解释深度学习纠错码

2022 IEEE International Symposium on Information Theory (ISIT) Pub Date : 2022-06-26 DOI:10.1109/ISIT50566.2022.9834599

N. Devroye, N. Mohammadi, A. Mulgund, H. Naik, R. Shekhar, Gyoergy Turan, Y. Wei, M. Žefran

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引用次数: 6

摘要

深度学习最近被用于学习纠错编码器和解码器，这可能会在某些制度下改进先前已知的代码。编码器和解码器是经过学习的“黑盒”，解释它们的行为对进一步的应用和将这项工作纳入编码理论都很有意义。理解这些代码为可解释的人工智能(XAI)提供了一个引人注目的案例研究:由于编码理论是一个发展良好的定量领域，因此产生的可解释性问题与传统考虑的问题不同。我们利用影响热图、混合整数线性规划(MILP)、傅立叶分析和性能测试，开发了基于自编码器的turbo ae二进制码深度学习编码器的即时可解释性技术。我们将学习的、可解释的编码器与BCJR解码器结合起来与原始的黑箱代码进行比较。

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Interpreting Deep-Learned Error-Correcting Codes

Deep learning has been used recently to learn error-correcting encoders and decoders which may improve upon previously known codes in certain regimes. The encoders and decoders are learned "black-boxes", and interpreting their behavior is of interest both for further applications and for incorporating this work into coding theory. Understanding these codes provides a compelling case study for Explainable Artificial Intelligence (XAI): since coding theory is a well-developed and quantitative field, the interpretability problems that arise differ from those traditionally considered. We develop post-hoc interpretability techniques to analyze the deep-learned, autoencoder-based encoders of TurboAE-binary codes, using influence heatmaps, mixed integer linear programming (MILP), Fourier analysis, and property testing. We compare the learned, interpretable encoders combined with BCJR decoders to the original black-box code.

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2022 IEEE International Symposium on Information Theory (ISIT)

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