Romis Attux scite author profile

Modern unorganized machines--extreme learning machines and echo state networks--provide an elegant balance between processing capability and mathematical simplicity, circumventing the difficulties associated with the conventional training approaches of feedforward/recurrent neural networks (FNNs/RNNs). This work performs a detailed investigation of the applicability of unorganized architectures to the problem of seasonal streamflow series forecasting, considering scenarios associated with four Brazilian hydroelectric plants and four distinct prediction horizons. Experimental results indicate the pertinence of these models to the focused task.

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A deep convolutional neural network for COVID-19 detection using chest X-rays

Bassi

Attux

2021

Res. Biomed. Eng.

119

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Purpose We present image classifiers based on Dense Convolutional Networks and transfer learning to classify chest X-ray images according to three labels: COVID-19, pneumonia, and normal. Methods We fine-tuned neural networks pretrained on ImageNet and applied a twice transfer learning approach, using NIH ChestX-ray14 dataset as an intermediate step. We also suggested a novelty called output neuron keeping, which changes the twice transfer learning technique. In order to clarify the modus operandi of the models, we used Layer-wise Relevance Propagation (LRP) to generate heatmaps. Results We were able to reach test accuracy of 100% on our test dataset. Twice transfer learning and output neuron keeping showed promising results improving performances, mainly in the beginning of the training process. Although LRP revealed that words on the X-rays can influence the networks' predictions, we discovered this had only a very small effect on accuracy. Conclusion Although clinical studies and larger datasets are still needed to further ensure good generalization, the state-of-the-art performances we achieved show that, with the help of artificial intelligence, chest X-rays can become a cheap and accurate auxiliary method for COVID-19 diagnosis. Heatmaps generated by LRP improve the interpretability of the deep neural networks and indicate an analytical path for future research on diagnosis. Twice transfer learning with output neuron keeping improved DNN performance.

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Comparative analysis of strategies for feature extraction and classification in SSVEP BCIs

Carvalho

Costa

Uribe

et al. 2015

Biomedical Signal Processing and Control

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Application of natural computing algorithms to maximum likelihood estimation of direction of arrival

et al. 2012

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Romis Attux

Performance analysis of unorganized machines in streamflow forecasting of Brazilian plants

Unorganized Machines for Seasonal Streamflow Series Forecasting

A deep convolutional neural network for COVID-19 detection using chest X-rays

Comparative analysis of strategies for feature extraction and classification in SSVEP BCIs

Application of natural computing algorithms to maximum likelihood estimation of direction of arrival

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