Your search keyword '"Rubayet Shafin"' showing total 8 results

1. Angle-Based Downlink Beam Selection and User Scheduling for Massive MIMO Systems

Author

Nan Qu, Bingbing Li, Rubayet Shafin, Mingqian Liu, Fengkui Gong, and Lingjia Liu

Subjects

Applied Mathematics, Electrical and Electronic Engineering, Computer Science Applications

Published

2022

2. Interference Alignment Meets Multi-Cell Multi-User Massive FD-MIMO Systems in DoA-Based Precoding

Author

Nan Qu, Lingjia Liu, Mingqian Liu, Rubayet Shafin, Bingbing Li, and Fengkui Gong

Subjects

Computer science, Applied Mathematics, MIMO, Degrees of freedom (mechanics), Interference (wave propagation), Multi-user, Precoding, Computer Science Applications, Power (physics), Telecommunications link, Electronic engineering, Electrical and Electronic Engineering, Interference alignment, Computer Science::Information Theory

Abstract

In this paper, a downlink (DL) precoding scheme is introduced for time-division-duplex (TDD) multi-cell multi-user 3D massive MIMO/full-dimension MIMO (FD-MIMO) systems. A pre-beamformer based on uplink direction-of-arrival (DoA) is incorporated with interference alignment (IA) scheme to provide more degrees of freedom for each cell. We analyze the feasible conditions of applying IA schemes and provide the corresponding precoding schemes for different inter-cell interference scenarios. Simulation results show that the introduced IA-DoA-based multi-cell multi-user precoding and power allocation scheme significantly outperform the existing IA-based precoding strategies for FD-MIMO systems.

Published

2021

3. Scalable Video Transmission in Cache-Aided Device-to-Device Networks

Author

Bodong Shang, Rubayet Shafin, Hao Song, Lingjia Liu, Junchao Ma, and Pingzhi Fan

Subjects

business.industry, Computer science, Applied Mathematics, Real-time computing, 020206 networking & telecommunications, 02 engineering and technology, Scalable Video Coding, Computer Science Applications, Transmission (telecommunications), Scalability, 0202 electrical engineering, electronic engineering, information engineering, Benchmark (computing), Wireless, Cache, Quality of experience, Electrical and Electronic Engineering, business

Abstract

Scalable video coding (SVC) and video caching are two promising techniques in the 5th generation networks to improve the users’ quality of experience (QoE) in terms of video retrieval. In this paper, we study the video content retrieval in cache-aided device-to-device (D2D) networks, where each video content is coded into multiple layers via SVC. In video caching placement phase, the probabilistic caching placement policy is applied, while in content retrieval phase, the non-orthogonal transmission scheme is utilized. Besides, different D2D transmitter selection algorithms are considered and cache-aided data rate (CADR) is formulated as a metric in this paper, and it is maximized by jointly optimizing the probability caching policy and the power allocation policy in two phases. Analytical results show that probabilistic caching policy incorporated with power domain non-orthogonal transmission scheme can achieve significant benefits compared with other benchmark schemes.

Published

2020

4. Self-Tuning Sectorization: Deep Reinforcement Learning Meets Broadcast Beam Optimization

Author

Jeong-Ho Park, Jianzhong Zhang, Sooyoung Hur, Rubayet Shafin, Jeffrey H. Reed, Lingjia Liu, Hao Chen, and Young-Han Nam

Subjects

Beamforming, Markov chain, Computer science, business.industry, Applied Mathematics, Distributed computing, MIMO, 020206 networking & telecommunications, 02 engineering and technology, Broadcasting, Computer Science Applications, 0202 electrical engineering, electronic engineering, information engineering, Cellular network, Key (cryptography), Reinforcement learning, Wireless, Electrical and Electronic Engineering, business, Computer Science::Information Theory

Abstract

Beamforming in multiple input multiple output (MIMO) systems is one of the key technologies for modern wireless communication. Creating appropriate sector-specific broadcast beams are essential for enhancing the coverage of cellular network and for improving the broadcast operation for control signals. However, in order to maximize the coverage, patterns for broadcast beams need to be adapted based on the users’ distribution and movement over time. In this work, we present self-tuning sectorization: a deep reinforcement learning framework to optimize MIMO broadcast beams autonomously and dynamically based on users’ distribution in the network. Taking directly UE measurement results as input, deep reinforcement learning agent can track and predict the UE distribution pattern and come up with the best broadcast beams for each cell. Extensive simulation results show that the introduced framework can achieve the optimal coverage, and converge to the oracle solution for both single sector and multiple sectors environment, and for both periodic and Markov mobility patterns.

Published

2020

5. Superimposed Pilot for Multi-Cell Multi-User Massive FD-MIMO Systems

Author

Lingjia Liu and Rubayet Shafin

Subjects

Computer science, business.industry, Applied Mathematics, MIMO, Duplex (telecommunications), 020206 networking & telecommunications, 02 engineering and technology, Multi-user, Computer Science Applications, Channel state information, Telecommunications link, 0202 electrical engineering, electronic engineering, information engineering, Network performance, Electrical and Electronic Engineering, business, Computer hardware, Computer Science::Information Theory, Communication channel, Mimo systems

Abstract

In this paper, superimposed pilot based communication strategies are investigated for a time-division duplex (TDD)-based massive Full-Dimension MIMO (FD-MIMO) network jointly considering both uplink (UL) and downlink (DL) performance. To be specific, the DL multi-cell multi-user MIMO operation is connected to UL channel estimation through the superimposed pilot. The performance of UL channel estimation is analytically characterized and the estimated UL channel is linked to the DL MIMO operation for the massive MIMO network. In this way, the corresponding feedback for DL channel state information (CSI) can be eliminated while the UL pilot overhead can be minimized. Results suggest that superimposed pilot could significantly improve the overall network performance of a massive FD-MIMO network.

Published

2020

6. Multi-Cell Multi-User Massive FD-MIMO: Downlink Precoding and Throughput Analysis

Author

Lingjia Liu and Rubayet Shafin

Subjects

FOS: Computer and information sciences, Computer science, Information Theory (cs.IT), Computer Science - Information Theory, Applied Mathematics, MIMO, Direction of arrival, 020206 networking & telecommunications, Throughput, 02 engineering and technology, Multi-user, Precoding, Computer Science Applications, Power (physics), Telecommunications link, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Algorithm, Computer Science::Information Theory

Abstract

In this paper, downlink (DL) precoding and power allocation strategies are identified for a time-division-duplex (TDD) multi-cell multi-user massive Full-Dimension MIMO (FD-MIMO) network. Utilizing channel reciprocity, DL channel state information (CSI) feedback is eliminated and the DL multi-user MIMO precoding is linked to the uplink (UL) direction of arrival (DoA) estimation through estimation of signal parameters via rotational invariance technique (ESPRIT). Assuming non-orthogonal/non-ideal spreading sequences of the UL pilots, the performance of the UL DoA estimation is analytically characterized and the characterized DoA estimation error is incorporated into the corresponding DL precoding and power allocation strategy. Simulation results verify the accuracy of our analytical characterization of the DoA estimation and demonstrate that the introduced multi-user MIMO precoding and power allocation strategy outperforms existing zero-forcing based massive MIMO strategies., 32 pages, 8 figures, submitted to IEEE Transactions on Wireless Communications

Published

2019

7. Angle and Delay Estimation for 3-D Massive MIMO/FD-MIMO Systems Based on Parametric Channel Modeling

Author

Jianzhong Zhang, Anding Wang, Lingjia Liu, Rubayet Shafin, and Yan Li

Subjects

3G MIMO, Computer science, Estimation theory, Applied Mathematics, 05 social sciences, MIMO, 050801 communication & media studies, 020206 networking & telecommunications, 02 engineering and technology, Multi-user MIMO, Computer Science Applications, Antenna array, Base station, 0508 media and communications, Control theory, Telecommunications link, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Algorithm, Computer Science::Information Theory, Communication channel

Abstract

In order to meet the challenge of increasing data-rate demand as well as the form factor limitation of the base station (BS), 3-D massive multiple-input multiple-output (MIMO) technology has been introduced as one of the enabling technologies for fifth generation mobile cellular systems. In 3-D massive MIMO systems, a BS will rely on the uplink sounding signals from mobile stations to figure out the spatial information for downlink MIMO operations. Accordingly, multi-dimensional parameter estimation of a MIMO channel becomes crucial for such systems to realize the predicted capacity gains. In this paper, we study the angle and delay estimation for 3-D massive MIMO systems under a parametric channel modeling. To be specific, we first introduce separate low complexity time delay and angle estimation algorithms based on unitary transformation, and analytically characterize the mean squared errors (MSEs) of these estimations for massive MIMO systems. Then, a matrix-based estimation of signal parameters via rotational invariance technique algorithm is applied to jointly estimate the delay and the angles where the MSEs are also analytically characterized. Our results show that the antenna array configuration at the BS plays a critical role in determining the underlying channel estimation performance. Simulation results suggest that the characterized MSEs match well with the simulated ones.

Published

2017

8. DoA Estimation and Capacity Analysis for 3-D Millimeter Wave Massive-MIMO/FD-MIMO OFDM Systems

Author

Jianzhong Zhang, Lingjia Liu, Rubayet Shafin, and Yik-Chung Wu

Subjects

Minimum mean square error, Mean squared error, Orthogonal frequency-division multiplexing, Computer science, Applied Mathematics, MIMO, Direction of arrival, 020206 networking & telecommunications, 020302 automobile design & engineering, Throughput, Data_CODINGANDINFORMATIONTHEORY, 02 engineering and technology, Spectral efficiency, MIMO-OFDM, Interference (wave propagation), Computer Science Applications, 0203 mechanical engineering, Channel state information, Statistics, Telecommunications link, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Algorithm, Computer Science::Information Theory, Communication channel

Abstract

With the promise of meeting future capacity demands, 3-D massive-MIMO/full dimension multiple-input-multiple-output (FD-MIMO) systems have gained much interest in recent years. Apart from the huge spectral efficiency gain, 3-D massive-MIMO/FD-MIMO systems can also lead to significant reduction of latency, simplified multiple access layer, and robustness to interference. However, in order to completely extract the benefits of the system, accurate channel state information is critical. In this paper, a channel estimation method based on direction of arrival (DoA) estimation is presented for 3-D millimeter wave massive-MIMO orthogonal frequency division multiplexing (OFDM) systems. To be specific, the DoA is estimated using estimation of signal parameter via rotational invariance technique method, and the root mean square error of the DoA estimation is analytically characterized for the corresponding MIMO-OFDM system. An ergodic capacity analysis of the system in the presence of DoA estimation error is also conducted, and an optimum power allocation algorithm is derived. Furthermore, it is shown that the DoA-based channel estimation achieves a better performance than the traditional linear minimum mean squared error estimation in terms of ergodic throughput and minimum chordal distance between the subspaces of the downlink precoders obtained from the underlying channel and the estimated channel.

Published

2016