Showing total 22 results

1. Optimization of Radio and Computational Resources for Energy Efficiency in Latency-Constrained Application Offloading.

Author

Munoz, Olga, Pascual-Iserte, Antonio, and Vidal, Josep

Subjects

MIMO systems, ENERGY consumption, WIRELESS communications, TELECOMMUNICATION systems, DATA transmission systems

Abstract

Providing femto access points (FAPs) with computational capabilities will allow (either total or partial) offloading of highly demanding applications from smartphones to the so-called femto-cloud. Such offloading promises to be beneficial in terms of battery savings at the mobile terminal (MT) and/or in latency reduction in the execution of applications. However, for this promise to become a reality, the energy and/or the time required for the communication process must be compensated by the energy and/or the time savings that result from the remote computation at the FAPs. For this problem, we provide in this paper a framework for the joint optimization of the radio and computational resource usage exploiting the tradeoff between energy consumption and latency. Multiple antennas are assumed to be available at the MT and the serving FAP. As a result of the optimization, the optimal communication strategy (e.g., transmission power, rate, and precoder) is obtained, as well as the optimal distribution of the computational load between the handset and the serving FAP. This paper also establishes the conditions under which total or no offloading is optimal, determines which is the minimum affordable latency in the execution of the application, and analyzes, as a particular case, the minimization of the total consumed energy without latency constraints. [ABSTRACT FROM PUBLISHER]

Published

2015

2. Intelligent Reflecting Surface Aided Secure Transmission With Colluding Eavesdroppers.

Author

Wang, Yang, Shi, Weiping, Huang, Mengxing, Shu, Feng, and Wang, Jiangzhou

Subjects

RIEMANNIAN manifolds, TELECOMMUNICATION systems, COMPUTATIONAL complexity, MISO, ARRAY processing

Abstract

This paper studies a secure multiuser multiple-input single-output (MISO) communication system aided by an intelligent reflecting surface (IRS), where multiple colluding eavesdroppers (EVEs) coexist. We aim to maximize the sum secrecy rate (SSR) via jointly optimizing the beamforming vectors, the artificial noise (AN) and the phase shifts at the IRS subject to the maximum transmit power constraint and unit modulus constraints. To address the non-convex optimization problem, we first propose an alternating optimization (AO) algorithm based on semidefinite relaxation (SDR) and obtain a high-quality sub-optimal solution. In order to reduce the high computational complexity, a low-complexity alternating optimization (LC-AO) algorithm is developed, in which the beamforming vectors, AN and the IRS phase shifts are optimized alternately by the generalized power iteration (GPI) and the Riemannian manifold conjugate gradient (RMCG) algorithm, respectively. Simulation results show the advantages of deploying the IRS in improving the system secrecy performance. [ABSTRACT FROM AUTHOR]

Published

2022

3. Double IRSs Aided Massive MIMO Channel Estimation and Spectrum Efficiency Maximization for High-Speed Railway Communications.

Author

Li, Tianyou, Tong, Huawei, Xu, Youyun, Su, Xinzhong, and Qiao, Guopeng

Subjects

CHANNEL estimation, TELECOMMUNICATION systems, MIMO systems, RAILROADS, WIRELESS communications, HIGH speed trains

Abstract

Intelligent reflecting surface (IRS)-enhanced wireless communication is one of the critical technologies of the sixth generation mobile communication, which has recently emerged as an innovative solution to the realization of intelligent transportation. It can meet the increasing demand for high-speed railway (HSR) communications services. In this paper, we consider a train-ground TDD wireless mobile communication paradigm to deploy two IRSs on the roadside and the train roof to assist the wireless transmission for the HSR communication system. To achieve the more significant performance gain, in the uplink transmission phase, we propose the practical channel estimation framework of the MIMO system aided by double IRSs to acquire reliable channel state information (CSI) of each channel. To facilitate the processing of the three-dimension tensor, we leverage the trilinearity of the parallel factor decomposition to decompose the received signal into a two-dimensional matrix. The Doppler frequency offset compensating scheme and channel tracking scheme based on Kalman-Filter are proposed to further decrease the pilot overheads. Then, in the downlink phase, a block coordinate descent (BCD) algorithm is proposed to handle the data rate maximization problem of double IRSs communication system with the estimated CSI. We reformulate the original problem and decouple the double IRSs phase optimization problem into two single IRS phase optimization non-convex problems under the unit-modulus constraint. The Majorization-Minimization (MM) algorithm is proposed to approximate the optimal solution of the two optimization subproblems. Simulation results corroborate the effectiveness of the proposed channel estimation and phase shifts optimization scheme. [ABSTRACT FROM AUTHOR]

Published

2022

4. On the Exposure Dose Minimization of Multi-Antenna Multi-Carrier System Users.

Author

Heliot, Fabien and Brown, Tim W. C.

Subjects

EXPOSURE dose, RECEIVING antennas, ELECTROMAGNETIC fields, TELECOMMUNICATION systems, RESOURCE allocation, MULTIUSER computer systems, RADIATION dosimetry

Abstract

From the fourth generation (4G) of cellular systems onward, wireless personal devices (WPDs) support multi-input multi-output (MIMO) communication. However, the impact of MIMO communication on the electromagnetic field (EMF) of WPD users has yet to be fully understood and analyzed at the system level. In this paper, we first provide a generic model for assessing the individual exposure dose of multi-antenna WPD users in a multi-user multi-carrier communication system. An optimization framework for minimizing this exposure dose is then developed based on our exposure model. This framework helps us to identify a new criterion, i.e., the ratio between the normalized exposure dose and the channel to noise ratio (CNR), as the main system level criterion for minimizing the individual exposure dose of multi-antenna WPD users. This criterion is further integrated in the design of two novel centralized resource allocation schemes that take advantage of the multiple antennas at the WPD to minimize the per-user exposure dose, when full or limited knowledge of each user channel is available. Our new schemes can significantly reduce the individual exposure dose of WPD users (by approximately 80%) in comparison with the most relevant existing resource allocation schemes. Our results also provide insights into the logarithmic relationship between the per-user exposure dose and the number of receive antennas (or the number of time slots), and how such a parameter can be exploited to further reduce the exposure and/or provide a higher SE while maintaining a low exposure dose. [ABSTRACT FROM AUTHOR]

Published

2022

5. Energy-Spectral Efficiency Tradeoff in DCO-OFDM Visible Light Communication System.

Author

Hei, Yongqiang, Kou, Yanchun, Shi, Guangming, Li, Wentao, and Gu, Huaxi

Subjects

OPTICAL communications, TELECOMMUNICATION systems, VISIBLE spectra, ORTHOGONAL frequency division multiplexing, LIGHT transmission, RAYLEIGH number

Abstract

Due to its simple implementation and higher spectral efficiency (SE), the direct current (DC) biased optical orthogonal frequency division multiplexing (DCO-OFDM) scheme has been extensively employed in visible light communication (VLC) system. In this paper, the tradeoff between energy efficiency (EE) and SE in DCO-OFDM system is investigated. Specifically, the achievable SE of DCO-OFDM system with power and bit loading is derived, and the closed-form expression of the EE-SE tradeoff is obtained, on the basis of which, the optimal SE to maximize EE is derived, and the optimal parameters of the DCO-OFDM system, e.g., the horizontal and vertical distances of optical transmission network, the number of subcarriers, to maximize the EE-SE tradeoff are theoretically derived. Moreover, to derive the optimal transmitted power, a Pareto optimal set based multi-objective optimization (MOO) is formulated, which is successfully transformed into a single-objective optimization (SOO), with the help of a proposed EE-SE tradeoff metric. Finally, simulation results are provided to verify the presented EE-SE tradeoff, the derived optimal SE, the optimal vertical distance of optical transmission network and the optimal transmitted power. [ABSTRACT FROM AUTHOR]

Published

2019

6. Forming a Two-Tier Heterogeneous Air-Network via Combination of High and Low Altitude Platforms.

Author

Ahmadinejad, Hosein and Falahati, Abolfazl

Subjects

ALTITUDES, COMPUTATIONAL complexity, FEMTOCELLS, POWER transmission, TELECOMMUNICATION systems, ENERGY consumption, ASSIGNMENT problems (Programming)

Abstract

In this paper, an aerial heterogeneous wireless network consists of a high altitude platform (HAP) and low altitude platforms (LAPs) as aerial base stations (ABSs) in a downlink orthogonal division multiple access (OFDMA) transmission is investigated. Two types of spectrum sharing, including spectrum underlay access (SUA) and spectrum overlay access (SOA) are employed to evaluate the inter-tier interference. Distributed problem formulation and solving method are used to reduce the computational complexity, communication overhead and system latency. Subcarrier assignment and power allocation in spectral efficiency (SE), energy efficiency (EE) and transmission power optimization problems are accomplished by the proposed two-layer algorithm. In the proposed algorithm, first, subcarrier assignment based on constraints of the optimization problems is carried out to cover both SUA and SOA with low computational complexity. Second, the proposed algorithm performs power allocation. The simulation results show the relation between spectrum reuse and inter-tier interference, such that system SE, EE and the number of served users are maximized when both spectrum reuse and inter-tier interference management are performed together. [ABSTRACT FROM AUTHOR]

Published

2022

7. Performance Trade-Off in UAV-Aided Wireless-Powered Communication Networks via Multi-Objective Optimization.

Author

Muhammad Hashir, Syed, Mehrabi, Arefe, Robat Mili, Mohammad, Emadi, Mohamamd Javad, Ng, Derrick Wing Kwan, and Krikidis, Ioannis

Subjects

TELECOMMUNICATION systems, WIRELESS sensor nodes, WIRELESS communications, WIRELESS sensor networks, ENERGY harvesting, DRONE aircraft

Abstract

In this paper, we study an unmanned aerial vehicle (UAV)-enabled wireless powered communication network, where a UAV serves multiple energy constrained wireless sensor nodes (WSNs). In such a network, a UAV transmits wireless power to a group of WSNs which exploits the harvested power to transfer their own information towards the UAV in the uplink. For practical scenarios, a nonlinear energy harvesting saturation model is considered at WSNs. We aim to design resource allocation which maximizes the achievable sum rate in the uplink and minimizes the downlink transmit power simultaneously. The design is formulated as a multi-objective optimization problem (MOOP) which optimizes the UAV's 3D position, its transmit power, the time splitting ratio, the uplink transmission time and the beamwidth angle of the UAV. The formulated problem is a non-convex problem which is generally intractable. To address the MOOP, a weighted Tchebycheff method is proposed. The numerical results show a trade-off between the minimum power in the downlink and the maximum rate as well as energy efficiency in the uplink. [ABSTRACT FROM AUTHOR]

Published

2021

8. Robust Trajectory and Transmit Power Design for Secure UAV Communications.

Author

Cui, Miao, Zhang, Guangchi, Wu, Qingqing, and Ng, Derrick Wing Kwan

Subjects

DRONE aircraft, WIRELESS communications, ALGORITHMS, AUTONOMOUS vehicles, TELECOMMUNICATION systems

Abstract

Unmanned aerial vehicles (UAVs) are anticipated to be widely deployed in future wireless communications, due to their advantages of high mobility and easy deployment. However, the broadcast nature of air-to-ground line-of-sight wireless channels brings a new challenge to the information security of UAV-ground communication. This paper tackles such a challenge in the physical layer by exploiting the mobility of UAV via its trajectory design. We consider a UAV-ground communication system with multiple potential eavesdroppers on the ground, where the information on the locations of the eavesdroppers is imperfect. We formulate an optimization problem, which maximizes the average worst case secrecy rate of the system by jointly designing the robust trajectory and transmit power of the UAV over a given flight duration. The nonconvexity of the optimization problem and the imperfect location information of the eavesdroppers make the problem difficult to be solved optimally. We propose an iterative suboptimal algorithm to solve this problem efficiently by applying the block coordinate descent method, $\mathcal {S}$ -procedure, and successive convex optimization method. Simulation results show that the proposed algorithm can improve the average worst case secrecy rate significantly, as compared to two other benchmark algorithms without robust design. [ABSTRACT FROM AUTHOR]

Published

2018

9. Intelligent Reflecting Surface Enhanced Secure Transmission Against Both Jamming and Eavesdropping Attacks.

Author

Sun, Yifu, An, Kang, Luo, Junshan, Zhu, Yonggang, Zheng, Gan, and Chatzinotas, Symeon

Subjects

WIRELESS channels, EAVESDROPPING, TELECOMMUNICATION systems, WIRELESS communications, SCHWARZ inequality, GAUSSIAN channels, MATHEMATICAL optimization, BEAMFORMING

Abstract

Both the jammer and the eavesdropper pose severe threat to wireless communications due to the broadcast nature of wireless channels. In this paper, an intelligent reflecting surface (IRS) assisted secure communication system is considered, where a base station (BS) wishes to reliably convey information to a user, in the presence of both a jammer and an eavesdropper whose transmit informations are not completely known. Specifically, with the imperfect third-party node's channel state information (CSI) and no knowledge of the jammer's transmit beamforming, we aim to maximize the system achievable rate by jointly designing the BS's transmit beamforming and the IRS's reflect beamforming, while limiting the information leakage to the potential eavesdropper. Due to the non-convexity and intractability of the original problem induced by the incompleted information, we utilize the auxiliary variables, Cauchy-Schwarz inequality, and General Sign-Definiteness transformation to convert the original optimization problem into a tractable convex optimization problem, and then obtain the high-quality optimal solution by using the successive convex approximation and penalty convex concave procedure. Numerical simulations demonstrate the superiority of our proposed optimization algorithm compared with existing approaches, and also reveal the impact of key parameters on the achievable system performance. [ABSTRACT FROM AUTHOR]

Published

2021

10. NOMA for Wireless-Powered Communication Networks With Buffered Sources.

Author

Ren, Juanjuan, Lei, Xianfu, Diamantoulakis, Panagiotis D., Zhou, Fuhui, Tang, Xiaohu, and Dobre, Octavia A.

Subjects

TELECOMMUNICATION systems, WIRELESS communications, MULTIPLE access protocols (Computer network protocols), ENERGY storage, SPACE-time block codes, ANALYTICAL solutions, UTILITY functions, FAIRNESS

Abstract

To increase the feasibility of wireless powered communication networks (WPCNs), the synergy of efficient multiple access protocols and diverse types of resources, e.g., multiple antennas, memories, and energy storage devices is of paramount importance. To this end, in this paper, we introduce the use of buffered sources in WPCNs with uplink non-orthogonal multiple access, in which a multi-antenna hybrid access point can both transmit energy and receive information. The proposed scheme aims at maximizing the long-term utility function, which is determined by the achieved average data rate and fairness among sources. The formulated long-term time-average optimization problem is converted into instantaneous ones by exploiting the Lyapunov optimization framework. The derived analytical solutions reveal the impact of data buffers’ length on the decoding order of sources’ messages. Finally, it is shown that the proposed scheme achieves superior long-term utility compared to the considered baseline schemes with non-buffered sources and buffered sources with orthogonal multiple access. Additionally, it is demonstrated that our proposed scheme can ensure fairness without reducing the average data rate. [ABSTRACT FROM AUTHOR]

Published

2021

11. Multi-Agent Deep Reinforcement Learning for Distributed Resource Management in Wirelessly Powered Communication Networks.

Author

Hwang, Sangwon, Kim, Hanjin, Lee, Hoon, and Lee, Inkyu

Subjects

TELECOMMUNICATION systems, POWER resources management, DEEP learning, WIRELESS communications, REINFORCEMENT learning, ACQUISITION of data

Abstract

This paper studies multi-agent deep reinforcement learning (MADRL) based resource allocation methods for multi-cell wireless powered communication networks (WPCNs) where multiple hybrid access points (H-APs) wirelessly charge energy-limited users to collect data from them. We design a distributed reinforcement learning strategy where H-APs individually determine time and power allocation variables. Unlike traditional centralized optimization algorithms which require global information collected at a central unit, the proposed MADRL technique models an H-AP as an agent producing its action based only on its own locally observable states. Numerical results verify that the proposed approach can achieve comparable performance of the centralized algorithms. [ABSTRACT FROM AUTHOR]

Published

2020

12. A Novel Graphics-Based Multi-Epoch Power Adjustment Strategy for WPCNs.

Author

Wang, Tong, Yan, Zhipeng, Gao, Lin, Jiang, Yufei, Ma, Ting, and Yang, Zhihua

Subjects

WIRELESS communications, TELECOMMUNICATION systems, TIME management, ENERGY consumption, ENERGY harvesting

Abstract

In this paper, we focus on a wireless powered communication network where a hybrid access point can wirelessly activate the power of source nodes, and receive their information. Considering the time-switching protocol that implies energy harvesting, and energy usage are separated by time, a novel graphics-based multi-epoch power adjustment (GB-MPA) strategy is proposed to maximize the sum-throughput over a finite time horizon consisting of multiple transmission epochs. The proposed strategy relies on graphical constraint conditions, and allows the elimination of restrictions corresponding to the objective of throughput maximization. Moreover, the proposed GB-MPA strategy can be combined with the time-switching factor optimization by employing an alternating optimization procedure for performance enhancement. Simulation results show the accuracy of the proposed strategy, reduced complexity compared with the conventional convex optimization method, and the existing multi-epoch power adjustment strategy, and the compatibility with the alternating optimization procedure for developing the joint power, and time allocation scheme. [ABSTRACT FROM AUTHOR]

Published

2020

13. Improving PHY-Security of UAV-Enabled Transmission With Wireless Energy Harvesting: Robust Trajectory Design and Communications Resource Allocation.

Author

Mamaghani, Milad Tatar and Hong, Yi

Subjects

ENERGY harvesting, RESOURCE allocation, WIRELESS power transmission, VERTICALLY rising aircraft, TELECOMMUNICATION systems, DRONE aircraft, MATHEMATICAL reformulation

Abstract

In this paper, we consider an unmanned aerial vehicle (UAV) assisted communications system, including two cooperative UAVs, a wireless-powered ground destination node leveraging simultaneous wireless information and power transfer (SWIPT) technique, and a terrestrial passive eavesdropper. One UAV delivers confidential information to destination and the other sends jamming signals to against eavesdropping and assist destination with energy harvesting. Assuming UAVs have partial information about eavesdropper's location, we propose two transmission schemes: friendly UAV jamming (FUJ) and Gaussian jamming transmission (GJT) for the cases when jamming signals are known and unknown a priori at destination, respectively. Then, we formulate an average secrecy rate maximization problem to jointly optimize the transmission power and trajectory of UAVs, and the power splitting ratio of destination. Being non-convex and hence difficult to solve the formulated problem, we propose a computationally efficient iterative algorithm based on block coordinate descent and successive convex approximation to obtain a suboptimal solution. Finally, numerical results are provided to substantiate the effectiveness of our proposed multiple-UAV schemes, compared to other existing benchmarks. Specifically, we find that the FUJ demonstrates significant secrecy performance improvement in terms of the optimal instantaneous and average secrecy rate compared to the GJT and the conventional single-UAV counterpart. [ABSTRACT FROM AUTHOR]

Published

2020

14. Two-Way Dual-Hop WPCN With A Practical Energy Harvesting Model.

Author

Ramezani, Parisa and Jamalipour, Abbas

Subjects

ENERGY harvesting, TELECOMMUNICATION systems, TWO-way communication, WIRELESS communications, RESOURCE allocation

Abstract

In this paper, we study a dual-hop wireless powered communication network (DH-WPCN), where the two-way communication between the users and the access point (AP) is assisted by a relay. Assuming a piece-wise linear energy harvesting (EH) model for the users and the relay, we investigate the problem of total throughput maximization for both amplify-and-forward (AF) and decode-and-forward (DF) relaying modes. To deal with the non-convexity of the throughput maximization problem, we apply the block coordinate descent (BCD) technique and alternately optimize different blocks of optimization variables until convergence is achieved. Numerical results demonstrate the substantial performance gain of the proposed scheme with piece-wise linear EH model as compared to the case with oversimplified linear EH model. This is due to the fact that our proposed scheme takes into consideration the saturation effect of practical EH circuits in optimizing the resource allocation. [ABSTRACT FROM AUTHOR]

Published

2020

15. Energy-Efficient Non-Orthogonal Multiple Access for UAV Communication System.

Author

Sohail, Muhammad Farhan, Leow, Chee Yen, and Won, SeungHwan

Subjects

MULTIPLE access protocols (Computer network protocols), TELECOMMUNICATION systems, DRONE aircraft, ENERGY consumption, POWER transmission, MATHEMATICAL optimization, NUMERICAL analysis

Abstract

The placement of Unmanned Aerial Vehicle (UAV) based aerial Base station (BS) has emerged as a viable solution to the contemplated high traffic demands of the future wireless networks. Nevertheless, the practical realization of UAVs for wireless coverage provisioning demands efficient utilization of its limited onboard energy reserves. This paper studies the power-domain Non-Orthogonal Multiple Access (NOMA) scheme for energy-efficient placement of the UAV-BS. The objective of maximized information bits per unit energy consumption of the UAV-BS is developed assuming a multi-Quality of Service (QoS) scenario. Also, the efficiency analysis is carried out considering the composite of energies consumed for the signal transmission and hover operation of the UAV-BS. The formulated Non-Linear Fractional Problem (NLFP) as a function of transmission power and altitude is solved by employing an alternating optimization technique based on a nested Dinkelbach structure. An investigation into the user pairing scheme also sheds new light on its effect upon the constrained feasible altitude range of the UAV-BS. Consequently, a computationally efficient approach is devised to render solution space based on the identified subset of user pairs. The numerical analyses of the proposed scheme signify a substantial increase in the energy efficiency of the NOMA based UAV-BS in comparison to the baseline scheme of Orthogonal Multiple Access (OMA). Thus, the improved energy efficiency enables enhanced coverage for the UAV-BS. [ABSTRACT FROM AUTHOR]

Published

2019

16. Resource Allocation in SWIPT Networks Under a Nonlinear Energy Harvesting Model: Power Efficiency, User Fairness, and Channel Nonreciprocity.

Author

Tran, Ha-Vu, Kaddoum, Georges, and Truong, Kien T.

Subjects

WIRELESS communications, ENERGY consumption, RESOURCE allocation, TELECOMMUNICATION systems, ECONOMICS

Abstract

This paper considers a multiuser simultaneous wireless information and power transfer system with a nonlinear energy harvesting model, in which a multiantenna base station estimates the downlink channel state information (CSI) via uplink pilots. Each single-antenna user is equipped with a power splitter. Three crucial issues on resource management for this system include: 1) power-efficient improvement, 2) user-fairness guarantee, and 3) nonideal channel reciprocity effect mitigation. Potentially, a resource allocation scheme to address jointly such issues can be devised by using the framework of multiobjective optimization. However, the resulting problem might be complex to solve since the three issues hold different characteristics. Therefore, we propose a novel method to design the resource allocation scheme. In particular, the principle of our method relies on structuralizing mathematically the issues into a cross-layer multilevel optimization problem. On this basis, we then devise solving algorithms and closed-form solutions. Moreover, to instantly adapt the CSI changes in practice while reducing computational burdens, we propose a closed-form suboptimal solution to tackle the problem. Finally, we provide numerical results to show the achievable performance gains using the optimal and suboptimal solutions, and then validate the proposed resource allocation scheme. [ABSTRACT FROM AUTHOR]

Published

2018

17. Joint User Pairing and Power Allocation Design for Heavy Loaded Full-Duplex Small Cell Systems.

Author

Chen, Lu, Zhong, Caijun, Lin, Hai, and Zhang, Zhaoyang

Subjects

WIRELESS communications, ALGORITHMS, NUMERICAL analysis, TELECOMMUNICATION systems, ALGEBRA

Abstract

This paper considers a heavy loaded full-duplex (FD) small cell consisting of one FD base station and multiple half-duplex users where the number of subchannels is less than the number of uplink and downlink users. With the objective of maximizing the total sum-rate, a joint power allocation, and user pairing problem is formulated. To solve this problem, a novel decomposition method is proposed, which decouples the power allocation and user pairing problem into two subproblems. It is proven that the optimal solution of subproblems is the optimal solution of the original problem. Then, optimal algorithms are developed for the two subproblems. Numerical results show that the proposed algorithm achieves better performance compared with the baselines of the greedy algorithm and random pairing algorithm. [ABSTRACT FROM AUTHOR]

Published

2018

18. Joint Transceiver and Power Splitting Optimization for Multiuser MIMO SWIPT Under MSE QoS Constraints.

Author

Zhang, Haixia, Dong, Anming, Jin, Shi, and Yuan, Dongfeng

Subjects

MIMO systems, WIRELESS communications, FEASIBILITY studies, MATHEMATICAL programming, TELECOMMUNICATION systems

Abstract

This paper studies the joint transceiver design and power splitting (JTDPS) for a downlink multiuser multiple-input multiple-output (MU-MIMO) simultaneous wireless information and power transfer (SWIPT) system. Aiming to minimize the transmit power by jointly optimizing the transmitter at a base station, the power splitting (PS) factors, and information decoding receivers at mobile stations (MSs) subject to both the predefined mean-square error (MSE) and the given energy harvesting (EH) constraints. The formulated problem is a nonconvex JTDPS optimization problem, which cannot be solved directly. To solve it, an iterative optimization framework composed of joint transmitter and PS factor optimization (JTxPS) subproblem and a receiver side minimum mean-square error (MMSE) minimization subproblem is proposed. By iteratively solve the two subproblems, the original optimization problem is solved. The sufficient and necessary conditions for the feasibility of the formulated JTDPS and the JTxPS problems are analyzed. Theoretical analysis shows that the JTxPS subproblem is also nonconvex and can be solved by using convex semidefinite programming (SDP). Considering the high computational complexity of the SDP-based scheme, a low-complexity suboptimal scheme based on the traditional MMSE transceiver design is also proposed. Simulations are done to validate the theoretical analysis, and results show the effectiveness of the proposed schemes. [ABSTRACT FROM AUTHOR]

Published

2017

19. Cross-Layer Resource Optimization for Wireless Relay Networks Under Dynamic Node Selfishness.

Author

Li, Jinglei, Yang, Qinghai, Kwak, Kyung Sup, and Rao, Ramesh R.

Subjects

WIRELESS communications, ALGORITHMS, LYAPUNOV exponents, TELECOMMUNICATION systems, ALGEBRA

Abstract

In this paper, we investigate the cross-layer resource optimization for wireless relay networks with dynamic node-selfishness information. The degree of intrinsic selfishness (DeIS) and the degree of extrinsic selfishness (DeES) of the relay node (RN) are defined as the effects of its own residual energy resource and the incentive in an incentive mechanism, respectively. A model of two-timescale node-selfishness dynamics is constructed to describe the time-varying characteristics of the RN's DeIS and DeES. Based on the two-timescale node-selfishness dynamics of the RNs, a two-timescale resource-optimization dynamical algorithm (TRODA) is employed to control the transmit powers of both RNs and end users (EU), as well as the flow rates of the data packets injected by all EUs. Meanwhile, the stability and the tracking error of the TRODA under the two-timescale node-selfishness dynamics are analyzed by Lyapunov theory. Our simulation results demonstrate that the two-timescale optimization algorithm is stable and has trivial tracking error. [ABSTRACT FROM AUTHOR]

Published

2017

20. Square-Root Nyquist Filter Design for QAM-Based Filter Bank Multicarrier Systems.

Author

Taheri, Sohail, Ghoraishi, Mir, Xiao, Pei, Zhang, Lei, and Xin, Yu

Subjects

WIRELESS communications, INTERFERENCE (Telecommunication), SAMPLING theorem, TELECOMMUNICATION systems, ELECTRIC interference

Abstract

Filter bank multicarrier systems with quadrature amplitude modulation (FBMC/QAM) have drawn attentions to get the advantage of complex symbol transmission, as well as very low out of band radiation and relaxed synchronization requirements for asynchronous scenarios. In order to make this system viable for practical deployment, the biggest challenge is designing appropriate filters to minimize the interference between adjacent subcarriers, while maintaining the Nyquist property of the filter. We show that the deviation from the Nyquist property can be compensated through the fractional shift of the filtered symbols, which provides flexibility to optimize the stopband of the filter. The proposed design method shows advantages over the state of the art designs, and provides guidance for the filter design in practical FBMC/QAM systems. [ABSTRACT FROM AUTHOR]

Published

2018

21. A Multi-Route Cascaded IRSs Beamforming Scheme for mmWave Communication Systems.

Author

Liang, Renjie, Fan, Jiancun, Luo, Jie, and Joung, Jingon

Subjects

TELECOMMUNICATION systems, MILLIMETER waves, BEAMFORMING, SIGNAL-to-noise ratio

Abstract

In this article, to improve the achievable sum-rate of the multi-user millimeter wave (mmWave) communication in densely blocked areas, we design a multi-route multi-hop (MRMH) cascaded intelligent reflecting surface (IRS)-aided system. In our designed system, we aim to maximize the achievable sum-rate for the multiple users by jointly optimizing the phase shifts (PSs) at the multiple IRSs and the active beamforming vector (ABV) at the base station (BS). To achieve this target, we formulate an optimization problem. However, it is non-convex and difficult to be solved. By considering the sparse scattering and near-orthogonality characteristics of the mmWave channels, we divide the optimization problem into multiple tractable sub-problems and obtain a near-optimal solution. The simulation results prove that the proposed scheme has better performance than the existing schemes. Furthermore, we prove the effectiveness of the multi-hop IRS-aided system by comparing the single-hop IRS-aided system. [ABSTRACT FROM AUTHOR]

Published

2022

22. Game Theory-Based Multi-Objective Optimization Interference Alignment Algorithm for HSR 5G Heterogeneous Ultra-Dense Network.

Author

Sheng, Jie, Tang, Ziwen, Wu, Cheng, Ai, Bo, and Wang, Yiming

Subjects

ALGORITHMS, RECURRENT neural networks, TELECOMMUNICATION systems, WIRELESS communications, 5G networks, INTERFERENCE (Telecommunication)

Abstract

The high-speed railway wireless communication network architecture is gradually transforming from a traditional GSM-Railway (GSM-R) cellular network to a 5G heterogeneous ultra-dense communication network. How to effectively deal with the interference while obtaining the capacity gain has become an inevitable problem. This article proposes a power allocation interference alignment algorithm based on game equilibrium with the goal of joint optimization about throughput and energy efficiency for imperfect channels in high-speed railway communication. Firstly, the imperfect Channel State Information including delay and fading is calculated. Then, in order to improve system throughput and energy efficiency, we establish a game model and prove the existence of Nash equilibrium in the model. At the same time, a power allocation iterative algorithm based on Recurrent Neural Network is proposed. Finally, combined with the interference alignment algorithm based on a maximal signal-to-noise ratio, the optimal power matrix is calculated by iteration to achieve interference management optimization. The simulation results prove that our algorithm has superior performance in improving the system throughput, energy efficiency and transmission reliability in high-speed railway wireless communication with imperfect channels. [ABSTRACT FROM AUTHOR]

Published

2020