Joint Resource Allocation for Multiuser Opportunistic Beamforming Systems with OFDM-NOMA

Sun, Wen-Bin; Tao, Mingliang; Yang, Xin; Zhou, Ruizhe; Yang, Zi-Xiong

doi:10.3390/e23070809

Cited by 2 publications

(1 citation statement)

References 35 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, motivated by the optimization schemes in this paper, we will delve into the problem of resource allocation in the MIMO-NOMA maritime system. The joint optimization project with beamforming and user clustering represents a significant challenge for our future work [37]. We aim to achieve improved signal strength and regional coverage while reducing signal interference in the next generation of this maritime communication system.…”

Section: Discussionmentioning

confidence: 99%

Optimization Algorithms for Joint Power and Sub-Channel Allocation for NOMA-Based Maritime Communications

Zhou

2021

Entropy

View full text Add to dashboard Cite

This paper investigates resource optimization schemes in a marine communication scenario based on non-orthogonal multiple access (NOMA). According to the offshore environment of the South China Sea, we first establish a Longley–Rice-based channel model. Then, the weighted achievable rate (WAR) is considered as the optimization objective to weigh the information rate and user fairness effectively. Our work introduces an improved joint power and user allocation scheme (RBPUA) based on a single resource block. Taking RBPUA as a basic module, we propose three joint multi-subchannel power and marine user allocation algorithms. The gradient descent algorithm (GRAD) is used as the reference standard for WAR optimization. The multi-choice knapsack algorithm combined with dynamic programming (MCKP-DP) obtains a WAR optimization result almost equal to that of GRAD. These two NOMA-based solutions are able to improve WAR performance by 7.47% compared with OMA. Due to the high computational complexity of the MCKP-DP, we further propose a DP-based fully polynomial-time approximation algorithm (DP-FPTA). The simulation results show that DP-FPTA can reduce the complexity by 84.3% while achieving an approximate optimized performance of 99.55%. This advantage of realizing the trade-off between performance optimization and complexity meets the requirements of practical low-latency systems.

show abstract

Section: Discussionmentioning

confidence: 99%

Optimization Algorithms for Joint Power and Sub-Channel Allocation for NOMA-Based Maritime Communications

Zhou

2021

Entropy

View full text Add to dashboard Cite

show abstract

Cooperative Reception of Multiple Satellite Downlinks

Al-Anbagi

Veřtát

2022

Sensors

View full text Add to dashboard Cite

Popular small satellites host individual sensors or sensor networks in space but require ground stations with directional antennas on rotators to download sensors’ data. Such ground stations can establish a single downlink communication with only one satellite at a time with high vulnerability to system outages when experiencing severe channel impairments or steering engine failures. To contribute to the area of improving the reception quality of small satellites signals, this paper presents a simple receive diversity scheme with proposed processing algorithms to virtually combine satellite downlink streams collected from multiple omnidirectional receivers. These algorithms process multiple received versions of the same signal from multiple geographically separated receiving sites to be combined in one virtual ground station. This virtual ground station helps detect the intended signal more reliably based only on a network of simple and cooperating software-defined radio receivers with omnidirectional antennas. The suggested receive diversity combining techniques can provide significant system performance improvement if compared to the performance of each individual receiving site. In addition, the probability of system outages is decreased even if one or more sites experience severe impairment consequences. Simulation results showed that the bit error rate (BER) of the combined stream is lower than the BER of the best quality receiving site if considered alone. Moreover, virtual ground stations with cooperative omnidirectional reception at geographically separated receivers also allow data to be received from multiple satellites in the same frequency band simultaneously, as software-defined receivers can digitize a wider portion of the frequency band. This can be a significant conceptual advantage as the number of small satellites transmitting data grows, and it is reasonable to avoid the corresponding necessary increase in the number of fully equipped ground stations with rotators.

show abstract

Joint Resource Allocation for Multiuser Opportunistic Beamforming Systems with OFDM-NOMA

Cited by 2 publications

References 35 publications

Optimization Algorithms for Joint Power and Sub-Channel Allocation for NOMA-Based Maritime Communications

Optimization Algorithms for Joint Power and Sub-Channel Allocation for NOMA-Based Maritime Communications

Cooperative Reception of Multiple Satellite Downlinks

Contact Info

Product

Resources

About