mitigar a ocorrência de multipercurso fornecendo as melhores estimativas para o atraso do sinal transmitido, que é um parâmetro relevante para determinar a geolocalização do usuário. Neste contexto, abordagens tensoriais baseadas em modelos PARAFAC (PArallel FActor Analysis) têm sido propostas na literatura, proporcionando um ótimo desempenho. Como essas técnicas são baseadas em subespaços, considerando um cenário de rastreamento em tempo real, o cálculo de uma EVD (Eigenvalue Decomposition)/SVD (Singular Value Decomposition) completa para estimativa de subespaço de sinal em cada instante de amostragem não é adequado, devido a razões de complexidade. Portanto, uma alternativa para reduzir o tempo de computação (Time of Computing) de estimativas de subespacos tem sido o desenvolvimento de algoritmos de rastreamento de subespaço. Este trabalho propõe o emprego de dois esquemas de rastreamento de subespaços para fornecer uma redução no desempenho computacional geral das técnicas de estimativa de atraso de tempo baseadas em tensores.Although Global Navigation Satellite Systems (GNSS) receivers nowadays achieve high accuracy when processing their geographic location under conditions of Line of Sight (LOS), errors due to interference by multipath and noise are the most degrading sources of accuracy. In order to solve the multipath interference, receivers based on multiple antennas have become the focus of technological research and development due to the fact they can mitigate multipath occurrence providing best estimates to the transmitted signal time-delay, which is a relevant parameter for determining the user’s geolocation. In this context, tensor-based approaches based on PArallel FActor Analysis (PARAFAC) models have been proposed in the literature, providing optimal performance. As these techniques are subspace-based, considering a real-time tracking scenario, the computation of a full Eigenvalue Decomposition (EVD)/Singular Value Decomposition (SVD) for signal subspace estimation at every sampling instant is not suitable, due to complexity reasons. Therefore, an alternative to reduce the Time of Computing (ToC) of subspace estimations has been the development of subspace tracking algorithms. This work proposes the employment of two subspace tracking schemes to provide a reduction in the overall computational performance of tensor-based time-delay estimation techniques