Your search keyword '"branch neural networks"' showing total 4 results

1. A Probabilistic Re-Intepretation of Confidence Scores in Multi-Exit Models

Author

Jary Pomponi, Simone Scardapane, and Aurelio Uncini

Subjects

branch neural networks, deep learning, deep neural networks, adaptive computation, fast inference, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

In this paper, we propose a new approach to train a deep neural network with multiple intermediate auxiliary classifiers, branching from it. These ‘multi-exits’ models can be used to reduce the inference time by performing early exit on the intermediate branches, if the confidence of the prediction is higher than a threshold. They rely on the assumption that not all the samples require the same amount of processing to yield a good prediction. In this paper, we propose a way to train jointly all the branches of a multi-exit model without hyper-parameters, by weighting the predictions from each branch with a trained confidence score. Each confidence score is an approximation of the real one produced by the branch, and it is calculated and regularized while training the rest of the model. We evaluate our proposal on a set of image classification benchmarks, using different neural models and early-exit stopping criteria.

Published

2021

2. A Probabilistic Re-Intepretation of Confidence Scores in Multi-Exit Models

Author

Aurelio Uncini, Simone Scardapane, and Jary Pomponi

Subjects

Science, Physics, QC1-999, branch neural networks, General Physics and Astronomy, deep learning, deep neural networks, adaptive computation, fast inference, Astrophysics, Article, QB460-466, High Energy Physics::Experiment

Abstract

In this paper, we propose a new approach to train a deep neural network with multiple intermediate auxiliary classifiers, branching from it. These ‘multi-exits’ models can be used to reduce the inference time by performing early exit on the intermediate branches, if the confidence of the prediction is higher than a threshold. They rely on the assumption that not all the samples require the same amount of processing to yield a good prediction. In this paper, we propose a way to train jointly all the branches of a multi-exit model without hyper-parameters, by weighting the predictions from each branch with a trained confidence score. Each confidence score is an approximation of the real one produced by the branch, and it is calculated and regularized while training the rest of the model. We evaluate our proposal on a set of image classification benchmarks, using different neural models and early-exit stopping criteria.

Published

2021

3. A Probabilistic Re-Intepretation of Confidence Scores in Multi-Exit Models.

Author

Pomponi, Jary, Scardapane, Simone, and Uncini, Aurelio

Subjects

*CONFIDENCE, *DEEP learning

Abstract

In this paper, we propose a new approach to train a deep neural network with multiple intermediate auxiliary classifiers, branching from it. These 'multi-exits' models can be used to reduce the inference time by performing early exit on the intermediate branches, if the confidence of the prediction is higher than a threshold. They rely on the assumption that not all the samples require the same amount of processing to yield a good prediction. In this paper, we propose a way to train jointly all the branches of a multi-exit model without hyper-parameters, by weighting the predictions from each branch with a trained confidence score. Each confidence score is an approximation of the real one produced by the branch, and it is calculated and regularized while training the rest of the model. We evaluate our proposal on a set of image classification benchmarks, using different neural models and early-exit stopping criteria. [ABSTRACT FROM AUTHOR]

Published

2022

4. A Probabilistic Re-Intepretation of Confidence Scores in Multi-Exit Models.

Author

Pomponi J, Scardapane S, and Uncini A

Abstract

In this paper, we propose a new approach to train a deep neural network with multiple intermediate auxiliary classifiers, branching from it. These 'multi-exits' models can be used to reduce the inference time by performing early exit on the intermediate branches, if the confidence of the prediction is higher than a threshold. They rely on the assumption that not all the samples require the same amount of processing to yield a good prediction. In this paper, we propose a way to train jointly all the branches of a multi-exit model without hyper-parameters, by weighting the predictions from each branch with a trained confidence score. Each confidence score is an approximation of the real one produced by the branch, and it is calculated and regularized while training the rest of the model. We evaluate our proposal on a set of image classification benchmarks, using different neural models and early-exit stopping criteria.

Published

2021