Your search keyword '"Intercell interference"' showing total 197 results

1. Performance Enhancement of Indoor Cellular Visible Light Communication through Cell Size and Wavelength Reuse Pattern.

Author

Elsayed, Rania A., Diab, Youssef A., Hussein, Khalid F. A., Farahat, Asmaa E. A., and Hamdi, Azhar A.

Subjects

OPTICAL communications, VISIBLE spectra, INTERNET exchange points, CELL size, CELL communication

Abstract

The emerging technology of visible light communication (VLC) has become a promising solution for the requirements of wide-bandwidth, high-speed, and infinite-capacity wireless communication networks. A novel design of high-performance multi-user indoor visible light communication (VLC) based on hexagonal-cell arrangement is introduced in the present paper. The wavelength division multiple access (WDMA) is used to enable multiple users to communicate through the network of access point (APs) by assigning a unique wavelength division channel (WDC) to each user. A wavelength reuse scheme is utilized to increase the maximum number of users in the system and to enhance the VLC system capacity. The on–off keying (OOK) is used as the modulation technique for light signaling. The intercell interference (ICI) caused by the wavelength reuse is evaluated and its dependence on the cell radius and the wavelength reuse pattern size is numerically investigated. Both the received power density and the ICI at the location of the moving user are evaluated and the resulting signal-to-ICI ratio (SICIR) is calculated at every point over the indoor area. The VLC system capacity is evaluated and its dependence on the design parameters including the cell radius, the size of the wavelength reuse pattern, and the user data rate is numerically investigated. A design procedure is proposed to minimize the bit-error rate (BER) resulting from the ICI and to maximize the system capacity and the maximum allowable number of users in the system by selecting the optimal radius of the hexagonal cells and the most appropriate size of the frequency reuse pattern. The effect of the data rate per user on the system capacity is numerically investigated. It is shown that a SICR of greater than 21 dB and BER of less than 1 × 10−15 is achieved. Also, a system capacity of more than 4 bps/Hz is achieved by the application of the proposed VLC design optimization procedure. [ABSTRACT FROM AUTHOR]

Published

2023

2. Fabrication of a Hole‐Type Vertical Resistive‐Switching Random‐Access Array and Intercell Interference Induced by Lateral Charge Spreading.

Author

Kim, Seung Soo, Yong, Soo Kyeom, Kim, Jihun, Choi, Jin Myung, Park, Tae Won, Kim, Hyun Young, Kim, Hae Jin, and Hwang, Cheol Seong

Subjects

NONVOLATILE random-access memory, RECORDS management

Abstract

A hole‐type vertical structure is adopted to fabricate a vertically stacked resistive switching random access memory (ReRAM) array. The vertical configuration is more advantageous in lowering the process cost and increasing integration density than the horizontal configuration. However, the memory cells constituting the hole‐type vertical‐ReRAM (V‐ReRAM) array can be short‐circuited if a middle electrode is introduced to stack a rectifying element onto the memory layer. Thus, a self‐rectifying Pt/Ta2O5/Al‐doped HfO2/TiN ReRAM is adopted in this study to prevent the sneak‐current and short‐circuit issues for efficient operation in vertical crossbar array configuration. A two‐ or three‐layer stacked V‐ReRAM is fabricated, and its electrical characteristics are evaluated. High switching uniformity and sufficiently large memory window and rectification ratio are acquired. The low operation power and high switching uniformity render this V‐ReRAM array suitable for high‐capacity storage devices. However, the on‐state data retention needs improvement. Detailed investigation of the three‐layer stacked device identifies that lateral charge spreading between neighboring cells in the V‐ReRAM causes such a problem, which can be mitigated by increasing the intercell distance. [ABSTRACT FROM AUTHOR]

Published

2023

3. Fabrication of a Hole‐Type Vertical Resistive‐Switching Random‐Access Array and Intercell Interference Induced by Lateral Charge Spreading

Author

Seung Soo Kim, Soo Kyeom Yong, Jihun Kim, Jin Myung Choi, Tae Won Park, Hyun Young Kim, Hae Jin Kim, and Cheol Seong Hwang

Subjects

Al‐doped HfO 2, intercell interference, lateral charge spreading, self‐rectifying memory, vertical resistive switching memory, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4, Physics, QC1-999

Abstract

Abstract A hole‐type vertical structure is adopted to fabricate a vertically stacked resistive switching random access memory (ReRAM) array. The vertical configuration is more advantageous in lowering the process cost and increasing integration density than the horizontal configuration. However, the memory cells constituting the hole‐type vertical‐ReRAM (V‐ReRAM) array can be short‐circuited if a middle electrode is introduced to stack a rectifying element onto the memory layer. Thus, a self‐rectifying Pt/Ta2O5/Al‐doped HfO2/TiN ReRAM is adopted in this study to prevent the sneak‐current and short‐circuit issues for efficient operation in vertical crossbar array configuration. A two‐ or three‐layer stacked V‐ReRAM is fabricated, and its electrical characteristics are evaluated. High switching uniformity and sufficiently large memory window and rectification ratio are acquired. The low operation power and high switching uniformity render this V‐ReRAM array suitable for high‐capacity storage devices. However, the on‐state data retention needs improvement. Detailed investigation of the three‐layer stacked device identifies that lateral charge spreading between neighboring cells in the V‐ReRAM causes such a problem, which can be mitigated by increasing the intercell distance.

Published

2023

4. Meta-Wall: Intelligent Omni-Surfaces Aided Multi-Cell MIMO Communications.

Author

Zhang, Yutong, Di, Boya, Zhang, Hongliang, Han, Zhu, Poor, H. Vincent, and Song, Lingyang

Abstract

Recently, reconfigurable intelligent surfaces (RISs) have been proposed as a novel solution to enhance wireless communications such as suppressing inter-cell interference. However, signals arriving at a conventional reflecting-type RIS can only be reflected towards one side, leading to a limited service coverage, especially in an indoor environment involving potential obstacles. In this paper, we consider an intelligent omni-surface (IOS) which can provide services for users on both sides by enabling simultaneous signal reflection and transmission. Specifically, we propose an IOS aided indoor communication system where an IOS is embedded in a wall between two independent access points (APs) to suppress inter-cell interference. Due to the independence of the APs, we design a distributed hybrid beamforming scheme consisting of digital beamforming at APs and IOS-based analog beamforming to maximize the sum rate without any exchange of channel state information (CSI) between APs. Simulation results indicate that the proposed system performs very close to an optimal centralized scheme, and has a better sum rate performance compared to existing schemes. [ABSTRACT FROM AUTHOR]

Published

2022

5. Delivering more to cell edge via joint multi‐cell non‐orthogonal multiple access and traffic offloading

Author

Yi Zhao, Di Yuan, and Lei You

Subjects

resource allocation, optimisation, nonorthogonal multiple access, telecommunication traffic, intercell interference, iterative decoding, Telecommunication, TK5101-6720

Abstract

Abstract We consider leveraging the joint potential of non‐orthogonal multiple access (NOMA) and traffic offloading to benefit cell‐edge users in multi‐cell scenarios. We formulate the edge‐driven throughput maximisation problem where both the offloading decision and resource allocation are to be optimised, accounting for the impact of the inter‐cell interference on the decoding order in NOMA. The inter‐cell interference is not given constants as it is influenced by resource allocation. Therefore the non‐orthogonal multiple access (NOMA) decoding order is not known a priori. We explore the problem by decomposing it into two subproblems. By analysis of structural properties, we derive algorithm modules which interact iteratively for reciprocity, forming the overall algorithm. Numerical results show that the proposed scheme considerably improves the cell‐edge throughput, compared with the conventional scheme of orthogonal multiple access without traffic offloading.

Published

2021

6. Radio and Energy Resource Management in Renewable Energy-Powered Wireless Networks With Deep Reinforcement Learning.

Author

Lee, Hyun-Suk, Kim, Do-Yup, and Lee, Jang-Won

Abstract

In this paper, we study radio and energy resource management in renewable energy-powered wireless networks, where base stations (BSs) are powered by both on-grid and renewable energy sources and can share their harvested energy with each other. To efficiently manage those resources, we propose a hierarchical and distributed resource management framework based on deep reinforcement learning. The proposed framework minimizes the on-grid energy consumption while satisfying the data rate requirement of each user. It is composed of three different policies in a distributed and hierarchical way. An intercell interference coordination policy constrains the transmission power at each BS to coordinate the intercell interference among the BSs. Under the power constraints, a distributed radio resource allocation policy of each BS determines its own user scheduling and power control. Lastly, an energy sharing policy manages the energy resources of the BSs by sharing the harvested energy via power lines between them. Through the simulation, we demonstrate that the proposed framework can effectively reduce the on-grid energy consumption while satisfying the data rate requirements. [ABSTRACT FROM AUTHOR]

Published

2022

7. ML and MAP Device Activity Detections for Grant-Free Massive Access in Multi-Cell Networks.

Author

Jiang, Dongdong and Cui, Ying

Abstract

Device activity detection is one main challenge in grant-free massive access, which is recently proposed to support massive machine-type communications (mMTC). Existing solutions for device activity detection fail to consider inter-cell interference generated by massive IoT devices or important prior information on device activities and inter-cell interference. In this paper, given different numbers of observations and network parameters, we consider both non-cooperative device activity detection and cooperative device activity detection in a multi-cell network, consisting of many access points (APs) and IoT devices. Under each activity detection mechanism, we consider the joint maximum likelihood (ML) estimation and joint maximum a posterior probability (MAP) estimation of both device activities and interference powers, utilizing tools from probability, stochastic geometry, and optimization. Each estimation problem is a challenging non-convex problem, and a coordinate descent algorithm is proposed to obtain a stationary point. Each proposed joint ML estimation extends the existing one for a single-cell network by considering the estimation of interference powers, together with the estimation of device activities. Each proposed joint MAP estimation further enhances the corresponding joint ML estimation by exploiting prior distributions of device activities and interference powers. The proposed joint ML estimation and joint MAP estimation under cooperative detection outperform the respective ones under non-cooperative detection at the costs of increasing backhaul burden, knowledge of network parameters, and computational complexities. Numerical results show the substantial gains of the proposed designs over well-known existing designs and reveal the importance of explicit consideration of inter-cell interference, the value of prior information, and the advantage of AP cooperation in device activity detection. [ABSTRACT FROM AUTHOR]

Published

2022

8. Robust Optimization of Instantaneous Beamforming and Quasi-Static Phase Shifts in an IRS-Assisted Multi-Cell Network.

Author

Jia, Yuhang, Cui, Ying, and Jiang, Wuyang

Abstract

The impacts of channel estimation errors, inter-cell interference, phase adjustment cost, and computation cost on an intelligent reflecting surface (IRS)-assisted system are severe in practice but have been ignored for simplicity in most existing works. In this paper, we investigate a multi-antenna base station (BS) serving a single-antenna user with the help of a multi-element IRS in a multi-cell network with inter-cell interference. We consider imperfect channel state information (CSI) at the BS, i.e., imperfect CSIT, and focus on the robust optimization of the BS’s instantaneous CSI-adaptive beamforming and the IRS’s quasi-static phase shifts in two scenarios. In the scenario of coding over many slots, we formulate a robust optimization problem to maximize the user’s ergodic rate. In the scenario of coding within each slot, we formulate a robust optimization problem to maximize the user’s average goodput under the successful transmission probability constraints. The robust optimization problems are challenging two-timescale stochastic non-convex problems. In both scenarios, we obtain closed-form robust beamforming designs for any given phase shifts and more tractable stochastic non-convex approximate problems only for the phase shifts. Besides, we propose an iterative algorithm to obtain a Karush-Kuhn-Tucker (KKT) point of each of the stochastic problems for the phase shifts. It is worth noting that the proposed methods offer closed-form robust instantaneous CSI-adaptive beamforming designs which can promptly adapt to rapid CSI changes over slots and robust quasi-static phase shift designs of low computation and phase adjustment costs in the presence of imperfect CSIT and inter-cell interference. Numerical results further demonstrate the notable gains of the proposed robust joint designs over existing ones and reveal the practical values of the proposed solutions. [ABSTRACT FROM AUTHOR]

Published

2022

9. Hybrid NOMA in Multi-Cell Networks: From a Centralized Analysis to Practical Schemes.

Author

Hussein, Abdalla, Rosenberg, Catherine, and Mitran, Patrick

Subjects

MODULATION coding, RADIO access networks, SIGNAL-to-noise ratio

Abstract

We investigate the performance of a hybrid non-orthogonal multiple access (NOMA) multi-cell downlink system (called hybrid as different users can have different successive interference cancellation (SIC) capabilities) by first formulating and solving a centralized proportional fair scheduling genie-assisted problem that jointly performs user selection, power allocation, power distribution, and modulation and coding scheme (MCS) selection. While such a genie is practically infeasible, it upper bounds the achievable performance. The results indicate that hybrid NOMA with a maximum of 2 multiplexed users can bring significant gains over a traditional OMA system (as long as enough users have the maximum SIC capability). Additionally, results show that the simple equal power allocation scheme (often used in the literature) yields performance lower than half the upper bound. Thus, we propose a simple static coordinated power allocation scheme across all cells for NOMA using a simple power map that is easily calibrated offline and show that with the calibrated power map, performance improves by 80%. Finally, we focus on the online scenario and propose a family of practical scheduling algorithms, each of them exhibiting a different trade-off between complexity (i.e., run-time) and performance. [ABSTRACT FROM AUTHOR]

Published

2022

10. Data, User and Power Allocations for Caching in Multi-Access Edge Computing.

Author

Xia, Xiaoyu, Chen, Feifei, He, Qiang, Cui, Guangming, Grundy, John C., Abdelrazek, Mohamed, Xu, Xiaolong, and Jin, Hai

Subjects

*EDGE computing, *NASH equilibrium, *INFORMATION retrieval, *ALLOCATION (Accounting), *VENDOR-managed inventory

Abstract

In the multi-access edge computing (MEC) environment, app vendors’ data can be cached on edge servers to ensure low-latency data retrieval. Massive users can simultaneously access edge servers with high data rates through flexible allocations of transmit power. The ability to manage networking resources offers unique opportunities to app vendors but also raises unprecedented challenges. To ensure fast data retrieval for users in the MEC environment, edge data caching must take into account the allocations of data, users, and transmit power jointly. We make the first attempt to study the Data, User, and Power Allocation (DUPA $^3$ 3 ) problem, aiming to serve the most users and maximize their overall data rate. First, we formulate the DUPA $^3$ 3 problem and prove its $\mathcal {NP}$ NP -completeness. Then, we model the DUPA $^3$ 3 problem as a potential DUPA $^3$ 3 game admitting at least one Nash equilibrium and propose a two-phase game-theoretic decentralized algorithm named DUPA $^3$ 3 Game to achieve the Nash equilibrium as the solution to the DUPA $^3$ 3 problem. To evaluate DUPA $^3$ 3 Game, we analyze its theoretical performance and conduct extensive experiments to demonstrate its effectiveness and efficiency. [ABSTRACT FROM AUTHOR]

Published

2022

11. Opportunistic Temporal Fair Mode Selection and User Scheduling in Full-Duplex Systems.

Author

Shahsavari, Shahram, Shirani, Farhad, Khojastepour, Mohammad Ali, and Erkip, Elza

Subjects

SCHEDULING, RESOURCE allocation, ONLINE algorithms

Abstract

In-band full-duplex (FD) communication has emerged as one of the promising techniques to improve data rates in next generation wireless systems. Typical FD scenarios considered in the literature assume FD base stations (BSs) and half-duplex (HD) users activated either in uplink (UL) or downlink (DL), where inter-user interference (IUI) is treated as noise at the DL user. This paper considers more general FD scenarios where an arbitrary fraction of the users are capable of FD and/or they can perform successive interference cancellation (SIC) to mitigate IUI. Consequently, one user can be activated in either UL or DL (HD-UL and HD-DL modes), or simultaneously in both directions requiring self-interference mitigation (SIM) at that user (FD-SIM mode). Furthermore, two users can be scheduled, one in UL and the other in DL (both operating in HD), where the DL user can treat IUI as noise (FD-IN mode) or perform SIC to mitigate IUI (FD-SIC mode). This paper studies opportunistic mode selection and user scheduling under long-term and short-term temporal fairness in single-carrier and multi-carrier (OFDM) FD systems, with the goal of maximizing system utility (e.g. sum-rate). First, the feasible region of temporal demands is characterized for both long-term and short-term fairness. Subsequently, optimal temporal fair schedulers as well as practical low-complexity online algorithms are devised. Simulation results demonstrate that using SIC to mitigate IUI as well as having FD capability at users can improve FD throughput gains significantly especially, when user distribution is concentrated around a few hotspots. [ABSTRACT FROM AUTHOR]

Published

2022

12. Experimental Assessment of New Generation Radio Networks Based on Layered Division Multiplexing.

Author

Martinez Alonso, Rodney, Plets, David, Deruyck, Margot, Martens, Luc, Nieto, Glauco Guillen, and Joseph, Wout

Subjects

*MULTICASTING (Computer networks), *RADIO networks, *MULTIPLEXING, *COMMUNICATION infrastructure, *NETWORK performance, *QUALITY of service

Abstract

Despite the recent advances in broadband penetration and accessibility, broadcasting networks continue to be the most efficient way for delivering media content to large areas independently of the user density. Nevertheless, a convergence of broadcasting services into the broadband networks is foreseen. In this context, Layered Division Multiplexing (LDM) allows the joint provision of unicast, multicast, and broadcast services in mobile cells infrastructure. Despite the success of LDM in broadcasting infrastructure, its practical application in Long Term Evolution networks providing Evolved Multimedia Broadcast Multicast Services (LTE eMBMS) and 5G-MBMS is more difficult. In this paper, we experimentally quantify the cell-interference and its impact on the network performance and Quality of Service. Our experiments reveal that the inter-cell interference margin for LTE eMBMS is about 3 dB higher compared to traditional LTE networks. If a layered architecture is incorporated this higher inter-cell interference would cause a reduction of approximately 19% of the Enhanced Layer (Lower Layer) coverage. [ABSTRACT FROM AUTHOR]

Published

2022

13. User-Number Threshold-Based Base Station On/Off Control for Maximizing Coverage Probability.

Author

Noh, Jung-Hoon, Lee, Byungju, and Oh, Seong-Jun

Subjects

*STOCHASTIC control theory, *PROBABILITY theory, *GEOMETRIC approach, *POISSON processes, *SIGNAL-to-noise ratio

Abstract

In this study, we investigate the operation of a user-number threshold-based base station (BS) on/off control, in which the BS turns off when the number of users is less than a specific threshold value. This paper presents a space-based analysis of the BS on/off control system to which a stochastic geometric approach is applied. In particular, we derive the approximated closed-form expression of the coverage probability of a homogeneous network (HomNet) with the user-number threshold-based BS on/off control. Moreover, the optimal user-number threshold for maximizing coverage probability is analytically derived. In addition to HomNet, we also derive the approximated closed-form expression of the coverage probability and the optimal user-number thresholds for a heterogeneous network (HetNet). The results show that HetNet, the analysis of which seems intractable, can be analyzed in the form of a linear combination of HomNets with weighted densities. In addition, the optimal user-number threshold of each tier is obtained independently from other tiers. The modeling and analysis presented in this paper are not only limited to the case of user-number threshold-based on/off control, but also applicable to other novel on/off controls with minor modifications. Finally, by comparing the analytical results with the simulated results, the theoretical contributions of this study are validated. [ABSTRACT FROM AUTHOR]

Published

2022

14. Performance Analysis of Inter-Cell Interference Coordination in mm-Wave Cellular Networks.

Author

Wei, Haichao, Deng, Na, and Haenggi, Martin

Abstract

In millimeter-wave (mm-wave) cellular networks, directional antenna arrays are typically adopted to mitigate the severe propagation loss. However, the interference caused by such highly directional beams may, in turn, result in a significant number of transmission failures, especially for dense networks. To tackle this problem, we propose two inter-cell interference coordination (ICIC) schemes in mm-wave bands: one is merely based on the path loss incorporating the blockage effect (PL-ICIC); the other considers both path loss and directivity gain (PG-ICIC). To fully investigate both schemes, we first derive an exact expression for the success probability (reliability) of the typical (served) user. We further provide an asymptotic analysis for the success probability and propose an effective approximation based on the asymptotic signal-to-interference ratio (SIR) gain relative to no ICIC. Secondly, to incorporate the cost of ICIC schemes, we derive the approximate normalized throughput taking into account that some users cannot be served due to limited resources. Numerical results show that the two proposed schemes provide significant reliability improvements in the low-SIR regime, and the higher the number of antennas, the wider the SIR range for which there is an improvement. In addition, compared with PL-ICIC, PG-ICIC balances the available resources among all users well. [ABSTRACT FROM AUTHOR]

Published

2022

15. A Joint Design for STAR-RIS Enhanced NOMA-CoMP Networks: A Simultaneous-Signal-Enhancement-and-Cancellation-Based (SSECB) Design.

Author

Hou, Tianwei, Wang, Jun, Liu, Yuanwei, Sun, Xin, Li, Anna, and Ai, Bo

Subjects

*RECEIVING antennas, *ARRAY processing

Abstract

In this correspondence, a novel simultaneous transmitting and reflecting (STAR) reconfigurable intelligent surfaces (RISs) design is proposed in a non-orthogonal multiple access (NOMA) enhanced coordinated multi-point transmission (CoMP) network. Based on the insights of signal-enhancement-based (SEB) and signal-cancellation-based (SCB) designs, we propose a novel simultaneous-signal-enhancement-and-cancellation-based (SSECB) design, where the inter-cell interferences and desired signals can be simultaneously eliminated and boosted. Our simulation results demonstrate that: i) the inter-cell interference can be perfectly eliminated, and the desired signals can be enhanced simultaneously with the aid of a large number of RIS elements; ii) the proposed SSECB design is capable of outperforming the conventional SEB and SCB designs. [ABSTRACT FROM AUTHOR]

Published

2022

16. QoS-Aware User Grouping Strategy for Downlink Multi-Cell NOMA Systems.

Author

Guo, Fengqian, Lu, Hancheng, Jiang, Xiaoda, Zhang, Ming, Wu, Jun, and Chen, Chang Wen

Abstract

In multi-cell non-orthogonal multiple access (NOMA) systems, designing an appropriate user grouping strategy is an open problem due to diverse quality of service (QoS) requirements and inter-cell interference. In this paper, we exploit both game theory and graph theory to study QoS-aware user grouping strategies, aiming at minimizing power consumption in downlink multi-cell NOMA systems. Under different QoS requirements, we derive the optimal successive interference cancellation (SIC) decoding order with inter-cell interference, which is different from existing SIC decoding order of increasing channel gains, and obtain the corresponding power allocation strategy. Based on this, the exact potential game model of the user grouping strategies adopted by multiple cells is formulated. We prove that, in this game, the problem for each player to find a grouping strategy can be converted into the problem of searching for specific negative loops in the graph composed of users. Bellman-Ford algorithm is expanded to find these negative loops. Furthermore, we design a greedy based suboptimal strategy to approach the optimal solution with polynomial time. Extensive simulations confirm the effectiveness of grouping users with consideration of QoS and inter-cell interference, and show that the proposed strategies can considerably reduce total power consumption comparing with reference strategies. [ABSTRACT FROM AUTHOR]

Published

2021

17. Self-Imitation Learning-Based Inter-Cell Interference Coordination in Autonomous HetNets.

Author

Yan, Mu, Yang, Jian, Chen, Keyu, Sun, Yao, and Feng, Gang

Abstract

Recently, mobile operators have been shifting to an intelligent autonomous network paradigm, where the mobile networks are automated in a plug-and-play manner to reduce the manual intervention. Under this circumstance, serious inter-cell interference becomes inevitable which may severely deteriorate system throughput performance and users’ quality of service (QoS), especially for dense residential small base station (SBS) deployment. This paper proposes an intelligent inter-cell interference coordination (ICIC) scheme for autonomous heterogeneous networks (HetNets), where the SBSs agilely schedule sub-channels to individual users at each Transmit Time Interval (TTI) with aim of mitigating interferences and maximizing long-term throughput by sensing the environment. Since the reward function is inexplicit and only few samples can be used for prior-training, we formulate the ICIC problem as a distributed inverse reinforcement learning (IRL) problem following the POMDP games. We propose a non-prior knowledge based self-imitating learning (SIL) algorithm which incorporates Wasserstein Generative Adversarial Networks (WGANs) and Double Deep Q Network (Double DQN) algorithms for performing behavior imitation and few-shot learning in solving the IRL problem from both the policy and value. Numerical results reveal that SIL is able to implement TTI level’s decision-making to solve the ICIC problem, and the overall network throughput of SIL can be improved by up to 19.8% when compared with other known benchmark algorithms. [ABSTRACT FROM AUTHOR]

Published

2021

18. Sparse Activity Detection in Multi-Cell Massive MIMO Exploiting Channel Large-Scale Fading.

Author

Chen, Zhilin, Sohrabi, Foad, and Yu, Wei

Subjects

*MIMO systems, *COVARIANCE matrices, *PHASE transitions, *COMPUTER architecture

Abstract

This paper studies the device activity detection problem in a multi-cell massive multiple-input multiple-output (MIMO) system, in which the active devices transmit signature sequences to multiple base stations (BSs) that are connected to a central unit (CU), and the BSs cooperate across multiple cells to detect the active devices based on the sample covariance matrices at the BSs. This paper demonstrates the importance of exploiting the knowledge of channel large-scale fadings in this cooperative detection setting through a phase transition analysis, which characterizes the length of signature sequences needed for successful device activity detection in the massive MIMO regime. It is shown that when the large-scale fadings are known, the phase transition for the multi-cell scenario is approximately the same as that of a single-cell system. In this case, the length of the signature sequences required for reliable activity detection in the multi-cell system can be made to be independent of the number of cells through cooperation, in contrast to the case where the large-scale fadings are not known. Further, this paper considers the case in which the fronthaul links between the BSs and the CU have capacity constraints and proposes a novel cooperation scheme based on the quantization of preliminary detection results at the BSs and the reconstruction of the sample covariance matrices at the CU. Simulations show that the proposed method significantly outperforms the scheme of directly quantizing the sample covariance matrices. [ABSTRACT FROM AUTHOR]

Published

2021

19. Deep Reinforcement Learning-Based Hierarchical Time Division Duplexing Control for Dense Wireless and Mobile Networks.

Author

Tuong, Van Dat, Dao, Nhu-Ngoc, Noh, Wonjong, and Cho, Sungrae

Abstract

Future wireless and mobile network services must accommodate highly dynamic downlink and uplink traffic asymmetry. To fulfill this requirement, the third-generation partnership project (3GPP) introduced the enhanced interference mitigation and traffic adaptation strategy in addition to dynamic time division duplexing (TDD). In this study, we develop a reinforcement learning (RL)-based dynamic TDD framework that effectively controls interference and serves various traffic demands. First, we introduce an interference-penalty model that evaluates interference indirectly based on the duplexing policy. This can significantly reduce overhead for measuring and exchanging channel information in a dense network. Second, we design a new mixed-reward model that consists of the achievable data rate and the implicit interference penalty. Third, we implement deep RL algorithms that base station (BSs) use to train their radio frame configurations (RFCs). The training process at each BS takes into account the traffic demand and the RFCs of the surrounding BSs. The BSs are coordinated in a single-leader multi-follower Stackelberg game, which achieves a global RFC setup that maximizes the data rate and minimizes the interference. Extensive simulations show that the proposed framework stably converges in various environments and provides near-optimal performance equivalent to 95% or more of the full-search-based optimal performance, which is 48.84%, 41.92%, and 62.11% higher than the currently utilized random RFC, fixed RFC, and traffic-matched RFC approaches. [ABSTRACT FROM AUTHOR]

Published

2021

20. Cellular Networks With Finite Precision CSIT: GDoF Optimality of Multi-Cell TIN and Extremal Gains of Multi-Cell Cooperation.

Author

Joudeh, Hamdi and Caire, Giuseppe

Subjects

*TRANSMITTERS (Communication), *BROADCAST channels, *TIN, *FINITE, The, *COOPERATION

Abstract

We study the generalized degrees-of-freedom (GDoF) of cellular networks under finite precision channel state information at the transmitters (CSIT). We consider downlink settings modeled by the interfering broadcast channel (IBC) under no multi-cell cooperation, and the overloaded multiple-input-single-output broadcast channel (MISO-BC) under full multi-cell cooperation. We focus on three regimes of interest: the mc-TIN regime, where a scheme based on treating inter-cell interference as noise (mc-TIN) was shown to be GDoF optimal for the IBC; the mc-CTIN regime, where the GDoF region achievable by mc-TIN is convex without the need for time-sharing; and the mc-SLS regime which extends a previously identified regime, where a simple layered superposition (SLS) scheme is optimal for the 3-transmitter-3-user MISO-BC, to overloaded cellular-type networks with more users than transmitters. We first show that the optimality of mc-TIN for the IBC extends to the entire mc-CTIN regime when CSIT is limited to finite precision. The converse proof of this result relies on a new application of aligned images bounds. We then extend the IBC converse proof to the counterpart overloaded MISO-BC, obtained by enabling full transmitter cooperation. This, in turn, is utilized to show that a multi-cell variant of the SLS scheme is optimal in the mc-SLS regime under full multi-cell cooperation, albeit only for 2-cell networks. The overwhelming combinatorial complexity of the GDoF region stands in the way of extending this result to larger networks. Alternatively, we appeal to extremal network analysis, recently introduced by Chan et al., and study the GDoF gain of multi-cell cooperation over mc-TIN in the three regimes of interest. We show that this extremal GDoF gain is bounded by small constants in the mc-TIN and mc-CTIN regimes, yet scales logarithmically with the number of cells in the mc-SLS regime. [ABSTRACT FROM AUTHOR]

Published

2021

21. Asymptotic Performance Analysis of MMSE Receivers in Multicell MU-MIMO Systems.

Author

Fu, Hua, Roy, Sebastien, and Peng, Linning

Subjects

*SYMBOL error rate, *MINI-Mental State Examination, *STATISTICS, *MULTIUSER computer systems, *ANTENNA arrays, *MIMO systems

Abstract

For large-scale antenna array multiple-input multiple-output (MIMO) systems, a typical solution often put forward for uplink detection consists in applying low-complexity linear receivers such as zero-forcing (ZF) and minimum mean-square error (MMSE) combiners. In this paper, the performance of uplink MMSE detection has been analyzed in the context of a multi-cell multiuser MIMO system. An approximate expression for the signal-to-interference-plus-noise ratio (SINR) is proposed, which is in simple form and becomes exact in the low SNR regime. This approximate SINR applies to systems where the base station (BS) has the statistical information of the out-of-cell interfering signals, and systems where the BS ignores the presence of such interfering signals. This approximate SINR is tight for arbitrary user powers, arbitrary number of antennas at the base station, and arbitrary channel correlation matrix associated with any particular user. Approximate expressions for capacity and bit-error rate/symbol-error rate have also been derived. Particularly, it can be proven that, when the MMSE receiver ignores the presence of out-of-cell interfering signals, the performance gap between ZF and MMSE vanishes in the high SNR regime. [ABSTRACT FROM AUTHOR]

Published

2021

22. On Lattice Packings and Coverings of Asymmetric Limited-Magnitude Balls.

Author

Wei, Hengjia, Wang, Xin, and Schwartz, Moshe

Subjects

*HAMMING codes, *ERROR-correcting codes, *INTEGERS, *ARITHMETIC series, *NONVOLATILE memory

Abstract

We construct integer error-correcting codes and covering codes for the limited-magnitude error channel with more than one error. The codes are lattices that pack or cover the space with the appropriate error ball. Some of the constructions attain an asymptotic packing/covering density that is constant. The results are obtained via various methods, including the use of codes in the Hamming metric, modular Bt-sequences, 2-fold Sidon sets, and sets avoiding arithmetic progression. [ABSTRACT FROM AUTHOR]

Published

2021

23. Multi-Layer Interference Alignment and GDoF of the K-User Asymmetric Interference Channel.

Author

Chen, Jinyuan

Subjects

*INTERFERENCE channels (Telecommunications), *GEOMETRIC series, *SIGNAL-to-noise ratio

Abstract

In wireless networks, link strengths are often affected by some topological factors such as propagation path loss, shadowing and inter-cell interference. Thus, different users in the network might experience different link strengths. In this work we consider a K-user asymmetric interference channel, where the channel gains of the links connected to Receiver k are scaled with √Pαk, k = 1,2, ⋅⋅⋅ , K , for 0 < α1 ≤ α2 ≤ ⋅⋅⋅ ≤ αK. For this setting, we show that the optimal sum generalized degrees-of-freedom (GDoF) is characterized as dsum = ∑k=1K αk + αK− αK−1/2 which matches the existing result d∑ = K/2 when α1 = α2 = ⋅⋅⋅ = αK = 1. The achievability is based on multi-layer interference alignment, where different interference alignment sub-schemes are designed in different layers associated with specific power levels, and successive decoding is applied at the receivers. While the converse for the symmetric case only requires bounding the sum degrees-of-freedom (DoF) for selected two users, the converse for this asymmetric case involves bounding the weighted sum GDoF for selected J + 2 users, with corresponding weights (2J, 2J−1, ⋅⋅⋅ , 22, 21), a geometric sequence with common ratio 2, for the first J users and with corresponding weights (1, 1) for the last two users, for J ∈ {1,2, ⋅⋅⋅ , ⌈log K/2⌉. [ABSTRACT FROM AUTHOR]

Published

2021

24. Shifted 2-N-PSK Method for the Detection of Pilot Contamination Attacks.

Author

Mihaylova, Dimitriya, Valkova-Jarvis, Zlatka, Iliev, Georgi, and Poulkov, Vladimir

Subjects

MIMO systems, WIRELESS communications

Abstract

One major security problem at the physical layer of a wireless system is its vulnerability to pilot contamination attacks. A potential method for the detection of such active attacks involves training with two N-PSK pilots which however suffers from operational problems. In this paper we propose and evaluate the Shifted 2-N-PSK technique as an improvement on the original method. The Shifted 2-N-PSK method operates with two pilots from different constellations, each of which is shifted from the original N-PSK constellation. The performance of three variations of Shifted 2-N-PSK is presented and the most effective implementation of the technique is revealed to be when neither the shift values nor the difference between them equal an N-PSK angle. Experimental results are also provided, in order to confirm the theoretical estimates. In addition, a detailed analysis of the shift values and the number of their optimal combinations are presented for different accuracies. [ABSTRACT FROM AUTHOR]

Published

2021

25. Cloud RAN

Author

Vaezi, Mojtaba, Zhang, Ying, Shen, Xuemin Sherman, Series editor, Vaezi, Mojtaba, and Zhang, Ying

Published

2017

26. Distributed Dual Optimization for the Uplink of Multi-Cell NOMA.

Author

Sung, Chi Wan, Chen, Yi, and Gu, Yuxuan

Subjects

*DISTRIBUTED algorithms, *RANDOM noise theory, *POWER transmission, *INTERFERENCE channels (Telecommunications), *COMPUTER simulation, *GEOMETRY

Abstract

This paper studies distributed power control for the uplink of multi-cell non-orthogonal multiple access (NOMA) systems. Within a cell, the transmissions of different users are modeled as a Gaussian multiple access channel, treating inter-cell interference as additive Gaussian noise. By analyzing the geometry of the feasible power region, using successive interference cancellation at each base station is proved to be optimal in minimizing the total transmission power of all users under rate constraints. The decoding order at each base station, however, remains to be determined. If the decoding order is decided without base station cooperation, the overall control algorithm is fully distributed but is suboptimal in general. To achieve optimality, a partially distributed algorithm is designed, which requires base stations to exchange control messages. Given any feasible instance, the algorithm is proved to converge to the optimal solution. The performance of the fully distributed and partially distributed power control algorithms is compared by computer simulations. The fully distributed algorithm is nearly optimal in terms of outage probability. When a high data rate is required, the partially distributed algorithm is able to reduce the total power consumption by about 20%. [ABSTRACT FROM AUTHOR]

Published

2021

27. Performance Analysis of Indoor mmWave Networks With Ceiling-Mounted Access Points.

Author

Firyaguna, Fadhil, Kibilda, Jacek, Galiotto, Carlo, and Marchetti, Nicola

Subjects

INTERNET exchange points, DIRECTIONAL antennas, NETWORK hubs, 5G networks, HUMAN body

Abstract

The objective of the Enhanced Mobile Broadband use case in 5G networks is to deliver high capacity access to densely populated areas, like city centres, transportation hubs or convention centres. Millimetre-wave communications are the go-to technology to realise that objective, yet due to weak outdoor-to-indoor penetration, outdoor deployments will not suffice and dedicated indoor deployments will be necessary. In this article, we study dense deployments of millimetre-wave access points mounted on the ceiling, with directional antennas pointing downwards to illuminate selected spots on the ground. In this setup, the signal propagation is primarily limited by human body blockages. Therefore, we develop a body blockage model and derive an expression for the probability of blockage. Using the developed expressions and our simulation framework, we assess the impact of densification and body blockage on the achievable performance. We find that both coverage and area spectral efficiency curves exhibit non-trivial behaviour with respect to the access point density and that there is an optimal beamwidth-density configuration that only maximises either coverage or area spectral efficiency. Such optimal configuration changes depending on the body blockage probability, leading to a necessity for network designers to carefully consider their intended application and scenario. [ABSTRACT FROM AUTHOR]

Published

2021

28. Multi-Level Sequence-Based Frequency-Hopping in Multi-Cell Networks.

Author

Zeng, Qi, Liu, Xing, and Du, Pengfei

Subjects

*QUALITY of service, *WIRELESS communications

Abstract

In heterogeneous multi-cell networks (HetNets), inter-and intra-cell interference are critical issues impairing the performance. In this paper, the frequency-hopping (FH) technique based on an attractive FH sequence (FHS) set with two-level Hamming correlations is exploited in such networks. Motivating from the idea of no-and low-hit-zone FHS sets, a construction algorithm of the new FHS set is proposed by utilizing the interleaving technique. Then, the performance metric of such FHS set in terms of Hamming correlation properties are derived, which are verified by an example. Compared with classic FHS sets (patterns), the proposed FHS set offers a zero Hamming cross-correlation for intra-cell users, and a low Hamming cross-correlation for inter-cell users (i.e., multi-level quality-of-services). The intra-and inter-interference in multi-cell HetNets can be significantly reduced by the proposed sequence-based FH technique. [ABSTRACT FROM AUTHOR]

Published

2021

29. Energy-Efficient Multi-Cell Massive MIMO Subject to Minimum User-Rate Constraints.

Author

Nguyen, Long Dinh, Tuan, Hoang Duong, Duong, Trung Q., Poor, H. Vincent, and Hanzo, Lajos

Subjects

*MIMO systems, *TRANSMITTING antennas, *SIGNAL processing, *ARRAY processing, *BEAMFORMING, *MAXIMA & minima

Abstract

The capability of massive multiple-input multiple-output (mMIMO) systems supporting the throughput requirement of as many users as possible is investigated. The bottleneck of serving small numbers of users by a large number of transmit antennas in conventional mMIMO is unblocked by a new time-fraction-wise beamforming technique, which focuses signal transmission in fractions of a time slot. Based on this time-fraction-wise signal transmission, a new user service scheduling scheme for multi-cell mMIMO, whose cell-edge users suffer not only poor channel conditions but also multi-cell interference, is proposed to support a large user-population. We demonstrate that the numbers of users served by our multi-cell mMIMO within a time-slot may be as high as twice the number of its transmit antennas. [ABSTRACT FROM AUTHOR]

Published

2021

30. Extending the Welch Bound: Non-Orthogonal Pilot Sequence Design for Two-Cell Interference Networks.

Author

Wang, Ji, Sun, Jun, Wang, Xiaodong, Yang, Kai, and Liu, Yingzhuang

Abstract

Interferences due to non-orthogonality of signals usually exist in wireless networks when the number of users is larger than the sequence length, such as non-orthogonality of the pilots in multi-cell systems and non-orthogonality of the signature sequences in overloaded code-division-multiple-access (CDMA) systems. We address this effect from the perspective of non-orthogonal sequence design in a two-cell multiple-antenna network. Specifically, we aim at designing pilot sequences to minimize the sum mean-squared-error (MSE) of channel estimation with a given sequence length $\tau $ where $\tau \in [K,2K]$ and $K$ is the number of users per cell. Considering the strength disparity between channels originating from the home cell and the neighbor cell, this problem boils down to minimizing the sum of squares of weighted correlations among sequences, whose lower bound is obtained in closed form and can be regarded as a generalization of the well-known Welch bound (Welch, 1974). We prove this extended Welch bound is achievable, and design an algorithm based on the Davies-Higham method to generate the interference-minimizing sequences. Three fundamental properties of the proposed sequences are presented. Finally, we derive closed-form expressions of the average signal-to-interference-plus-noise-ratio (SINR) and rate for data transmission, based on which the optimal training duration can be found. [ABSTRACT FROM AUTHOR]

Published

2021

31. Multi‐user two‐way relaying in the presence of co‐channel interference.

Author

Ozduran, Volkan and Soleimani‐Nasab, Ehsan

Abstract

This study investigates the impact of co‐channel interference caused by external terminals on multi‐user bi‐directional amplify‐and‐forward based wireless relaying network. The investigation considers multi‐user pair and a single bi‐directional relay terminal and a finite number of co‐channel interference in the system model. A lower bound on the end‐to‐end outage probability is derived for the simultaneous transmission and the opportunistic source‐pair selection strategy. According to analytical, asymptotic, and Monte‐Carlo based computer simulation results, the opportunistic source‐pair selection strategy achieves a near‐optimal performance for the inter‐cell interference caused by other user‐pairs within the system. Results also show that the opportunistic source‐pair selection strategy also achieves optimal diversity order, which is equal to N, in high signal‐to‐noise ratio regimes. Results also show that the co‐channel interference degrades the achievable diversity order from N to 0 while also affecting the system coding gain. [ABSTRACT FROM AUTHOR]

Published

2020

32. Energy-Efficient 3-D Deployment of Aerial Access Points in a UAV Communication System.

Author

Babu, Nithin, Papadias, Constantinos B., and Popovski, Petar

Abstract

In this letter, we propose an energy-efficient 3-dimensional placement of multiple aerial access points (AAPs), in the desired area, acting as flying base stations for uplink communication from a set of ground user equipment (UE). The globally optimal energy-efficient vertical position of AAPs is derived analytically by considering the inter-cell interference and AAP energy consumption. The horizontal position of AAPs, which maximize the packing density of the AAP coverage area, are determined using a novel regular polygon-based AAP placement algorithm. We also determine an accurate upper bound on the maximum number of AAPs that could be deployed in a given circular area. The effect of the AAP energy consumption on the optimal placement and the analytic findings are verified via numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2020

33. On the Optimality of Treating Inter-Cell Interference as Noise: Downlink Cellular Networks and Uplink-Downlink Duality.

Author

Joudeh, Hamdi, Yi, Xinping, Clerckx, Bruno, and Caire, Giuseppe

Subjects

*GAUSSIAN channels, *BROADCAST channels, *NOISE, *IMAC (Computer), *TIN

Abstract

We consider the information-theoretic optimality of treating inter-cell interference as noise (multi-cell TIN) in downlink cellular networks. We focus on scenarios modeled by the Gaussian interfering broadcast channel (IBC), comprising $K$ mutually interfering Gaussian broadcast channels (BCs), each formed by a base station communicating independent messages to an arbitrary number of users. We establish a new power allocation duality between the IBC and its dual interfering multiple access channel (IMAC), which entails that the corresponding generalized degrees-of-freedom regions achieved through multi-cell TIN and power control (TINA regions) for both networks are identical. As by-products of this duality, we obtain an explicit characterization of the IBC TINA region from a previously established characterization of the IMAC TINA region; and identify a multi-cell convex-TIN regime in which the IBC TINA region is a polyhedron (hence convex) without the need for time-sharing. We then identify a smaller multi-cell TIN regime in which the IBC TINA region is optimal and multi-cell TIN achieves the entire capacity region of the IBC, up to a constant gap. This is accomplished by deriving a new genie-aided outer bound for the IBC, that reveals a novel BC-type order that holds amongst users in each constituent BC (or cell) under inter-cell interference, which in turn is not implied by previously known BC-type orders (i.e. degraded, less noisy and more capable orders). The multi-cell TIN regime that we identify for the IBC coincides with a corresponding multi-cell TIN regime previously identified for the IMAC, hence establishing a comprehensive uplink-downlink duality of multi-cell TIN in the GDoF (and approximate capacity) sense. [ABSTRACT FROM AUTHOR]

Published

2020

34. Deep Reinforcement Learning for Distributed Dynamic MISO Downlink-Beamforming Coordination.

Author

Ge, Jungang, Liang, Ying-Chang, Joung, Jingon, and Sun, Sumei

Subjects

*REINFORCEMENT learning, *DEEP learning, *MISO, *MIMO systems, *FRACTIONAL programming, *ALGORITHMS, *TRANSMITTERS (Communication)

Abstract

We consider a homogeneous cellular network where a multi-antenna base station (BS) in each cell transmits messages to its intended user over a common frequency band. To improve the system capacity of this multi-cell multi-input single-output (MISO) interference channel, one of the state-of-the-art algorithms, namely, downlink-beamforming coordination, allows all BSs to cooperate with one another to mitigate the effect of inter-cell interference. However, most existing algorithms are suboptimal and impractical in a dynamic wireless environment, due to the high computational complexity and the overhead involved in collecting global channel state information (CSI). In this study, we exploit deep reinforcement learning (DRL) and propose a distributed dynamic downlink-beamforming coordination (DDBC) method with partial observability of the CSI. Each BS is able to train its own deep Q-network and employs appropriate beamformer depending on its environment, which is observed through a designed limited-information exchange protocol. The simulation results show that the proposed DRL-based DDBC method, with a considerably lower system overhead, achieves a system capacity that is very close to that of the fractional programming algorithm with global and instantaneous CSI measurements. In addition, this work demonstrates the potential of utilizing DRL to solve DDBC problems in a more practical manner. [ABSTRACT FROM AUTHOR]

Published

2020

35. Effect of intercell interference on cell boundary users in three‐cell and seven‐cell HetCN.

Author

Borah, Janmoni, Hussain, Anwar, and Bora, Joyatri

Subjects

*ENERGY consumption, *SHOPPING malls, *KEY performance indicators (Management), *MULTIPLE access protocols (Computer network protocols), *RAILROAD stations, *CELLS, *TRAFFIC incident management

Abstract

Summary: Indoor and cell‐edge coverage has been a major issue of concern for predeployed traditional macrocell (MC)–based homogeneous cellular network. Moreover, with the extensive increase of mobile users and developments of smart and highly specified devices, user demands and activities have led to huge cellular traffic. The key solutions to these that include network upgradation, overlaying of small cells (SCs), and scaling of resources have turned out to be the major causes for intercell interference (ICI) and energy‐efficiency degradation in heterogeneous cellular networks (HetCNs). In this paper, authors have tried to analyze the downlink performance metrics of cell boundary users with MCs overlaying SCs for three‐cell circular and seven‐cell sectorized networks through frequency reuse (FR) schemes. This paper also discusses the impact of ICI being encountered by users and the effect of SCs on the energy efficiency of the network. The locations for SCs are perceived where user density is large and demands high data rate such as at hot‐spot (HS) areas, railway stations, shopping malls, working farms, and organization. The performance metrics sum rate, average user throughput, and energy efficiency are compared by employing FR‐1 (full spectrum) and FR‐3 (three subbands) among MCs and deployed SCs. For both scenarios, simulation results and analyses depict that without SCs, utilization of FR‐1 results in performance degradation due to ICI effects. However, the downlink performance of cell boundary user and energy efficiency of the network could be enhanced by overlaying SCs near cell boundaries of preexisting MCs along with the allocation of FR‐1. [ABSTRACT FROM AUTHOR]

Published

2020

36. Characterization of Inter-Cell Interference in 3D NAND Flash Memory.

Author

Park, Suk Kwang and Moon, Jaekyun

Subjects

*FLASH memory, *PIPE

Abstract

We characterize inter-cell interference in commercial three-dimensional NAND flash memory. By writing random data into 3D NAND and collecting sample means and sample variances of cell values corresponding to a particular set of input values in fixed relative neighboring cell locations, it is shown that the interference coming from any target cell locations can be measured. We observe that four neighboring cells, two along the same pipe and two along the same bit line, are responsible for most of the interference exerted on a given victim cell. Contrary to the general belief, the total amount of interference is found to be fairly significant even in 3D NAND; if compensated properly, the number of errors can be reduced significantly. [ABSTRACT FROM AUTHOR]

Published

2021

37. Chapter 8 Mobile Ad Hoc and Cellular Networks

Author

Torrieri, Don and Torrieri, Don

Published

2015

38. Capacity-Achieving Codes That Mitigate Intercell Interference and Charge Leakage in Flash Memories.

Author

Chee, Yeow Meng, Chrisnata, Johan, Kiah, Han Mao, Ling, San, Nguyen, Tuan Thanh, and Vu, Van Khu

Subjects

*FLASH memory, *CIPHERS, *ELECTRIC leakage, *ELECTRIC interference, *TRANSISTORS

Abstract

We investigate constant-composition constrained codes for the mitigation of intercell interference for multilevel cell flash memories with a dynamic threshold scheme. The first explicit formula for the maximum size of a $q$ -ary ${\mathcal F}$ -avoiding code with a given composition and certain families of substrings ${\mathcal F}$ is presented. In addition, we provide methods to determine the asymptotic rate for ${\mathcal F}$ -avoiding codes with any composition ratio and to find the optimal composition ratio that maximizes the asymptotic rate. We also give the first efficient encoder/decoder for these $q$ -ary constant-composition codes achieving the channel capacity, for all $q$ values. [ABSTRACT FROM AUTHOR]

Published

2019

39. MIMO in Cellular Standards

Author

Huang, Howard, Papadias, Constantinos B., Venkatesan, Sivarama, Huang, Howard, Papadias, Constantinos B., and Venkatesan, Sivarama

Published

2012

40. Resource Management and Inter-Cell-Interference Coordination in LTE Uplink System Using Random Neural Network and Optimization

Author

Ahsan Adeel, Hadi Larijani, and Ali Ahmadinia

Subjects

artificial neural network, coverage and capacity optimization, fractional power control, genetic algorithm, Intercell interference, power control, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In orthogonal frequency division multiple access systems, inter-cell interference (ICI) can be considered as a collision between resource blocks (RBs), which can be reduced by employing a power control strategy at colliding RBs. This paper presents a random neural network (RNN) and a genetic algorithm-based hybrid cognitive engine (CE) architecture to reduce the ICI and achieve the coverage and capacity optimization in a long-term evolution uplink system. The embedded CE within eNodeB learns from the local environment about the effect of ICI on the reliability of communications. Consequently, the CE dynamically selects the optimal transmission power for serving users based on an experienced signal-to-interference-plus-noise ratio and an ICI on a scheduled RB in the subsequent transmission time intervals. The CE also suggests acceptable transmit power to users operating on the same scheduled RB in adjacent cells through the X2 interface (a communication interface between eNodeBs). The RNN features help the CE to acquire long-term learning, fast decision making, and less computational complexity, which are essential for the development and practical deployment of any real-time cognitive communication system. In six different test cases, the simulation results have shown improvements up to 87% in long-term learning and a quick convergence of the RNN as compared with artificial neural network models. Moreover, the gains of 7% in average cell capacity and 118% in system coverage have been achieved as compared with a fractional power control method.

Published

2015

41. Interference Evaluation in Cellular Networks.

Author

Sbit, Selma, Dadi, Mohamed Béchir, and Rhaimi, Belgacem Chibani

Subjects

WIRELESS communications, INTERFERENCE (Telecommunication), FEMTOCELLS, FREQUENCY division multiple access, NETWORK performance

Abstract

Interference in cellular networks is one of the most common problems in the radio access network. In fact, it is the major issue in cellular networks that affects performances and quality of service. Indeed, interference can be caused by a call on the same frequency from neighboring cell, or a call on an adjacent channel in the same or in neighboring cell. So, we can classify interference on intra-cell interference and inter-cell interference. In 4G, thanks to the use of orthogonal frequency division multiple access and single carrier frequency division multiple access as access techniques in downlink and uplink respectively, intra-cell interference is reduced compared to the inter cell one which caused by the frequency reuse one mechanism and the femto cells deployment. In this work, we will evaluate the interference in different cellular network standards from 2G to 4G. [ABSTRACT FROM AUTHOR]

Published

2018

42. Network-Assisted Radio Resource Management for Cell-Edge Performance Enhancement

Author

Choi, Young-June, Prasad, Narayan, Rangarajan, Sampath, Akan, Ozgur, Series editor, Bellavista, Paolo, Series editor, Cao, Jiannong, Series editor, Dressler, Falko, Series editor, Ferrari, Domenico, Series editor, Gerla, Mario, Series editor, Kobayashi, Hisashi, Series editor, Palazzo, Sergio, Series editor, Sahni, Sartaj, Series editor, Shen, Xuemin (Sherman), Series editor, Stan, Mircea, Series editor, Xiaohua, Jia, Series editor, Zomaya, Albert, Series editor, Coulson, Geoffrey, Series editor, Bartolini, Novella, editor, Nikoletseas, Sotiris, editor, Sinha, Prasun, editor, Cardellini, Valeria, editor, and Mahanti, Anirban, editor

Published

2009

43. A Decentralized RAT Selection Algorithm Enabled by IEEE P1900.4

Author

Pérez-Romero, J., Sallent, O., Agustí, R., Nasreddine, J., Muck, M., István, Frigyes, editor, Bitó, János, editor, and Bakki, Péter, editor

Published

2008

44. Iterative Intercell Interference Cancellation for DL MC-CDMA Systems

Author

Chacun, M., Hélard, M., Legouable, R., Plass, Simon, editor, Dammann, Armin, editor, Kaiser, Stefan, editor, and Fazel, Khaled, editor

Published

2007

45. Erlang Capacity of a CDMA Link with Transmission Rate Control

Author

Koukoutsidis, Ioannis, Altman, Eitan, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Nierstrasz, Oscar, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Sudan, Madhu, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Dough, Series editor, Vardi, Moshe Y., Series editor, Weikum, Gerhard, Series editor, Koucheryavy, Yevgeni, editor, Harju, Jarmo, editor, and Iversen, Villy B., editor

Published

2006

46. An Adaptive Scheduled Transmission Strategy for Multimedia Services in WCDMA Systems

Author

Wu, Eric Hsiao-Kuang, Jui-Hao, Chiang, Chung, Hsin-Pu, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Dough, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Lu, Xicheng, editor, and Zhao, Wei, editor

Published

2005

47. A Peek Into Pandora’s Box: Direct Sequence vs. Frequency Hopped Spread Spectrum

Author

Morrow, Robert K., Jr., Tranter, William H., editor, Rappaport, Theodore S., editor, Woerner, Brian D., editor, and Reed, Jeffrey H., editor

Published

2002

48. Energy and area spectral efficiency trade-off for MC-CDMA with carrier frequency offset.

Author

AHMED, Junaid, TIWANA, Moazzam Islam, AHMAD, Omar, and SOHAIB, Sarmad

Subjects

*ENERGY consumption, *WIRELESS communications, *SIGNAL-to-noise ratio, *INFORMATION measurement, *SIGNAL processing

Abstract

Intercell interference is a major factor that limits the capacity of cellular wireless communication systems. This paper proposes an accurate statistical model that caters to interference and noise to determine the ergodic capacity. A new expression for ergodic capacity is derived that enables us to calculate area spectral efficiency (ASE) and energy efficiency (EE). This expression has been used to calculate and compare ASE and EE for low and high traffic scenarios with various signal-to-noise ratios and intercell distances. [ABSTRACT FROM AUTHOR]

Published

2017

49. Resource Allocation for Integrated Voice/WWW Traffic in UMTS/TDD Systems

Author

Mihailescu, C., Lagrange, X., Godlewski, Ph., Biglieri, Ezio, editor, Fratta, Luigi, editor, and Jabbari, Bijan, editor

Published

1999

50. Measurement of Intercell Interference in LTE and Analysis of the Burstiness of Interference Pikes

Author

Pengili, Xhemal

Subjects

memory coefficient, LTE, interference pikes, interference measurement, burstiness, burst size, intercell interference

Abstract

Interference is a phenomenon that occurs in any wireless network, and the understanding of interference will help in developing efficient interference management techniques. This thesis focuses on a specific type of interference that is present in any cellular network, called intercell interference. Then, we analyse the burstiness of high interference events called “pikes” in the LTE network. In Chapter 2 of the thesis, we analyse three main factors that may impact the burstiness of interference pikes: these factors are car speed, mobile data traffic and track direction. We perform the measurements by changing these three main factors and analysing the statistics values. We find that car speed will impact only the time durations of pikes but not the burstiness of them. But mobile data traffic and track direction will have a substantial impact on the burstiness of interference pikes. Burstiness of interference pikes is analysed in two different environments, the urban area and rural area. In Chapters 3 and 4 of this thesis, we analyse all statistics of these interference pikes, including time durations and burstiness. This analysis is done using different values for the interference power threshold. In those two chapters, we find that increasing the threshold will always decrease the number of pikes and in most cases, it will decrease the pike durations of the pikes and increase valley durations. But the impact of the threshold value in the three burstiness measures will be different for different environments. Also, the three burstiness measures will not change following a specific function but rather in a random way. A comparison of statistics between different environments is done in Chapter 5 of this thesis. We compare results between two cities with very different urban structures, two rural areas in different countries and an urban and rural area. We find that in a city with higher population density and higher interference power interference pikes are more bursty and have a longer time duration. In a highway that passes through populated areas pikes are more bursty compared with highways that pass through unpopulated areas. In rural areas, interference pikes are more bursty and come in longer bursts compared to urban areas., Xhemal Pengili, Masterarbeit Universität Klagenfurt 2022

Published

2022