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Paper Detail

Paper IDCOM-2.3
Paper Title COMPREHENSIVE COMPARISONS OF UNIFORM QUANTIZERS FOR DEEP IMAGE COMPRESSION
Authors Koki Tsubota, Kiyoharu Aizawa, University of Tokyo, Japan
SessionCOM-2: Learning-based Image and Video Coding
LocationArea H
Session Time:Wednesday, 22 September, 14:30 - 16:00
Presentation Time:Wednesday, 22 September, 14:30 - 16:00
Presentation Poster
Topic Image and Video Communications: Lossy coding of images & video
IEEE Xplore Open Preview  Click here to view in IEEE Xplore
Abstract Deep image compression is formulated as a joint rate-distortion optimization problem using an auto-encoder architecture. Latent representations obtained by an encoder are quantized by a quantizer and fed to a decoder and an entropy model to reconstruct the images and estimate probabilities for entropy coding, respectively. Existing methods presented several methods to approximate the quantization for optimization because the gradient of a naive quantizer is zero almost everywhere. Although quantization is a fundamental operation in image compression, there are few comparisons between these quantization methods and the best approximation among them remains unexplored. To address this problem, we comprehensively compare existing approximations of the uniform quantization. Furthermore, focusing on the fact that a decoder and an entropy model have different compatibility with the approximation of quantization, we also evaluate different combinations of approximations for the decoder and the entropy model. Through experiments, we find that the approximations by adding noise are better than rounding and that the best combination of approximations among what we explored outperforms existing approximations.