Your search keyword '"Shim, Byonghyo"' showing total 9 results

1. Energy-Efficient Millimeter-Wave Cell-Free Systems Under Limited Feedback.

Author

Kim, Seungnyun and Shim, Byonghyo

Subjects

*PSYCHOLOGICAL feedback, *ENERGY consumption, *CONSUMPTION (Economics), *ALGORITHMS

Abstract

MmWave cell-free systems where multiple base stations (BSs) cooperatively serve user using the mmWave band signal have gained much attention recently due to its capability to dramatically improve the system capacity. One potential drawback of mmWave cell-free systems is that an intensive deployment of BSs increases the energy consumption of network substantially. To improve the energy efficiency, acquisition of accurate downlink channel state information (CSI) at the BSs is essential. However, this task is not easy since the CSI feedback overhead scales linearly with the number of antennas as well as the number of BSs. In this paper, we propose an approach to maximize the energy efficiency of mmWave cell-free systems under the limited feedback. Key idea of the proposed energy-efficient dominating path selection (EE-DPS) algorithm is to choose a small number of paths in the angular domain channel and then exploit the channel information of chosen paths in the data precoding and power allocation. By choosing the dominating paths maximizing the energy efficiency and then feeding back the components of chosen paths, we achieve a considerable reduction in the feedback overhead. Numerical results demonstrate that EE-DPS achieves more than 80% energy efficiency improvement over the conventional CSI feedback-based schemes. [ABSTRACT FROM AUTHOR]

Published

2021

2. Downlink Compressive Channel Estimation With Phase Noise in Massive MIMO Systems.

Author

Zhang, Ruoyu, Shim, Byonghyo, and Zhao, Honglin

Subjects

*PHASE noise, *CHANNEL estimation, *MIMO systems, *RESTRICTED isometry property, *ALGORITHMS, *LEAST squares

Abstract

Phase noise (PN) introduced by the oscillator at the base station and user side severely degrades the channel estimation performance. This paper investigates the impact of PN on downlink compressive channel estimation in massive multiple-input multiple-output (MIMO) systems. Particularly, the downlink compressive channel estimation with PN is modeled as a sparse signal recovery problem with additive correlated perturbation on the pilot matrix, which is a general formulation for both non-synchronous and synchronous PN. Based on this signal model, the performance of the equivalent sensing matrix is analyzed by invoking restricted isometry property (RIP) in compressive sensing. In addition, the upper bound for $l_{1}$ -minimization based channel estimation method and tight channel estimation bound are derived in the framework of RIP and Oracle least square methodology, respectively. Finally, we propose a PN-aware sparse Bayesian learning (PNA-SBL) algorithm to improve the channel estimation performance in the presence of synchronous PN. Simulation results demonstrate our analysis and superiority of the proposed PNA-SBL algorithm. [ABSTRACT FROM AUTHOR]

Published

2020

3. Channel Feedback Based on AoD-Adaptive Subspace Codebook in FDD Massive MIMO Systems.

Author

Shen, Wenqian, Dai, Linglong, Shim, Byonghyo, Wang, Zhaocheng, and Heath, Robert W.

Subjects

MIMO systems, FEEDBACK control systems, WIRELESS channels, SPECTRUM allocation, IEEE 802 standard

Abstract

Channel feedback is essential in frequency division duplexing (FDD) massive multiple-input multiple-output (MIMO) systems. Unfortunately, prior work on multiuser MIMO has shown that the feedback overhead scales linearly with the number of base station (BS) antennas, which is large in massive MIMO systems. To reduce the feedback overhead, we propose an angle-of-departure (AoD) adaptive subspace codebook for channel feedback in FDD massive MIMO systems. Our key insight is to leverage the observation that path AoDs vary more slowly than the path gains. Within the angle coherence time, by utilizing the constant AoD information, the proposed AoD-adaptive subspace codebook is able to quantize the channel vector in a more accurate way. From the performance analysis, we show that the feedback overhead of the proposed codebook only scales linearly with a small number of dominant (path) AoDs instead of the large number of BS antennas. Moreover, we compare the proposed quantized feedback technique using the AoD-adaptive subspace codebook with a comparable analog feedback method. Extensive simulations show that the proposed AoD-adaptive subspace codebook achieves good channel feedback quality, while requiring low overhead. [ABSTRACT FROM AUTHOR]

Published

2018

4. Joint Channel Training and Feedback for FDD Massive MIMO Systems.

Author

Shen, Wenqian, Dai, Linglong, Wang, Zhaocheng, Shi, Yi, and Shim, Byonghyo

Subjects

5G networks, MIMO systems, CHANNEL estimation, ORTHOGONAL frequency division multiplexing, WIRELESS communications

Abstract

Massive multiple-input multiple-output (MIMO) is widely recognized as a promising technology for future 5G wireless communication systems. To achieve the theoretical performance gains in massive MIMO systems, accurate channel-state information at the transmitter (CSIT) is crucial. Due to the overwhelming pilot signaling and channel feedback overhead, however, conventional downlink channel estimation and uplink channel feedback schemes might not be suitable for frequency-division duplexing (FDD) massive MIMO systems. In addition, these two topics are usually separately considered in the literature. In this paper, we propose a joint channel training and feedback scheme for FDD massive MIMO systems. Specifically, we first exploit the temporal correlation of time-varying channels to propose a differential channel training and feedback scheme, which simultaneously reduces the overhead for downlink training and uplink feedback. We next propose a structured compressive sampling matching pursuit (S-CoSaMP) algorithm to acquire a reliable CSIT by exploiting the structured sparsity of wireless MIMO channels. Simulation results demonstrate that the proposed scheme can achieve substantial reduction in the training and feedback overhead. [ABSTRACT FROM PUBLISHER]

Published

2016

5. Joint CSIT Acquisition Based on Low-Rank Matrix Completion for FDD Massive MIMO Systems.

Author

Shen, Wenqian, Dai, Linglong, Shim, Byonghyo, Mumtaz, Shahid, and Wang, Zhaocheng

Abstract

Channel state information at the transmitter (CSIT) is essential for frequency-division duplexing (FDD) massive MIMO systems, but conventional solutions involve overwhelming overhead both for downlink channel training and uplink channel feedback. In this letter, we propose a joint CSIT acquisition scheme to reduce the overhead. Particularly, unlike conventional schemes where each user individually estimates its own channel and then feed it back to the base station (BS), we propose that all scheduled users directly feed back the pilot observation to the BS, and then joint CSIT recovery can be realized at the BS. We further formulate the joint CSIT recovery problem as a low-rank matrix completion problem by utilizing the low-rank property of the massive MIMO channel matrix, which is caused by the correlation among users. Finally, we propose a hybrid low-rank matrix completion algorithm based on the singular value projection to solve this problem. Simulations demonstrate that the proposed scheme can provide accurate CSIT with lower overhead than conventional schemes. [ABSTRACT FROM PUBLISHER]

Published

2015

6. Downlink Pilot Reduction for Massive MIMO Systems via Compressed Sensing.

Author

Choi, Jun Won, Shim, Byonghyo, and Chang, Seok-Ho

Abstract

This letter addresses a problem of downlink pilot allocation for massive multiple-input multiple-output (MIMO) systems. When a massive MIMO is employed in frequency division duplex (FDD) systems, significant amount of radio resources are dedicated to the transmission of downlink pilots. Such huge pilot overhead leads to a substantial loss in the maximum data throughput, which motivates us to reduce the number of pilots. In this letter, we propose a pilot reduction strategy based on compressed sensing techniques for orthogonal frequency division multiplexing systems. The pilots are randomly located in a low density manner over the time and frequency domain. To estimate the channels with such low density pilots, we propose a novel sparse channel estimation technique that exploits the common support of the consecutive channel impulse responses over the certain time duration. The evaluation shows that for a massive MIMO with 128 antennas, the proposed scheme achieves significant reduction of pilot overhead, while maintaining good channel estimation performance. [ABSTRACT FROM PUBLISHER]

Published

2015

7. Recent trend of multiuser MIMO in LTE-advanced.

Author

Lim, Chaiman, Yoo, Taesang, Clerckx, Bruno, Lee, Byungju, and Shim, Byonghyo

Subjects

MIMO systems, WIRELESS communications, LONG-Term Evolution (Telecommunications), CELL phone system standards, MOBILE communication systems

Abstract

Recently, the mobile communication industry is moving rapidly toward Long Term Evolution, or LTE, systems. The leading carriers and vendors are committed to launching LTE service in the near future; in fact, a number of major operators such as Verizon have initiated LTE service already. LTE aims to provide improved service quality over 3G systems in terms of throughput, spectral efficiency, latency, and peak data rate, and the MIMO technique is one of the key enablers of the LTE system for achieving these diverse goals. Among several operational modes of MIMO, multiuser MIMO (MU-MIMO), in which the base station transmits multiple streams to multiple users, has received much attention as a way of achieving improvement in performance. From the initial release (Rel. 8) to the recent release (Rel. 10), so called LTE-Advanced, MUMIMO techniques have evolved from their premature form to a more elaborate version. In this article, we provide an overview of design challenges and the specific solutions for MU-MIMO systems developed in the LTE-Advanced standard. [ABSTRACT FROM PUBLISHER]

Published

2013

8. A Vector Perturbation with User Selection for Multiuser MIMO Downlink.

Author

Lee, Byungju and Shim, Byonghyo

Subjects

*MIMO systems, *MULTIUSER detection (Telecommunication), *PERTURBATION theory, *MOBILE communication systems, *SIGNAL-to-noise ratio, *LEAST squares, *DATA transmission systems

Abstract

Recent works on multiuser MIMO study have shown that the linear growth of capacity in single user MIMO system can be translated to the multiuser MIMO scenario as well. In this paper, we propose a method pursuing performance gain of vector perturbation in multiuser downlink systems. Instead of employing the maximum number of mobile users for communication, we use small part of them as virtual users for improving reliability of users participating communication. By controlling parameters of the virtual users including information and perturbation vector, we obtain considerable improvement in the effective SNR. Simulation results on the realistic multiuser MISO and MIMO downlink systems show that the proposed method brings substantial performance gain over the standard vector perturbation with marginal overhead in computations. [ABSTRACT FROM AUTHOR]

Published

2012

9. A MMSE Vector Precoding with Block Diagonalization for Multiuser MIMO Downlink.

Author

Park, Jungyong, Lee, Byungju, and Shim, Byonghyo

Subjects

CODING theory, MULTIUSER computer systems, MIMO systems, ALGORITHMS, MATHEMATICAL decomposition, SIMULATION methods & models, ERROR rates, COMPUTATIONAL complexity

Abstract

Block diagonalization (BD) algorithm is a generalization of the channel inversion that converts multiuser multi-input multi-output (MIMO) broadcast channel into single-user MIMO channel without inter-user interference. In this paper, we combine the BD technique with a minimum mean square error vector precoding (MMSE-VP) for achieving further gain in performance with minimal computational overhead. Two key ingredients to make our approach effective are the QR decomposition based block diagonalization and joint optimization of transmitter and receiver parameters in the MMSE sense. In fact, by optimizing precoded signal vector and perturbation vector in the transmitter and receiver jointly, we pursue an optimal balance between the residual interference mitigation and the noise enhancement suppression. From the sum rate analysis as well as the bit error rate simulations (both uncoded and coded cases) in realistic multiuser MIMO downlink, we show that the proposed BD-MVP brings substantial performance gain over existing multiuser MIMO algorithms. [ABSTRACT FROM AUTHOR]

Published

2012