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Learned Wyner–Ziv Compressors Recover Binning

Ezgi Özyılkan, Johannes Ballé, Elza Erkip

202315 citationsDOI

Abstract

We consider lossy compression of an information source when the decoder has lossless access to a correlated one. This setup, also known as the Wyner-Ziv problem, is a special case of distributed source coding. To this day, real-world applications of this problem have neither been fully developed nor heavily investigated. We propose a data-driven method based on machine learning that leverages the universal function approximation capability of artificial neural networks. We find that our neural network-based compression scheme re-discovers some principles of the optimum theoretical solution of the Wyner-Ziv setup, such as binning in the source space as well as linear decoder behavior within each quantization index, for the quadratic-Gaussian case. These behaviors emerge although no structure exploiting knowledge of the source distributions was imposed. Binning is a widely used tool in information theoretic proofs and methods, and to our knowledge, this is the first time it has been explicitly observed to emerge from data-driven learning.

Topics & Concepts

Computer scienceLossless compressionEntropy encodingLossy compressionSource codeDecoding methodsDistributed source codingGaussianAlgorithmArtificial neural networkQuadratic equationData compressionTheoretical computer scienceEntropy (arrow of time)Coding (social sciences)Quantization (signal processing)Mathematical proofArtificial intelligenceChannel codeMathematicsPhysicsGeometryOperating systemStatisticsQuantum mechanicsWireless Communication Security TechniquesChaos-based Image/Signal EncryptionComputability, Logic, AI Algorithms