Ensemble Federated Learning: an approach for collaborative pneumonia
diagnosis
- URL: http://arxiv.org/abs/2312.07428v1
- Date: Tue, 12 Dec 2023 16:53:18 GMT
- Title: Ensemble Federated Learning: an approach for collaborative pneumonia
diagnosis
- Authors: Alhassan Mabrouk and Rebeca P. D\'iaz Redondo and Mohamed Abd Elaziz
and Mohammed Kayed
- Abstract summary: In smart healthcare systems, exchanging data implies privacy concerns and a quick reaction is needed.
In this paper, we work on the first scenario, where preserving privacy is key and, consequently, building a unique and massive medical image data set is not an option.
We propose an ensemble federated learning (EFL) approach that is based on the following characteristics.
- Score: 7.901279301392376
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Federated learning is a very convenient approach for scenarios where (i) the
exchange of data implies privacy concerns and/or (ii) a quick reaction is
needed. In smart healthcare systems, both aspects are usually required. In this
paper, we work on the first scenario, where preserving privacy is key and,
consequently, building a unique and massive medical image data set by fusing
different data sets from different medical institutions or research centers
(computation nodes) is not an option. We propose an ensemble federated learning
(EFL) approach that is based on the following characteristics: First, each
computation node works with a different data set (but of the same type). They
work locally and apply an ensemble approach combining eight well-known CNN
models (densenet169, mobilenetv2, xception, inceptionv3, vgg16, resnet50,
densenet121, and resnet152v2) on Chest X-ray images. Second, the best two local
models are used to create a local ensemble model that is shared with a central
node. Third, the ensemble models are aggregated to obtain a global model, which
is shared with the computation nodes to continue with a new iteration. This
procedure continues until there are no changes in the best local models. We
have performed different experiments to compare our approach with centralized
ones (with or without an ensemble approach)\color{black}. The results conclude
that our proposal outperforms these ones in Chest X-ray images (achieving an
accuracy of 96.63\%) and offers very competitive results compared to other
proposals in the literature.
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