Your search keyword '"Probability"' showing total 3,257 results

51. Outage Probability Due to PDL Using Threshold Exceedances: Implications of DD-LMS Equalization and Inter-Channel Fiber Nonlinearities.

Author

Cartledge, J. C. and El-Rahman, A. I. Abd

Abstract

The outage probability due to polarization dependent loss (PDL) is estimated using the method of threshold exceedances for a multi-channel transmission model that includes i) decision-directed least-mean-square equalization to partially compensate PDL, ii) the dominant fiber nonlinear effects of cross-phase modulation and cross-polarization modulation, and iii) transceiver noise. The outage probability is defined in terms of the bit-wise achievable information rate (BW-AIR) being less than a threshold value for the generalized mutual information determined by the forward error correcting code rate. The root mean square error between the mean excess function and a theoretical fit to it is used for the critical step of determining the threshold below which the BW-AIR data is represented by the generalized Pareto distribution. The applicability of the method of threshold exceedances is demonstrated for 32 Gbaud, dual-polarization 64-ary quadrature amplitude modulation with a uniform constellation. [ABSTRACT FROM AUTHOR]

Published

2022

52. Outage Probability and Finite-SNR DMT Analysis for IRS-Aided MIMO Systems: How Large IRSs Need to be?

Author

Zhang, Xin, Yu, Xianghao, and Song, S.H.

Abstract

Intelligent reflecting surfaces (IRSs) are promising enablers for high-capacity wireless communication systems by constructing favorable channels between the transmitter and receiver. However, general, accurate, and tractable outage probability analysis for IRS-aided multiple-input-multiple-output (MIMO) systems is not available in the literature. In this paper, we first characterize the distribution of the mutual information (MI) for IRS-aided MIMO systems by capitalizing on large random matrix theory (RMT). Based on this result, a closed-form approximation for the outage probability is derived and a gradient-based algorithm is proposed to minimize the outage probability with statistical channel state information (CSI). We also investigate the diversity-multiplexing tradeoff (DMT) with finite signal-to-noise ratio (SNR). Based on these theoretical results, we further study the impact of the IRS size on system performance. In the high SNR regime, we provide closed-form expressions for the ergodic mutual information (EMI) and outage probability as a function of the IRS size, which analytically reveal that the benefit of increasing the IRS size saturates quickly. Simulation results validate the accuracy of the theoretical analysis and confirm the increasing cost to improve system performance by deploying larger IRSs. For example, for an IRS-aided MIMO system with 20 antennas at both the transmitter and receiver, we need to double the size of the IRS to increase the throughput from 90% to 95% of its maximum value. [ABSTRACT FROM AUTHOR]

Published

2022

53. STAR-RISs: A Correlated T&R Phase-Shift Model and Practical Phase-Shift Configuration Strategies.

Author

Xu, Jiaqi, Liu, Yuanwei, Mu, Xidong, Schober, Robert, and Poor, H. Vincent

Abstract

A correlated transmission and reflection (T&R) phase-shift model is proposed for passive lossless simultaneously transmitting and reflecting reconfigurable intelligent surfaces (STAR-RISs). A STAR-RIS-aided two-user downlink communication system is investigated for both orthogonal multiple access (OMA) and non-orthogonal multiple access (NOMA). To evaluate the impact of the correlated T&R phase-shift model on the communication performance, three phase-shift configuration strategies are developed, namely the primary-secondary phase-shift configuration (PS-PSC), the diversity preserving phase-shift configuration (DP-PSC), and the T/R-group phase-shift configuration (TR-PSC) strategies. Furthermore, we derive the outage probabilities for the three proposed phase-shift configuration strategies as well as for those for the random phase-shift configuration and the independent phase-shift model, which constitute performance lower and upper bounds, respectively. Then, the diversity order of each strategy is investigated based on the obtained analytical results. It is shown that the proposed DP-PSC strategy achieves full diversity order simultaneously for users located on both sides of the STAR-RIS. Moreover, power scaling laws are derived for the three proposed strategies and for the random phase-shift configuration. Numerical simulations reveal a performance gain if the users on both sides of the STAR-RIS are served by NOMA instead of OMA. Moreover, it is shown that the proposed DP-PSC strategy yields the same diversity order as achieved by STAR-RISs under the independent phase-shift model and a comparable power scaling law with only 4 dB reduction in received power. [ABSTRACT FROM AUTHOR]

Published

2022

54. Joint Impact of Channel Estimation Errors and Pointing Errors on FSO Communication Systems Over $\mathcal {F}$ Turbulence Channel.

Author

Han, Liqiang, Liu, Xuemei, Wang, Yawei, and Li, Boyu

Abstract

In this paper, we provide the performance analysis of free-space optical (FSO) communication systems over Fisher-Snedecor $\mathcal {F}$ fading channel with estimation errors in the presence of pointing errors. The probability density function (PDF) and cumulative distribution function (CDF) of signal-to-noise ratio (SNR) are derived in the presence of channel estimation errors and pointing errors. Subsequently, the novel expressions for the outage probability, average bit error rate (BER) and ergodic capacity are obtained. The asymptotic expressions for the outage probability and average BER are also presented to provide further insights into the FSO system performance in high SNR regime. Through numerical simulations, the impact of imprecise channel on the performance of the FSO communication systems is analyzed as compared with precise channel. Finally, Monte Carlo simulations are presented to validate the proposed analysis. [ABSTRACT FROM AUTHOR]

Published

2022

55. Geometry-Based Stochastic Line-of-Sight Probability Model for A2G Channels Under Urban Scenarios.

Author

Zhu, Qiuming, Bai, Fei, Pang, Minghui, Li, Jie, Zhong, Weizhi, Chen, Xiaomin, and Mao, Kai

Subjects

*MONTE Carlo method, *STATISTICS, *COMPUTATIONAL complexity, *PARAMETRIC modeling, *STOCHASTIC processes, *SPACE

Abstract

Line-of-sight (LoS) path is essential for the reliability of air-to-ground (A2G) communications, but the existence of the LoS path is difficult to predict due to random obstacles on the ground. Based on the statistical geographic information and Fresnel clearance zone, a general stochastic LoS probability model for 3-D A2G channels under urban scenarios is developed. By considering the factors, that is, building height distribution, building width, building space, carrier frequency, and transceiver’s heights, the proposed model is suitable for different frequencies and altitudes. Moreover, in order to get a closed-form expression and reduce the computational complexity, an approximate parametric model is also built with the machine-learning (ML) method to estimate the model parameters. The simulation results show that the proposed model has good consistency with existing models at low altitude. When the altitude increases, it has a better performance by comparing with that of the ray-tracing (RT) Monte-Carlo simulation data. The analytical results of the proposed model are helpful for the channel modeling and performance analyses such as cell coverage, outage probability, and bit error rate in A2G communications. [ABSTRACT FROM AUTHOR]

Published

2022

56. Outdated Access Point Selection for Mobile Edge Computing With Cochannel Interference.

Author

Lai, Xiazhi, Xia, Junjuan, Fan, Lisheng, Duong, Trung Q., and Nallanathan, Arumugam

Subjects

*MOBILE computing, *EDGE computing, *SYSTEMS design, *ENERGY consumption, *RADIO transmitter fading, *RELIABILITY in engineering

Abstract

In this paper, we investigate a mobile edge computing (MEC) network, where the user has some computational tasks to be assisted by multiple computational access points (CAPs) through offloading. We consider practical communication scenarios with limited spectrum resources, and the cochannel interference arising from the aggressive reuse of frequency severely degrades the system offloading performance. To enhance the system performance, we provide three CAP selection criteria to choose one best CAP among multiple ones. Specifically, criterion I maximizes the computational capability at the CAP, criterion II minimizes the interfering power, while criterion III maximizes the instantaneous channel gain of data link. In time-varying channel environments, the CAP selection may be outdated, which deteriorates the system performance. For the three criteria, we evaluate the system outage probability in the outdated channel state information (CSI) by taking into account the latency, energy consumption and data rate, and provide the analytical and asymptotic expressions of outage probability, from which we obtain some critical insights on the system design. Simulation results are finally demonstrated to verify the proposed studies. In particular, criterion III under the perfect CSI can achieve the system whole diversity order coming from multiple CAPs. [ABSTRACT FROM AUTHOR]

Published

2022

57. New Antenna Selection Schemes for Full-Duplex Cooperative MIMO-NOMA Systems.

Author

Mobini, Zahra, Mohammadi, Mohammadali, Tsiftsis, Theodoros A., Ding, Zhiguo, and Tellambura, Chintha

Subjects

*ANTENNAS (Electronics), *TRANSMITTING antennas, *RECEIVING antennas, *LINEAR network coding

Abstract

In this paper, we address the antenna selection (AS) problem in full-duplex (FD) cooperative non-orthogonal multiple access (NOMA) systems, where a multi-antenna FD relay bridges the connection between the multi-antenna base station and NOMA far user. Specifically, two AS schemes, namely max-U1 and max-U2, are proposed to maximize the end-to-end signal-to-interference-plus-noise ratio at either or both near and far users, respectively. Moreover, a two-stage AS scheme, namely quality-of-service (QoS) provisioning scheme, is designed to realize a specific rate at the far user while improving the near user’s rate. To enhance the performance of the QoS provisioning AS scheme, the idea of dynamic antenna clustering is applied at the relay to adaptively partition the relay’s antennas into transmit and receive subsets. The proposed AS schemes’ exact outage probability and achievable rate expressions are derived. To provide more insight, closed-form asymptotic outage probability expressions for the max-U1 and max-U2 AS schemes are obtained. Our results show that while the QoS provisioning AS scheme can deliver a near-optimal performance for static antenna setup at the relay, it provides up to 12% average sum rate gain over the optimum AS selection with fixed antenna setup. [ABSTRACT FROM AUTHOR]

Published

2022

58. Impact of Relaxation on the Performance of GeSe True Random Number Generator Based on Ovonic Threshold Switching.

Author

Zhou, Xue, Hu, Zeyu, Chai, Zheng, Zhang, Weidong, Clima, Sergiu, Degraeve, Robin, Zhang, Jian Fu, Fantini, Andrea, Garbin, Daniele, Delhougne, Romain, Goux, Ludovic, and Kar, Gouri Sankar

Subjects

RANDOM number generators, RANDOM numbers

Abstract

Volatile Ovonic threshold switching (OTS) are promising not only as the selector in crossbar resistive switching memory arrays, but also as true random number generators (TRNG) by utilizing its probabilistic switching characteristics. However, investigation on the reliability of OTS-based TRNG is still lacking, which hinders its practical application. Previously, we found that switching probability is dependent on the pulse amplitude and width. In this work, we report that relaxation which happens during the time interval between pulses can also cause switching probability drift. Optimizing the bit-generation waveform and modulating the pulse conditions could provide a practical solution, in addition to the impact of external bias and temperature. This work provides useful guidance for the practical design and operation of OTS-based TRNGs. [ABSTRACT FROM AUTHOR]

Published

2022

59. Fluid Antenna Multiple Access.

Author

Wong, Kai-Kit and Tong, Kin-Fai

Abstract

Fluid antenna system represents an emerging technology that enables an antenna to switch its physical location in a predefined space. This paper explores the potential of using a single fluid antenna at each mobile user for multiple access, which we refer to it as fluid antenna multiple access (FAMA). FAMA exploits spatial moments of deep fade suffered by the interference to achieve a favourable channel condition for the desired signal, without requiring sophisticated signal processing. We analyze the FAMA network by first deriving the outage probability of the signal-to-interference ratio (SIR) in a double integral form. We then obtain an outage probability upper bound in closed form and an average outage rate lower bound for the FAMA system, with an arbitrary number of interferers, from which the multiplexing gain of FAMA is characterized. We also estimate how large the number of locations is required to achieve a given multiplexing gain using fluid antennas with a given size. Results show that it is possible for FAMA to support hundreds of users using only one fluid antenna of a few wavelengths of space at each user, giving rise to significant gain in the average network outage rate. [ABSTRACT FROM AUTHOR]

Published

2022

60. Secure-Reliable Transmission Designs for Full-Duplex Receiver With Finite-Alphabet Inputs.

Author

Xia, Guiyang, Zhou, Xiaobo, Gu, Lichuan, Shu, Feng, Wu, Yongpeng, and Wang, Jiangzhou

Abstract

This paper studies a convincingly secure transmission framework under an allowable outage probability for practical finite-alphabet inputs, where a full-duplex receiver (Bob) is taken into account to emit the artificial noise for deteriorating the eavesdropper’s decoding performance. We develop a secure-reliable mechanism to take the place of prior secrecy rate (SR) maximization strategy, where a closed form expression is invoked for substituting the non-closed SR expression upon exploiting the multi-exponential decay fitting approach. Hence, the intractable expectation operation over a large number of noise samples is circumvented. Moreover, a pair of critical probabilities of the reliable transmission and secure outage are first analyzed, and then a low-complexity optimization scheme is formulated. Apart from designing the transmission scheme for classically secure networks consisting of a transmitter, Bob and an eavesdropper, we further carry out an investigation on conceiving a secure-reliable strategy against multiple Eves for improving the system’s extensibility. To this end, analytical expressions of both the reliability outage and secrecy outage probabilities for multiple-Eve scenarios are also derived. Furthermore, a pragmatic iterative solution is conceived for addressing the corresponding max-min optimization problem. Finally, the simulation results validate the significance of our considered secure-reliable transmission in terms of the average SR performance attained. [ABSTRACT FROM AUTHOR]

Published

2022

61. Relay Cooperative Transmission Algorithms for IoV Under Aggregated Interference.

Author

Ji, Baofeng, Han, Ying, Wang, Yanan, Cao, Dun, Tao, Fazhan, Fu, Zhumu, Li, Peng, and Wen, Hong

Abstract

The Internet of Vehicles (IoV) has always attracted attention as the emerging communication network with the most development potential in the 5G era. However, the performance of IoV under 5G ultra-dense networks is an open issue, especially in practice the outage probability and ergodic capacity of the relay cooperative IoV network under aggregate interference are still unclear. Therefore, an opportunistic Decoding and Forwarding (DF) relay cooperative transmission algorithm was proposed in this paper when the destination node of IoV has aggregated interference. In addition, based on mathematical theoretical knowledge such as numerical analysis, the closed expressions of the outage probability and ergodic capacity of the IoV system under aggregated interference was derived. Finally, simulation experiments verify the effectiveness of the proposed scheme and the correctness of the theoretical analysis, which improves the transmission rate of the system. [ABSTRACT FROM AUTHOR]

Published

2022

62. Hazardous Scenario Enhanced Generation for Automated Vehicle Testing Based on Optimization Searching Method.

Author

Zhu, Bing, Zhang, Peixing, Zhao, Jian, and Deng, Weiwen

Abstract

The scenario-based test method is the research hotspot of automated vehicle (AV) validation and verification (V&V), and testing with hazardous scenarios is of important means. An Optimization Searching (OS) method for enhanced generation in hazardous scenarios is proposed in this paper to efficiently explore functional boundary scenarios in a huge logical state space. The method is computationally tractable, and its generated experimental parameters are optimized using past test results. The method includes five essential modules. The Exploration and Exploitation module uses the Multi-arm bandit method to obtain the greatest sum of the $TTC^{\mathbf {-1}}$ (Time To Collision). The Parameter Moving Probability Determination module uses an analytic hierarchy process to ensure that influential parameters are more likely to move. The Step Size Determination module is built with Levy-step to find a greater number of hazardous scenarios. The Memory Function module is used to avoid repeat experiments that can reduce computing efficiency. The Result Analysis module creates a hazard parameter space for subsequent tests. We tested an ACC (Adaptive Cruise Control) algorithm with a specified logical scenario in the virtual environment built by PreScan. The results showed that the OS method can effectively discover the dangerous range with the tested ACC algorithm, and its test speed can reach more than five times that of an exhaustive algorithm without prior knowledge. [ABSTRACT FROM AUTHOR]

Published

2022

63. A Novel Three-Way Decision Model Based on Utility Theory in Incomplete Fuzzy Decision Systems.

Author

Zhan, Jianming, Ye, Jin, Ding, Weiping, and Liu, Peide

Subjects

UTILITY theory, FUZZY systems, CONDITIONAL probability, FUZZY sets, UTILITY functions

Abstract

The existing three-way decision (TWD)-making methods cannot effectively handle incomplete multiattribute decision-making (MADM) problems in real life; it is necessary to explore an effective three-way MADM model in incomplete fuzzy decision systems (IFDSs). First, we consider the preference of decision makers for each alternative and introduce the concept of predecisions, thus an IFDS is obtained. Then, the weighted conditional probabilities are calculated with the aid of the defined similarity relation. Subsequently, we introduce the notion of relative utility functions and then present an approach to determine the relative utility function values. Afterward, we construct a TWD model in IFDSs and apply it to the modeling of incomplete MADM (IMADM) problems. Our study not only enriches TWD and MADM theories but also provides a new perspective for realistic IMADM problems. At last, the results of comparative and experimental analyses demonstrate the validity, stability, and superiority of our proposed model. [ABSTRACT FROM AUTHOR]

Published

2022

64. Design of THz-NOMA in the Presence of Beam Misalignment.

Author

Ding, Zhiguo and Poor, H. Vincent

Abstract

In this letter, the application of non-orthogonal multiple access (NOMA) to Terahertz (THz) transmission is proposed in order to mitigate the harmful effect of beam alignment errors. In particular, two types of cognitive radio inspired NOMA (CR-NOMA) schemes are developed to realize different tradeoffs between system performance and user fairness. Both analytical and simulation results are presented to demonstrate the superior performance gain of THz-NOMA over conventional orthogonal multiple access based THz transmission. [ABSTRACT FROM AUTHOR]

Published

2022

65. Outage Analysis and Beamwidth Optimization for Positioning-Assisted Beamforming.

Author

Zhu, Bingcheng, Zhang, Zaichen, and Cheng, Julian

Abstract

Beamforming based on channel estimation can be computationally intensive and inaccurate when the antenna array is large, while positioning information can reduce the complexity. In this work, we study the outage probability of positioning-assisted beamforming systems. Closed-form outage probability bounds are derived by considering positioning error, link distance and beamwidth. Based on the analytical result, we show that the beamwidth should be optimized with respect to the link distance and the transmit power, and such optimization significantly suppresses the outage probability. [ABSTRACT FROM AUTHOR]

Published

2022

66. Outage Performance of BackCom Systems With Multiple Self-Powered Tags Under Channel Estimation Error.

Author

Liu, Yingting, Ma, Jiaxiu, Ye, Yinghui, Li, Xingwang, and Zhao, Yongli

Abstract

In this letter, a backscatter communication (BackCom) system with multiple self-powered tags is considered, where in each transmission, the tag that can maximize the received signal-to-noise ratio at the destination is selected to convey the information. To satisfy the tag’s power requirement, the fixed reflection coefficient is adopted. Different from the existing literatures, the effect of the channel estimation error (CEE) on the outage performance is considered. With and without the CEE, the analytical results for the outage probability and the diversity performance under the independent but not necessarily identically distributed Rayleigh fading channels are derived. The numerical results verify the analytical results and then investigate the important parameters on the outage performance. The numerical results show that the CEE and especially the consumed power by tags have a significant impact on the system outage performance. [ABSTRACT FROM AUTHOR]

Published

2022

67. The Statistics of Superdirective Beam Patterns.

Subjects

*PROBABILITY density function, *STATISTICS, *QUANTILE regression, *RICIAN channels

Abstract

Superdirective arrays have been extensively studied because of their considerable potential accompanied, unfortunately, by a high sensitivity to random errors that affect the responses and positions of array elements. However, the statistics of their actual beam pattern (BP) has never been systematically investigated. This paper shows that the Rician probability density function (PDF), sometimes adopted to study the impact of errors in conventional arrays, is a valid approximation for superdirective BP statistics only where some mathematical terms are negligible. The paper also shows that this is the case for all linear end-fire arrays considered. A similar study is proposed concerning the correlation between BP lobes, showing that for the superdirective arrays considered the lobes, especially non-adjacent ones, are almost independent. Furthermore, knowledge of the PDF of the actual BP allows one to define quantile BP functions, whose probability of being exceeded, at any point, is fixed. Combining the lobes’ independence with quantile BP functions, an empirical equation for the probability that the entire actual BP will not exceed a quantile function over an interval larger than a given size is obtained. This new knowledge and these tools make it possible to devise new methods to design robust superdirective arrays via optimization goals with clearer and more relevant statistical meaning. [ABSTRACT FROM AUTHOR]

Published

2022

68. Patterns Quantization With Noise Using Gaussian Features and Bayesian Learning in VLC Systems.

Author

Lu, Xingyu, Liu, Yuanyuan, Chen, Junjie, Ran, Yulin, Xiao, Yunpeng, and Liu, Yanbing

Abstract

Nonlinear impairments seriously affect the transmission performance of high-speed visible light communication (VLC) systems, which have become the bottleneck of VLC systems in practical applications. To compensate for the nonlinear impairments of VLC systems, we propose a Pattern quantization method (PQM) based on Gaussian feature inputs and Bayesian learning in the time-domain. First, we investigate the signal distribution of VLC systems in the presence of additive white Gaussian noise (AWGN) and nonlinear impairments. Second, probability statistics are used to quantify the noise. Finally, a nonlinear compensator for PAM-8 VLC systems is realized using the Bayesian machine learning principle. In the experiment, a PAM-8 VLC system with a maximum transmission data rate of 1 Gb/s and bit error rate (BER) below the threshold of hard decision forward error correction (HD-FEC) is successfully demonstrated. The results indicate that the PQM compensator can significantly reduce nonlinear impairment and improve BER performance while requiring little computational effort. The Q-Factor is improved by 2.1 dB, the transmission distance is increased by 1/3, and the BER is reduced by 90.05% when compared with conventional nonlinear Volterra equalizers. As far as we know, our study is the first to investigate the input features and quantify the white noise in VLC systems, thereby providing a novel approach to machine learning input data processing. [ABSTRACT FROM AUTHOR]

Published

2022

69. Secrecy Outage Performance Analysis of UAV-Assisted Relay Communication Systems With Multiple Aerial and Ground Eavesdroppers.

Author

Bao, Tingnan, Wang, Haiming, Wang, Wen-Jing, Yang, Hong-Chuan, and Hasna, Mazen

Subjects

*TELECOMMUNICATION systems, *SYMBOL error rate, *DRONE aircraft, *RAYLEIGH fading channels, *EARTH stations

Abstract

In this article, we study the secrecy performance of an unmanned aerial vehicle (UAV)-assisted relay communication system, where a ground base station (GBS) intends to send confidential information to the ground legitimate user Bob with the help of a UAV relay in the presence of multiple aerial and ground eavesdroppers. We consider the height-dependent probabilistic line-of-sight and the general $\kappa$ - $\mu$ shadowed channel fading model in the system. To enhance the secrecy performance, the GBS and UAV relay apply directional beamforming transmission while implementing protection zones around their intended receiving destinations. We then derive the approximate closed-form expressions of the secrecy outage probability (SOP) under different aerial and ground eavesdropperscolluding strategies. To get insights, we also obtain the SOP expression over Rayleigh fading as a special case. After discussing the impacts of transmitting and multiple aerial and ground eavesdropping parameters on the SOP, we show that the optimal altitude of UAV relay exists with the minimal SOP value under different urban environments. We also show that UAV eavesdroppers have a larger effect on the system performance than ground eavesdroppers. [ABSTRACT FROM AUTHOR]

Published

2022

70. Tracking Code Bug Fix Ripple Effects Based on Change Patterns Using Markov Chain Models.

Author

Ufuktepe, Ekincan, Tuglular, Tugkan, and Palaniappan, Kannappan

Subjects

*STATISTICAL correlation, *MARKOV processes

Abstract

Change impact analysis evaluates the changes that are made in the software and finds the ripple effects, in other words, finds the affected software components. Code changes and bug fixes can have a high impact on code quality by introducing new vulnerabilities or increasing their severity. A recent high-visibility example of this is the code changes in the log4j web software CVE-2021-45105 to fix known vulnerabilities by removing and adding method called change types. This bug fix process exposed further code security concerns. In this article, we analyze the most common set of bug fix change patterns to have a better understanding of the distribution of software changes and their impact on code quality. To achieve this, we implemented a tool that compares two versions of the code and extracts the changes that have been made. Then, we investigated how these changes are related to change impact analysis. In our case study, we identified the change types for bug-inducing and bug fix changes using the Quixbugs dataset. Furthermore, we used 13 of the projects and 621 bugs from Defects4J to identify the common change types in bug fixes. Then, to find the change types that cause an impact on the software, we performed an impact analysis on a subset of projects and bugs of Defects4J. The results have shown that, on average, 90% of the bug fix change types are adding a new method declaration and changing the method body. Then, we investigated if these changes cause an impact or a ripple effect in the software by performing a Markov chain-based change impact analysis. The results show that the bug fix changes had only impact rates within a range of 0.4–5%. Furthermore, we performed a statistical correlation analysis to find if any of the bug fixes have a significant correlation with the impact of change. The results have shown that there is a negative correlation between caused impact with the change types adding new method declaration and changing method body. On the other hand, we found that there is a positive correlation between caused impact and changing the field type. [ABSTRACT FROM AUTHOR]

Published

2022

71. Time-Domain Differential Protection of Transmission Lines Based on Bayesian Inference.

Author

Tiferes, Rodrigo Rozenblit and Manassero, Giovanni

Subjects

*ELECTRIC lines, *ELECTRIC fault location, *CURRENT transformers (Instrument transformer), *BAYESIAN field theory, *INTERCONNECTED power systems, *BAYES' theorem, *SAMPLING theorem, *FAULT location (Engineering)

Abstract

This paper presents a time-domain differential protection method based on the Bayes’ Theorem and on the current samples to determine the fault occurrence probability as a function of time. It also describes the theory involved in developing the proposed protection method when considering the differential protection of transmission lines. The authors performed fault simulations using an existing electrical system modeled in EMTP varying the fault type, phases involved, fault resistance, inception angle, and fault location, and carried out a sensitivity analysis regarding high impedance faults, current transformer saturation, noisy data, misalignments between terminal samples and power swings. The authors also tested the proposed method against actual fault events from four existing transmission lines of the Brazilian interconnected power system. All results indicate that the proposed solution is fast, accurate, secure, and dependable. [ABSTRACT FROM AUTHOR]

Published

2022

72. Aerial-Terrestrial Network NOMA for Cellular-Connected UAVs.

Author

New, Wee Kiat, Leow, Chee Yen, Navaie, Keivan, and Ding, Zhiguo

Subjects

*MULTIPLE access protocols (Computer network protocols), *DIRECTIONAL antennas, *ARRAY processing

Abstract

Efficient connectivity in cellular-connected unmanned aerial vehicles (UAV)s is limited by scarcity of the radio spectrum and strong inter-cell interference (ICI). To address these issues, we propose an aerial-terrestrial network non-orthogonal multiple access (ATN-NOMA) scheme. In this proposed scheme, we pair the aerial user (AU) and terrestrial user (TU) in a NOMA setting to leverage their asymmetric channel gains and rate demands in downlink communications. In ATN-NOMA, the strong ICI issue at the AU receiver is further managed by an elevation-angle based user association, equipping the AU with an adjustable beamwidth directional antenna, and forming a beamforming among the coordinated terrestrial base stations (BS)s. We then obtain the optimal beamwidth and suboptimal power allocation so that the TUs’ sum-rate is maximized subject to the AU’s Quality-of-Service (QoS) requirement. The corresponding optimization problem is non-convex in which we exploit the structure of the problem and apply successive convex approximation (SCA) to obtain a suboptimal solution. We then derive the statistical properties, which consequently enable us to estimate the aggregated ICI. In cases where no interfering BSs have the same elevation angle as the coordinated BSs, we further approximate the AU’s outage probability. We then compare the TUs’ sum-rate and the outage probability of the ATN-NOMA with multiple existing schemes. Extensive simulation results show that our proposed ATN-NOMA scheme outperforms existing schemes by 52-91% in terms of the sum-rate, and its analytical outage probability can be as low as the order of $10^{-17}$. Furthermore, we show that the pairing of AU and TU in multi-cell networks remains beneficial, subject to effective mitigation of ICI. [ABSTRACT FROM AUTHOR]

Published

2022

73. Performance of NOMA-Based Dual-Hop Hybrid Powerline-Wireless Communication Systems.

Author

Samir, Ahmed, Elsayed, Mohamed, El-Banna, Ahmad A. Aziz, Wu, Kaishun, and ElHalawany, Basem M.

Subjects

*DECODE & forward communication, *TELECOMMUNICATION systems, *ADDITIVE white Gaussian noise, *CARRIER transmission on electric lines, *SYMBOL error rate, *BINOMIAL distribution, *LOGNORMAL distribution

Abstract

The mixture of wireless and power line communications (PLC) is vital for implementing new applications in smart grid and vehicular communications. In this work, we investigate the performance of non-orthogonal multiple access (NOMA) based dual-hop hybrid communication systems with decode-and-forward relay. The wireless channel is characterized by Nakagami-m fading under an additive white Gaussian noise (AWGN), while the PLC channels are characterized by Log-normal distribution with Bernoulli Gaussian noise including both background and impulsive noise components. New closed-form expressions for the outage probability, the asymptotic outage probability and ergodic capacity are derived and verified via extensive representative simulations. For more insights on the outage performance, we analyze the diversity order. Additionally, we proposed a power allocation optimization technique to achieve an outage-optimal performance. The results show that the system outage probability improves as the impulsive noise index and the arrival probability of the impulsive component of the PLC additive noise decrease, while their effect is negligible on the ergodic capacity. Finally, the performance of the proposed system is compared against a benchmark OMA-based system. [ABSTRACT FROM AUTHOR]

Published

2022

74. Extreme Value Theory Based Rate Selection for Ultra-Reliable Communications.

Author

Mehrnia, Niloofar and Coleri, Sinem

Subjects

*EXTREME value theory, *WIRELESS channels, *ERROR probability, *PARETO distribution, *EXTRAPOLATION, *ERROR rates, *MAXIMUM likelihood statistics

Abstract

Ultra-reliable low latency communication (URLLC) requires the packet error rate to be on the order of $10^{-9}$ - $10^{-5}$. Determining the appropriate transmission rate to satisfy this ultra-reliability constraint requires deriving the statistics of the channel in the ultra-reliable region and then incorporating these statistics into the rate selection. In this paper, we propose a framework for determining the rate selection for ultra-reliable communications based on the extreme value theory (EVT). We first model the wireless channel at URLLC by estimating the parameters of the generalized Pareto distribution (GPD) best fitting to the tail distribution of the received powers, i.e., the power values below a certain threshold. Then, we determine the maximum transmission rate by incorporating the Pareto distribution into the rate selection function. Finally, we validate the selected rate by computing the resulting error probability. Based on the data collected within the engine compartment of Fiat Linea, we demonstrate the superior performance of the proposed methodology in determining the maximum transmission rate compared to the traditional extrapolation-based approaches. [ABSTRACT FROM AUTHOR]

Published

2022

75. Online Task Offloading for 5G Small Cell Networks.

Author

Zhou, Ruiting, Zhang, Xueying, Qin, Shixin, Lui, John C.S., Zhou, Zhi, Huang, Hao, and Li, Zongpeng

Subjects

5G networks, GREEDY algorithms, ONLINE education, EDGE computing, VIRTUAL reality

Abstract

Small cells are deployed in 5G networks to complement the macro cells for improving coverage and capacity. Small cells and edge computing are natural partners which can improve users’ experience. Small cell nodes (SCNs) equipped with edge servers can support emerging computing services, such as virtual reality which impose low-latency and precise contextual requirements. With the proliferation of wireless devices, there is an increasing demand for offloading tasks to SCNs. Given limited computation and communication resources, the fundamental problem for a small cell network is how to select computing tasks to maximize effective rewards in an uncertain and stochastic environment. To this end, we propose an online learning framework, LFSC, which has the performance guarantee to guide task offloading in a small cell network. LFSC balances between reward and constraint violations, and it consists of three subroutines: i) a randomized algorithm which calculates selection probability of each task based on task weights; ii) a greedy assignment algorithm which cooperatively allocates tasks among different SCNs based on the selection probability; iii) an update algorithm which exploits the multi-armed bandit (MAB) technique to update task weights according to the feedback. Our theoretical analysis shows that both the regret and violations metrics of LFSC have the sub-linear property. Extensive simulation studies based on real world data confirm that LFSC achieves a close-to-optimal reward with low violations, and outperforms many state-of-the-art algorithms. [ABSTRACT FROM AUTHOR]

Published

2022

76. Improving Quality-of-Service in Cluster-Based UAV-Assisted Edge Networks.

Author

Bose, Tushar, Suresh, Aala, Pandey, Om Jee, Cenkeramaddi, Linga Reddy, and Hegde, Rajesh M.

Abstract

With millions of devices connected together, the Internet of Things (IoT) has become an emerging technology for future wireless networks. The ever-increasing number of smart devices and data hungry applications demand a high Quality-of-Service (QoS) for IoT. In conventional networks, data being sent to cloud for computational purpose leads to poor QoS. In order to address QoS challenges, mobile edge networks have emerged as a promising solution. In edge networks, bringing the networks resources closer to the end devices results in improved QoS. The maneuverability and the ease of versatile deployment coupled with cost efficiency makes unmanned aerial vehicles (UAVs) a promising candidate for future edge networks. The UAVs can act as edge servers to provide computational capabilities and improved services to the edge devices. Due to the flying ability, UAVs can establish better line-of-sight link with the ground devices. In this paper, we consider that the edge devices in the area of interest have to be facilitated with a certain desired QoS, which is based on the notion of outage probability of the wireless link between the UAV and the edge devices. In this context, we first propose a novel method that computes the optimum height at which UAV should hover, resulting in maximum coverage radius with sufficiently small outage probability. Then the geographical area is divided in optimal number of clusters using a novel algorithm based on K-means clustering. The method computes the optimum number of UAVs required for covering the area of interest. Each of the UAVs utilizes 3D beamforming in order to cover its own coverage area. For this purpose, we are taking coordinate transformation of the original area and forming a wide beam to cover the desired area. The obtained results demonstrate the effectiveness of the proposed method when compared to existing methods, which validate the utilization of the proposed method over large scale network applications. [ABSTRACT FROM AUTHOR]

Published

2022

77. Federated Learning With Erroneous Communication Links.

Author

Shirvanimoghaddam, Mahyar, Salari, Ayoob, Gao, Yifeng, and Guha, Aradhika

Abstract

In this letter, we consider the federated learning (FL) problem in the presence of communication errors. We model the link between the devices and the central node (CN) by a packet erasure channel, where the local parameters from devices are either erased or received correctly by CN with probability $\epsilon $ and $1-\epsilon $ , respectively. We proved that the FL algorithm in the presence of communication errors, where the CN uses the past local update if the fresh one is not received from a device, converges to the same global parameter as that the FL algorithm converges to without any communication error. We provide several simulation results to validate our theoretical analysis. We also show that when the dataset is uniformly distributed among devices, the FL algorithm that only uses fresh updates and discards missing updates might converge faster than the FL algorithm that uses past local updates. [ABSTRACT FROM AUTHOR]

Published

2022

78. On Performance of SWIPT Enabled PPP Distributed Cooperative NOMA Networks Using Stochastic Geometry.

Author

Parihar, Abhinav Singh, Swami, Pragya, and Bhatia, Vimal

Subjects

*STOCHASTIC geometry, *MONTE Carlo method, *WIRELESS power transmission, *POISSON processes, *ENERGY harvesting, *POINT processes

Abstract

Non-orthogonal multiple access (NOMA) is considered as a multiple access technique for supporting massive number of devices with high spectral efficiency. Simultaneous wireless information and power transfer (SWIPT) is an efficient solution for fully autonomous and sustainable communication networks. In this paper, application of SWIPT in networks employing cooperative NOMA (CNOMA) is investigated with imperfect channel state information (CSI). Performance of the CNOMA network with SWIPT is investigated in a multi-tier downlink scenario with macro-base stations (MBSs) and femto-base stations (FBSs). The distribution of MBSs and FBSs follow Poisson point process model. Unlike solution in the existing literature, instead of using only the superimposed signal for energy harvesting (EH), in this work, the cooperating node/user employs EH using interference from the adjacent base stations. Expressions for outage probability and throughput are derived at the user pair (comprising a cell-center user and a cell-edge user) served using NOMA. Comparison of the proposed EH system with the existing solutions is highlighted. Monte Carlo simulations are carried out to validate the analytical results. [ABSTRACT FROM AUTHOR]

Published

2022

79. Fresnel Line-of-Sight Probability With Applications in Airborne Platform-Assisted Communications.

Author

Hmamouche, Yassine, Benjillali, Mustapha, and Saoudi, Samir

Subjects

*STOCHASTIC geometry, *PROBABILITY theory, *PROBABILITY density function, *QUALITY of service, *GAUSSIAN channels

Abstract

The ecosystem of airborne platforms is maturing rapidly and becoming essential to meeting the communication requirements of modern wireless networks. In such a context, the speed, range, and quality of service are highly dependent on a timely access to the right amount and type of affordable spectrum. In this way, evaluating the statistical properties of the air-to-ground (AtG) channel in different built-up propagation environments with regard to the operating frequency is crucial for performance analysis of airborne platform-assisted communications. In this paper, we construct a framework for the line-of-sight (LoS) probability based on the intrusion ratio of obstacles within the first Fresnel zone, yielding an analytical expression for the LoS probability that is sensitive to the operating frequency, the transmitter and receiver heights, the horizontal distance between them, and three other parameters depicting the statistical properties of the urban environment. The model developed is accurate enough to capture scattering mechanisms such as reflection and diffraction, while being sufficiently flexible mathematically to allow, based for instance on powerful analytical tools such as stochastic geometry, a seamless and physically meaningful system-level performance evaluation of modern wireless networks in the presence of airborne platforms. [ABSTRACT FROM AUTHOR]

Published

2022

80. User Pairing and Outage Analysis in Multi-Carrier NOMA-THz Networks.

Author

Melhem, Sadeq Bani and Tabassum, Hina

Subjects

*TERAHERTZ technology, *THERMAL noise, *SIGNAL-to-noise ratio

Abstract

This paper provides a comprehensive framework to analyze the performance of non-orthogonal multiple access (NOMA) in the downlink transmission of a single-carrier and multi-carrier terahertz (THz) network. Specifically, we first develop a novel user pairing scheme for the THz-NOMA network which ensures the performance gains of NOMA over orthogonal multiple access (OMA) for each individual user in the NOMA pair and adapts according to the molecular absorption. Then, we characterize novel outage probability expressions considering a single-carrier and multi-carrier THz-NOMA network in the presence of various user pairing schemes, Nakagami- $m$ channel fading, and molecular absorption noise. We propose a moment-generating-function (MGF) based approach to analyze the outage probability of users in a multi-carrier THz network. Furthermore, for negligible thermal noise, we provide simplified single-integral expressions to compute the outage probability in a multi-carrier network. Numerical results demonstrate the performance of the proposed user-pairing scheme and validate the accuracy of the derived expressions. [ABSTRACT FROM AUTHOR]

Published

2022

81. Finite Block Length Analysis of RIS-Assisted UAV-Based Multiuser IoT Communication System With Non-Linear EH.

Author

Agrawal, Neelima, Bansal, Ankur, Singh, Keshav, Li, Chih-Peng, and Mumtaz, Shahid

Subjects

*NONLINEAR systems, *MONTE Carlo method, *INTERNET of things, *DISTRIBUTION (Probability theory), *TELECOMMUNICATION systems, *MULTIUSER computer systems, *ENERGY harvesting, *DRONE aircraft

Abstract

Reconfigurable intelligent surface (RIS) has emerged as an important transmission technology for numerous applications in Internet of Things (IoT) systems. Thus, in this paper, we investigate the application of RIS in energy harvesting (EH) based unmanned aerial vehicle (UAV) communication network with finite block length (BL) codes, where a rotary wing type flying UAV communicates with the multiple single antenna IoT users with the aid of multiple RISs mounted on several skyscraper buildings. To transmit the signal to a particular IoT user, the UAV selects an RIS on the basis of either UAV-RIS (i.e., partial) or UAV-RIS-IoT (i.e., full) channel state information (CSI) and then transmits the signal through the selected RIS along with the direct link transmission. In particular, we derive (i) the expression for probability of RIS selection, (ii) the statistical distribution of instantaneously received information signal-to-noise ratio (SNR) at the IoT user. Based on the derived statistics, we analyze the performance of the considered system under finite BL codes in terms of the average outage probability, average block error rate (ABLER) and goodput averaged over entire flying duration. Moreover, the BLER performance with finite BL codes is also compared with the infinite BL codes scenario. Additionally, we also investigate the impact of various channel and system parameters like imperfect CSI, number of RISs and the number of reflecting elements at each RIS, location of IoT users, variable altitude of the UAV, and the severity of channel fading of UAV-RIS link on the system performance. Furthermore, we have obtained the optimum UAV location in each time slot which minimizes the ABLER per time slot over all the users in the network. The analytical results are corroborated with Monte Carlo simulations. [ABSTRACT FROM AUTHOR]

Published

2022

82. Performance Analysis of MIMO-HARQ Assisted V2V Communications With Keyhole Effect.

Author

Zhang, Huan, Liao, Zhengtao, Shi, Zheng, Yang, Guanghua, Dou, Qingping, and Ma, Shaodan

Subjects

*RELIABILITY in engineering, *PROBABILITY theory, *SYMBOL error rate

Abstract

Vehicle-to-vehicle (V2V) communications under dense urban environments usually experience severe keyhole fading effect especially for multi-input multi-output (MIMO) channels, which degrades the capacity and outage performance due to the rank deficiency. To avoid these, the integration of MIMO and hybrid automatic repeat request (HARQ) is proposed to assist V2V communications in this paper. By using the methods of integral transforms, the outage probabilities are derived in closed-form for different HARQ-assisted schemes, including Type I-HARQ, HARQ with chase combining (HARQ-CC), and HARQ with incremental redundancy (HARQ-IR). With the results, meaningful insights are gained by conducting the asymptotic outage analysis. Specifically, it is revealed that full time diversity order can be achieved, while full spatial diversity order is unreachable as compared to MIMO-HARQ systems without keyhole effect. Moreover, we prove that the asymptotic outage probability is a monotonically increasing and convex function of the transmission rate. More importantly, although HARQ-IR performs better than HARQ-CC owing to its higher coding complexity, this advantage becomes negligible in the large-scale array regime. Finally, the numerical results are verified by Monte-Carlo simulations along with some in-depth discussions. [ABSTRACT FROM AUTHOR]

Published

2022

83. On the Performance of Multi-Antenna IRS-Assisted NOMA Networks With Continuous and Discrete IRS Phase Shifting.

Author

Sun, Zeyu and Jing, Yindi

Abstract

In this paper we study an intelligent reflecting surface (IRS) assisted non-orthogonal multiple access (NOMA) network where the direct link between the base station (BS) and one of the users is blocked and the IRS is deployed to serve the blocked user. The IRS designs under both the ideal IRS with continuous phase shifting and the non-ideal IRS with discrete phase shifting are considered. For both cases, by leveraging the isotropic random vector and the Laguerre series, we derive insightful results and closed-form expressions on performance measures including the average required transmit power, the outage probability, and the diversity order. Our analytical results show that the transmit power scales down linearly with the BS antenna number and quadratically with the IRS element number. The diversity order equals the smaller of the BS antenna number and the IRS element number with a scaling coefficient. Our results also reveal the effect of the phase quantization resolution to the system performance when non-ideal IRS is used. Numerical results are provided to validate the accuracy of our analysis and the non-ideal IRS with four or more bits for quantization is shown to achieve nearly the same performance as the ideal IRS. [ABSTRACT FROM AUTHOR]

Published

2022

84. Secrecy Outage Analysis of Two-Hop Decode-and-Forward Mixed RF/UWOC Systems.

Author

Lou, Yi, Sun, Ruofan, Cheng, Julian, Nie, Donghu, and Qiao, Gang

Abstract

The secrecy performance is analyzed for a two-hop mixed radio frequency (RF)/underwater wireless optical communication (UWOC) system using a decode-and-forward (DF) relay. All RF and UWOC links are modeled by the $\alpha -\mu $ and exponential-generalized Gamma distributions, respectively. We first derive the expressions of a lower bound of secrecy outage probability in closed-form, and these expressions are used to derive asymptotic expressions in simple functions at high signal-to-noise ratio. Moreover, based on the asymptotic expressions, we can numerically determine a suboptimal transmit power for a wide variety of RF and UWOC channel conditions. All analyses are validated using Monte Carlo simulation. [ABSTRACT FROM AUTHOR]

Published

2022

85. Performance of UAV-Assisted Multiuser Terrestrial-Satellite Communication System Over Mixed FSO/RF Channels.

Author

Singya, Praveen Kumar and Alouini, Mohamed-Slim

Subjects

*SYMBOL error rate, *TELECOMMUNICATION satellites, *TELECOMMUNICATION systems, *QUADRATURE amplitude modulation, *FREE-space optical technology, *HETERODYNE detection, *TRANSMITTING antennas

Abstract

In this letter, performance of a multiantenna multiuser unmanned aerial vehicle (UAV)-assisted terrestrial-satellite communication system over mixed free space optics (FSO)/radiofrequency (RF) channels is analyzed. Downlink transmission from the satellite to the UAV is completed through FSO link which follows gamma–gamma distribution with pointing error impairments. Both the heterodyne detection and intensity modulation direct detection techniques are considered at the FSO receiver. To avail the antenna diversity, multiple transmit antennas are considered at the UAV. Selective decode-and-forward scheme is assumed at the UAV and opportunistic user scheduling is performed while considering the practical constraints of outdated channel state information (CSI) during the user selection and transmission phase. The RF links are assumed to follow Nakagami-m distribution due to its versatile nature. In this context, for the performance analysis, analytical expressions of outage probability, asymptotic outage probability, ergodic capacity, effective capacity, and generalized average symbol-error-rate expressions of various quadrature amplitude modulation (QAM) schemes such as hexagonal-QAM, cross-QAM, and rectangular QAM are derived. A comparison of various modulation schemes is presented. Further, the impact of pointing error, number of antennas, delay constraint, fading severity, and imperfect CSI are highlighted on the system performance. Finally, all the analytical results are verified through the Monte–Carlo simulations. [ABSTRACT FROM AUTHOR]

Published

2022

86. Performance of Dual-Hop Relaying for OWC System Over Foggy Channel With Pointing Errors and Atmospheric Turbulence.

Author

Rahman, Ziyaur, Shah, Tejas, Zafaruddin, Syed Mohammad, and Chaubey, Vinod

Subjects

*ATMOSPHERIC turbulence, *DISTRIBUTION (Probability theory), *OPTICAL communications, *ATTENUATION coefficients, *WIRELESS communications, *SIGNAL-to-noise ratio

Abstract

Optical wireless communication (OWC) over atmospheric turbulence and pointing errors is a well-studied topic. Still, there is limited research on signal fading due to random fog in an outdoor environment for terrestrial wireless communications. In this paper, we analyze the performance of a decode-and-forward (DF) relaying under the combined effect of random fog, pointing errors, and atmospheric turbulence with a negligible line-of-sight (LOS) direct link. We consider a generalized model for the end-to-end channel with independent and not identically distributed (i.ni.d.) pointing errors, random fog with Gamma distributed attenuation coefficient, double generalized gamma (DGG) atmospheric turbulence, and asymmetrical distance between the source and destination. We develop density and distribution functions of signal-to-noise ratio (SNR) under the combined effect of random fog, pointing errors, and atmospheric turbulence (FPT) channel and distribution function for the combined channel with random fog and pointing errors (FP). Using the derived statistical results, we present analytical expressions of the outage probability, average SNR, ergodic rate, and average bit error rate (BER) for both FP and FPT channels in terms of OWC system parameters. We also develop simplified and asymptotic performance analysis to provide insight on the system behavior analytically under various practically relevant scenarios. We demonstrate the mutual effects of channel impairments and pointing errors on the OWC performance, and show that the relaying system provides significant performance improvement compared with the direct transmissions, especially when pointing errors and fog becomes more pronounced. [ABSTRACT FROM AUTHOR]

Published

2022

87. Performance Analysis of Satellite Communication System Under the Shadowed-Rician Fading: A Stochastic Geometry Approach.

Author

Jung, Dong-Hyun, Ryu, Joon-Gyu, Byun, Woo-Jin, and Choi, Junil

Subjects

*TELECOMMUNICATION satellites, *STOCHASTIC geometry, *LIMIT theorems, *LOW earth orbit satellites, *SYMBOL error rate, *POINT processes

Abstract

In this paper, we consider downlink low Earth orbit (LEO) satellite communication systems where multiple LEO satellites are uniformly distributed over a sphere at a certain altitude according to a homogeneous binomial point process (BPP). Based on the characteristics of the BPP, we analyze the distance distributions and the distribution cases for the serving satellite. We analytically derive the exact outage probability, and its approximated expression is obtained using the Poisson limit theorem. With these derived expressions, the system throughput maximization problem is formulated under the satellite-visibility and outage constraints. To solve this problem, we reformulate it with bounded feasible sets and propose an iterative algorithm to obtain near-optimal solutions. Simulation results perfectly match the derived exact expressions for the outage probability and system throughput. The analytical results of the approximated expressions are fairly close to those of the exact ones. It is also shown that the proposed algorithm for the throughput maximization is very close to the optimal performance obtained by a two-dimensional exhaustive search. [ABSTRACT FROM AUTHOR]

Published

2022

88. Unified Performance Analysis of Reconfigurable Intelligent Surface Empowered Free-Space Optical Communications.

Author

Chapala, Vinay Kumar and Zafaruddin, S. M.

Subjects

*FREE-space optical technology, *ATMOSPHERIC turbulence, *PROBABILITY density function, *CUMULATIVE distribution function, *HETERODYNE detection, *NUMBER systems

Abstract

Reconfigurable intelligent surface (RIS) is an excellent use case for line-of-sight (LOS) based technologies such as free-space optical (FSO) communications. In this paper, we analyze the performance of RIS-empowered FSO (RISE-FSO) systems by unifying Fisher-Snedecor (${\mathcal{F}}$), Gamma-Gamma ($\cal {GG}$), and Malága ($\cal {M}$) distributions for atmospheric turbulence with zero-boresight pointing errors over deterministic as well as random path-loss in foggy conditions with heterodyne detection (HD) and intensity modulation/direct detection (IM/DD) methods. By deriving the probability density function (PDF) and cumulative distribution function (CDF) of the direct-link (DL) with the statistical effect of atmospheric turbulence, pointing errors and random fog, we develop exact expressions of PDF and CDF of the resultant channel for the RISE-FSO system. Using the derived statistical results, we present exact expressions of outage probability, average bit-error-rate (BER), ergodic capacity, and moments of signal-to-noise ratio (SNR) for both DL-FSO and RISE-FSO systems. We also develop an asymptotic analysis of the outage probability and average BER and derive the diversity order of the considered systems. We validate the analytical expressions using Monte-Carlo simulations and demonstrate the performance scaling of the FSO system with the number of RIS elements for various turbulence channels, detection techniques, and weather conditions. [ABSTRACT FROM AUTHOR]

Published

2022

89. Prediction Method of the Breakdown Probability for Multiple Vacuum Gaps in Series Considering Dielectric Recovery Under a Lightning Impulse Voltage.

Author

Ma, Hui, Shen, Jingyu, Ding, Jian'gang, Chi, Dianyu, Liu, Zhiyuan, Geng, Yingsan, and Wang, Jianhua

Subjects

*VACUUM circuit breakers, *DIELECTRICS, *DIELECTRIC strength, *LIGHTNING, *VOLTAGE, *PROBABILITY theory

Abstract

The objective of this article is to propose a novel prediction method of the breakdown (BD) probability for multiple vacuum gaps (VGs) in series considering their dielectric recovery under a lightning impulse voltage. Based on the experimental data of the BD probability for each single VG and the calculated voltage distribution of multiple VGs, the BD probability of multiple VGs in series could be calculated by the proposed prediction method. By dielectric tests under the lightning impulse voltage, we see that the calculated BD probability distributions fit well with the experimental results for double VGs and triple VGs in series. Under sphere–plane electrode VGs, the prediction error was approximately 15% in the whole range of BD probabilities. The errors of the 50% BD voltage were 11.4% and 12.9% for double VGs and triple VGs in series, respectively. Therefore, the reliability of this prediction method considering the dielectric recovery was validated. This prediction method could be used to estimate the dielectric strength of multibreak vacuum circuit breaker (VCB) and multiple floating shields inside high-voltage vacuum interrupters. [ABSTRACT FROM AUTHOR]

Published

2022

90. Insulation Coordination Model Based on Breakdown Characteristics of Air-Gap Subjected to Damped Alternating Overvoltages.

Author

Sima, Wenxia, Huang, Yuhang, Sun, Potao, Yang, Ming, Xu, Jianwei, and Yuan, Tao

Subjects

*OVERVOLTAGE, *ELECTRIC breakdown, *SAFETY factor in engineering, *PREDICTION models, *ECONOMIC models, *SYSTEM safety

Abstract

This article examines and calculates the probability of failure probability of a rod-plane air gap (RPAG) under a damped alternating overvoltage (DAOV) based on a large amount of experimental data and the probability density distribution of measured overvoltages in a power system. By changing the length of the RPAG, the authors propose a prediction model for the breakdown characteristics of any length of RPAG, with the variable of DAOV parameters (including the damping factor and frequency). The results show that the model can adequately predict the breakdown characteristics of any RPAG under the action of the DAOV. Based on color channel representation, we show the results of 4-D prediction in the form of a 2-D graph. The authors combine this with a system economic model to develop a model for dynamic insulation coordination (DIC). With changes in the length of the RPAG, this model can dynamically characterize the safety factor of the system to efficiently and accurately determine whether the insulation for the air gap meets the relevant safety requirements. The proposed DIC model helps improve the accuracy of insulation design and can be used in industrial applications as a statistical method for coordinating insulations in power systems. [ABSTRACT FROM AUTHOR]

Published

2022

91. Performance Analysis of Intelligent Reflecting Surface Assisted NOMA Networks.

Author

Yue, Xinwei and Liu, Yuanwei

Abstract

Intelligent reflecting surface (IRS) is a promising technology to enhance the coverage and performance of wireless networks. We consider the application of IRS to non-orthogonal multiple access (NOMA), where a base station transmits superposed signals to multiple users by the virtue of an IRS. The performance of an IRS-assisted NOMA networks with imperfect successive interference cancellation (ipSIC) and perfect successive interference cancellation (pSIC) is investigated by invoking 1-bit coding scheme. In particular, we derive new exact and asymptotic expressions for both outage probability and ergodic rate of the $m$ -th user with ipSIC/pSIC. Based on analytical results, the diversity order of the $m$ -th user with pSIC is in connection with the number of reflecting elements and channel ordering. The high signal-to-noise radio (SNR) slope of ergodic rate for the $m$ -th user is obtained. The throughput and energy efficiency of IRS-NOMA networks are discussed both in delay-limited and delay-tolerant transmission modes. Additionally, we derive new exact expressions of outage probability and ergodic rate for IRS-assisted orthogonal multiple access (IRS-OMA). Numerical results are presented to substantiate our analyses and demonstrate that: i) The outage behaviors of IRS-NOMA are superior to that of IRS-OMA and relaying schemes; ii) The $M$ -th user has a larger ergodic rate than IRS-OMA and benchmarks. However, the ergodic performance of the $m$ -th user exceeds relaying schemes in the low SNR regime; and iii) The IRS-assisted NOMA networks have ability to achieve the enhanced energy efficiency compared to conventional cooperative communications. [ABSTRACT FROM AUTHOR]

Published

2022

92. NOMA and Coded Multicasting in Cache-Aided Wireless Networks.

Author

Dani, Muhammad Norfauzi, So, Daniel K. C., Tang, Jie, and Ding, Zhiguo

Abstract

Coded multicasting is considered to be an effective approach to simultaneously serve multiple users in the same frequency/time/code resource, which is made possible by exploiting the information available in users’ caches. Recently, non-orthogonal multiple access (NOMA) has emerged as an alternative transmission technique for cache-aided network. In cache-aided NOMA system, cache-enabled interference cancellation (CIC) is employed to cancel the interference using the information in the cache, and thus enhance the user transmission rate, particularly for the weak users. Despite the enhanced spectral efficiency offered by both techniques, complexity issue arises from handling large number of users. Therefore, user pairing/clustering should be employed to limit the number of users served in the same time-frequency resource. However, the key question is which delivery technique performs better under different pairing scenarios. In this paper, the performance of NOMA and coded multicasting for two-user pairing are investigated in terms of probability of sum rate comparison and outage probability. In order to exploit the benefits of NOMA and coded multicasting, we also propose a hybrid delivery scheme, which select either NOMA or coded multicasting depending on the channel conditions of the paired users in each resource block (RB). A joint mode selection, power allocation and user pairing scheme is developed to enhance the performance of the hybrid scheme. Both analytical and simulation results demonstrate that NOMA outperforms coded multicasting when pairing users whose channel gains are highly distinctive, while coded multicasting is preferred when the paired users have similar channel gains. In addition, the hybrid scheme is demonstrated to offer enhanced sum rate performance in comparison to NOMA and coded multicasting. [ABSTRACT FROM AUTHOR]

Published

2022

93. On the performance of a relay assisted hybrid RF-NLOS UVC system with imperfect channel estimation.

Author

Garg, Kamal K., Shaik, Parvez, Bhatia, Vimal, and Krejcar, Ondrej

Abstract

Non-line-of-sight (NLOS) ultraviolet communication (UVC) is emerging as an attractive optical wireless communication technology that enables wireless connectivity in radio-frequency (RF) prohibited areas with no LOS availability. NLOS UVC, however, suffers from a very high path loss, thereby restricting its usage to smaller link distances. In this paper, we address the challenge of providing long-distance wireless connectivity to RF prohibited areas by mixing NLOS UVC with RF communication using a decode-and-forward relay. The RF link is modeled using Rayleigh distribution, and the NLOS UV link is modeled using lognormal distribution under weak turbulence conditions. A framework for analytical expressions of the outage probability and probability density function (PDF) of the end-to-end signal-to-noise ratio is presented by considering the practical scenario of imperfect channel state information (CSI) at the receiver. Subsequently, a PDF based novel closed-form analytical expression of the average symbol error rate is deduced for spectrally efficient higher-order modulation schemes, including rectangular quadrature modulation (RQAM), square QAM (SQAM), cross-QAM (XQAM), and hexagonal QAM (HQAM). Numerical investigations are conducted, and the impact of CSI imperfections on the system performance is evaluated. It is shown that the RF link is more vulnerable to channel estimation error (CEE) than the NLOS UV link. Further, it is illustrated that for constellation sizes greater than four, HQAM always performs better than the RQAM, SQAM, and XQAM schemes, irrespective of the amount of CEE present. Furthermore, it is shown that an elevation angle of 70° or less in the NLOS UVC link results in better outage performance. Correctness of the derived analytical expressions is supported through extensive Monte Carlo simulations [ABSTRACT FROM AUTHOR]

Published

2022

94. Blind Detection and Identification of Polar Codes Based on the Parity Check Conformity.

Author

Liu, Qian, Zhang, Hao, and Yu, Peidong

Abstract

Polar code is an emerging error-correcting code. The blind detection and identification of polar codes are less studied. This letter proposes an algorithm to determine whether a bitstream is encoded with polar codes. Also, the proposed algorithm identifies the frame synchronization, code block length, rate, and the frozen-bit locations of the polar code by calculating the proposed parity check conformity of the soft-output sequence. Our method has lower computational complexity than the general methods because it does not need a decoding process. Simulation results also indicate that our algorithm performs well under low SNR. [ABSTRACT FROM AUTHOR]

Published

2022

95. Misper-Bayes: A Bayesian Network Model for Missing Person Investigations

Author

Denis Reilly, Mark Taylor, Paul Fergus, Carl Chalmers, and Steven Thompson

Subjects

Algorithms, Bayesian methods, computer and information processing, decision support systems, modeling, probability, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Bayesian Networks are probabilistic graph models that can be used for classification, prediction, diagnosis and parameter learning. Probabilities can be inferred from the models and missing values can be imputed, based on probability theory. Missing person cases place a strain on the already overstretched resources of Police Forces. Such cases predominantly come from at risk groups such as children in care and people suffering from depression or dementia. Current approaches for dealing with such cases are manual and rely upon empirical studies and domain knowledge. This paper proposes the use of a Bayesian Network model, which can be used to predict the likely location of a missing person (misper) for a number of at risk groups. The model is evaluated using a set of misper cases and results compare very favourably with those of the manual processes currently used by UK Police forces. The novel approach described provides both a theoretical foundation and a practical framework for the future development of a decision support system. In addition to the model, a contribution is made through guidelines, which recount experiences in learning a Bayesian Network from data.

Published

2021

96. Spatio-Spectral Feature Representation for Motor Imagery Classification Using Convolutional Neural Networks.

Author

Bang, Ji-Seon, Lee, Min-Ho, Fazli, Siamac, Guan, Cuntai, and Lee, Seong-Whan

Subjects

*CONVOLUTIONAL neural networks, *MOTOR imagery (Cognition), *ELECTROENCEPHALOGRAPHY, *BRAIN-computer interfaces

Abstract

Convolutional neural networks (CNNs) have recently been applied to electroencephalogram (EEG)-based brain–computer interfaces (BCIs). EEG is a noninvasive neuroimaging technique, which can be used to decode user intentions. Because the feature space of EEG data is highly dimensional and signal patterns are specific to the subject, appropriate methods for feature representation are required to enhance the decoding accuracy of the CNN model. Furthermore, neural changes exhibit high variability between sessions, subjects within a single session, and trials within a single subject, resulting in major issues during the modeling stage. In addition, there are many subject-dependent factors, such as frequency ranges, time intervals, and spatial locations at which the signal occurs, which prevent the derivation of a robust model that can achieve the parameterization of these factors for a wide range of subjects. However, previous studies did not attempt to preserve the multivariate structure and dependencies of the feature space. In this study, we propose a method to generate a spatiospectral feature representation that can preserve the multivariate information of EEG data. Specifically, 3-D feature maps were constructed by combining subject-optimized and subject-independent spectral filters and by stacking the filtered data into tensors. In addition, a layer-wise decomposition model was implemented using our 3-D-CNN framework to secure reliable classification results on a single-trial basis. The average accuracies of the proposed model were 87.15% (±7.31), 75.85% (±12.80), and 70.37% (±17.09) for the BCI competition data sets IV_2a, IV_2b, and OpenBMI data, respectively. These results are better than those obtained by state-of-the-art techniques, and the decomposition model obtained the relevance scores for neurophysiologically plausible electrode channels and frequency domains, confirming the validity of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2022

97. Line-of-Sight Probability in Cluttered Urban Microcells: Analyses Using Poisson Point Process and Point Cloud.

Author

Koivumaki, Pasi, Molisch, Andreas F., and Haneda, Katsuyuki

Subjects

*POISSON processes, *POINT cloud, *STREET signs, *PROBABILITY theory, *RAY tracing, *POINT processes, *CHANNEL estimation

Abstract

Line-of-sight (LOS) probability is a key component of system-level simulations that are required for creating new standards and recommendations for wireless systems. In particular, for millimeter-wave systems, an unobstructed view between the base station at an elevation and a user at ground level is important to ensure high-throughput service. While statistical models for LOS blockage by buildings exist, such models for blockage by multiple small objects, such as trees and street signs, are currently lacking. In this work, we present a Poisson point process-based analytic solution in a form of an algorithm for evaluating LOS probability in the presence of any combination of arbitrarily shaped shadowing objects, taking into account carrier frequency. The algorithm is validated against the LOS probability obtained from ray tracing in a realistic urban microcell scenario. [ABSTRACT FROM AUTHOR]

Published

2022

98. Estimation of the Trap Energy Characteristics of Row Hammer-Affected Cells in Gamma-Irradiated DDR4 DRAM.

Author

Baeg, Sanghyeon, Yun, Donghyuk, Chun, Myungsun, and Wen, Shi-Jie

Subjects

*DYNAMIC random access memory, *ELECTRON traps, *ELECTRON emission, *GAMMA rays

Abstract

Dynamic random access memory (DRAM) bits can be erroneously flipped when the row near the error bits is repeatedly accessed with the activate and precharge commands in a process called row hammering. The trap at an Si–SiO2 interface has been previously reported as the leading cause of such errors. The number of row hammering required for flipping bits initially decreases and then saturates with the increases in the row precharge time ($t_{\mathrm {RP}}$). The DRAM timing parameter is the time interval between an activate command and a precharge command. This study uses the saturation $t_{\mathrm {RP}}$ to estimate the electron emission time of the trap associated with a DRAM bit error. During $t_{\mathrm {RP}}$ time, the traps at the Si–SiO2 interface emit the trapped electrons. There are more chances of emission as $t_{\mathrm {RP}}$ increases, and less row hammering is needed. The emission time of a trapped electron is experimentally measured herein using commercial DDR4 components. The components are irradiated with gamma rays to induce the interface traps. The trap characteristics are then extracted without requiring an additional measurement setup with a device-level preparation. The trap energies with respect to the mid-band at the Si–SiO2 interface are 0.118–0.280 eV. The trap energies are distributed within approximately 5.6 kT energies at room temperature. [ABSTRACT FROM AUTHOR]

Published

2022

99. Outage Probability for OTFS Based Downlink LEO Satellite Communication.

Author

Shi, Jia, Hu, Junfan, Yue, Yang, Xue, Xuan, Liang, Wei, and Li, Zan

Subjects

*TELECOMMUNICATION satellites, *LOW earth orbit satellites, *DOPPLER effect, *SYMBOL error rate, *DRONE aircraft, *TELECOMMUNICATION systems, *PROBABILITY theory

Abstract

As an important technique of enabling global access for 6G, low earth orbit satellite (LEO-Sat) communication is still facing the challenges of large path-loss, and severe Doppler effect. This paper studies the reliability performance of a downlink LEO-Sat communication system, where the orthogonal time frequency space (OTFS) scheme is employed to combat severe Doppler effect. Further, the unmanned aerial vehicle (UAV) based cooperative transmission is developed, in order to compensate for the large margin of path-loss caused by the long transmission distance. In particular, the closed-form expression for the outage probability of the OTFS based LEO-Sat transmission is derived, where the novel moment matching approach is used to closely approximate the PDF of a sum of shadowing Rician (SR) variables. Further, the condition of using UAV cooperation is obtained so that the positive reliability gain is guaranteed. Finally, both the theoretical analysis and simulation results show that, the OTFS scheme can significantly outperform the traditional OFDM scheme, while demanding to carefully address the trade-off between reliability improvement and implementation complexity determined by modulation size. [ABSTRACT FROM AUTHOR]

Published

2022

100. Reconfigurable Intelligent Surface Enabled Vehicular Communication: Joint User Scheduling and Passive Beamforming.

Author

Al-Hilo, Ahmed, Samir, Moataz, Elhattab, Mohamed, Assi, Chadi, and Sharafeddine, Sanaa

Subjects

*BEAMFORMING, *REINFORCEMENT learning, *DEEP learning, *SCHEDULING, *MARKOV processes, *MULTICASTING (Computer networks)

Abstract

Given its ability to control and manipulate wireless environments, reconfigurable intelligent surface (RIS), also known as intelligent reflecting surface (IRS), has emerged as a key enabler technology for the six-generation (6G) cellular networks. In the meantime, vehicular environment radio propagation is negatively influenced by a large set of objects that cause transmission distortion such as high buildings. Therefore, this work is devoted to explore the area of RIS technology integration with vehicular communications while considering the dynamic nature of such communication environment. Specifically, we provide a system model where RoadSide Unit (RSU) leverages RIS to provide indirect wireless transmissions to disconnected areas, known as dark zones. Dark zones are spots within RSU coverage where the communication links are blocked due to the existence of blockages. In details, a discrete RIS is utilized to provide communication links between the RSU and the vehicles passing through out-of-service zones. Therefore, the joint problem of RSU resource scheduling and RIS passive beamforming or phase-shift matrix is formulated as an optimization problem with the objective of maximizing the minimum average bit rate. The formulated problem is mixed integer non-convex program which is difficult to be solved and does not account for the uncertain dynamic environment in vehicular networks. Thereby, we resort to alternative methods based on Deep Reinforcement Learning to determine RSU wireless scheduling and Block Coordinate Descent (BCD) to solve for the phase-shift matrix, i.e., passive beamforming, of the RIS. The Markov Decision Process (MDP) is defined and the complexity of the solution approach is discussed. Our numerical results demonstrate the superiority of our proposed approach over baseline techniques. [ABSTRACT FROM AUTHOR]

Published

2022