Your search keyword '"eess.SP"' showing total 12 results

1. Linear and Deep Neural Network-Based Receivers for Massive MIMO Systems With One-Bit ADCs

Author

Nguyen, Ly V, Swindlehurst, A Lee, and Nguyen, Duy HN

Subjects

Affordable and Clean Energy, Receivers, Massive MIMO, Wireless communication, Radio frequency, Search methods, Computational complexity, Support vector machines, one-bit ADCs, linear receivers, deep neural networks, machine learning, data detection, eess.SP, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies, Networking & Telecommunications

Abstract

The use of one-bit analog-to-digital converters (ADCs) is a practical solution for reducing cost and power consumption in massive Multiple-Input-Multiple-Output (MIMO) systems. However, the distortion caused by one-bit ADCs makes the data detection task much more challenging. In this paper, we propose a two-stage detection method for massive MIMO systems with one-bit ADCs. In the first stage, we present several linear receivers based on the Bussgang decomposition that show significant performance gains over conventional linear receivers. Next, we reformulate the maximum-likelihood (ML) detection problem to address its non-robustness. Based on the reformulated ML detection problem, we propose a model-driven deep neural network-based detector, namely OBMNet, whose performance is comparable with an existing support vector machine-based receiver, albeit with a much lower computational complexity. A nearest-neighbor search method is then proposed for the second stage to refine the first stage solution. Unlike existing search methods that typically perform the search over a large candidate set, the proposed search method generates a limited number of most likely candidates and thus limits the search complexity. Numerical results confirm the low complexity, efficiency, and robustness of the proposed two-stage detection method.

Published

2021

2. UAV-Assisted Intelligent Reflecting Surface Symbiotic Radio System

Author

Hua, Meng, Yang, Luxi, Wu, Qingqing, Pan, Cunhua, Li, Chunguo, and Swindlehurst, A Lee

Subjects

Unmanned aerial vehicles, Optimization, Bit error rate, Symbiosis, Array signal processing, Trajectory, Signal to noise ratio, Intelligent reflecting surface, unmanned aerial vehicle, phase shift optimization, UAV trajectory optimization, eess.SP, cs.IT, math.IT, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies, Networking & Telecommunications

Abstract

This paper investigates a symbiotic unmanned aerial vehicle (UAV)-assisted intelligent reflecting surface (IRS) radio system, where the UAV is leveraged to help the IRS reflect its own signals to the base station, and meanwhile enhance the UAV transmission by passive beamforming at the IRS. First, we consider the weighted sum bit error rate (BER) minimization problem among all IRSs by jointly optimizing the UAV trajectory, IRS phase shift matrix, and IRS scheduling, subject to the minimum primary rate requirements. To tackle this complicated problem, a relaxation-based algorithm is proposed. We prove that the converged relaxation scheduling variables are binary, which means that no reconstruct strategy is needed, and thus the UAV rate constraints are automatically satisfied. Second, we consider the fairness BER optimization problem. We find that the relaxation-based method cannot solve this fairness BER problem since the minimum primary rate requirements may not be satisfied by the binary reconstruction operation. To address this issue, we first transform the binary constraints into a series of equivalent equality constraints. Then, a penalty-based algorithm is proposed to obtain a suboptimal solution. Numerical results are provided to evaluate the performance of the proposed designs under different setups, as compared with benchmarks.

Published

2021

3. Joint Symbol-Level Precoding and Reflecting Designs for IRS-Enhanced MU-MISO Systems

Author

Liu, Rang, Li, Ming, Liu, Qian, and Swindlehurst, A Lee

Subjects

Affordable and Clean Energy, Precoding, Wireless communication, Quality of service, Interference, Phase shift keying, Minimization, Intelligent reflecting surface, symbol-level precoding, multiuser multiple-input single-output (MU-MISO) systems, manifold optimization, eess.SP, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies, Networking & Telecommunications

Abstract

Intelligent reflecting surfaces (IRSs) have emerged as a revolutionary solution to enhance wireless communications by changing propagation environment in a cost-effective and hardware-efficient fashion. In addition, symbol-level precoding (SLP) has attracted considerable attention recently due to its advantages in converting multiuser interference (MUI) into useful signal energy. Therefore, it is of interest to investigate the employment of IRS in symbol-level precoding systems to exploit MUI in a more effective way by manipulating the multiuser channels. In this article, we focus on joint symbol-level precoding and reflecting designs in IRS-enhanced multiuser multiple-input single-output (MU-MISO) systems. Both power minimization and quality-of-service (QoS) balancing problems are considered. In order to solve the joint optimization problems, we develop an efficient iterative algorithm to decompose them into separate symbol-level precoding and block-level reflecting design problems. An efficient gradient-projection-based algorithm is utilized to design the symbol-level precoding and a Riemannian conjugate gradient (RCG)-based algorithm is employed to solve the reflecting design problem. Simulation results demonstrate the significant performance improvement introduced by the IRS and illustrate the effectiveness of our proposed algorithms.

Published

2021

4. Joint Symbol-Level Precoding and Reflecting Designs for IRS-Enhanced MU-MISO Systems

Author

Liu, R, Li, M, Liu, Q, and Swindlehurst, AL

Subjects

Precoding, Wireless communication, Quality of service, Interference, Phase shift keying, Minimization, Intelligent reflecting surface, symbol-level precoding, multiuser multiple-input single-output (MU-MISO) systems, manifold optimization, eess.SP, Networking & Telecommunications, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies

Abstract

Intelligent reflecting surfaces (IRSs) have emerged as a revolutionary solution to enhance wireless communications by changing propagation environment in a cost-effective and hardware-efficient fashion. In addition, symbol-level precoding (SLP) has attracted considerable attention recently due to its advantages in converting multiuser interference (MUI) into useful signal energy. Therefore, it is of interest to investigate the employment of IRS in symbol-level precoding systems to exploit MUI in a more effective way by manipulating the multiuser channels. In this article, we focus on joint symbol-level precoding and reflecting designs in IRS-enhanced multiuser multiple-input single-output (MU-MISO) systems. Both power minimization and quality-of-service (QoS) balancing problems are considered. In order to solve the joint optimization problems, we develop an efficient iterative algorithm to decompose them into separate symbol-level precoding and block-level reflecting design problems. An efficient gradient-projection-based algorithm is utilized to design the symbol-level precoding and a Riemannian conjugate gradient (RCG)-based algorithm is employed to solve the reflecting design problem. Simulation results demonstrate the significant performance improvement introduced by the IRS and illustrate the effectiveness of our proposed algorithms.

Published

2021

5. Supervised and Semi-Supervised Learning for MIMO Blind Detection With Low-Resolution ADCs

Author

Nguyen, Ly V, Ngo, Duy Trong, Tran, Nghi H, Swindlehurst, A Lee, and Nguyen, Duy HN

Subjects

MIMO, low-resolution ADCs, blind detection, non-coherent detection, learning techniques, eess.SP, cs.IT, math.IT, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies, Networking & Telecommunications

Abstract

The use of low-resolution analog-to-digital converters (ADCs) is considered to be an effective technique to reduce the power consumption and hardware complexity of wireless transceivers. However, in systems with low-resolution ADCs, obtaining channel state information (CSI) is difficult due to significant distortions in the received signals. The primary motivation of this paper is to show that learning techniques can mitigate the impact of CSI unavailability. We study the blind detection problem in multiple-input-multiple-output (MIMO) systems with low-resolution ADCs using learning approaches. Two methods, which employ a sequence of pilot symbol vectors as the initial training data, are proposed. The first method exploits the use of a cyclic redundancy check (CRC) to obtain more training data, which helps improve the detection accuracy. The second method is based on the perspective that the to-be-decoded data can itself assist the learning process, so no further training information is required except the pilot sequence. For the case of 1-bit ADCs, we provide a performance analysis of the vector error rate for the proposed methods. Based on the analytical results, a criterion for designing transmitted signals is also presented. Simulation results show that the proposed methods outperform existing techniques and are also more robust.

Published

2020

6. Supervised and Semi-Supervised Learning for MIMO Blind Detection with Low-Resolution ADCs

Author

Nguyen, LV, Ngo, DT, Tran, NH, Swindlehurst, AL, and Nguyen, DHN

Subjects

MIMO, low-resolution ADCs, blind detection, non-coherent detection, learning techniques, eess.SP, cs.IT, math.IT, Networking & Telecommunications, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies

Abstract

The use of low-resolution analog-to-digital converters (ADCs) is considered to be an effective technique to reduce the power consumption and hardware complexity of wireless transceivers. However, in systems with low-resolution ADCs, obtaining channel state information (CSI) is difficult due to significant distortions in the received signals. The primary motivation of this paper is to show that learning techniques can mitigate the impact of CSI unavailability. We study the blind detection problem in multiple-input-multiple-output (MIMO) systems with low-resolution ADCs using learning approaches. Two methods, which employ a sequence of pilot symbol vectors as the initial training data, are proposed. The first method exploits the use of a cyclic redundancy check (CRC) to obtain more training data, which helps improve the detection accuracy. The second method is based on the perspective that the to-be-decoded data can itself assist the learning process, so no further training information is required except the pilot sequence. For the case of 1-bit ADCs, we provide a performance analysis of the vector error rate for the proposed methods. Based on the analytical results, a criterion for designing transmitted signals is also presented. Simulation results show that the proposed methods outperform existing techniques and are also more robust.

Published

2020

7. mmWave Amplify-and-Forward MIMO Relay Networks With Hybrid Precoding/Combining Design

Author

Jiang, Lisi and Jafarkhani, Hamid

Subjects

mmWave, MIMO, amplify-and-forward, relay, hybrid beamforming, robust, cs.IT, eess.SP, math.IT, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies, Networking & Telecommunications

Abstract

In this paper, we consider the amplify-and-forward relay networks in mmWave systems and propose a hybrid precoder/combiner design approach. The phase-only RF precoding/combining matrices are first designed to support multi-stream transmission, where we compensate the phase for the eigenmodes of the channel. Then, the baseband precoders/combiners are performed to achieve the maximum mutual information. Based on the data processing inequality for the mutual information, we first jointly design the baseband source and relay nodes to maximize the mutual information before the destination baseband receiver. The proposed low-complexity iterative algorithm for the source and relay nodes is based on the equivalence between the mutual information maximization and the weighted MMSE. After we obtain the optimal precoder and combiner for the source and relay nodes, we implement the MMSE-SIC filter at the baseband receiver to keep the mutual information unchanged, thus obtaining the optimal mutual information for the whole relay system. Simulation results show that our algorithm achieves better performance with lower complexity compared with other algorithms in the literature. In addition, we also propose a robust joint transceiver design for imperfect channel state information.

Published

2020

8. MmWave Amplify-and-Forward MIMO Relay Networks with Hybrid Precoding/Combining Design

Author

Jiang, L and Jafarkhani, H

Subjects

mmWave, MIMO, amplify-and-forward, relay, hybrid beamforming, robust, cs.IT, eess.SP, math.IT, Networking & Telecommunications, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies

Abstract

In this paper, we consider the amplify-and-forward relay networks in mmWave systems and propose a hybrid precoder/combiner design approach. The phase-only RF precoding/combining matrices are first designed to support multi-stream transmission, where we compensate the phase for the eigenmodes of the channel. Then, the baseband precoders/combiners are performed to achieve the maximum mutual information. Based on the data processing inequality for the mutual information, we first jointly design the baseband source and relay nodes to maximize the mutual information before the destination baseband receiver. The proposed low-complexity iterative algorithm for the source and relay nodes is based on the equivalence between the mutual information maximization and the weighted MMSE. After we obtain the optimal precoder and combiner for the source and relay nodes, we implement the MMSE-SIC filter at the baseband receiver to keep the mutual information unchanged, thus obtaining the optimal mutual information for the whole relay system. Simulation results show that our algorithm achieves better performance with lower complexity compared with other algorithms in the literature. In addition, we also propose a robust joint transceiver design for imperfect channel state information.

Published

2020

9. Massive MIMO 1-Bit DAC Transmission: A Low-Complexity Symbol Scaling Approach

Author

Li, Ang, Masouros, Christos, Liu, Fan, and Swindlehurst, A Lee

Subjects

Affordable and Clean Energy, Massive MIMO, 1-bit quantization, beamforming, constructive interference, Lagrangian, low-complexity scheme, eess.SP, cs.IT, math.IT, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies, Networking & Telecommunications

Abstract

We study multi-user massive multiple-input single-output systems and focus on downlink transmission for PSK modulation, where the base station employs a large antenna array with low-cost 1-bit digital-to-analog converters (DACs). The direct combination of existing beamforming schemes with 1-bit DACs is shown to lead to an error floor at medium-to-high SNR regime, due to the coarse quantization of the DACs with limited precision. In this paper, based on the constructive interference, we consider both a quantized linear beamforming scheme where we analytically obtain the optimal beamforming matrix and a non-linear mapping scheme where we directly design the transmit signal vector. Due to the 1-bit quantization, the formulated optimization for the non-linear mapping scheme is shown to be non-convex. The non-convex constraints of the 1-bit DACs are first relaxed into convex, followed by an element-wise normalization to satisfy the 1-bit DAC transmission. We further propose a low-complexity symbol scaling scheme that consists of three stages, in which the quantized transmit signal on each antenna element is selected sequentially. Numerical results show that the proposed symbol scaling scheme achieves a comparable performance to the optimization-based non-linear mapping approach, while the corresponding performance-complexity tradeoff is more favorable for the proposed symbol scaling method.

Published

2018

10. Massive MIMO 1-Bit DAC Transmission: A low-complexity symbol scaling approach

Author

Li, A, Masouros, C, Liu, F, and Swindlehurst, AL

Subjects

Massive MIMO, 1-bit quantization, beamforming, constructive interference, Lagrangian, low-complexity scheme, eess.SP, cs.IT, math.IT, Networking & Telecommunications, Electrical and Electronic Engineering, Communications Technologies, Distributed Computing

Abstract

We study multi-user massive multiple-input single-output systems and focus on downlink transmission for PSK modulation, where the base station employs a large antenna array with low-cost 1-bit digital-to-analog converters (DACs). The direct combination of existing beamforming schemes with 1-bit DACs is shown to lead to an error floor at medium-to-high SNR regime, due to the coarse quantization of the DACs with limited precision. In this paper, based on the constructive interference, we consider both a quantized linear beamforming scheme where we analytically obtain the optimal beamforming matrix and a non-linear mapping scheme where we directly design the transmit signal vector. Due to the 1-bit quantization, the formulated optimization for the non-linear mapping scheme is shown to be non-convex. The non-convex constraints of the 1-bit DACs are first relaxed into convex, followed by an element-wise normalization to satisfy the 1-bit DAC transmission. We further propose a low-complexity symbol scaling scheme that consists of three stages, in which the quantized transmit signal on each antenna element is selected sequentially. Numerical results show that the proposed symbol scaling scheme achieves a comparable performance to the optimization-based non-linear mapping approach, while the corresponding performance-complexity tradeoff is more favorable for the proposed symbol scaling method.

Published

2018

11. Interleaving Channel Estimation and Limited Feedback for Point-to-Point Systems With a Large Number of Transmit Antennas

Author

Koyuncu, Erdem, Zou, Xun, and Jafarkhani, Hamid

Subjects

Theory Of Computation, Information and Computing Sciences, Communications Engineering, Engineering, Interleaving, limited feedback, training, beam-forming, partial CSIT and CSIR, cs.IT, eess.SP, math.IT, Distributed Computing, Electrical and Electronic Engineering, Communications Technologies, Networking & Telecommunications, Communications engineering, Electrical engineering, Distributed computing and systems software

Abstract

We introduce and investigate the opportunities of multi-antenna communication schemes whose training and feedback stages are interleaved and mutually interacting. Specifically, unlike the traditional schemes, where the transmitter first trains all of its antennas at once and then receives a single feedback message, we consider a scenario, where the transmitter instead trains its antennas one by one and receives feedback information immediately after training each one of its antennas. The feedback message may ask the transmitter to train another antenna; or, it may terminate the feedback/training phase and provide the quantized codeword (e.g., a beamforming vector) to be utilized for data transmission. As a specific application, we consider a multiple-input single-output system with t transmit antennas, a short-term power constraint P , and target data rate p. We show that for any t , the same outage probability as a system with perfect transmitter and receiver channel state information can be achieved with a feedback rate of R1 bits per channel state and via training R2 transmit antennas on average, where R1 and R2 are independent of t, and depend only on p and P. In addition, we design variable-rate quantizers for channel coefficients to further minimize the feedback rate of our scheme.

Published

2018

12. Interleaving channel estimation and limited feedback for point-to-point systems with a large number of transmit antennas

Author

Koyuncu, E, Zou, X, and Jafarkhani, H

Subjects

Interleaving, limited feedback, training, beam-forming, partial CSIT and CSIR, cs.IT, eess.SP, math.IT, Electrical and Electronic Engineering, Communications Technologies, Distributed Computing, Networking & Telecommunications

Abstract

We introduce and investigate the opportunities of multi-antenna communication schemes whose training and feedback stages are interleaved and mutually interacting. Specifically, unlike the traditional schemes, where the transmitter first trains all of its antennas at once and then receives a single feedback message, we consider a scenario, where the transmitter instead trains its antennas one by one and receives feedback information immediately after training each one of its antennas. The feedback message may ask the transmitter to train another antenna; or, it may terminate the feedback/training phase and provide the quantized codeword (e.g., a beamforming vector) to be utilized for data transmission. As a specific application, we consider a multiple-input single-output system with t transmit antennas, a short-term power constraint P , and target data rate p. We show that for any t , the same outage probability as a system with perfect transmitter and receiver channel state information can be achieved with a feedback rate of R1 bits per channel state and via training R2 transmit antennas on average, where R1 and R2 are independent of t, and depend only on p and P. In addition, we design variable-rate quantizers for channel coefficients to further minimize the feedback rate of our scheme.

Published

2018