SemiPFL: Personalized Semi-Supervised Federated Learning Framework for Edge Intelligence

Tashakori, Arvin; Zhang, Wenwen; Wang, Z. Jane; Servati, Peyman

doi:10.1109/jiot.2022.3233599

Cited by 3 publications

(1 citation statement)

References 62 publications

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“…They incorporated the vertical FL and horizontal FL schemes together, which were employed to extract features from heterogeneous data generated across multiple IoT devices, and aggregate the encrypted local models among multiple individual users respectively. Tashakori et al [8] developed a PFL model for multi-sensory classifications based on a semi-supervised training scheme. They designed a personalized autoencoder for each user from a hyper network in the cloud server, then generated a series of base models which would be delivered to local training according to different user distributions using their own labeled datasets.…”

Section: A Personalized Federated Learningmentioning

confidence: 99%

Personalized Federated Learning With Model-Contrastive Learning for Multi-Modal User Modeling in Human-Centric Metaverse

Zhou,

Yang,

Zheng

et al. 2024

IEEE J. Select. Areas Commun.

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With the flourish of digital technologies and rapid development of 5G and beyond networks, Metaverse has become an increasingly hotly discussed topic, which offers users with multiple roles for diversified experience interacting with virtual services. How to capture and model users' multi-platform or cross-space data/behaviors become essential to enrich people with more realistic and immersed experience in Metaverseenabled smart applications over 5G and beyond networks. In this study, we propose a Personalized Federated Learning with Model-Contrastive Learning (PFL-MCL) framework, which may efficiently enhance the communication and interaction in humancentric Metaverse environments by making use of the largescale, heterogeneous, and multi-modal Metaverse data. Differing from the conventional Federated Learning (FL) architecture, a multi-center aggregation structure to learn multiple global models based on the changes of dynamically updated local model weights, is developed in global, while a hierarchical neural network structure which includes a personalized module and a federated module to tackle both issues on data heterogeneity and model heterogeneity, is designed in local, so as to enhance the performance of PFL with unique characteristics of Metaverse data. In particular, a two-stage iterative clustering algorithm with a more precise initialization is developed to facilitate the personalized global aggregation with dynamically updated multiple aggregation centers. A personalized multi-modal fusion network is constructed to greatly reduce the computational cost and feature dimensions from the high-dimensional heterogeneous inputs for more efficient cross-modal fusion, based on a hierarchical shift-window attention mechanism and a newly designed bridge attention mechanism. A MCL scheme is then incorporated to speed up the model convergence with less communication

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Section: A Personalized Federated Learningmentioning

confidence: 99%

Personalized Federated Learning With Model-Contrastive Learning for Multi-Modal User Modeling in Human-Centric Metaverse

Zhou,

Yang,

Zheng

et al. 2024

IEEE J. Select. Areas Commun.

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Group-Personalized Federated Learning for Human Activity Recognition Through Cluster Eccentricity Analysis

Al-Saedi

Boeva

2023

Communications in Computer and Information Science

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FL_GIoT: Federated Learning Enabled Edge-Based Green Internet of Things System: A Comprehensive Survey

Awotunde,

Sur,

Jimoh

et al. 2023

IEEE Access

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In today's world, the importance of the Green Internet of Things (GIoT) in the transformed sustainable smart cities cannot be overstated. For a variety of applications, the GIoT may make use of advanced machine learning (ML) methodologies. However, owing to high processing costs and privacy issues, centralized ML-based models are not a feasible option for the large data kept at a single cloud server and created by multiple devices. In such circumstances, edge-based computing may be used to increase the privacy of GIoT networks by bringing them closer to users and decentralizing them without requiring a central authority in such circumstances. Nonetheless, enormous amounts of data are stored in a distribution mechanism, and managing them for application purposes remains a difficulty. Hence, federated learning (FL) is one of the most promising solutions for bringing learning to end devices through edge computing without sharing private data with a central server. Therefore, the paper proposes a federated learning-enabled edgebased GIoT system, which seeks to improve the communication strategy while lowering liability in terms of energy management and data security for data transmission. The proposed model uses FL to produce feature values for data routing, which could aid in sensor training for identifying the best routes to edge servers. Furthermore, combining FL-enabled edge-based techniques simplifies security solutions while also allowing for a more efficient computing system. The experimental results show an improved performance against existing models in terms of network overhead, route interruption, energy consumption, and end-toend delay, route interruption.INDEX TERMS Federated learning, Network overhead, Energy consumption, Edge computing, Green Internet of Things, Security and privacy, End-to-end delay, Route interruption.

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SemiPFL: Personalized Semi-Supervised Federated Learning Framework for Edge Intelligence

Cited by 3 publications

References 62 publications

Personalized Federated Learning With Model-Contrastive Learning for Multi-Modal User Modeling in Human-Centric Metaverse

Personalized Federated Learning With Model-Contrastive Learning for Multi-Modal User Modeling in Human-Centric Metaverse

Group-Personalized Federated Learning for Human Activity Recognition Through Cluster Eccentricity Analysis

FL_GIoT: Federated Learning Enabled Edge-Based Green Internet of Things System: A Comprehensive Survey

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