Binary domain generalization for sparsifying binary neural networks

Machine learning and knowledge discovery in databases : European Conference, ECML PKDD ... : proceedings. ECML PKDD (Conference) Pub Date : 2023-06-23 DOI:10.48550/arXiv.2306.13515

Riccardo Schiavone, Francesco Galati, Maria A. Zuluaga

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Abstract

Binary neural networks (BNNs) are an attractive solution for developing and deploying deep neural network (DNN)-based applications in resource constrained devices. Despite their success, BNNs still suffer from a fixed and limited compression factor that may be explained by the fact that existing pruning methods for full-precision DNNs cannot be directly applied to BNNs. In fact, weight pruning of BNNs leads to performance degradation, which suggests that the standard binarization domain of BNNs is not well adapted for the task. This work proposes a novel more general binary domain that extends the standard binary one that is more robust to pruning techniques, thus guaranteeing improved compression and avoiding severe performance losses. We demonstrate a closed-form solution for quantizing the weights of a full-precision network into the proposed binary domain. Finally, we show the flexibility of our method, which can be combined with other pruning strategies. Experiments over CIFAR-10 and CIFAR-100 demonstrate that the novel approach is able to generate efficient sparse networks with reduced memory usage and run-time latency, while maintaining performance.

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稀疏化二值神经网络的二值域泛化

二元神经网络(bnn)是在资源受限设备中开发和部署基于深度神经网络(DNN)的应用程序的一种有吸引力的解决方案。尽管它们取得了成功，但bnn仍然受到固定和有限的压缩因子的影响，这可能是因为现有的全精度dnn修剪方法不能直接应用于bnn。事实上，对bnn进行权值修剪会导致性能下降，这表明bnn的标准二值化域不能很好地适应该任务。这项工作提出了一种新的更通用的二进制域，扩展了对剪枝技术更健壮的标准二进制域，从而保证了改进的压缩并避免了严重的性能损失。我们展示了一个将全精度网络的权重量化到所提出的二值域的封闭解。最后，我们展示了我们的方法的灵活性，它可以与其他修剪策略相结合。在CIFAR-10和CIFAR-100上的实验表明，这种新方法能够生成高效的稀疏网络，减少内存使用和运行时延迟，同时保持性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Machine learning and knowledge discovery in databases : European Conference, ECML PKDD ... : proceedings. ECML PKDD (Conference)

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