Your search keyword '"self-organized devices"' showing total 3 results

1. D2D Mobile Relaying Meets NOMA—Part II: A Reinforcement Learning Perspective

Author

Safaa Driouech, Essaid Sabir, Mounir Ghogho, and El-Mehdi Amhoud

Subjects

D2D relaying, 5G/B5G/6G, biform game, self-organized devices, Nash equilibrium, distributed reinforcement learning, Chemical technology, TP1-1185

Abstract

Structureless communications such as Device-to-Device (D2D) relaying are undeniably of paramount importance to improving the performance of today’s mobile networks. Such a communication paradigm requires a certain level of intelligence at the device level, thereby allowing it to interact with the environment and make proper decisions. However, decentralizing decision-making may induce paradoxical outcomes, resulting in a drop in performance, which sustains the design of self-organizing yet efficient systems. We propose that each device decides either to directly connect to the eNodeB or get access via another device through a D2D link. In the first part of this article, we describe a biform game framework to analyze the proposed self-organized system’s performance, under pure and mixed strategies. We use two reinforcement learning (RL) algorithms, enabling devices to self-organize and learn their pure/mixed equilibrium strategies in a fully distributed fashion. Decentralized RL algorithms are shown to play an important role in allowing devices to be self-organized and reach satisfactory performance with incomplete information or even under uncertainties. We point out through a simulation the importance of D2D relaying and assess how our learning schemes perform under slow/fast channel fading.

Published

2021

2. D2D Mobile Relaying Meets NOMA—Part I: A Biform Game Analysis

Author

Safaa Driouech, Essaid Sabir, Mounir Ghogho, and El-Mehdi Amhoud

Subjects

D2D-relaying, 5G/B5G/6G, biform game, self-organized devices, Nash equilibrium, distributed reinforcement learning, Chemical technology, TP1-1185

Abstract

Structureless communications such as Device-to-Device (D2D) relaying are undeniably of paramount importance to improving the performance of today’s mobile networks. Such a communication paradigm requires implementing a certain level of intelligence at device level, allowing to interact with the environment and select proper decisions. However, decentralizing decision making sometimes may induce some paradoxical outcomes resulting, therefore, in a performance drop, which sustains the design of self-organizing, yet efficient systems. Here, each device decides either to directly connect to the eNodeB or get access via another device through a D2D link. Given the set of active devices and the channel model, we derive the outage probability for both cellular link and D2D link, and compute the system throughput. We capture the device behavior using a biform game perspective. In the first part of this article, we analyze the pure and mixed Nash equilibria of the induced game where each device seeks to maximize its own throughput. Our framework allows us to analyse and predict the system’s performance. The second part of this article is devoted to implement two Reinforcement Learning (RL) algorithms enabling devices to self-organize themselves and learn their equilibrium pure/mixed strategies, in a fully distributed fashion. Simulation results show that offloading the network by means of D2D-relaying improves per device throughput. Moreover, detailed analysis on how the network parameters affect the global performance is provided.

Published

2021

3. D2D Mobile Relaying Meets NOMA –Part I:A Biform Game Analysis

Author

Safaa Driouech, El-Mehdi Amhoud, Mounir Ghogho, Essaid Sabir, Phare, LIP6, Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Ecole Nationale Supérieure d'Electricité et de Mécanique [Casablanca] (ENSEM), Université Hassan II [Casablanca] (UH2MC), Université du Québec à Montréal = University of Québec in Montréal (UQAM), Department of Computer Science and Software Engineering [Québec], Université Laval [Québec] (ULaval), Université Internationale de Rabat (UIR), and Mohammed VI Polytechnic University [Marocco] (UM6P)

Subjects

Game analysis, Computer science, distributed reinforcement learning, 02 engineering and technology, lcsh:Chemical technology, Biochemistry, Article, Nash equilibrium, Analytical Chemistry, Noma, self-organized devices, [INFO.INFO-NI]Computer Science [cs]/Networking and Internet Architecture [cs.NI], symbols.namesake, Perspective (geometry), 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, medicine, Reinforcement learning, lcsh:TP1-1185, NOMA/OMA, Electrical and Electronic Engineering, [MATH]Mathematics [math], Set (psychology), Instrumentation, Throughput (business), ComputingMilieux_MISCELLANEOUS, 5G/B5G/6G, business.industry, 020206 networking & telecommunications, 020302 automobile design & engineering, medicine.disease, Atomic and Molecular Physics, and Optics, symbols, business, D2D-relaying, biform game, Computer network

Abstract

Structureless communications such as Device-to-Device (D2D) relaying are undeniably of paramount importance to improving the performance of today&rsquo, s mobile networks. Such a communication paradigm requires implementing a certain level of intelligence at device level, allowing to interact with the environment and select proper decisions. However, decentralizing decision making sometimes may induce some paradoxical outcomes resulting, therefore, in a performance drop, which sustains the design of self-organizing, yet efficient systems. Here, each device decides either to directly connect to the eNodeB or get access via another device through a D2D link. Given the set of active devices and the channel model, we derive the outage probability for both cellular link and D2D link, and compute the system throughput. We capture the device behavior using a biform game perspective. In the first part of this article, we analyze the pure and mixed Nash equilibria of the induced game where each device seeks to maximize its own throughput. Our framework allows us to analyse and predict the system&rsquo, s performance. The second part of this article is devoted to implement two Reinforcement Learning (RL) algorithms enabling devices to self-organize themselves and learn their equilibrium pure/mixed strategies, in a fully distributed fashion. Simulation results show that offloading the network by means of D2D-relaying improves per device throughput. Moreover, detailed analysis on how the network parameters affect the global performance is provided.

Published

2021