Integrated Sensing and Communication With mmWave Massive MIMO: A Compressed Sampling Perspective

Gao, Zhen; Wan, Ziwei; Zheng, Dezhi; Tan, Shufeng; Masouros, Christos; Ng, Derrick Wing Kwan; Chen, Sheng

doi:10.1109/twc.2022.3206614

Cited by 41 publications

(12 citation statements)

References 48 publications

(145 reference statements)

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“…MmWave communication has been considered as a pivotal technique [18] due to the vast available spectrum. Employing a NOMA scheme in the mmWave communication system can support more than one user to transmit signals simultaneously in the same time-frequency-code-space resource block, enabling large-scale user connections and improving spectrum efficiency [14][15][16].…”

Section: Mmwave and Nomamentioning

confidence: 99%

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Secure wireless communications for STAR‐RIS‐assisted millimetre‐wave NOMA uplink networks

et al. 2023

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This paper explores the potential application of simultaneously transmitting and reflecting reconfigurable intelligent surface (STAR-RIS) in improving the physical layer security (PLS) of millimetre wave (mmWave) non-orthogonal multiple access (NOMA) uplink communications. In particular, the legitimate users on both sides of STAR-RIS send confidential information simultaneously to the base station (BS) while keeping it secret from the eavesdroppers near the BS by exploiting the STAR-RIS to proactively regulate the electromagnetic propagation environment. By jointly designing the transmit power, the active beamforming at the BS, and the reflecting/transmitting coefficients at the STAR-RIS, the authors' goal is to maximize the minimum secrecy capacity subject to the successive interference cancellation decoding order constraints. Due to the nonconvexity of the formulated problem, an efficient algorithm is proposed by capitalizing on alternating optimization, a penalty-based approach, successive convex approximation, and semi-definite relaxation. Firstly, a two-layer iterative algorithm based on the penalty for the joint beamforming optimization sub-problem is proposed. Then, the non-convex problem is transformed into a convex positive semi-definite programming problem for the transmit power sub-problem. Numerical simulation results reveal that the STAR-RISaided system has more tremendous advantages and effectiveness in improving the PLS of mmWave NOMA uplink communication compared with the benchmark schemes.

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Section: Mmwave and Nomamentioning

confidence: 99%

“…Up to this point, since the rank-one constraint (9g) is the only non-convex part in the optimization problem (18), we apply the SDR technique to drop the rank constraint in (9g). It can be proved that the solutions {W} obtained for the relaxed version of problem ( 18) always satisfy Rank(W) = 1 without loss of optimality [37].…”

Section: Trmentioning

confidence: 99%

Secure wireless communications for STAR‐RIS‐assisted millimetre‐wave NOMA uplink networks

et al. 2023

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“…mmWave bistatic JCS. A few works have addressed bistatic JCS in mmWave systems, assuming synchronized transmitter and receiver [27], [28], [29]. Others have focused on tracking targets based on distance and Angle of Arrival (AoA), without addressing sensing tasks that require phase analysis or aggregation of signal samples over coherent processing intervals, such as Doppler speed estimation [30].…”

Section: Related Workmentioning

confidence: 99%

SPARCS: A Sparse Recovery Approach for Integrated Communication and Human Sensing in mmWave Systems

Pegoraro

Lacruz

Rossi

et al. 2022

2022 21st ACM/IEEE International Conference on Information Processing in Sensor Networks (IPSN)

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Wideband millimeter-wave communication systems can be extended to provide radar-like sensing capabilities on top of data communication, in a cost-effective manner. However, the development of joint communication and sensing technology is hindered by practical challenges, such as occlusions to the line-of-sight path and clock asynchrony between devices. The latter introduces time-varying timing and frequency offsets that prevent the estimation of sensing parameters and, in turn, the use of standard signal processing solutions. Existing approaches cannot be applied to commonly used phased-array receivers, as they build on stringent assumptions about the multipath environment, and are computationally complex. We present JUMP, the first system enabling practical bistatic and asynchronous joint communication and sensing, while achieving accurate target tracking and micro-Doppler extraction in realistic conditions. Our system compensates for the timing offset by exploiting the channel correlation across subsequent packets. Further, it tracks multipath reflections and eliminates frequency offsets by observing the phase of a dynamically-selected static reference path. JUMP has been implemented on a 60 GHz experimental platform, performing extensive evaluations of human motion sensing, including non-line-of-sight scenarios. In our results, JUMP attains comparable tracking performance to a fullduplex monostatic system and similar micro-Doppler quality with respect to a phase-locked bistatic receiver.

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“…2 Even if the system works in half duplex mode [27], for the normal communications distance, it can still be considered that the transmitting antenna array and the receiving antenna array are at the same location. Hence there is still wr = wt when the two arrays have the same configuration and are placed in parallel.…”

Section: A the Influence Of Beam Squint On Sensingmentioning

confidence: 99%

“…One can easily extend this work to the half duplex mode, in which the BS has separate transmitting and receiving antenna array with certain protection distance to eliminate the self-interference[27]. Nevertheless, we choose full duplex assumption here mainly to illustrate the proposed YOLO algorithm in a clearer way.…”

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confidence: 99%

Engineering Mathematics Course in Department of Electrical Engineering at Southern University

Luo¹,

Bhattacharya²

2008 GSW Proceedings

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Engineering Mathematics Course at Electrical Engineering Department of Southern University is a fundamental core engineering course. This core course is taught in a way that shows how the engineering problems in the real world are related to the mathematic problems and how to solve these related engineering problems by adopting different mathematical tools, which is one of the greatest strengths of SU's EE curriculum-and having emphasis on fundamentals about how they apply to real-world problems. There always are very many types of mathematical topics to be covered in this course, and some of them overlap with other classes, such as Laplace Transform, Fourier series and transforms, etc. The main concern in this paper is how to set the materials for whole EE curriculum in engineering mathematics area, which covers most of useful engineering mathematics tools, and at the same time, reduces the overlaps with other EE classes. In other words, in our proposed Engineering Mathematics Course (ENGR 340), we will emphasize some mathematical methods only offered in the E-math course, and cut or reduce the materials which will be taught at other courses to increase students learning efficiency. In this paper, proposed E-math course teaching materials will be given, and some discussion will be provided.

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Integrated Sensing and Communication With mmWave Massive MIMO: A Compressed Sampling Perspective

Cited by 41 publications

References 48 publications

Secure wireless communications for STAR‐RIS‐assisted millimetre‐wave NOMA uplink networks

Secure wireless communications for STAR‐RIS‐assisted millimetre‐wave NOMA uplink networks

SPARCS: A Sparse Recovery Approach for Integrated Communication and Human Sensing in mmWave Systems

Engineering Mathematics Course in Department of Electrical Engineering at Southern University

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