Litcius/Paper detail

Learned Variable-Rate Image Compression With Residual Divisive Normalization

Mohammad Akbari, Jie Liang, Jingning Han, Chengjie Tu

202027 citationsDOI

Abstract

Recently deep learning-based image compression has shown the potential to outperform traditional codecs. However, most existing methods train multiple networks for multiple bit rates, which increases the implementation complexity. In this paper, we propose a variable-rate image compression framework, which employs more Generalized Divisive Normalization (GDN) layers than previous GDN-based methods. Novel GDN-based residual sub-networks are also developed in the encoder and decoder networks. Our scheme also uses a stochastic rounding-based scalar quantization. To further improve the performance, we encode the residual between the input and the reconstructed image from the decoder network as an enhancement layer. To enable a single model to operate with different bit rates and to learn multi-rate image features, a new objective function is introduced. Experimental results show that the proposed framework trained with variable-rate objective function outperforms all standard codecs such as H.265/HEVC-based BPG and state-of-the-art learning-based variable-rate methods.

Topics & Concepts

Computer scienceResidualNormalization (sociology)Image compressionRoundingAlgorithmCodecArtificial intelligenceMNIST databaseQuantization (signal processing)EncoderDecoding methodsPattern recognition (psychology)Image processingDeep learningImage (mathematics)Operating systemSociologyComputer hardwareAnthropologyAdvanced Data Compression TechniquesImage and Signal Denoising MethodsAdvanced Image Processing Techniques