Related papers: Deep Reinforcement Learning Based Resource Allocation for Cloud Native Wireless Network

Deep Reinforcement Learning Based Resource Allocation for Cloud Native Wireless Network

URL: http://arxiv.org/abs/2305.06249v1
Date: Wed, 10 May 2023 15:32:22 GMT
Title: Deep Reinforcement Learning Based Resource Allocation for Cloud Native Wireless Network
Authors: Lin Wang, Jiasheng Wu, Yue Gao, Jingjing Zhang
Abstract summary: Cloud native technology has revolutionized 5G beyond and 6G communication networks, offering unprecedented levels of operational automation, flexibility, and adaptability. The vast array of cloud native services and applications presents a new challenge in resource allocation for dynamic cloud computing environments. We introduce deep reinforcement learning techniques and introduce two model-free algorithms capable of monitoring the network state and dynamically training allocation policies. Our findings demonstrate significant improvements in network efficiency, underscoring the potential of our proposed techniques in unlocking the full potential of cloud native wireless networks.
Score: 20.377823731801456
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Cloud native technology has revolutionized 5G beyond and 6G communication networks, offering unprecedented levels of operational automation, flexibility, and adaptability. However, the vast array of cloud native services and applications presents a new challenge in resource allocation for dynamic cloud computing environments. To tackle this challenge, we investigate a cloud native wireless architecture that employs container-based virtualization to enable flexible service deployment. We then study two representative use cases: network slicing and Multi-Access Edge Computing. To optimize resource allocation in these scenarios, we leverage deep reinforcement learning techniques and introduce two model-free algorithms capable of monitoring the network state and dynamically training allocation policies. We validate the effectiveness of our algorithms in a testbed developed using Free5gc. Our findings demonstrate significant improvements in network efficiency, underscoring the potential of our proposed techniques in unlocking the full potential of cloud native wireless networks.

Related papers

Deep Reinforcement Learning Based Placement for Integrated Access Backhauling in UAV-Assisted Wireless Networks [6.895620511689995]
This paper introduces a novel approach leveraging deep reinforcement learning (DRL) to optimize UAV placement in real-time. The unique contribution of this work lies in its ability to autonomously position UAVs in a way that not only ensures robust connectivity to ground users but also maintains seamless integration with central network infrastructure.
arXiv Detail & Related papers (2023-12-21T19:02:27Z)
Artificial Intelligence Empowered Multiple Access for Ultra Reliable and Low Latency THz Wireless Networks [76.89730672544216]
Terahertz (THz) wireless networks are expected to catalyze the beyond fifth generation (B5G) era. To satisfy the ultra-reliability and low-latency demands of several B5G applications, novel mobility management approaches are required. This article presents a holistic MAC layer approach that enables intelligent user association and resource allocation, as well as flexible and adaptive mobility management.
arXiv Detail & Related papers (2022-08-17T03:00:24Z)
Artificial Intelligence in Vehicular Wireless Networks: A Case Study Using ns-3 [18.54699818319184]
We present an ns-3 simulation framework, able to implement AI algorithms for the optimization of wireless networks. Our pipeline consists of: (i) a new geometry-based mobility-dependent channel model for V2X; (ii) all the layers of a 5G-NR-compliant protocol stack; and (iii) a new application to simulate V2X data transmission.
arXiv Detail & Related papers (2022-03-10T16:20:54Z)
IoV Scenario: Implementation of a Bandwidth Aware Algorithm in Wireless Network Communication Mode [49.734868032441625]
This paper proposes a bandwidth aware multi domain virtual network embedding algorithm (BA-VNE) The algorithm is mainly aimed at the problem that users need a lot of bandwidth in wireless communication mode. In order to improve the performance of the algorithm, we introduce particle swarm optimization (PSO) algorithm.
arXiv Detail & Related papers (2022-02-03T03:34:06Z)
Edge-Cloud Polarization and Collaboration: A Comprehensive Survey [61.05059817550049]
We conduct a systematic review for both cloud and edge AI. We are the first to set up the collaborative learning mechanism for cloud and edge modeling. We discuss potentials and practical experiences of some on-going advanced edge AI topics.
arXiv Detail & Related papers (2021-11-11T05:58:23Z)
Dynamic Slimmable Network [105.74546828182834]
We develop a dynamic network slimming regime named Dynamic Slimmable Network (DS-Net) Our DS-Net is empowered with the ability of dynamic inference by the proposed double-headed dynamic gate. It consistently outperforms its static counterparts as well as state-of-the-art static and dynamic model compression methods.
arXiv Detail & Related papers (2021-03-24T15:25:20Z)
Deep Reinforcement Learning-Aided RAN Slicing Enforcement for B5G Latency Sensitive Services [10.718353079920007]
This paper presents a novel architecture that leverages Deep Reinforcement Learning at the edge of the network in order to address Radio Access Network Slicing and Radio Resource Management. The effectiveness of our proposal against baseline methodologies is investigated through computer simulation, by considering an autonomous-driving use-case.
arXiv Detail & Related papers (2021-03-18T14:18:34Z)
Deep Reinforcement Learning for Adaptive Network Slicing in 5G for Intelligent Vehicular Systems and Smart Cities [19.723551683930776]
We develop a network slicing model based on a cluster of fog nodes (FNs) coordinated with an edge controller (EC) For each service request in a cluster, the EC decides which FN to execute the task, locally serve the request at the edge, or to reject the task and refer it to the cloud. We propose a deep reinforcement learning (DRL) solution to adaptively learn the optimal slicing policy.
arXiv Detail & Related papers (2020-10-19T23:30:08Z)
Reinforcement Learning on Computational Resource Allocation of Cloud-based Wireless Networks [22.06811314358283]
Wireless networks used for Internet of Things (IoT) are expected to largely involve cloud-based computing and processing. In a cloud environment, dynamic computational resource allocation is essential to save energy while maintaining the performance of the processes. This paper models this dynamic computational resource allocation problem into a Markov Decision Process (MDP) and designs a model-based reinforcement-learning agent to optimise the dynamic resource allocation of the CPU usage. The results show that our agent rapidly converges to the optimal policy, stably performs in different settings, outperforms or at least equally performs compared to a baseline algorithm in energy savings for different scenarios.
arXiv Detail & Related papers (2020-10-10T15:16:26Z)
Cognitive Radio Network Throughput Maximization with Deep Reinforcement Learning [58.44609538048923]
Radio Frequency powered Cognitive Radio Networks (RF-CRN) are likely to be the eyes and ears of upcoming modern networks such as Internet of Things (IoT) To be considered autonomous, the RF-powered network entities need to make decisions locally to maximize the network throughput under the uncertainty of any network environment. In this paper, deep reinforcement learning is proposed to overcome the shortcomings and allow a wireless gateway to derive an optimal policy to maximize network throughput.
arXiv Detail & Related papers (2020-07-07T01:49:07Z)
Deep Learning for Ultra-Reliable and Low-Latency Communications in 6G Networks [84.2155885234293]
We first summarize how to apply data-driven supervised deep learning and deep reinforcement learning in URLLC. To address these open problems, we develop a multi-level architecture that enables device intelligence, edge intelligence, and cloud intelligence for URLLC.
arXiv Detail & Related papers (2020-02-22T14:38:11Z)

This list is automatically generated from the titles and abstracts of the papers in this site.