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    COMMUNICATIONS THEORIES & SYSTEMS
  • COMMUNICATIONS THEORIES & SYSTEMS
    UAMP-Based Delay-Doppler Channel Estimation for OTFS Systems
    Zhongjie Li, Weijie Yuan, Qinghua Guo, Nan Wu, Ji Zhang
    2024, 21(10): 1-15. https://doi.org/10.23919/JCC.ea.2023-0067.202401
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    Orthogonal time frequency space (OTFS) technique, which modulates data symbols in the delay-Doppler (DD) domain, presents a potential solution for supporting reliable information transmission in high-mobility vehicular networks. In this paper, we study the issues of DD channel estimation for OTFS in the presence of fractional Doppler. We first propose a channel estimation algorithm with both low complexity and high accuracy based on the unitary approximate message passing (UAMP), which exploits the structured sparsity of the effective DD domain channel using hidden Markov model (HMM). The empirical state evolution (SE) analysis is then leveraged to predict the performance of our proposed algorithm. To refine the hyperparameters in the proposed algorithm, we derive the update criterion for the hyperparameters through the expectation-maximization (EM) algorithm. Finally, Our simulation results demonstrate that our proposed algorithm can achieve a significant gain over various baseline schemes.
  • COMMUNICATIONS THEORIES & SYSTEMS
    Improved Variable Forgetting Factor Proportionate RLS Algorithm with Sparse Penalty and Fast Implementation Using DCD Iterations
    Zhen Han, Fengrui Zhang, Yu Zhang, Yanfeng Han, Peng Jiang
    2024, 21(10): 16-27. https://doi.org/10.23919/JCC.ja.2022-0367
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    The proportionate recursive least squares (PRLS) algorithm has shown faster convergence and better performance than both proportionate updating (PU) mechanism based least mean squares (LMS) algorithms and RLS algorithms with a sparse regularization term. In this paper, we propose a variable forgetting factor (VFF) PRLS algorithm with a sparse penalty, e.g., $l_1$-norm, for sparse identification. To reduce the computation complexity of the proposed algorithm, a fast implementation method based on dichotomous coordinate descent (DCD) algorithm is also derived. Simulation results indicate superior performance of the proposed algorithm.
  • COMMUNICATIONS THEORIES & SYSTEMS
    DR-IS: Dynamic Response Incremental Scheduling in Time-Sensitive Network
    Jinchuan Pei, Yuxiang Hu, Le Tian, Ziyong Li
    2024, 21(10): 28-42. https://doi.org/10.23919/JCC.ja.2023-0066
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    Time-Sensitive Network (TSN) with deterministic transmission capability is increasingly used in many emerging fields. It mainly guarantees the Quality of Service (QoS) of applications with strict requirements on time and security. One of the core features of TSN is traffic scheduling with bounded low delay in the network. However, traffic scheduling schemes in TSN are usually synthesized offline and lack dynamism. To implement incremental scheduling of newly arrived traffic in TSN, we propose a Dynamic Response Incremental Scheduling (DR-IS) method for time-sensitive traffic and deploy it on a software-defined time-sensitive network architecture. Under the premise of meeting the traffic scheduling requirements, we adopt two modes, traffic shift and traffic exchange, to dynamically adjust the time slot injection position of the traffic in the original scheme, and determine the sending offset time of the new time-sensitive traffic to minimize the global traffic transmission jitter. The evaluation results show that DR-IS method can effectively control the large increase of traffic transmission jitter in incremental scheduling without affecting the transmission delay, thus realizing the dynamic incremental scheduling of time-sensitive traffic in TSN.
  • COMMUNICATIONS THEORIES & SYSTEMS
    A Non-Stationary Beam-Enabled Stochastic Channel Model and Characterization over Non-Reciprocal Beam Patterns
    Jiachi Zhang, Liu Liu, Zhenhui Tan, Kai Wang, Lu Li, Tao Zhou
    2024, 21(10): 43-58. https://doi.org/10.23919/JCC.ea.2022-0292.202401
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    The multiple-input multiple-output (MIMO)-enabled beamforming technology offers great data rate and channel quality for next-generation communication. In this paper, we propose a beam channel model and enable it with time-varying simulation capability by adopting the stochastic geometry theory. First, clusters are generated located within transceivers' beam ranges based on the Matérn hard-core Poisson cluster process. The line-of-sight, single-bounce, and double-bounce components are calculated when generating the complex channel impulse response. Furthermore, we elaborate on the expressions of channel links based on the propagation-graph theory. A birth-death process consisting of the effects of beams and cluster velocities is also formulated. Numerical simulation results prove that the proposed model can capture the channel non-stationarity. Besides, the non-reciprocal beam patterns yield severe channel dispersion compared to the reciprocal patterns.
  • COMMUNICATIONS THEORIES & SYSTEMS
    Blind Recognition of Non-Binary LDPC Codes Based on Ant Colony Optimization
    Mengsheng Guan, Wanting Gao, Qi Chen, Min Zhu, Baoming Bai
    2024, 21(10): 59-69. https://doi.org/10.23919/JCC.fa.2024-0286.202410
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    This paper introduces a novel blind recognition of non-binary low-density parity-check (LDPC) codes without a candidate set, using ant colony optimization (ACO) algorithm over additive white Gaussian noise (AWGN) channels. Specifically, the scheme that effectively combines the ACO algorithm and the non-binary elements over finite fields is proposed. Furthermore, an improved, simplified elitist ACO algorithm based on soft decision reliability is introduced to recognize the parity-check matrix over noisy channels. Simulation results show that the recognition rate continuously increases with an increased signal-to-noise ratio (SNR) over the AWGN channel.
  • COMMUNICATIONS THEORIES & SYSTEMS
    Parallel Implementation of the CCSDS Turbo Decoder on GPU
    Zhanxian Liu, Rongke Liu, Haijun Zhang, Ning Wang, Lei Sun, Jianquan Wang
    2024, 21(10): 70-77. https://doi.org/10.23919/JCC.2023.00.101
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    This paper presents a software turbo decoder on graphics processing units (GPU). Unlike previous works, the proposed decoding architecture for turbo codes mainly focuses on the Consultative Committee for Space Data Systems (CCSDS) standard. However, the information frame lengths of the CCSDS turbo codes are not suitable for flexible sub-frame parallelism design. To mitigate this issue, we propose a padding method that inserts several bits before the information frame header. To obtain low-latency performance and high resource utilization, two-level intra-frame parallelisms and an efficient data structure are considered. The presented Max-Log-Map decoder can be adopted to decode the Long Term Evolution (LTE) turbo codes with only small modifications. The proposed CCSDS turbo decoder at 10 iterations on NVIDIA RTX3070 achieves about 150 Mbps and 50 Mbps throughputs for the code rates 1/6 and 1/2, respectively.
  • COMMUNICATIONS THEORIES & SYSTEMS
    Deep Learning Based Signal Detection for Quadrature Spatial Modulation System
    Dingyun Shu, Yuyang Peng, Ming Yue, Fawaz AL-Hazemi, Mohammad Meraj Mirza
    2024, 21(10): 78-85. https://doi.org/10.23919/JCC.ea.2023-0153.202401
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    With the development of communication systems, modulation methods are becoming more and more diverse. Among them, quadrature spatial modulation (QSM) is considered as one method with less capacity and high efficiency. In QSM, the traditional signal detection methods sometimes are unable to meet the actual requirement of low complexity of the system. Therefore, this paper proposes a signal detection scheme for QSM systems using deep learning to solve the complexity problem. Results from the simulations show that the bit error rate performance of the proposed deep learning-based detector is better than that of the zero-forcing (ZF) and minimum mean square error (MMSE) detectors, and similar to the maximum likelihood (ML) detector. Moreover, the proposed method requires less processing time than ZF, MMSE, and ML.
  • COMMUNICATIONS THEORIES & SYSTEMS
    Multi-User Semantic Fusion for Semantic Communications over Degraded Broadcast Channels
    Tong Wu, Zhiyong Chen, Meixia Tao, Bin Xia, Wenjun Zhang
    2024, 21(10): 86-100. https://doi.org/10.23919/JCC.fa.2023-0766.202410
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    Degraded broadcast channels (DBC) are a typical multiuser communication scenario, Semantic communications over DBC still lack in-depth research. In this paper, we design a semantic communications approach based on multi-user semantic fusion for wireless image transmission over DBC. The transmitter extracts semantic features for two users separately and then effectively fuses them for broadcasting by leveraging semantic similarity. Unlike traditional allocation of time, power, or bandwidth, the semantic fusion scheme can dynamically control the weight of the semantic features of the two users to balance their performance. Considering the different channel state information (CSI) of both users over DBC, a DBC-Aware method is developed that embeds the CSI of both users into the joint source-channel coding encoder and fusion module to adapt to the channel. Experimental results show that the proposed system outperforms the traditional broadcasting schemes.
  • COMMUNICATIONS THEORIES & SYSTEMS
    Joint Active and Passive Beamforming Design for Hybrid RIS-Aided Integrated Sensing and Communication
    Hongyun Chu, Mengyao Yang, Xue Pan, Ge Xiao
    2024, 21(10): 101-112. https://doi.org/10.23919/JCC.ja.2023-0213
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    Integrated sensing and communication (ISAC) is considered an effective technique to solve spectrum congestion in the future. In this paper, we consider a hybrid reconfigurable intelligent surface (RIS)-assisted downlink ISAC system that simultaneously serves multiple single-antenna communication users and senses multiple targets. Hybrid RIS differs from fully passive RIS in that it is composed of both active and passive elements, with the active elements having the effect of amplifying the signal in addition to phase-shifting. We maximize the achievable sum rate of communication users by collaboratively improving the beamforming matrix at the dual function base station (DFBS) and the phase-shifting matrix of the hybrid RIS, subject to the transmit power constraint at the DFBS, the signal-to-interference-plus-noise-ratio (SINR) constraint of the radar echo signal and the RIS constraint are satisfied at the same time. The built-in RIS-assisted ISAC design problem model is significantly non-convex due to the fractional objective function of this optimization problem and the coupling of the optimization variables in the objective function and constraints. As a result, we provide an effective alternating optimization approach based on fractional programming (FP) with block coordinate descent (BCD) to solve the optimization variables. Results from simulations show that the hybrid RIS-assisted ISAC system outperforms the other benchmark solutions.
  • COMMUNICATIONS THEORIES & SYSTEMS
    Hybrid Seagull and Whale Optimization Algorithm-Based Dynamic Clustering Protocol for Improving Network Longevity in Wireless Sensor Networks
    P. Vinoth Kumar, K. Venkatesh
    2024, 21(10): 113-131. https://doi.org/10.23919/JCC.ea.2022-0141.202401
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    Energy efficiency is the prime concern in Wireless Sensor Networks (WSNs) as maximized energy consumption without essentially limits the energy stability and network lifetime. Clustering is the significant approach essential for minimizing unnecessary transmission energy consumption with sustained network lifetime. This clustering process is identified as the Non-deterministic Polynomial (NP)-hard optimization problems which has the maximized probability of being solved through metaheuristic algorithms. This adoption of hybrid metaheuristic algorithm concentrates on the identification of the optimal or near-optimal solutions which aids in better energy stability during Cluster Head (CH) selection. In this paper, Hybrid Seagull and Whale Optimization Algorithm-based Dynamic Clustering Protocol (HSWOA-DCP) is proposed with the exploitation benefits of WOA and exploration merits of SEOA to optimal CH selection for maintaining energy stability with prolonged network lifetime. This HSWOA-DCP adopted the modified version of SEagull Optimization Algorithm (SEOA) to handle the problem of premature convergence and computational accuracy which is maximally possible during CH selection. The inclusion of SEOA into WOA improved the global searching capability during the selection of CH and prevents worst fitness nodes from being selected as CH, since the spiral attacking behavior of SEOA is similar to the bubble-net characteristics of WOA. This CH selection integrates the spiral attacking principles of SEOA and contraction surrounding mechanism of WOA for improving computation accuracy to prevent frequent election process. It also included the strategy of levy flight strategy into SEOA for potentially avoiding premature convergence to attain better trade-off between the rate of exploration and exploitation in a more effective manner. The simulation results of the proposed HSWOA-DCP confirmed better network survivability rate, network residual energy and network overall throughput on par with the competitive CH selection schemes under different number of data transmission rounds. The statistical analysis of the proposed HSWOA-DCP scheme also confirmed its energy stability with respect to ANOVA test.
    • NETWORKS & SECURITY
  • NETWORKS & SECURITY
    A High Resolution Convolutional Neural Network with Squeeze and Excitation Module for Automatic Modulation Classification
    Ruifeng Duan, Yuanlin Zhao, Haiyan Zhang, Xinze Li, Peng Cheng, Yonghui Li
    2024, 21(10): 132-147. https://doi.org/10.23919/JCC.ja.2022-0270
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    Automatic modulation classification (AMC) technology is one of the cutting-edge technologies in cognitive radio communications. AMC based on deep learning has recently attracted much attention due to its superior performances in classification accuracy and robustness. In this paper, we propose a novel, high resolution and multi-scale feature fusion convolutional neural network model with a squeeze-excitation block, referred to as HRSENet, to classify different kinds of modulation signals. The proposed model establishes a parallel computing mechanism of multi-resolution feature maps through the multi-layer convolution operation, which effectively reduces the information loss caused by down-sampling convolution. Moreover, through dense skip-connecting at the same resolution and up-sampling or down-sampling connection at different resolutions, the low resolution representation of the deep feature maps and the high resolution representation of the shallow feature maps are simultaneously extracted and fully integrated, which is benificial to mine signal multi-level features. Finally, the feature squeeze and excitation module embedded in the decoder is used to adjust the response weights between channels, further improving classification accuracy of proposed model. The proposed HRSENet significantly outperforms existing methods in terms of classification accuracy on the public dataset "Over the Air" in signal-to-noise (SNR) ranging from-2dB to 20dB. The classification accuracy in the proposed model achieves 85.36% and 97.30% at 4dB and 10dB, respectively, with the improvement by 9.71% and 5.82% compared to LWNet. Furthermore, the model also has a moderate computation complexity compared with several state-of-the-art methods.
  • NETWORKS & SECURITY
    MDTCNet: Multi-Task Classifications Network and TCNN for Direction of Arrival Estimation
    Jiarun Yu, Yafeng Wang
    2024, 21(10): 148-166. https://doi.org/10.23919/JCC.fa.2022-0619.202410
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    The direction-of-arrival (DoA) estimation is one of the hot research areas in signal processing. To overcome the DoA estimation challenge without the prior information about signal sources number and multipath number in millimeter wave system, the multi-task deep residual shrinkage network (MT-DRSN) and transfer learning-based convolutional neural network (TCNN), namely MDTCNet, are proposed. The sampling covariance matrix based on the received signal is used as the input to the proposed network. A DRSN-based multi-task classifications model is first introduced to estimate signal sources number and multipath number simultaneously. Then, the DoAs with multi-signal and multipath are estimated by the regression model. The proposed CNN is applied for DoAs estimation with the predicted number of signal sources and paths. Furthermore, the model-based transfer learning is also introduced into the regression model. The TCNN inherits the partial network parameters of the already formed optimization model obtained by the CNN. A series of experimental results show that the MDTCNet-based DoAs estimation method can accurately predict the signal sources number and multipath number under a range of signal-to-noise ratios. Remarkably, the proposed method achieves the lower root mean square error compared with some existing deep learning-based and traditional methods.% so as to reduce the out-of-band (OOB) radiation as much as possible. Parameters of the proposed scheme are solved under joint con-straints of constant power and unity cumulative distribution. A new receiving method is also proposed to improve the bit error rate (BER) performance of OFDM systems. Simulation results indicate the proposed scheme can achieve better OOB radiation and BER performance at same PAPR levels, compared with existing similar companding algorithms.
  • NETWORKS & SECURITY
    Energy Minimization for Heterogenous Traffic Coexistence with Puncturing in Mobile Edge Computing-Based Industrial Internet of Things
    Xue Wang, Ying Wang, Zixuan Fei, Junwei Zhao
    2024, 21(10): 167-180. https://doi.org/10.23919/JCC.ja.2022-0009
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    Puncturing has been recognized as a promising technology to cope with the coexistence problem of enhanced mobile broadband (eMBB) and ultra-reliable low latency communications (URLLC) traffic. However, the steady performance of eMBB traffic while meeting the requirements of URLLC traffic with puncturing is a major challenge in some realistic scenarios. In this paper, we pay attention to the timely and energy-efficient processing for eMBB traffic in the industrial Internet of Things (IIoT), where mobile edge computing (MEC) is employed for data processing. Specifically, the performance of eMBB traffic and URLLC traffic in a MEC-based IIoT system is ensured by setting the threshold of tolerable delay and outage probability, respectively. Furthermore, considering the limited energy supply, an energy minimization problem of eMBB device is formulated under the above constraints, by jointly optimizing the resource blocks (RBs) punctured by URLLC traffic, data offloading and transmit power of eMBB device. With Markov's inequality, the problem is reformulated by transforming the probabilistic outage constraint into a deterministic constraint. Meanwhile, an iterative energy minimization algorithm (IEMA) is proposed. Simulation results demonstrate that our algorithm has a significant reduction in the energy consumption for eMBB device and achieves a better overall effect compared to several benchmarks.
  • NETWORKS & SECURITY
    A Double-Timescale Reinforcement Learning Based Cloud-Edge Collaborative Framework for Decomposable Intelligent Services in Industrial Internet of Things
    Qiuyang Zhang, Ying Wang, Xue Wang
    2024, 21(10): 181-199. https://doi.org/10.23919/JCC.ja.2022-0281
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    With the proportion of intelligent services in the industrial internet of things (IIoT) rising rapidly, its data dependency and decomposability increase the difficulty of scheduling computing resources. In this paper, we propose an intelligent service computing framework. In the framework, we take the long-term rewards of its important participants, edge service providers, as the optimization goal, which is related to service delay and computing cost. Considering the different update frequencies of data deployment and service offloading, double-timescale reinforcement learning is utilized in the framework. In the small-scale strategy, the frequent concurrency of services and the difference in service time lead to the fuzzy relationship between reward and action. To solve the fuzzy reward problem, a reward mapping-based reinforcement learning (RMRL) algorithm is proposed, which enables the agent to learn the relationship between reward and action more clearly. The large time scale strategy adopts the improved Monte Carlo tree search (MCTS) algorithm to improve the learning speed. The simulation results show that the strategy is superior to popular reinforcement learning algorithms such as double Q-learning (DDQN) and dueling Q-learning (dueling-DQN) in learning speed, and the reward is also increased by 14%.
  • NETWORKS & SECURITY
    A Physical Security Technology Based upon Doubly Multiple Parameters Weighted Fractional Fourier Transform
    Yong Li, Teng Sun, Xuejun Sha, Zhiqun Song, Bin Wang
    2024, 21(10): 200-209. https://doi.org/10.23919/JCC.ea.2021-0244.202401
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    Enhancing the security of the wireless communication is necessary to guarantee the reliable of the data transmission, due to the broadcast nature of wireless channels. In this paper, we provide a novel technology referred to as doubly multiple parameters weighted fractional Fourier transform (DM-WFRFT), which can strengthen the physical layer security of wireless communication. This paper introduces the concept of DM-WFRFT based on multiple parameters WFRFT (MP-WFRFT), and then presents its four properties. Based on these properties, the parameters decryption probability is analyzed in terms of the number of parameters. The number of parameters for DM-WFRFT is more than that of the MP-WFRFT, which indicates that the proposed scheme can further strengthen the the physical layer security. Lastly, some numerical simulations are carried out to illustrate that the efficiency of proposed DM-WFRFT is related to preventing eavesdropping, and the effect of parameters variety on the system performance is associated with the bit error ratio (BER).
  • NETWORKS & SECURITY
    OFDM with Generalized Cascade Index Modulation for Secure Communications
    Zeng Hu, Xiaopin Jin, Yudong Yao, Chen Fangjiong, Dehuan Wan, Yun Liu
    2024, 21(10): 210-225. https://doi.org/10.23919/JCC.ea.2023-0052.202401
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    Cascade index modulation (CIM) is a recently proposed improvement of orthogonal frequency division multiplexing with index modulation (OFDM-IM) and achieves better error performance. In CIM, at least two different IM operations construct a super IM operation or achieve new functionality. First, we propose a OFDM with generalized CIM (OFDM-GCIM) scheme to achieve a joint IM of subcarrier selection and multiple-mode (MM) permutations by using a multilevel digital algorithm. Then, two schemes, called double CIM (D-CIM) and multiple-layer CIM (M-CIM), are proposed for secure communication, which combine new IM operation for disrupting the original order of bits and symbols with conventional OFDM-IM, to protect the legitimate users from eavesdropping in the wireless communications. A subcarrier-wise maximum likelihood (ML) detector and a low complexity log-likelihood ratio (LLR) detector are proposed for the legitimate users. A tight upper bound on the bit error rate (BER) of the proposed OFDM-GCIM, D-CIM and M-CIM at the legitimate users are derived in closed form by employing the ML criteria detection. Computer simulations and numerical results show that the proposed OFDM-GCIM achieves superior error performance than OFDM-IM, and the error performance at the eavesdroppers demonstrates the security of D-CIM and M-CIM.
    • EMERGING TECHNOLOGIES & APPLICATIONS
  • EMERGING TECHNOLOGIES & APPLICATIONS
    Joint Beam Scheduling and Power Optimization for Beam Hopping LEO Satellite Systems
    Shuang Zheng, Xing Zhang, Peng Wang, Wenbo Wang
    2024, 21(10): 226-239. https://doi.org/10.23919/JCC.ja.2022-0864
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    Low earth orbit (LEO) satellite communications can provide ubiquitous and reliable services, making it an essential part of the Internet of Everything network. Beam hopping (BH) is an emerging technology for effectively addressing the issue of low resource utilization caused by the non-uniform spatio-temporal distribution of traffic demands. However, how to allocate multi-dimensional resources in a timely and efficient way for the highly dynamic LEO satellite systems remains a challenge. This paper proposes a joint beam scheduling and power optimization beam hopping (JBSPO-BH) algorithm considering the differences in the geographic distribution of sink nodes. The JBSPO-BH algorithm decouples the original problem into two sub-problems. The beam scheduling problem is modelled as a potential game, and the Nash equilibrium (NE) point is obtained as the beam scheduling strategy. Moreover, the penalty function interior point method is applied to optimize the power allocation. Simulation results show that the JBSPO-BH algorithm has low time complexity and fast convergence and achieves better performance both in throughput and fairness. Compared with greedy-based BH, greedy-based BH with the power optimization, round-robin BH, Max-SINR BH and satellite resource allocation algorithm, the throughput of the proposed algorithm is improved by 44.99%, 20.79%, 156.06%, 15.39% and 8.17%, respectively.
  • EMERGING TECHNOLOGIES & APPLICATIONS
    Joint User Association and Satellite Selection for Satellite-Terrestrial Integrated networks
    Wenjing Qiu, Aijun Liu, Chen Han
    2024, 21(10): 240-255. https://doi.org/10.23919/JCC.fa.2022-0058.202410
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    In this paper, we investigate a cooperation mechanism for satellite-terrestrial integrated networks. The terrestrial relays act as the supplement of traditional small cells and cooperatively provide seamless coverage for users in the densely populated areas. To deal with the dynamic satellite backhaul links and backhaul capacity caused by the satellite mobility, severe co-channel interference in both satellite backhaul links and user links introduced by spectrum sharing, and the difference demands of users as well as heterogeneous characteristics of terrestrial backhaul and satellite backhaul, we propose a joint user association and satellite selection scheme to maximize the total sum rate. The optimization problem is formulated via jointly considering the influence of dynamic backhaul links, individual requirements and targeted interference management strategies, which is decomposed into two subproblems: user association and satellite selection. The user association is formulated as a non-convex optimization problem, and solved through a low-complexity heuristic scheme to find the most suitable access point serving each user. Then, the satellite selection is resolved based on the cooperation among terrestrial relays to maximize the total backhaul capacity with the minimum date rate constraints. Finally, simulation results show the effectiveness of the proposed scheme in terms of total sum rate and power efficiency of TRs' backhaul.
  • EMERGING TECHNOLOGIES & APPLICATIONS
    Wireless Information and Power Transfer in Underwater Acoustic Sensor Networks
    Yizhi Feng, Fei Ji
    2024, 21(10): 256-266. https://doi.org/10.23919/JCC.fa.2021-0186.202410
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    Wireless information and power transfer (WIPT) enables simultaneously communications and sustainable power supplement without the erection of power supply lines and the replacement operation of the batteries for the terminals. The application of WIPT to the underwater acoustic sensor networks (UWASNs) not only retains the long range communication capabilities, but also provides an auxiliary and convenient energy supplement way for the terminal sensors, and thus is a promising scheme to solve the energy-limited problem for the UWASNs. In this paper, we propose the integration of WIPT into the UWASNs and provide an overview on various enabling techniques for the WIPT based UWASNs (WIPT-UWASNs) as well as pointing out future research challenges and opportunities for WIPT-UWASNs.
  • EMERGING TECHNOLOGIES & APPLICATIONS
    An Intelligent SDN-IoT Enabled Intrusion Detection System for Healthcare Systems Using a Hybrid Deep Learning and Machine Learning Approach
    R Arthi, S Krishnaveni, Sherali Zeadally
    2024, 21(10): 267-287. https://doi.org/10.23919/JCC.ja.2022-0681
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    The advent of pandemics such as COVID-19 significantly impacts human behaviour and lives every day. Therefore, it is essential to make medical services connected to internet, available in every remote location during these situations. Also, the security issues in the Internet of Medical Things (IoMT) used in these service, make the situation even more critical because cyberattacks on the medical devices might cause treatment delays or clinical failures. Hence, services in the healthcare ecosystem need rapid, uninterrupted, and secure facilities. The solution provided in this research addresses security concerns and services availability for patients with critical health in remote areas. This research aims to develop an intelligent Software Defined Networks (SDNs) enabled secure framework for IoT healthcare ecosystem. We propose a hybrid of machine learning and deep learning techniques (DNN + SVM) to identify network intrusions in the sensor-based healthcare data. In addition, this system can efficiently monitor connected devices and suspicious behaviours. Finally, we evaluate the performance of our proposed framework using various performance metrics based on the healthcare application scenarios. the experimental results show that the proposed approach effectively detects and mitigates attacks in the SDN-enabled IoT networks and performs better that other state-of-art-approaches.
  • EMERGING TECHNOLOGIES & APPLICATIONS
    Effect of Types and Orders of Electromagnetic Field Finite Element Meshes on Power Communication Harmonic Parameters Calculation Results of Tubular Hydrogenerators
    Zhennan Fan, Jie Chen, Zhiting Zhou, Yong Yang
    2024, 21(10): 288-300. https://doi.org/10.23919/JCC.fa.2024-0197.202410
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    In generator design field, waveform total harmonic distortion (THD) and telephone harmonic factor (THF) are parameters commonly used to measure the impact of generator no-load voltage harmonics on the power communication quality. Tubular hydrogenerators are considered the optimal generator for exploiting low-head, high-flow hydro resources, and they have seen increasingly widespread application in China's power systems recent years. However, owing to the compact and constrained internal space of such generators, their internal magnetic-field harmonics are pronounced. Therefore, accurate calculation of their THD and THF is crucial during the analysis and design stages to ensure the quality of power communication. Especially in the electromagnetic field finite element modeling analysis of such generators, the type and order of the finite element meshes may have a significant impact on the THD and THF calculation results, which warrants in-depth research. To address this, this study takes a real 34 MW large tubular hydrogenerator as an example, and establishes its electromagnetic field finite element model under no-load conditions. Two types of meshes, five mesh densities, and two mesh orders are analyzed to reveal the effect of electromagnetic field finite element mesh types and orders on the calculation results of THD and THF for such generators.