Federated Learning for Internet of Things: Recent Advances, Taxonomy, and Open Challenges
TL;DR: In this paper, a taxonomy of federated learning over IoT networks is presented, where a set of metrics such as sparsification, robustness, quantization, scalability, security, and privacy are evaluated.
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Abstract: The Internet of Things (IoT) will be ripe for the deployment of novel machine learning algorithm for both network and application management. However, given the presence of massively distributed and private datasets, it is challenging to use classical centralized learning algorithms in the IoT. To overcome this challenge, federated learning can be a promising solution that enables on-device machine learning without the need to migrate the private end-user data to a central cloud. In federated learning, only learning model updates are transferred between end-devices and the aggregation server. Although federated learning can offer better privacy preservation than centralized machine learning, it has still privacy concerns. In this paper, first, we present the recent advances of federated learning towards enabling federated learning-powered IoT applications. A set of metrics such as sparsification, robustness, quantization, scalability, security, and privacy, is delineated in order to rigorously evaluate the recent advances. Second, we devise a taxonomy for federated learning over IoT networks. Finally, we present several open research challenges with their possible solutions.
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Citations
DetFed: Dynamic Resource Scheduling for Deterministic Federated Learning over Time-sensitive Networks
Dong Yang,Weiting Zhang,Qiang Ye,Chuan Zhang,Ning Zhang,Chuan Xiu Huang,Dongke Zhang,Xiaoyuan Chen +7 more
TL;DR: Experimental results based on real-world dataset demonstrate that the proposed DetFed significantly accelerates FL convergence and improves learning accuracy as compared to state-of-the-art benchmarks.
58
Gradient and Channel Aware Dynamic Scheduling for Over-the-Air Computation in Federated Edge Learning Systems
TL;DR: In this article , the authors proposed a dynamic device scheduling mechanism, which can select qualified edge devices to transmit their local models with a proper power control policy so as to participate the model training at the server in federated learning via AirComp.
AUDD: Audio Urdu Digits Dataset for Automatic Audio Urdu Digit Recognition
TL;DR: In this paper, a convolutional neural network (CNN) was proposed for audio digit classification in Urdu, and the results show that the proposed CNN is efficient and outperforms the baseline algorithms in terms of classification accuracy.
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Communication and computation efficiency in Federated Learning: A survey
Omair Rashed Abdulwareth Almanifi,Chee-Onn Chow,Mau-Luen Tham,Joon Huang Chuah,Jeevan Kanesan +4 more
TL;DR: In this paper , a systematic review of recent work conducted to improve the communication and/or computation efficiency in federated learning is presented, followed by the literature review placed according to an encompassing, easy-to-follow taxonomy.
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Multitentacle Federated Learning Over Software-Defined Industrial Internet of Things Against Adaptive Poisoning Attacks
TL;DR: In this paper , a multi-tentacle federated learning (MTFL) framework is proposed to guarantee the trustness of training data in SD-IIoT, where participants with similar learning tasks are assigned to the same tentacle group.
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