Your search keyword '"Yang, Zhaohui"' showing total 231 results

1. On differential privacy for federated learning in wireless systems with multiple base stations

Author

Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., Poor, H. Vincent, Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., and Poor, H. Vincent

Abstract

In this work, we consider a federated learning model in a wireless system with multiple base stations and inter-cell interference. We apply a differentially private scheme to transmit information from users to their corresponding base station during the learning phase. We show the convergence behavior of the learning process by deriving an upper bound on its optimality gap. Furthermore, we define an optimization problem to reduce this upper bound and the total privacy leakage. To find the locally optimal solutions of this problem, we first propose an algorithm that schedules the resource blocks and users. We then extend this scheme to reduce the total privacy leakage by optimizing the differential privacy artificial noise. We apply the solutions of these two procedures as parameters of a federated learning system where each user is equipped with a classifier and communication cells have mostly fewer resource blocks than numbers of users. The simulation results show that our proposed scheduler improves the average accuracy of the predictions compared with a random scheduler. In particular, the results show an improvement of over 6%. Furthermore, its extended version with noise optimizer significantly reduces the amount of privacy leakage.

Published

2024

2. On differential privacy for federated learning in wireless systems with multiple base stations

Author

Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., Poor, H. Vincent, Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., and Poor, H. Vincent

Abstract

In this work, we consider a federated learning model in a wireless system with multiple base stations and inter-cell interference. We apply a differentially private scheme to transmit information from users to their corresponding base station during the learning phase. We show the convergence behavior of the learning process by deriving an upper bound on its optimality gap. Furthermore, we define an optimization problem to reduce this upper bound and the total privacy leakage. To find the locally optimal solutions of this problem, we first propose an algorithm that schedules the resource blocks and users. We then extend this scheme to reduce the total privacy leakage by optimizing the differential privacy artificial noise. We apply the solutions of these two procedures as parameters of a federated learning system where each user is equipped with a classifier and communication cells have mostly fewer resource blocks than numbers of users. The simulation results show that our proposed scheduler improves the average accuracy of the predictions compared with a random scheduler. In particular, the results show an improvement of over 6%. Furthermore, its extended version with noise optimizer significantly reduces the amount of privacy leakage.

Published

2024

3. On differential privacy for federated learning in wireless systems with multiple base stations

Author

Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., Poor, H. Vincent, Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., and Poor, H. Vincent

Abstract

In this work, we consider a federated learning model in a wireless system with multiple base stations and inter-cell interference. We apply a differentially private scheme to transmit information from users to their corresponding base station during the learning phase. We show the convergence behavior of the learning process by deriving an upper bound on its optimality gap. Furthermore, we define an optimization problem to reduce this upper bound and the total privacy leakage. To find the locally optimal solutions of this problem, we first propose an algorithm that schedules the resource blocks and users. We then extend this scheme to reduce the total privacy leakage by optimizing the differential privacy artificial noise. We apply the solutions of these two procedures as parameters of a federated learning system where each user is equipped with a classifier and communication cells have mostly fewer resource blocks than numbers of users. The simulation results show that our proposed scheduler improves the average accuracy of the predictions compared with a random scheduler. In particular, the results show an improvement of over 6%. Furthermore, its extended version with noise optimizer significantly reduces the amount of privacy leakage.

Published

2024

4. On differential privacy for federated learning in wireless systems with multiple base stations

Author

Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., Poor, H. Vincent, Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., and Poor, H. Vincent

Abstract

In this work, we consider a federated learning model in a wireless system with multiple base stations and inter-cell interference. We apply a differentially private scheme to transmit information from users to their corresponding base station during the learning phase. We show the convergence behavior of the learning process by deriving an upper bound on its optimality gap. Furthermore, we define an optimization problem to reduce this upper bound and the total privacy leakage. To find the locally optimal solutions of this problem, we first propose an algorithm that schedules the resource blocks and users. We then extend this scheme to reduce the total privacy leakage by optimizing the differential privacy artificial noise. We apply the solutions of these two procedures as parameters of a federated learning system where each user is equipped with a classifier and communication cells have mostly fewer resource blocks than numbers of users. The simulation results show that our proposed scheduler improves the average accuracy of the predictions compared with a random scheduler. In particular, the results show an improvement of over 6%. Furthermore, its extended version with noise optimizer significantly reduces the amount of privacy leakage.

Published

2024

5. On differential privacy for federated learning in wireless systems with multiple base stations

Author

Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., Poor, H. Vincent, Tavangaran, Nima, Chen, Mingzhe, Yang, Zhaohui, Da Silva Jr., José Mairton B., and Poor, H. Vincent

Abstract

In this work, we consider a federated learning model in a wireless system with multiple base stations and inter-cell interference. We apply a differentially private scheme to transmit information from users to their corresponding base station during the learning phase. We show the convergence behavior of the learning process by deriving an upper bound on its optimality gap. Furthermore, we define an optimization problem to reduce this upper bound and the total privacy leakage. To find the locally optimal solutions of this problem, we first propose an algorithm that schedules the resource blocks and users. We then extend this scheme to reduce the total privacy leakage by optimizing the differential privacy artificial noise. We apply the solutions of these two procedures as parameters of a federated learning system where each user is equipped with a classifier and communication cells have mostly fewer resource blocks than numbers of users. The simulation results show that our proposed scheduler improves the average accuracy of the predictions compared with a random scheduler. In particular, the results show an improvement of over 6%. Furthermore, its extended version with noise optimizer significantly reduces the amount of privacy leakage.

Published

2024

6. Energy-Guided Data Sampling for Traffic Prediction with Mini Training Datasets

Author

Yang, Zhaohui, Jerath, Kshitij, Yang, Zhaohui, and Jerath, Kshitij

Abstract

Recent endeavors aimed at forecasting future traffic flow states through deep learning encounter various challenges and yield diverse outcomes. A notable obstacle arises from the substantial data requirements of deep learning models, a resource often scarce in traffic flow systems. Despite the abundance of domain knowledge concerning traffic flow dynamics, prevailing deep learning methodologies frequently fail to fully exploit it. To address these issues, we propose an innovative solution that merges Convolutional Neural Networks (CNNs) with Long Short-Term Memory (LSTM) architecture to enhance the prediction of traffic flow dynamics. A key revelation of our research is the feasibility of sampling training data for large traffic systems from simulations conducted on smaller traffic systems. This insight suggests the potential for referencing a macroscopic-level distribution to inform the sampling of microscopic data. Such sampling is facilitated by the observed scale invariance in the normalized energy distribution of the statistical mechanics model, thereby streamlining the data generation process for large-scale traffic systems. Our simulations demonstrate promising agreement between predicted and actual traffic flow dynamics, underscoring the efficacy of our proposed approach.

Published

2024

7. Freshness-aware Block Propagation Optimization in 6G-based Web 3.0: An Evolutionary Game Approach

Author

Wen, Jinbo, Kang, Jiawen, Xiong, Zehui, Du, Hongyang, Yang, Zhaohui, Niyato, Dusit, Shen, Meng, Jiao, Yutao, Zhang, Yang, Wen, Jinbo, Kang, Jiawen, Xiong, Zehui, Du, Hongyang, Yang, Zhaohui, Niyato, Dusit, Shen, Meng, Jiao, Yutao, and Zhang, Yang

Abstract

Driven by the aspiration to establish a decentralized digital economy, Web 3.0 is emerging as the fundamental technology for digital transformation. Incorporating the promising sixth-generation (6G) technology with large bandwidth and space-air-ground integrated coverage, 6G-based Web 3.0 holds great potential in empowering users with enhanced data control and facilitating secure peer-to-peer transactions, especially in consumer electronics, through the utilization of blockchain technologies. However, 6G-based Web 3.0 is still in its infancy, such as ensuring block freshness and optimizing block propagation to improve blockchain performance. In this paper, we develop a freshness-aware block propagation optimization framework for 6G-based Web 3.0. We first propose a novel metric called Age of Block Information (AoBI) based on the concept of age of information to quantify block freshness. To make block propagation optimization tractable, we classify miners into five different states and propose a block propagation model for public blockchains inspired by epidemic models. Moreover, considering that the miners are bounded rational, we propose an incentive mechanism based on the evolutionary game for block propagation to improve block propagation efficiency. Numerical results demonstrate that compared with other block propagation mechanisms, the proposed scheme has a higher block forwarding probability, which improves block propagation efficiency.

Published

2024

8. Low-Complexity Beam Training for Multi-RIS-Assisted Multi-User Communications

Author

Xu, Yuan, Huang, Chongwen, Wei, Li, Yang, Zhaohui, Chen, Xiaoming, Zhang, Zhaoyang, Yuen, Chau, Debbah, Mérouane, Xu, Yuan, Huang, Chongwen, Wei, Li, Yang, Zhaohui, Chen, Xiaoming, Zhang, Zhaoyang, Yuen, Chau, and Debbah, Mérouane

Abstract

In this paper, we investigate the beam training problem in the multi-user millimeter wave (mmWave) communication system, where multiple reconfigurable intelligent surfaces (RISs) are deployed to improve the coverage and the achievable rate. However, existing beam training techniques in mmWave systems suffer from the high complexity (i.e., exponential order) and low identification accuracy. To address these problems, we propose a novel hashing multi-arm beam (HMB) training scheme that reduces the training complexity to the logarithmic order with the high accuracy. Specifically, we first design a generation mechanism for HMB codebooks. Then, we propose a demultiplexing algorithm based on the soft decision to distinguish signals from different RIS reflective links. Finally, we utilize a multi-round voting mechanism to align the beams. Simulation results show that the proposed HMB training scheme enables simultaneous training for multiple RISs and multiple users, and reduces the beam training overhead to the logarithmic level. Moreover, it also shows that our proposed scheme can significantly improve the identification accuracy by at least 20% compared to existing beam training techniques.

Published

2024

9. Coverage and Rate Analysis for Integrated Sensing and Communication Networks

Author

Gan, Xu, Huang, Chongwen, Yang, Zhaohui, Chen, Xiaoming, He, Jiguang, Zhang, Zhaoyang, Yuen, Chau, Guan, Yong Liang, Debbah, Mérouane, Gan, Xu, Huang, Chongwen, Yang, Zhaohui, Chen, Xiaoming, He, Jiguang, Zhang, Zhaoyang, Yuen, Chau, Guan, Yong Liang, and Debbah, Mérouane

Abstract

Integrated sensing and communication (ISAC) is increasingly recognized as a pivotal technology for next-generation cellular networks, offering mutual benefits in both sensing and communication capabilities. This advancement necessitates a re-examination of the fundamental limits within networks where these two functions coexist via shared spectrum and infrastructures. However, traditional stochastic geometry-based performance analyses are confined to either communication or sensing networks separately. This paper bridges this gap by introducing a generalized stochastic geometry framework in ISAC networks. Based on this framework, we define and calculate the coverage and ergodic rate of sensing and communication performance under resource constraints. Then, we shed light on the fundamental limits of ISAC networks by presenting theoretical results for the coverage rate of the unified performance, taking into account the coupling effects of dual functions in coexistence networks. Further, we obtain the analytical formulations for evaluating the ergodic sensing rate constrained by the maximum communication rate, and the ergodic communication rate constrained by the maximum sensing rate. Extensive numerical results validate the accuracy of all theoretical derivations, and also indicate that denser networks significantly enhance ISAC coverage. Specifically, increasing the base station density from $1$ $\text{km}^{-2}$ to $10$ $\text{km}^{-2}$ can boost the ISAC coverage rate from $1.4\%$ to $39.8\%$. Further, results also reveal that with the increase of the constrained sensing rate, the ergodic communication rate improves significantly, but the reverse is not obvious.

Published

2024

10. Hashing Beam Training for Near-Field Communications

Author

Xu, Yuan, Wei, Li, Huang, Chongwen, Zhu, Chen, Yang, Zhaohui, Yang, Jun, He, Jiguang, Zhang, Zhaoyang, Debbah, Mérouane, Xu, Yuan, Wei, Li, Huang, Chongwen, Zhu, Chen, Yang, Zhaohui, Yang, Jun, He, Jiguang, Zhang, Zhaoyang, and Debbah, Mérouane

Abstract

In this paper, we investigate the millimeter-wave (mmWave) near-field beam training problem to find the correct beam direction. In order to address the high complexity and low identification accuracy of existing beam training techniques, we propose an efficient hashing multi-arm beam (HMB) training scheme for the near-field scenario. Specifically, we first design a set of sparse bases based on the polar domain sparsity of the near-field channel. Then, the random hash functions are chosen to construct the near-field multi-arm beam training codebook. Each multi-arm beam codeword is scanned in a time slot until all the predefined codewords are traversed. Finally, the soft decision and voting methods are applied to distinguish the signal from different base stations and obtain correctly aligned beams. Simulation results show that our proposed near-field HMB training method can reduce the beam training overhead to the logarithmic level, and achieve 96.4% identification accuracy of exhaustive beam training. Moreover, we also verify applicability under the far-field scenario., Comment: arXiv admin note: text overlap with arXiv:2402.04913

Published

2024

11. Stochastic Geometry Analysis for Distributed RISs-Assisted mmWave Communications

Author

Xu, Yuan, Wei, Li, Huang, Chongwen, Zhu, Yongxu, Yang, Zhaohui, Yang, Jun, He, Jiguang, Zhang, Zhaoyang, Debbah, Mérouane, Xu, Yuan, Wei, Li, Huang, Chongwen, Zhu, Yongxu, Yang, Zhaohui, Yang, Jun, He, Jiguang, Zhang, Zhaoyang, and Debbah, Mérouane

Abstract

Millimeter wave (mmWave) has attracted considerable attention due to its wide bandwidth and high frequency. However, it is highly susceptible to blockages, resulting in significant degradation of the coverage and the sum rate. A promising approach is deploying distributed reconfigurable intelligent surfaces (RISs), which can establish extra communication links. In this paper, we investigate the impact of distributed RISs on the coverage probability and the sum rate in mmWave wireless communication systems. Specifically, we first introduce the system model, which includes the blockage, the RIS and the user distribution models, leveraging the Poisson point process. Then, we define the association criterion and derive the conditional coverage probabilities for the two cases of direct association and reflective association through RISs. Finally, we combine the two cases using Campbell's theorem and the total probability theorem to obtain the closed-form expressions for the ergodic coverage probability and the sum rate. Simulation results validate the effectiveness of the proposed analytical approach, demonstrating that the deployment of distributed RISs significantly improves the ergodic coverage probability by 45.4% and the sum rate by over 1.5 times., Comment: arXiv admin note: substantial text overlap with arXiv:2402.06154

Published

2024

12. Probabilistic Semantic Communication over Wireless Networks with Rate Splitting

Author

Zhao, Zhouxiang, Yang, Zhaohui, Hu, Ye, Yang, Qianqian, Xu, Wei, Zhang, Zhaoyang, Zhao, Zhouxiang, Yang, Zhaohui, Hu, Ye, Yang, Qianqian, Xu, Wei, and Zhang, Zhaoyang

Abstract

In this paper, the problem of joint transmission and computation resource allocation for probabilistic semantic communication (PSC) system with rate splitting multiple access (RSMA) is investigated. In the considered model, the base station (BS) needs to transmit a large amount of data to multiple users with RSMA. Due to limited communication resources, the BS is required to utilize semantic communication techniques to compress the large-sized data. The semantic communication is enabled by shared probability graphs between the BS and the users. The probability graph can be used to further compress the transmission data at the BS, while the received compressed semantic information can be recovered through using the same shared probability graph at each user side. The semantic information compression progress consumes additional computation power at the BS, which inevitably decreases the transmission power due to limited total power budget. Considering both the effect of semantic compression ratio and computation power, the semantic rate expression for RSMA is first obtained. Then, based on the obtained rate expression, an optimization problem is formulated with the aim of maximizing the sum of semantic rates of all users under total power, semantic compression ratio, and rate allocation constraints. To tackle this problem, an iterative algorithm is proposed, where the rate allocation and transmit beamforming design subproblem is solved using a successive convex approximation method, and the semantic compression ratio subproblem is addressed using a greedy algorithm. Numerical results validate the effectiveness of the proposed scheme.

Published

2024

13. A Joint Communication and Computation Design for Probabilistic Semantic Communications

Author

Zhao, Zhouxiang, Yang, Zhaohui, Chen, Mingzhe, Zhang, Zhaoyang, Poor, H. Vincent, Zhao, Zhouxiang, Yang, Zhaohui, Chen, Mingzhe, Zhang, Zhaoyang, and Poor, H. Vincent

Abstract

In this paper, the problem of joint transmission and computation resource allocation for a multi-user probabilistic semantic communication (PSC) network is investigated. In the considered model, users employ semantic information extraction techniques to compress their large-sized data before transmitting them to a multi-antenna base station (BS). Our model represents large-sized data through substantial knowledge graphs, utilizing shared probability graphs between the users and the BS for efficient semantic compression. The resource allocation problem is formulated as an optimization problem with the objective of maximizing the sum of equivalent rate of all users, considering total power budget and semantic resource limit constraints. The computation load considered in the PSC network is formulated as a non-smooth piecewise function with respect to the semantic compression ratio. To tackle this non-convex non-smooth optimization challenge, a three-stage algorithm is proposed where the solutions for the receive beamforming matrix of the BS, transmit power of each user, and semantic compression ratio of each user are obtained stage by stage. Numerical results validate the effectiveness of our proposed scheme.

Published

2024

14. Robust Beamforming for RIS-aided Communications: Gradient-based Manifold Meta Learning

Author

Zhu, Fenghao, Wang, Xinquan, Huang, Chongwen, Yang, Zhaohui, Chen, Xiaoming, Alhammadi, Ahmed, Zhang, Zhaoyang, Yuen, Chau, Debbah, Mérouane, Zhu, Fenghao, Wang, Xinquan, Huang, Chongwen, Yang, Zhaohui, Chen, Xiaoming, Alhammadi, Ahmed, Zhang, Zhaoyang, Yuen, Chau, and Debbah, Mérouane

Abstract

Reconfigurable intelligent surface (RIS) has become a promising technology to realize the programmable wireless environment via steering the incident signal in fully customizable ways. However, a major challenge in RIS-aided communication systems is the simultaneous design of the precoding matrix at the base station (BS) and the phase shifting matrix of the RIS elements. This is mainly attributed to the highly non-convex optimization space of variables at both the BS and the RIS, and the diversity of communication environments. Generally, traditional optimization methods for this problem suffer from the high complexity, while existing deep learning based methods are lack of robustness in various scenarios. To address these issues, we introduce a gradient-based manifold meta learning method (GMML), which works without pre-training and has strong robustness for RIS-aided communications. Specifically, the proposed method fuses meta learning and manifold learning to improve the overall spectral efficiency, and reduce the overhead of the high-dimensional signal process. Unlike traditional deep learning based methods which directly take channel state information as input, GMML feeds the gradients of the precoding matrix and phase shifting matrix into neural networks. Coherently, we design a differential regulator to constrain the phase shifting matrix of the RIS. Numerical results show that the proposed GMML can improve the spectral efficiency by up to 7.31\%, and speed up the convergence by 23 times faster compared to traditional approaches. Moreover, they also demonstrate remarkable robustness and adaptability in dynamic settings., Comment: journal

Published

2024

15. Bayesian Learning for Double-RIS Aided ISAC Systems with Superimposed Pilots and Data

Author

Gan, Xu, Huang, Chongwen, Yang, Zhaohui, Zhong, Caijun, Chen, Xiaoming, Zhang, Zhaoyang, Guo, Qinghua, Yuen, Chau, Debbah, Merouane, Gan, Xu, Huang, Chongwen, Yang, Zhaohui, Zhong, Caijun, Chen, Xiaoming, Zhang, Zhaoyang, Guo, Qinghua, Yuen, Chau, and Debbah, Merouane

Abstract

Reconfigurable intelligent surface (RIS) has great potential to improve the performance of integrated sensing and communication (ISAC) systems, especially in scenarios where line-of-sight paths between the base station and users are blocked. However, the spectral efficiency (SE) of RIS-aided ISAC uplink transmissions may be drastically reduced by the heavy burden of pilot overhead for realizing sensing capabilities. In this paper, we tackle this bottleneck by proposing a superimposed symbol scheme, which superimposes sensing pilots onto data symbols over the same time-frequency resources. Specifically, we develop a structure-aware sparse Bayesian learning framework, where decoded data symbols serve as side information to enhance sensing performance and increase SE. To meet the low-latency requirements of emerging ISAC applications, we further propose a low-complexity simultaneous communication and localization algorithm for multiple users. This algorithm employs the unitary approximate message passing in the Bayesian learning framework for initial angle estimate, followed by iterative refinements through reduced-dimension matrix calculations. Moreover, the sparse code multiple access technology is incorporated into this iterative framework for accurate data detection which also facilitates localization. Numerical results show that the proposed superimposed symbol-based scheme empowered by the developed algorithm can achieve centimeter-level localization while attaining up to $96\%$ of the SE of conventional communications without sensing capabilities. Moreover, compared to other typical ISAC schemes, the proposed superimposed symbol scheme can provide an effective throughput improvement over $133\%$.

Published

2024

16. Digital versus Analog Transmissions for Federated Learning over Wireless Networks

Author

Yao, Jiacheng, Xu, Wei, Yang, Zhaohui, You, Xiaohu, Bennis, Mehdi, Poor, H. Vincent, Yao, Jiacheng, Xu, Wei, Yang, Zhaohui, You, Xiaohu, Bennis, Mehdi, and Poor, H. Vincent

Abstract

In this paper, we quantitatively compare these two effective communication schemes, i.e., digital and analog ones, for wireless federated learning (FL) over resource-constrained networks, highlighting their essential differences as well as their respective application scenarios. We first examine both digital and analog transmission methods, together with a unified and fair comparison scheme under practical constraints. A universal convergence analysis under various imperfections is established for FL performance evaluation in wireless networks. These analytical results reveal that the fundamental difference between the two paradigms lies in whether communication and computation are jointly designed or not. The digital schemes decouple the communication design from specific FL tasks, making it difficult to support simultaneous uplink transmission of massive devices with limited bandwidth. In contrast, the analog communication allows over-the-air computation (AirComp), thus achieving efficient spectrum utilization. However, computation-oriented analog transmission reduces power efficiency, and its performance is sensitive to computational errors. Finally, numerical simulations are conducted to verify these theoretical observations., Comment: Accepted by ICC 2024

Published

2024

17. A System-Level Dynamic Binary Translator using Automatically-Learned Translation Rules

Author

Jiang, Jinhu, Liang, Chaoyi, Dong, Rongchao, Yang, Zhaohui, Zhou, Zhongjun, Wang, Wenwen, Yew, Pen-Chung, Zhang, Weihua, Jiang, Jinhu, Liang, Chaoyi, Dong, Rongchao, Yang, Zhaohui, Zhou, Zhongjun, Wang, Wenwen, Yew, Pen-Chung, and Zhang, Weihua

Abstract

System-level emulators have been used extensively for system design, debugging and evaluation. They work by providing a system-level virtual machine to support a guest operating system (OS) running on a platform with the same or different native OS that uses the same or different instruction-set architecture. For such system-level emulation, dynamic binary translation (DBT) is one of the core technologies. A recently proposed learning-based DBT approach has shown a significantly improved performance with a higher quality of translated code using automatically learned translation rules. However, it has only been applied to user-level emulation, and not yet to system-level emulation. In this paper, we explore the feasibility of applying this approach to improve system-level emulation, and use QEMU to build a prototype. ... To achieve better performance, we leverage several optimizations that include coordination overhead reduction to reduce the overhead of each coordination, and coordination elimination and code scheduling to reduce the coordination frequency. Experimental results show that it can achieve an average of 1.36X speedup over QEMU 6.1 with negligible coordination overhead in the system emulation mode using SPEC CINT2006 as application benchmarks and 1.15X on real-world applications., Comment: 10 pages, 19 figures, to be published in International Symposium on Code Generation and Optimization (CGO) 2024

Published

2024

18. Coverage and Rate Analysis for Distributed RISs-Assisted mmWave Communications

Author

Xu, Yuan, Huang, Chongwen, Li, Wei, Zhu, Yongxu, Yang, Zhaohui, He, Jiguang, Yang, Jun, Zhang, Zhaoyang, Yuen, Chau, Debbah, Merouane, Xu, Yuan, Huang, Chongwen, Li, Wei, Zhu, Yongxu, Yang, Zhaohui, He, Jiguang, Yang, Jun, Zhang, Zhaoyang, Yuen, Chau, and Debbah, Merouane

Abstract

The millimeter wave (mmWave) has received considerable interest due to its expansive bandwidth and high frequency. However, a noteworthy challenge arises from its vulnerability to blockages, leading to reduced coverage and achievable rates. To address these limitations, a potential solution is to deploy distributed reconfigurable intelligent surfaces (RISs), which comprise many low-cost and passively reflected elements, and can facilitate the establishment of extra communication links. In this paper, we leverage stochastic geometry to investigate the ergodic coverage probability and the achievable rate in both distributed RISs-assisted single-cell and multi-cell mmWave wireless communication systems. Specifically, we first establish the system model considering the stochastically distributed blockages, RISs and users by the Poisson point process. Then we give the association criterion and derive the association probabilities, the distance distributions, and the conditional coverage probabilities for two cases of associations between base stations and users without or with RISs. Finally, we use Campbell's theorem and the total probability theorem to obtain the closed-form expressions of the ergodic coverage probability and the achievable rate. Simulation results verify the effectiveness of our analysis method, and demonstrate that by deploying distributed RISs, the ergodic coverage probability is significantly improved by approximately 50%, and the achievable rate is increased by more than 1.5 times.

Published

2024

19. Hashing Beam Training for Near-Field Integrated Sensing and Communication Systems

Author

Xu, Yuan, Huang, Chongwen, Li, Wei, Yang, Zhaohui, Hammadi, Ahmed Al, Yang, Jun, Zhang, Zhaoyang, Yuen, Chau, Debbah, Mérouane, Xu, Yuan, Huang, Chongwen, Li, Wei, Yang, Zhaohui, Hammadi, Ahmed Al, Yang, Jun, Zhang, Zhaoyang, Yuen, Chau, and Debbah, Mérouane

Abstract

In millimeter-wave (mmWave) integrated sensing and communication networks, users may be within the coverage of multiple access points (AP), which typically employ large-scale antenna arrays to mitigate obstacle occlusion and path loss. However, large-scale arrays generate pencil-shaped beams, which necessitate a higher number of training beams to cover the desired space. Furthermore, as the antenna aperture increases, users are more likely to be situated in the near-field region of the AP antenna array. This motivates our investigation into the near-field beam training problem to achieve effective positioning services. To address the high complexity and low identification accuracy of existing beam training techniques, we propose an efficient hashing multi-arm beam (HMB) training scheme for the near-field scenario. Specifically, we first construct a near-field single-beam training codebook for the uniform planar arrays. Then, the hash functions are chosen independently to construct the multi-arm beam training codebooks for each AP. All APs traverse the predefined multi-arm beam training codeword simultaneously and the multi-AP superimposed signals at the user are recorded. Finally, the soft decision and voting methods are applied to obtain the correctly aligned beams only based on the signal powers. In addition, we logically prove that the traversal complexity is at the logarithmic level. Simulation results show that our proposed near-field HMB training method can achieve 96.4% identification accuracy of the exhaustive beam training method and greatly reduce the training overhead. Furthermore, we verify its applicability under the far-field scenario as well.

Published

2024

20. Semantic Entropy Can Simultaneously Benefit Transmission Efficiency and Channel Security of Wireless Semantic Communications

Author

Rong, Yankai, Nan, Guoshun, Zhang, Minwei, Chen, Sihan, Wang, Songtao, Zhang, Xuefei, Ma, Nan, Gong, Shixun, Yang, Zhaohui, Cui, Qimei, Tao, Xiaofeng, Quek, Tony Q. S., Rong, Yankai, Nan, Guoshun, Zhang, Minwei, Chen, Sihan, Wang, Songtao, Zhang, Xuefei, Ma, Nan, Gong, Shixun, Yang, Zhaohui, Cui, Qimei, Tao, Xiaofeng, and Quek, Tony Q. S.

Abstract

Recently proliferated deep learning-based semantic communications (DLSC) focus on how transmitted symbols efficiently convey a desired meaning to the destination. However, the sensitivity of neural models and the openness of wireless channels cause the DLSC system to be extremely fragile to various malicious attacks. This inspires us to ask a question: "Can we further exploit the advantages of transmission efficiency in wireless semantic communications while also alleviating its security disadvantages?". Keeping this in mind, we propose SemEntropy, a novel method that answers the above question by exploring the semantics of data for both adaptive transmission and physical layer encryption. Specifically, we first introduce semantic entropy, which indicates the expectation of various semantic scores regarding the transmission goal of the DLSC. Equipped with such semantic entropy, we can dynamically assign informative semantics to Orthogonal Frequency Division Multiplexing (OFDM) subcarriers with better channel conditions in a fine-grained manner. We also use the entropy to guide semantic key generation to safeguard communications over open wireless channels. By doing so, both transmission efficiency and channel security can be simultaneously improved. Extensive experiments over various benchmarks show the effectiveness of the proposed SemEntropy. We discuss the reason why our proposed method benefits secure transmission of DLSC, and also give some interesting findings, e.g., SemEntropy can keep the semantic accuracy remain 95% with 60% less transmission., Comment: 13 pages, 12 figures

Published

2024

21. Video Semantic Communication with Major Object Extraction and Contextual Video Encoding

Author

Li, Haopeng, Tong, Haonan, Wang, Sihua, Yang, Nuocheng, Yang, Zhaohui, Yin, Changchuan, Li, Haopeng, Tong, Haonan, Wang, Sihua, Yang, Nuocheng, Yang, Zhaohui, and Yin, Changchuan

Abstract

This paper studies an end-to-end video semantic communication system for massive communication. In the considered system, the transmitter must continuously send the video to the receiver to facilitate character reconstruction in immersive applications, such as interactive video conference. However, transmitting the original video information with substantial amounts of data poses a challenge to the limited wireless resources. To address this issue, we reduce the amount of data transmitted by making the transmitter extract and send the semantic information from the video, which refines the major object and the correlation of time and space in the video. Specifically, we first develop a video semantic communication system based on major object extraction (MOE) and contextual video encoding (CVE) to achieve efficient video transmission. Then, we design the MOE and CVE modules with convolutional neural network based motion estimation, contextual extraction and entropy coding. Simulation results show that compared to the traditional coding schemes, the proposed method can reduce the amount of transmitted data by up to 25% while increasing the peak signal-to-noise ratio (PSNR) of the reconstructed video by up to 14%., Comment: 6 pages, 9 figures, accepted by IEEE WCNC wksp 2024

Published

2024

22. A Joint Communication and Computation Framework for Digital Twin over Wireless Networks

Author

Yang, Zhaohui, Chen, Mingzhe, Liu, Yuchen, Zhang, Zhaoyang, Yang, Zhaohui, Chen, Mingzhe, Liu, Yuchen, and Zhang, Zhaoyang

Abstract

In this paper, the problem of low-latency communication and computation resource allocation for digital twin (DT) over wireless networks is investigated. In the considered model, multiple physical devices in the physical network (PN) needs to frequently offload the computation task related data to the digital network twin (DNT), which is generated and controlled by the central server. Due to limited energy budget of the physical devices, both computation accuracy and wireless transmission power must be considered during the DT procedure. This joint communication and computation problem is formulated as an optimization problem whose goal is to minimize the overall transmission delay of the system under total PN energy and DNT model accuracy constraints. To solve this problem, an alternating algorithm with iteratively solving device scheduling, power control, and data offloading subproblems. For the device scheduling subproblem, the optimal solution is obtained in closed form through the dual method. For the special case with one physical device, the optimal number of transmission times is reveled. Based on the theoretical findings, the original problem is transformed into a simplified problem and the optimal device scheduling can be found. Numerical results verify that the proposed algorithm can reduce the transmission delay of the system by up to 51.2\% compared to the conventional schemes.

Published

2024

23. Joint Semantic Communication and Target Sensing for 6G Communication System

Author

Yang, Yinchao, Shikh-Bahaei, Mohammad, Yang, Zhaohui, Huang, Chongwen, Xu, Wei, Zhang, Zhaoyang, Yang, Yinchao, Shikh-Bahaei, Mohammad, Yang, Zhaohui, Huang, Chongwen, Xu, Wei, and Zhang, Zhaoyang

Abstract

This paper investigates the secure resource allocation for a downlink integrated sensing and communication system with multiple legal users and potential eavesdroppers. In the considered model, the base station (BS) simultaneously transmits sensing and communication signals through beamforming design, where the sensing signals can be viewed as artificial noise to enhance the security of communication signals. To further enhance the security in the semantic layer, the semantic information is extracted from the original information before transmission. The user side can only successfully recover the received information with the help of the knowledge base shared with the BS, which is stored in advance. Our aim is to maximize the sum semantic secrecy rate of all users while maintaining the minimum quality of service for each user and guaranteeing overall sensing performance. To solve this sum semantic secrecy rate maximization problem, an iterative algorithm is proposed using the alternating optimization method. The simulation results demonstrate the superiority of the proposed algorithm in terms of secure semantic communication and reliable detection.

Published

2024

24. Multi-Sources Information Fusion Learning for Multi-Points NLOS Localization

Author

Wang, Bohao, Shuai, Zitao, Huang, Chongwen, Yang, Qianqian, Yang, Zhaohui, Jin, Richeng, Alhammadi, Ahmed, Zhang, Zhaoyang, Yuen, Chau, Debbah, Mérouane, Wang, Bohao, Shuai, Zitao, Huang, Chongwen, Yang, Qianqian, Yang, Zhaohui, Jin, Richeng, Alhammadi, Ahmed, Zhang, Zhaoyang, Yuen, Chau, and Debbah, Mérouane

Abstract

Accurate localization of mobile terminals is a pivotal aspect of integrated sensing and communication systems. Traditional fingerprint localization methods, which infer coordinates from channel information within pre-defined rectangular areas, often face challenges due to the heterogeneous distribution of fingerprints inherent in non-line-of-sight (NLOS) scenarios. To overcome this limitation, we have developed a novel multi-source information fusion learning framework referred to as the Autosync Multi-Domain NLOS Localization (AMDNLoc). Specifically, AMDNLoc employs a two-stage matched filter fused with a target tracking algorithm and iterative centroid-based clustering to automatically and irregularly segment NLOS regions, ensuring uniform fingerprint distribution within channel state information across frequency, power, and time-delay domains. Additionally, the framework utilizes a segment-specific linear classifier array, coupled with deep residual network-based feature extraction and fusion, to establish the correlation function between fingerprint features and coordinates within these regions. Simulation results demonstrate that AMDNLoc achieves an impressive accuracy of 1.46 meters on typical wireless artificial intelligence research datasets and offers interpretability, adaptability, and scalability in various scenarios.

Published

2024

25. An Edge-Cloud Collaboration Framework for Generative AI Service Provision with Synergetic Big Cloud Model and Small Edge Models

Author

Tian, Yuqing, Zhang, Zhaoyang, Yang, Yuzhi, Chen, Zirui, Yang, Zhaohui, Jin, Richeng, Quek, Tony Q. S., Wong, Kai-Kit, Tian, Yuqing, Zhang, Zhaoyang, Yang, Yuzhi, Chen, Zirui, Yang, Zhaohui, Jin, Richeng, Quek, Tony Q. S., and Wong, Kai-Kit

Abstract

Generative artificial intelligence (GenAI) offers various services to users through content creation, which is believed to be one of the most important components in future networks. However, training and deploying big artificial intelligence models (BAIMs) introduces substantial computational and communication overhead.This poses a critical challenge to centralized approaches, due to the need of high-performance computing infrastructure and the reliability, secrecy and timeliness issues in long-distance access of cloud services. Therefore, there is an urging need to decentralize the services, partly moving them from the cloud to the edge and establishing native GenAI services to enable private, timely, and personalized experiences. In this paper, we propose a brand-new bottom-up BAIM architecture with synergetic big cloud model and small edge models, and design a distributed training framework and a task-oriented deployment scheme for efficient provision of native GenAI services. The proposed framework can facilitate collaborative intelligence, enhance adaptability, gather edge knowledge and alleviate edge-cloud burden. The effectiveness of the proposed framework is demonstrated through an image generation use case. Finally, we outline fundamental research directions to fully exploit the collaborative potential of edge and cloud for native GenAI and BAIM applications., Comment: 9 pages, 5 figures

Published

2024

26. Multiple Access Techniques for Intelligent and Multi-Functional 6G: Tutorial, Survey, and Outlook

Author

Clerckx, Bruno, Mao, Yijie, Yang, Zhaohui, Chen, Mingzhe, Alkhateeb, Ahmed, Liu, Liang, Qiu, Min, Yuan, Jinhong, Wong, Vincent W. S., Montojo, Juan, Clerckx, Bruno, Mao, Yijie, Yang, Zhaohui, Chen, Mingzhe, Alkhateeb, Ahmed, Liu, Liang, Qiu, Min, Yuan, Jinhong, Wong, Vincent W. S., and Montojo, Juan

Abstract

Multiple access (MA) is a crucial part of any wireless system and refers to techniques that make use of the resource dimensions to serve multiple users/devices/machines/services, ideally in the most efficient way. Given the needs of multi-functional wireless networks for integrated communications, sensing, localization, computing, coupled with the surge of machine learning / artificial intelligence (AI) in wireless networks, MA techniques are expected to experience a paradigm shift in 6G and beyond. In this paper, we provide a tutorial, survey and outlook of past, emerging and future MA techniques and pay a particular attention to how wireless network intelligence and multi-functionality will lead to a re-thinking of those techniques. The paper starts with an overview of orthogonal, physical layer multicasting, space domain, power domain, ratesplitting, code domain MAs, and other domains, and highlight the importance of researching universal multiple access to shrink instead of grow the knowledge tree of MA schemes by providing a unified understanding of MA schemes across all resource dimensions. It then jumps into rethinking MA schemes in the era of wireless network intelligence, covering AI for MA such as AI-empowered resource allocation, optimization, channel estimation, receiver designs, user behavior predictions, and MA for AI such as federated learning/edge intelligence and over the air computation. We then discuss MA for network multi-functionality and the interplay between MA and integrated sensing, localization, and communications. We finish with studying MA for emerging intelligent applications before presenting a roadmap toward 6G standardization. We also point out numerous directions that are promising for future research., Comment: submitted for publication in Proceedings of the IEEE

Published

2024

27. Near-field Beamforming for Extremely Large-scale MIMO Based on Unsupervised Deep Learning

Author

Nie, Jiali, Cui, Yuanhao, Yang, Zhaohui, Yuan, Weijie, Jing, Xiaojun, Nie, Jiali, Cui, Yuanhao, Yang, Zhaohui, Yuan, Weijie, and Jing, Xiaojun

Abstract

Extremely Large-scale Array (ELAA) is considered a frontier technology for future communication systems, pivotal in improving wireless systems' rate and spectral efficiency. However, as ELAA employs a multitude of antennas operating at higher frequencies, users are typically situated in the near-field region where the spherical wavefront propagates. This inevitably leads to a significant increase in the overhead of beam training, requiring complex two-dimensional beam searching in both the angle domain and the distance domain. To address this problem, we propose a near-field beamforming method based on unsupervised deep learning. Our convolutional neural network efficiently extracts complex channel state information features by strategically selecting padding and kernel size. We optimize the beamformers to maximize achievable rates in a multi-user network without relying on predefined custom codebooks. Upon deployment, the model requires solely the input of pre-estimated channel state information to derive the optimal beamforming vector. Simulation results show that our proposed scheme can obtain stable beamforming gain compared with the baseline scheme. Furthermore, owing to the inherent traits of deep learning methodologies, this approach substantially diminishes the beam training costs in near-field regions.

Published

2024

28. Semi-Federated Learning for Internet of Intelligence

Author

Ni, Wanli, Yang, Zhaohui, Ni, Wanli, and Yang, Zhaohui

Abstract

One key vision of intelligent Internet of Things (IoT) is to provide connected intelligence for a large number of application scenarios, such as self-driving cars, industrial manufacturing, and smart city. However, existing centralized or federated learning paradigms have difficulties in coordinating heterogeneous resources in distributed IoT environments. In this article, we introduce a semi-federated learning (SemiFL) framework to tackle the challenges of data and device heterogeneity in massive IoT networks. In SemiFL, only users with sufficient computing resources are selected for local model training, while the remaining users only transmit raw data to the base station for remote computing. By doing so, SemiFL incorporates conventional centralized and federated learning paradigms into a harmonized framework that allows all devices to participate in the global model training regardless of their computational capabilities and data distributions. Furthermore, we propose a next-generation multiple access scheme by seamlessly integrating communication and computation over the air. This achieves the concurrent transmission of raw data and model parameters in a spectrum-efficient manner. With their abilities to change channels and charge devices, two emerging techniques, reconfigurable intelligent surface and wireless energy transfer, are merged with our SemiFL framework to enhance its performance in bandwidth- and energy-limited IoT networks, respectively. Simulation results are presented to demonstrate the superiority of our SemiFL for achieving edge intelligence among computing-heterogeneous IoT devices., Comment: 8 pages, submitted to IEEE magazines

Published

2024

29. Wireless Federated Learning over Resource-Constrained Networks: Digital versus Analog Transmissions

Author

Yao, Jiacheng, Xu, Wei, Yang, Zhaohui, You, Xiaohu, Bennis, Mehdi, Poor, H. Vincent, Yao, Jiacheng, Xu, Wei, Yang, Zhaohui, You, Xiaohu, Bennis, Mehdi, and Poor, H. Vincent

Abstract

To enable wireless federated learning (FL) in communication resource-constrained networks, two communication schemes, i.e., digital and analog ones, are effective solutions. In this paper, we quantitatively compare these two techniques, highlighting their essential differences as well as respectively suitable scenarios. We first examine both digital and analog transmission schemes, together with a unified and fair comparison framework under imbalanced device sampling, strict latency targets, and transmit power constraints. A universal convergence analysis under various imperfections is established for evaluating the performance of FL over wireless networks. These analytical results reveal that the fundamental difference between the digital and analog communications lies in whether communication and computation are jointly designed or not. The digital scheme decouples the communication design from FL computing tasks, making it difficult to support uplink transmission from massive devices with limited bandwidth and hence the performance is mainly communication-limited. In contrast, the analog communication allows over-the-air computation (AirComp) and achieves better spectrum utilization. However, the computation-oriented analog transmission reduces power efficiency, and its performance is sensitive to computation errors from imperfect channel state information (CSI). Furthermore, device sampling for both schemes are optimized and differences in sampling optimization are analyzed. Numerical results verify the theoretical analysis and affirm the superior performance of the sampling optimization., Comment: Accepted by IEEE TWC. arXiv admin note: text overlap with arXiv:2402.09657

Published

2024

30. Minimizing End-to-End Latency for Joint Source-Channel Coding Systems

Author

Chi, Kaiyi, Yang, Qianqian, Shu, Yuanchao, Yang, Zhaohui, Shi, Zhiguo, Chi, Kaiyi, Yang, Qianqian, Shu, Yuanchao, Yang, Zhaohui, and Shi, Zhiguo

Abstract

While existing studies have highlighted the advantages of deep learning (DL)-based joint source-channel coding (JSCC) schemes in enhancing transmission efficiency, they often overlook the crucial aspect of resource management during the deployment phase. In this paper, we propose an approach to minimize the transmission latency in an uplink JSCC-based system. We first analyze the correlation between end-to-end latency and task performance, based on which the end-to-end delay model for each device is established. Then, we formulate a non-convex optimization problem aiming at minimizing the maximum end-to-end latency across all devices, which is proved to be NP-hard. We then transform the original problem into a more tractable one, from which we derive the closed form solution on the optimal compression ratio, truncation threshold selection policy, and resource allocation strategy. We further introduce a heuristic algorithm with low complexity, leveraging insights from the structure of the optimal solution. Simulation results demonstrate that both the proposed optimal algorithm and the heuristic algorithm significantly reduce end-to-end latency. Notably, the proposed heuristic algorithm achieves nearly the same performance to the optimal solution but with considerably lower computational complexity., Comment: 7 Pages, 5 Figures, accepted by 2024 IEEE ICC Workshop

Published

2024

31. Resource Allocation for Green Probabilistic Semantic Communication with Rate Splitting

Author

Xu, Ruopeng, Yang, Zhaohui, Zhao, Zhouxiang, Yang, Qianqian, Zhang, Zhaoyang, Xu, Ruopeng, Yang, Zhaohui, Zhao, Zhouxiang, Yang, Qianqian, and Zhang, Zhaoyang

Abstract

In this paper, the energy efficient design for probabilistic semantic communication (PSC) system with rate splitting multiple access (RSMA) is investigated. Basic principles are first reviewed to show how the PSC system works to extract, compress and transmit the semantic information in a task-oriented transmission. Subsequently, the process of how multiuser semantic information can be represented, compressed and transmitted with RSMA is presented, during which the semantic compression ratio (SCR) is introduced to directly measure the computation overhead in a transmission task, and communication overhead is indirectly described as well. Hence, the problem of wireless resource allocation jointly considering the computation and communication consumption for the PSC system with RSMA is investigated. Both conventional wireless resource constraints and unique constraints on semantic communication are considered to maximize the energy efficiency (EE). Simulation results verify the effectiveness of the proposed scheme.

Published

2024

32. Fluid Antenna Relay Assisted Communication Systems Through Antenna Location Optimization

Author

Xu, Ruopeng, Chen, Yixuan, Kang, Jiawen, Xu, Minrui, Yang, Zhaohui, Huang, Chongwen, Dusit, Niyato, Xu, Ruopeng, Chen, Yixuan, Kang, Jiawen, Xu, Minrui, Yang, Zhaohui, Huang, Chongwen, and Dusit, Niyato

Abstract

In this paper, we investigate the problem of resource allocation for fluid antenna relay (FAR) system with antenna location optimization. In the considered model, each user transmits information to a base station (BS) with help of FAR. The antenna location of the FAR is flexible and can be adapted to dynamic location distribution of the users. We formulate a sum rate maximization problem through jointly optimizing the antenna location and bandwidth allocation with meeting the minimum rate requirements, total bandwidth budget, and feasible antenna region constraints. To solve this problem, we obtain the optimal bandwidth in closed form. Based on the optimal bandwidth, the original problem is reduced to the antenna location optimization problem and an alternating algorithm is proposed. Simulation results verify the effectiveness of the proposed algorithm and the sum rate can be increased by up to 125% compared to the conventional schemes.

Published

2024

33. A Joint Communication and Computation Design for Distributed RISs Assisted Probabilistic Semantic Communication in IIoT

Author

Zhao, Zhouxiang, Yang, Zhaohui, Huang, Chongwen, Wei, Li, Yang, Qianqian, Zhong, Caijun, Xu, Wei, Zhang, Zhaoyang, Zhao, Zhouxiang, Yang, Zhaohui, Huang, Chongwen, Wei, Li, Yang, Qianqian, Zhong, Caijun, Xu, Wei, and Zhang, Zhaoyang

Abstract

In this paper, the problem of spectral-efficient communication and computation resource allocation for distributed reconfigurable intelligent surfaces (RISs) assisted probabilistic semantic communication (PSC) in industrial Internet-of-Things (IIoT) is investigated. In the considered model, multiple RISs are deployed to serve multiple users, while PSC adopts compute-then-transmit protocol to reduce the transmission data size. To support high-rate transmission, the semantic compression ratio, transmit power allocation, and distributed RISs deployment must be jointly considered. This joint communication and computation problem is formulated as an optimization problem whose goal is to maximize the sum semantic-aware transmission rate of the system under total transmit power, phase shift, RIS-user association, and semantic compression ratio constraints. To solve this problem, a many-to-many matching scheme is proposed to solve the RIS-user association subproblem, the semantic compression ratio subproblem is addressed following greedy policy, while the phase shift of RIS can be optimized using the tensor based beamforming. Numerical results verify the superiority of the proposed algorithm.

Published

2024

34. Unlocking Potentials of Near-Field Propagation: ELAA-Empowered Integrated Sensing and Communication

Author

He, Zhenyao, Xu, Wei, Yang, Zhaohui, Shen, Hong, Fu, Ningning, Huang, Yongming, Zhang, Zhaoyang, You, Xiaohu, He, Zhenyao, Xu, Wei, Yang, Zhaohui, Shen, Hong, Fu, Ningning, Huang, Yongming, Zhang, Zhaoyang, and You, Xiaohu

Abstract

The exploration of extremely large antenna arrays (ELAAs) using high-frequency spectrum has led to a paradigm shift in electromagnetic radiation field, transitioning from the common use case of far-field propagation to near-field propagation. This shift necessitates the modification of the conventional planar-wavefront approximation to more accurate spherical waves, exerting a profound impact on wireless transmission technologies encompassing communication and sensing. Concurrently, integrated sensing and communication (ISAC) has gained prominence in the context of the sixth-generation (6G) wireless networks owing to its ability to cater to the ever-increasing demands of future networks. In line with this evolving trend, this article presents a systematical investigation on ELAA-empowered near-field ISAC. We begin by introducing the fundamentals of near-field propagation with an emphasis on its double-edged effects to near-field communications. Then, we turn to near-field sensing and expound upon various typical applications. Following the separate elaborations on communications and sensing, we articulate in-depth advantages of ELAA-empowered ISAC in near field, particularly including featured opportunities arising from the dual-functional integrations, potential ISAC applications benefiting from the additional degrees-of-freedom in near field, and enablements of other complementary technologies. Finally, we outline key technical challenges that merit further exploration in the realm of ELAA-empowered near-field ISAC.

Published

2024

35. Mapping Wireless Networks into Digital Reality through Joint Vertical and Horizontal Learning

Author

Zhang, Zifan, Chen, Mingzhe, Yang, Zhaohui, Liu, Yuchen, Zhang, Zifan, Chen, Mingzhe, Yang, Zhaohui, and Liu, Yuchen

Abstract

In recent years, the complexity of 5G and beyond wireless networks has escalated, prompting a need for innovative frameworks to facilitate flexible management and efficient deployment. The concept of digital twins (DTs) has emerged as a solution to enable real-time monitoring, predictive configurations, and decision-making processes. While existing works primarily focus on leveraging DTs to optimize wireless networks, a detailed mapping methodology for creating virtual representations of network infrastructure and properties is still lacking. In this context, we introduce VH-Twin, a novel time-series data-driven framework that effectively maps wireless networks into digital reality. VH-Twin distinguishes itself through complementary vertical twinning (V-twinning) and horizontal twinning (H-twinning) stages, followed by a periodic clustering mechanism used to virtualize network regions based on their distinct geological and wireless characteristics. Specifically, V-twinning exploits distributed learning techniques to initialize a global twin model collaboratively from virtualized network clusters. H-twinning, on the other hand, is implemented with an asynchronous mapping scheme that dynamically updates twin models in response to network or environmental changes. Leveraging real-world wireless traffic data within a cellular wireless network, comprehensive experiments are conducted to verify that VH-Twin can effectively construct, deploy, and maintain network DTs. Parametric analysis also offers insights into how to strike a balance between twinning efficiency and model accuracy at scale., Comment: Accepted by IFIP/IEEE Networking 2024

Published

2024

36. Was Wuhan the early epicenter of the COVID-19 pandemic?—A critique

Author

Cao, Yanan, Chen, Lingling, Chen, Hua, Cun, Yupeng, Dai, Xiaofeng, Du, Hongli, Gao, Feng, Guo, Fengbiao, Guo, Yalong, Hao, Pei, He, Shunmin, He, Shunping, He, Xionglei, Hu, Zheng, Hoh, Boon-Peng, Jin, Xin, Jiang, Qian, Jiang, Qinghua, Khan, Asifullah, Kong, Hong-Zhi, Li, Jinchen, Li, Shuai Cheng, Li, Ying, Lin, Qiang, Liu, Jianquan, Liu, Qi, Lu, Jian, Lu, Xuemei, Luo, Shujin, Nie, Qinghua, Qiu, Zilong, Shi, Tieliu, Song, Xiaofeng, Su, Jianzhong, Tao, Sheng-ce, Wang, Chaolong, Wang, Chuanchao, Wang, Guo-Dong, Wang, Jiguang, Wu, Qi, Wu, Shaoyuan, Xu, Shuhua, Xue, Yu, Yang, Wenjun, Yang, Zhaohui, Ye, Kai, Ye, Yuan-Nong, Yu, Li, Zhao, Fangqing, Zhao, Yiqiang, Zhai, Weiwei, Zhang, Dandan, Zhang, Liye, Zheng, Houfeng, Zhou, Qi, Zhu, Tianqi, Zhang, Ya-ping, Cao, Yanan, Chen, Lingling, Chen, Hua, Cun, Yupeng, Dai, Xiaofeng, Du, Hongli, Gao, Feng, Guo, Fengbiao, Guo, Yalong, Hao, Pei, He, Shunmin, He, Shunping, He, Xionglei, Hu, Zheng, Hoh, Boon-Peng, Jin, Xin, Jiang, Qian, Jiang, Qinghua, Khan, Asifullah, Kong, Hong-Zhi, Li, Jinchen, Li, Shuai Cheng, Li, Ying, Lin, Qiang, Liu, Jianquan, Liu, Qi, Lu, Jian, Lu, Xuemei, Luo, Shujin, Nie, Qinghua, Qiu, Zilong, Shi, Tieliu, Song, Xiaofeng, Su, Jianzhong, Tao, Sheng-ce, Wang, Chaolong, Wang, Chuanchao, Wang, Guo-Dong, Wang, Jiguang, Wu, Qi, Wu, Shaoyuan, Xu, Shuhua, Xue, Yu, Yang, Wenjun, Yang, Zhaohui, Ye, Kai, Ye, Yuan-Nong, Yu, Li, Zhao, Fangqing, Zhao, Yiqiang, Zhai, Weiwei, Zhang, Dandan, Zhang, Liye, Zheng, Houfeng, Zhou, Qi, Zhu, Tianqi, and Zhang, Ya-ping

Published

2023

37. Channel Modeling and Multi-User Precoding for Tri-Polarized Holographic MIMO Communications

Author

Wei, Li, Huang, Chongwen, Alexandropoulos, George C., Yang, Zhaohui, Yang, Jun, Sha, Wei E. I., Debbah, Merouane, Yuen, Chau, Wei, Li, Huang, Chongwen, Alexandropoulos, George C., Yang, Zhaohui, Yang, Jun, Sha, Wei E. I., Debbah, Merouane, and Yuen, Chau

Abstract

This paper studies the exploitation of triple polarization (TP) for multi-user (MU) holographic multiple-input multiple-output surface (HMIMOS) wireless communication systems, aiming at capacity boosting without enlarging the antenna array size. We specifically consider that both the transmitter and receiver are equipped with an HMIMOS comprising compact sub-wavelength TP patch antennas. To characterize TP MUHMIMOS systems, a TP near-field channel model is proposed using the dyadic Green's function, whose characteristics are leveraged to design a user-cluster-based precoding scheme for mitigating the cross-polarization and inter-user interference contributions. A theoretical correlation analysis for HMIMOS with infinitely small patch antennas is also presented. According to the proposed scheme, the users are assigned to one of the three polarizations, which is easy to implement, at the cost, however, of reducing the system's diversity. Our numerical results showcase that the cross-polarization channel components have a nonnegligible impact on the system performance, which is efficiently eliminated with the proposed MU precoding scheme., Comment: arXiv admin note: substantial text overlap with arXiv:2211.03479

Published

2023

38. Cooperative Task-Oriented Communication for Multi-Modal Data with Transmission Control

Author

Wang, Shiqi, Yang, Qianqian, Shi, Zhiguo, Yang, Zhaohui, Zhang, Zhaoyang, Wang, Shiqi, Yang, Qianqian, Shi, Zhiguo, Yang, Zhaohui, and Zhang, Zhaoyang

Abstract

Real-time intelligence applications in Internet of Things (IoT) environment depend on timely data communication. However, it is challenging to transmit and analyse massive data of various modalities. Recently proposed task-oriented communication methods based on deep learning have showed its superiority in communication efficiency. In this paper, we propose a cooperative task-oriented communication method for the transmission of multi-modal data from multiple end devices to a central server. In particular, we use the transmission result of data of one modality, which is with lower rate, to control the transmission of other modalities with higher rate in order to reduce the amount of transmitted date. We take the human activity recognition (HAR) task in a smart home environment and design the semantic-oriented transceivers for the transmission of monitoring videos of different rooms and acceleration data of the monitored human. The numerical results demonstrate that by using the transmission control based on the obtained results of the received acceleration data, the transmission is reduced to 2% of that without transmission control while preserving the performance on the HAR task.

Published

2023

39. Sum-Rate Maximization for Active RIS-Aided Downlink RSMA System

Author

Li, Xinhao, Wang, Tao, Tong, Haonan, Yang, Zhaohui, Mao, Yijie, Yin, Changchuan, Li, Xinhao, Wang, Tao, Tong, Haonan, Yang, Zhaohui, Mao, Yijie, and Yin, Changchuan

Abstract

In this paper, the problem of sum-rate maximization for an active reconfigurable intelligent surface (RIS) assisted downlink rate-splitting multiple access (RSMA) transmission system is studied. In the considered model, the active RIS is deployed to overcome severe power attenuation, which is caused by the cumulative product of RIS incidence path loss and the reflection path loss. Since the active RIS can adjust both the phase and the amplitude of the incident signal simultaneously, the RIS control scheme requires delicate design to improve RSMA communication performance. To address this issue, a sum-rate maximization problem is formulated to jointly optimize the beamforming vectors, rate allocation vector, and RIS precoding matrix. To solve this non-convex sum-rate maximization problem, an iterative algorithm based on fractional programming (FP) and quadratic constraint quadratic programming (QCQP) is proposed. In particular, the proposed algorithm firstly decomposes the original problem into two subproblems, namely, 1) beamforming and rate allocation optimization and 2) active RIS precoding optimization. The corresponding variables of the two subproblems are optimized through sequential convex approximation (SCA) and block coordinate descent (BCD), respectively. Numerical results show that the proposed active RIS-aided RSMA system could increase the sum-rate by up to 45% over the conventional passive RIS-aided RSMA system with the same energy consumption.

Published

2023

40. Blockchain-aided Secure Semantic Communication for AI-Generated Content in Metaverse

Author

Lin, Yijing, Du, Hongyang, Niyato, Dusit, Nie, Jiangtian, Zhang, Jiayi, Cheng, Yanyu, Yang, Zhaohui, Lin, Yijing, Du, Hongyang, Niyato, Dusit, Nie, Jiangtian, Zhang, Jiayi, Cheng, Yanyu, and Yang, Zhaohui

Abstract

The construction of virtual transportation networks requires massive data to be transmitted from edge devices to Virtual Service Providers (VSP) to facilitate circulations between the physical and virtual domains in Metaverse. Leveraging semantic communication for reducing information redundancy, VSPs can receive semantic data from edge devices to provide varied services through advanced techniques, e.g., AI-Generated Content (AIGC), for users to explore digital worlds. But the use of semantic communication raises a security issue because attackers could send malicious semantic data with similar semantic information but different desired content to break Metaverse services and cause wrong output of AIGC. Therefore, in this paper, we first propose a blockchain-aided semantic communication framework for AIGC services in virtual transportation networks to facilitate interactions of the physical and virtual domains among VSPs and edge devices. We illustrate a training-based targeted semantic attack scheme to generate adversarial semantic data by various loss functions. We also design a semantic defense scheme that uses the blockchain and zero-knowledge proofs to tell the difference between the semantic similarities of adversarial and authentic semantic data and to check the authenticity of semantic data transformations. Simulation results show that the proposed defense method can reduce the semantic similarity of the adversarial semantic data and the authentic ones by up to 30% compared with the attack scheme., Comment: 10 pages, 8 figures, journal

Published

2023

41. Energy Efficient Semantic Communication over Wireless Networks with Rate Splitting

Author

Yang, Zhaohui, Chen, Mingzhe, Zhang, Zhaoyang, Huang, Chongwen, Yang, Zhaohui, Chen, Mingzhe, Zhang, Zhaoyang, and Huang, Chongwen

Abstract

In this paper, the problem of wireless resource allocation and semantic information extraction for energy efficient semantic communications over wireless networks with rate splitting is investigated. In the considered model, a base station (BS) first extracts semantic information from its large-scale data, and then transmits the small-sized semantic information to each user which recovers the original data based on its local common knowledge. At the BS side, the probability graph is used to extract multi-level semantic information. In the downlink transmission, a rate splitting scheme is adopted, while the private small-sized semantic information is transmitted through private message and the common knowledge is transmitted through common message. Due to limited wireless resource, both computation energy and transmission energy are considered. This joint computation and communication problem is formulated as an optimization problem aiming to minimize the total communication and computation energy consumption of the network under computation, latency, and transmit power constraints. To solve this problem, an alternating algorithm is proposed where the closed-form solutions for semantic information extraction ratio and computation frequency are obtained at each step. Numerical results verify the effectiveness of the proposed algorithm.

Published

2023

42. Secure Semantic Communications: Fundamentals and Challenges

Author

Yang, Zhaohui, Chen, Mingzhe, Li, Gaolei, Yang, Yang, Zhang, Zhaoyang, Yang, Zhaohui, Chen, Mingzhe, Li, Gaolei, Yang, Yang, and Zhang, Zhaoyang

Abstract

Semantic communication allows the receiver to know the intention instead of the bit information itself, which is an emerging technique to support real-time human-machine and machine-to-machine interactions for future wireless communications. In semantic communications, both transmitter and receiver share some common knowledge, which can be used to extract small-size information at the transmitter and recover the original information at the receiver. Due to different design purposes, security issues in semantic communications have two unique features compared to standard bit-wise communications. First, an attacker in semantic communications considers not only the amount of stolen data but also the meanings of stolen data. Second, an attacker in semantic communication systems can attack not only semantic information transmission as done in standard communication systems but also attacks machine learning (ML) models used for semantic information extraction since most of semantic information is generated using ML based methods. Due to these unique features, in this paper, we present an overview on the fundamentals and key challenges in the design of secure semantic communication. We first provide various methods to define and extract semantic information. Then, we focus on secure semantic communication techniques in two areas: information security and semantic ML model security. For each area, we identify the main problems and challenges. Then, we will provide a comprehensive treatment of these problems. In a nutshell,this article provides a holistic set of guidelines on how to design secure semantic communication systems over real-world wireless communication networks., Comment: 7 pages, 5 figures

Published

2023

43. Distributed Machine Learning for UAV Swarms: Computing, Sensing, and Semantics

Author

Ding, Yahao, Yang, Zhaohui, Pham, Quoc-Viet, Zhang, Zhaoyang, Shikh-Bahaei, Mohammad, Ding, Yahao, Yang, Zhaohui, Pham, Quoc-Viet, Zhang, Zhaoyang, and Shikh-Bahaei, Mohammad

Abstract

Unmanned aerial vehicle (UAV) swarms are considered as a promising technique for next-generation communication networks due to their flexibility, mobility, low cost, and the ability to collaboratively and autonomously provide services. Distributed learning (DL) enables UAV swarms to intelligently provide communication services, multi-directional remote surveillance, and target tracking. In this survey, we first introduce several popular DL algorithms such as federated learning (FL), multi-agent Reinforcement Learning (MARL), distributed inference, and split learning, and present a comprehensive overview of their applications for UAV swarms, such as trajectory design, power control, wireless resource allocation, user assignment, perception, and satellite communications. Then, we present several state-of-the-art applications of UAV swarms in wireless communication systems, such us reconfigurable intelligent surface (RIS), virtual reality (VR), semantic communications, and discuss the problems and challenges that DL-enabled UAV swarms can solve in these applications. Finally, we describe open problems of using DL in UAV swarms and future research directions of DL enabled UAV swarms. In summary, this survey provides a comprehensive survey of various DL applications for UAV swarms in extensive scenarios.

Published

2023

44. GoMORE: Global Model Reuse for Resource-Constrained Wireless Federated Learning

Author

Yao, Jiacheng, Yang, Zhaohui, Xu, Wei, Chen, Mingzhe, Niyato, Dusit, Yao, Jiacheng, Yang, Zhaohui, Xu, Wei, Chen, Mingzhe, and Niyato, Dusit

Abstract

Due to the dynamics of wireless environment and limited bandwidth, wireless federated learning (FL) is challenged by frequent transmission errors and incomplete aggregation from devices. In order to overcome these challenges, we propose a global model reuse strategy (GoMORE) that reuses the outdated global model to replace the local model parameters once a transmission error occurs. We analytically prove that the proposed GoMORE is strictly superior over the existing strategy, especially at low signal-to-noise ratios (SNRs). In addition, based on the derived expression of weight divergence, we further optimize the number of participating devices in the model aggregation to maximize the FL performance with limited communication resources. Numerical results verify that the proposed GoMORE successfully approaches the performance upper bound by an ideal transmission. It also mitigates the negative impact of non-independent and non-identically distributed (non-IID) data while achieving over 5 dB reduction in energy consumption., Comment: accepted by TEEE WCL

Published

2023

45. Adversarial Attacks and Defenses for Semantic Communication in Vehicular Metaverses

Author

Kang, Jiawen, He, Jiayi, Du, Hongyang, Xiong, Zehui, Yang, Zhaohui, Huang, Xumin, Xie, Shengli, Kang, Jiawen, He, Jiayi, Du, Hongyang, Xiong, Zehui, Yang, Zhaohui, Huang, Xumin, and Xie, Shengli

Abstract

For vehicular metaverses, one of the ultimate user-centric goals is to optimize the immersive experience and Quality of Service (QoS) for users on board. Semantic Communication (SemCom) has been introduced as a revolutionary paradigm that significantly eases communication resource pressure for vehicular metaverse applications to achieve this goal. SemCom enables high-quality and ultra-efficient vehicular communication, even with explosively increasing data traffic among vehicles. In this article, we propose a hierarchical SemCom-enabled vehicular metaverses framework consisting of the global metaverse, local metaverses, SemCom module, and resource pool. The global and local metaverses are brand-new concepts from the metaverse's distribution standpoint. Considering the QoS of users, this article explores the potential security vulnerabilities of the proposed framework. To that purpose, this study highlights a specific security risk to the framework's SemCom module and offers a viable defense solution, so encouraging community researchers to focus more on vehicular metaverse security. Finally, we provide an overview of the open issues of secure SemCom in the vehicular metaverses, notably pointing out potential future research directions.

Published

2023

46. Semantic-aware Digital Twin for Metaverse: A Comprehensive Review

Author

Jagatheesaperumal, Senthil Kumar, Yang, Zhaohui, Yang, Qianqian, Huang, Chongwen, Xu, Wei, Shikh-Bahaei, Mohammad, Zhang, Zhaoyang, Jagatheesaperumal, Senthil Kumar, Yang, Zhaohui, Yang, Qianqian, Huang, Chongwen, Xu, Wei, Shikh-Bahaei, Mohammad, and Zhang, Zhaoyang

Abstract

To facilitate the deployment of digital twins in Metaverse, the paradigm with semantic awareness has been proposed as a means for enabling accurate and task-oriented information extraction with inherent intelligence. However, this framework requires all devices in the Metaverse environment to be directly linked with the semantic model to enable faithful interpretation of messages. In contrast, this article introduces the digital twin framework, considering a smart industrial application, which enables semantic communication in conjugation with the Metaverse enabling technologies. The fundamentals of this framework are demonstrated on an industrial shopfloor management use case with a digital twin so as to improve its performance through semantic communication. An overview of semantic communication, Metaverse, and digital twins is presented. Integration of these technologies with the basic architecture as well as the impact on future industrial applications is presented. In a nutshell, this article showcases how semantic awareness can be an effective candidate in the implementation of digital twins for Metaverse applications., Comment: 9 pages, 5 figures, 1 table

Published

2023

47. Complex CNN CSI Enhancer for Integrated Sensing and Communications

Author

Chen, Xu, Feng, Zhiyong, Zhang, J. Andrew, Gao, Feifei, Yuan, Xin, Yang, Zhaohui, Zhang, Ping, Chen, Xu, Feng, Zhiyong, Zhang, J. Andrew, Gao, Feifei, Yuan, Xin, Yang, Zhaohui, and Zhang, Ping

Abstract

In this paper, we propose a novel complex convolutional neural network (CNN) CSI enhancer for integrated sensing and communications (ISAC), which exploits the correlation between the sensing parameters (such as angle-of-arrival and range) and the channel state information (CSI) to significantly improve the CSI estimation accuracy and further enhance the sensing accuracy. Within the CNN CSI enhancer, we use the complex-valued computation layers to form the CNN, which maintains the phase information of CSI. We also transform the CSI into the sparse angle-delay domain, leading to heatmap images with prominent peaks that can be efficiently processed by CNN. Based on the enhanced CSI outputs, we further propose a novel biased fast Fourier transform (FFT)-based sensing scheme for improving the range sensing accuracy, by artificially introducing phase biasing terms. Extensive simulation results show that the ISAC complex CNN CSI enhancer can converge within 30 training epochs. The normalized mean square error (NMSE) of its CSI estimates is about 17 dB lower than that of the linear minimum mean square error (LMMSE) estimator, and the bit error rate (BER) of demodulation using the enhanced CSI estimation approaches that with perfect CSI. Finally, the range estimation MSE of the proposed biased FFT-based sensing method approaches that of the subspace-based sensing method, at a much lower complexity., Comment: 13 pages, 15 figures, submitted to IEEE Journal of Selected Topics in Signal Processing

Published

2023

48. Distributed Learning over Networks with Graph-Attention-Based Personalization

Author

Tian, Zhuojun, Zhang, Zhaoyang, Yang, Zhaohui, Jin, Richeng, Dai, Huaiyu, Tian, Zhuojun, Zhang, Zhaoyang, Yang, Zhaohui, Jin, Richeng, and Dai, Huaiyu

Abstract

In conventional distributed learning over a network, multiple agents collaboratively build a common machine learning model. However, due to the underlying non-i.i.d. data distribution among agents, the unified learning model becomes inefficient for each agent to process its locally accessible data. To address this problem, we propose a graph-attention-based personalized training algorithm (GATTA) for distributed deep learning. The GATTA enables each agent to train its local personalized model while exploiting its correlation with neighboring nodes and utilizing their useful information for aggregation. In particular, the personalized model in each agent is composed of a global part and a node-specific part. By treating each agent as one node in a graph and the node-specific parameters as its features, the benefits of the graph attention mechanism can be inherited. Namely, instead of aggregation based on averaging, it learns the specific weights for different neighboring nodes without requiring prior knowledge about the graph structure or the neighboring nodes' data distribution. Furthermore, relying on the weight-learning procedure, we develop a communication-efficient GATTA by skipping the transmission of information with small aggregation weights. Additionally, we theoretically analyze the convergence properties of GATTA for non-convex loss functions. Numerical results validate the excellent performances of the proposed algorithms in terms of convergence and communication cost., Comment: Accepted for publication in IEEE TSP; with supplementary details for the derivations

Published

2023

49. Self-information Domain-based Neural CSI Compression with Feature Coupling

Author

Yin, Ziqing, Xie, Renjie, Xu, Wei, Yang, Zhaohui, You, Xiaohu, Yin, Ziqing, Xie, Renjie, Xu, Wei, Yang, Zhaohui, and You, Xiaohu

Abstract

Deep learning (DL)-based channel state information (CSI) feedback methods compressed the CSI matrix by exploiting its delay and angle features straightforwardly, while the measure in terms of information contained in the CSI matrix has rarely been considered. Based on this observation, we introduce self-information as an informative CSI representation from the perspective of information theory, which reflects the amount of information of the original CSI matrix in an explicit way. Then, a novel DL-based network is proposed for temporal CSI compression in the self-information domain, namely SD-CsiNet. The proposed SD-CsiNet projects the raw CSI onto a self-information matrix in the newly-defined self-information domain, extracts both temporal and spatial features of the self-information matrix, and then couples these two features for effective compression. Experimental results verify the effectiveness of the proposed SD-CsiNet by exploiting the self-information of CSI. Particularly for compression ratios 1/8 and 1/16, the SD-CsiNet respectively achieves 7.17 dB and 3.68 dB performance gains compared to state-of-the-art methods.

Published

2023

50. Reconfigurable Quantum Internet Service Provider

Author

Yang, Zhaohui, Cui, Chaohan, Yang, Zhaohui, and Cui, Chaohan

Abstract

With the recent developments in engineering quantum systems, the realization of scalable local-area quantum networks has become viable. However, the design and implementation of a quantum network is a holistic task that is way beyond the scope of an abstract design problem. As such, a testbed on which multiple disciplines can verify the design and implementation across a full networking stack has become a necessary infrastructure for the future development of quantum networks. In this work, we demonstrate the concept of quantum internet service provider (QISP), in analogy to the conventional ISP that allows for the sharing of classical information between the network nodes. The QISP is significant for the next-generation quantum networks as it coordinates the production, management, control, and sharing of quantum information across the end-users of a quantum network. We construct a reconfigurable QISP comprising both the quantum hardware and classical control software. Building on the fiber-based quantum-network testbed of the Center for Quantum Networks (CQN) at the University of Arizona (UA), we develop an integrated QISP prototype based on a Platform-as-a-Service (PaaS) architecture, whose classical control software is abstracted and modularized as an open-source QISP framework. To verify and characterize the QISP's performance, we demonstrate multi-channel entanglement distribution and routing among multiple quantum-network nodes with a time-energy entangled-photon source. We further perform field tests of concurrent services for multiple users across the quantum-network testbed. Our experiment demonstrates the robust capabilities of the QISP, laying the foundation for the design and verification of architectures and protocols for future quantum networks., Comment: 7 pages,6 figures, 2023 IEEE International Conference on Communications

Published

2023