Abolfazl Amiri scite author profile

This paper focuses on new communication paradigms arising in massive multiple-input-multiple-output systems where the antenna array at the base station is of extremely large dimension (xMaMIMO). Due to the extreme dimension of the array, xMaMIMO is characterized by spatial non-stationary field properties along the array; this calls for a multi-antenna transceiver design that is adapted to the array dimension but also its non-stationary properties. We address implementation aspects of xMaMIMO, with computational efficiency as our primary objective. To reduce the computational burden of centralized schemes, we distribute the processing into smaller, disjoint subarrays. Then, we consider several low-complexity data detection algorithms as candidates for uplink communication in crowded xMaMIMO systems. Drawing inspiration from coded random access, one of the main contributions of the paper is the design of low complexity scheme that exploits the non-stationary nature of xMaMIMO systems and where the data processing is decentralized. We evaluate the bit-error-rate performance of the transceivers in crowded xMaMIMO scenarios. The results confirm their practical potential.Index Terms-Very large arrays, Massive MIMO, coded random access, non-stationary, 5G

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Optimal unambiguous discrimination of quantum states

Jafarizadeh

Rezaei

Karimi

et al. 2008

Phys. Rev. A

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Antenna Selection for Improving Energy Efficiency in XL-MIMO Systems

Marinello

Abrão

Amiri

et al. 2020

IEEE Trans. Veh. Technol.

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We consider the recently proposed extra-large scale massive multiple-input multiple-output (XL-MIMO) systems, with some hundreds of antennas serving a smaller number of users. Since the array length is of the same order as the distance to the users, the long-term fading coefficients of a given user vary with the different antennas at the base station (BS). Thus, the signal transmitted by some antennas might reach the user with much more power than that transmitted by some others. From a green perspective, it is not effective to simultaneously activate hundreds or even thousands of antennas, since the power-hungry radio frequency (RF) chains of the active antennas increase significantly the total energy consumption. Besides, a larger number of selected antennas increases the power required by linear processing, such as precoding matrix computation, and short-term channel estimation. In this paper, we propose four antenna selection (AS) approaches to be deployed in XL-MIMO systems aiming at maximizing the total energy efficiency (EE). Besides, employing some simplifying assumptions, we derive a closed-form analytical expression for the EE of the XL-MIMO system, and propose a straightforward iterative method to determine the optimal number of selected antennas able to maximize it. The proposed AS schemes are based solely on longterm fading parameters, thus, the selected antennas set remains valid for a relatively large time/frequency intervals. Comparing the results, we find that the genetic-algorithm based AS scheme usually achieves the best EE performance, although our proposed highest normalized received power AS scheme also achieves very promising EE performance in a simple and straightforward way.

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Low-Complexity Distributed XL-MIMO for Multiuser Detection

Rodrigues

Amiri

Abrão

et al. 2020

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Abolfazl Amiri

Non-Stationarities in Extra-Large-Scale Massive MIMO

Extremely Large Aperture Massive MIMO: Low Complexity Receiver Architectures

Optimal unambiguous discrimination of quantum states

Antenna Selection for Improving Energy Efficiency in XL-MIMO Systems

Low-Complexity Distributed XL-MIMO for Multiuser Detection

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