Distributed Federated Learning for Ultra-Reliable Low-Latency Vehicular Communications

Samarakoon, Sumudu; Bennis, Mehdi; Saad, Walid; Debbah, Mérouane

doi:10.1109/tcomm.2019.2956472

Cited by 355 publications

(191 citation statements)

References 38 publications

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“…In contrast to the above research that has overlooked the participatory method to build a high-quality central ML model and its criticality, and primarily focused on the convergence of learning time with variants of learning algorithms, our work addresses the challenge in designing a communication and computational cost effective FL framework by exploring a crowdsourcing structure. In this regard, few recent studies have discussed about the participation to build a global ML model with FL as in [29], [30]. Basically, in [29] the authors proposed a novel distributed approach based on FL to learn the network-wide queue dynamics in vehicular networks for achieving ultra-reliable low-latency communication (URLLC) via a joint power and resource allocation problem.…”

Section: Related Workmentioning

confidence: 99%

“…In this regard, few recent studies have discussed about the participation to build a global ML model with FL as in [29], [30]. Basically, in [29] the authors proposed a novel distributed approach based on FL to learn the network-wide queue dynamics in vehicular networks for achieving ultra-reliable low-latency communication (URLLC) via a joint power and resource allocation problem. The vehicles participate in FL to provide information related to sample events (i.e., queue lengths) to parameterize the distribution of extremes.…”

Section: Related Workmentioning

confidence: 99%

“…is the minimum incentive value required obtained from (29) to attain the local consensus accuracy θ th at client k for the defined parameters ν k and T k . This means, θ k (r) < θ th when z k = 1, and θ th ≤ θ k (r) < 1 when z k = 0.…”

Section: B Stackelberg Equilibrium: Algorithm and Solution Approachmentioning

confidence: 99%

See 2 more Smart Citations

A Crowdsourcing Framework for On-Device Federated Learning

Pandey

Tran

Bennis

et al. 2020

IEEE Trans. Wireless Commun.

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235

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Federated learning (FL) rests on the notion of training a global model in a decentralized manner. Under this setting, mobile devices perform computations on their local data before uploading the required updates to improve the global model. However, when the participating clients implement an uncoordinated computation strategy, the difficulty is to handle the communication efficiency (i.e., the number of communications per iteration) while exchanging the model parameters during aggregation. Therefore, a key challenge in FL is how users participate to build a high-quality global model with communication efficiency. We tackle this issue by formulating a utility maximization problem, and propose a novel crowdsourcing framework to leverage FL that considers the communication efficiency during parameters exchange. First, we show an incentivebased interaction between the crowdsourcing platform and the participating client's independent strategies for training a global learning model, where each side maximizes its own benefit. We formulate a two-stage Stackelberg game to analyze such scenario and find the game's equilibria. Second, we formalize an admission control scheme for participating clients to ensure a level of local accuracy. Simulated results demonstrate the efficacy of our proposed solution with up to 22% gain in the offered reward.

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Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

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A Crowdsourcing Framework for On-Device Federated Learning

Pandey

Tran

Bennis

et al. 2020

IEEE Trans. Wireless Commun.

Self Cite

235

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“…In federated learning systems, the raw data is collected and stored at multiple edge nodes, and a machine learning model is trained from the distributed data without sending the raw data from the nodes to a central place [23,24]. Different from the traditional joint learning method where multiple edges are learning at the same time, LFRL adopts the method of first training then fusing to reduce the dependence on the quality of communication [25,26].…”

Section: Federated Learningmentioning

confidence: 99%

Lifelong Federated Reinforcement Learning: A Learning Architecture for Navigation in Cloud Robotic Systems

Liu

Wang

Liu

2019

IEEE Robot. Autom. Lett.

165

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This paper was motivated by the problem of how to make robots fuse and transfer their experience so that they can effectively use prior knowledge and quickly adapt to new environments. To address the problem, we present a learning architecture for navigation in cloud robotic systems: Lifelong Federated Reinforcement Learning (LFRL). In the work, we propose a knowledge fusion algorithm for upgrading a shared model deployed on the cloud. Then, effective transfer learning methods in LFRL are introduced. LFRL is consistent with human cognitive science and fits well in cloud robotic systems. Experiments show that LFRL greatly improves the efficiency of reinforcement learning for robot navigation. The cloud robotic system deployment also shows that LFRL is capable of fusing prior knowledge. In addition, we release a cloud robotic navigation-learning website to provide the service based on LFRL: www.shared-robotics.com.

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“…Recently, a number of existing works such as in [18]- [21] studied important problems related to the implementation of distributed learning over wireless networks. While interesting, these prior works [18]- [21] that focus on the optimization of the performance of distributed learning algorithms such as federated learning do not consider the use of distributed learning to optimize the performance of wireless networks. In particular, these existing works [18]- [21] do not consider the use of distributed learning algorithms to predict users' orientations and locations to reduce the BIP of wireless VR users.…”

Section: Introductionmentioning

confidence: 99%

Federated Echo State Learning for Minimizing Breaks in Presence in Wireless Virtual Reality Networks

Chen

Semiari

Saad

et al. 2020

IEEE Trans. Wireless Commun.

Self Cite

102

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In this paper, the problem of enhancing the virtual reality (VR) experience for wireless users is investigated by minimizing the occurrence of breaks in presence (BIP) that can detach the users from their virtual world. To measure the BIP for wireless VR users, a novel model that jointly considers the VR application type, transmission delay, VR video quality, and users' awareness of the virtual environment is proposed. In the developed model, the base stations (BSs) transmit VR videos to the wireless VR users using directional transmission links so as to provide high data rates for the VR users, thus, reducing the number of BIP for each user. Since the body movements of a VR user may result in a blockage of its wireless link, the location and orientation of VR users must also be considered when minimizing BIP. The BIP minimization problem is formulated as an optimization problem which jointly considers the predictions of users' locations, orientations, and their BS association. To predict the orientation and locations of VR users, a distributed learning algorithm based on the machine learning framework of deep (ESNs) is proposed. The proposed algorithm uses concept from federated learning to enable multiple BSs to locally train their deep ESNs using their collected data and cooperatively build a learning model to predict the entire users' locations and orientations. Using these predictions, the user association policy that minimizes BIP is derived. Simulation results demonstrate that the developed algorithm reduces the users' BIP by up to 16% and 26%, respectively, compared to centralized ESN and deep learning algorithms.

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Distributed Federated Learning for Ultra-Reliable Low-Latency Vehicular Communications

Cited by 355 publications

References 38 publications

A Crowdsourcing Framework for On-Device Federated Learning

A Crowdsourcing Framework for On-Device Federated Learning

Lifelong Federated Reinforcement Learning: A Learning Architecture for Navigation in Cloud Robotic Systems

Federated Echo State Learning for Minimizing Breaks in Presence in Wireless Virtual Reality Networks

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