wireless communication network
Multi-Agent Conditional Diffusion Model with Mean Field Communication as Wireless Resource Allocation Planner
Meng, Kechen, Zhang, Sinuo, Li, Rongpeng, Meng, Xiangming, Deng, Yansha, Wang, Chan, Lei, Ming, Zhao, Zhifeng
In wireless communication systems, efficient and adaptive resource allocation plays a crucial role in enhancing overall Quality of Service (QoS). Compared to the conventional Model-Free Reinforcement Learning (MFRL) scheme, Model-Based RL (MBRL) first learns a generative world model for subsequent planning. The reuse of historical experience in MBRL promises more stable training behavior, yet its deployment in large-scale wireless networks remains challenging due to high-dimensional stochastic dynamics, strong inter-agent cooperation, and communication constraints. To overcome these challenges, we propose the Multi-Agent Conditional Diffusion Model Planner (MA-CDMP) for decentralized communication resource management. Built upon the Distributed Training with Decentralized Execution (DTDE) paradigm, MA-CDMP models each communication node as an autonomous agent and employs Diffusion Models (DMs) to capture and predict environment dynamics. Meanwhile, an inverse dynamics model guides action generation, thereby enhancing sample efficiency and policy scalability. Moreover, to approximate large-scale agent interactions, a Mean-Field (MF) mechanism is introduced as an assistance to the classifier in DMs. This design mitigates inter-agent non-stationarity and enhances cooperation with minimal communication overhead in distributed settings. We further theoretically establish an upper bound on the distributional approximation error introduced by the MF-based diffusion generation, guaranteeing convergence stability and reliable modeling of multi-agent stochastic dynamics. Extensive experiments demonstrate that MA-CDMP consistently outperforms existing MARL baselines in terms of average reward and QoS metrics, showcasing its scalability and practicality for real-world wireless network optimization.
Connecting the Dots: Inferring Patent Phrase Similarity with Retrieved Phrase Graphs
We study the patent phrase similarity inference task, which measures the semantic similarity between two patent phrases. As patent documents employ legal and highly technical language, existing semantic textual similarity methods that use localized contextual information do not perform satisfactorily in inferring patent phrase similarity. To address this, we introduce a graph-augmented approach to amplify the global contextual information of the patent phrases. For each patent phrase, we construct a phrase graph that links to its focal patents and a list of patents that are either cited by or cite these focal patents. The augmented phrase embedding is then derived from combining its localized contextual embedding with its global embedding within the phrase graph. We further propose a self-supervised learning objective that capitalizes on the retrieved topology to refine both the contextualized embedding and the graph parameters in an end-to-end manner. Experimental results from a unique patent phrase similarity dataset demonstrate that our approach significantly enhances the representation of patent phrases, resulting in marked improvements in similarity inference in a self-supervised fashion. Substantial improvements are also observed in the supervised setting, underscoring the potential benefits of leveraging retrieved phrase graph augmentation.
A Safe Deep Reinforcement Learning Approach for Energy Efficient Federated Learning in Wireless Communication Networks
Koursioumpas, Nikolaos, Magoula, Lina, Petropouleas, Nikolaos, Thanopoulos, Alexandros-Ioannis, Panagea, Theodora, Alonistioti, Nancy, Gutierrez-Estevez, M. A., Khalili, Ramin
Progressing towards a new era of Artificial Intelligence (AI) - enabled wireless networks, concerns regarding the environmental impact of AI have been raised both in industry and academia. Federated Learning (FL) has emerged as a key privacy preserving decentralized AI technique. Despite efforts currently being made in FL, its environmental impact is still an open problem. Targeting the minimization of the overall energy consumption of an FL process, we propose the orchestration of computational and communication resources of the involved devices to minimize the total energy required, while guaranteeing a certain performance of the model. To this end, we propose a Soft Actor Critic Deep Reinforcement Learning (DRL) solution, where a penalty function is introduced during training, penalizing the strategies that violate the constraints of the environment, and contributing towards a safe RL process. A device level synchronization method, along with a computationally cost effective FL environment are proposed, with the goal of further reducing the energy consumption and communication overhead. Evaluation results show the effectiveness and robustness of the proposed scheme compared to four state-of-the-art baseline solutions on different network environments and FL architectures, achieving a decrease of up to 94% in the total energy consumption.
FedDCT: A Dynamic Cross-Tier Federated Learning Scheme in Wireless Communication Networks
Liu, Peng, Xian, Youquan, Yao, Chuanjian, Gan, Xiaoyun, Zhou, Lianghaojie, Jiang, Jianyong, Li, Dongcheng
With the rapid proliferation of Internet of Things (IoT) devices and the growing concern for data privacy among the public, Federated Learning (FL) has gained significant attention as a privacy-preserving machine learning paradigm. FL enables the training of a global model among clients without exposing local data. However, when a federated learning system runs on wireless communication networks, limited wireless resources, heterogeneity of clients, and network transmission failures affect its performance and accuracy. In this study, we propose a novel dynamic cross-tier FL scheme, named FedDCT to increase training accuracy and performance in wireless communication networks. We utilize a tiering algorithm that dynamically divides clients into different tiers according to specific indicators and assigns specific timeout thresholds to each tier to reduce the training time required. To improve the accuracy of the model without increasing the training time, we introduce a cross-tier client selection algorithm that can effectively select the tiers and participants. Simulation experiments show that our scheme can make the model converge faster and achieve a higher accuracy in wireless communication networks.
Look to Smart Cities for Innovative Solutions that Leverage the Artificial Intelligence of Things and 5G
Author of many technical papers about various telecommunications subjects including the published reports "Yes 2 Prepay" and "Data on SS7" as well as co-author of the books "Wireless Intelligent Networking" and "Mobile Positioning and Location Management". What is the "Artificial Intelligence of Things" (AIoT)? Simply put, AIoT represents the convergence of AI and IoT. This convergence will lead to "thinking" networks and systems that are becoming increasingly more capable of solving a wide range of problems across a diverse number of industry verticals. Many of the early solutions involving AIoT are consumer product related, utilizing cognitive intelligence to help end-users interact with retails products such as appliances.
NFV - Part 2: Are NFV & SDN Both Key to Driving the Fourth Industrial Revolution? Lanner
As we enter the Fourth Industrial Revolution, several new technological trends have begun to transform the systems that enable us to both work and live. Network Function Virtualization (NFV) is allowing network operators to both reduce their outgoings and speed-up the deployment of new services and this concept is currently becoming more and more widespread around the world. In this two-part series of articles, we'll be looking at what Network Function Virtualization is, how it works, how it compares to SDN, what its benefits are and, later, what it means for the Fourth Industrial Revolution alongside the likes of Software Defined Networking (SDN). As advanced automation, driverless vehicles, robotics, drones, AI, virtualization and 5G wireless communications technologies all drive us further into the future, it is already glaringly obvious that what has become known as the Fourth Industrial Revolution is well and truly underway. However, in order to truly unlock the promises of technologies such as automation and driverless vehicles, certain underlying architectures will need to be in place before we can begin to do so.