Volumetric End-to-End Optimized Compression for Brain Images

Shuo Gao, Yueyi Zhang, Dong Liu, Zhiwei Xiong
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引用次数: 3

Abstract

The amount of volumetric brain image increases rapidly, which requires a vast amount of resources for storage and transmission, so it’s urgent to explore an efficient volumetric compression method. Recent years have witnessed the progress of deep learning-based approaches for two-dimensional (2D) natural image compression, but the field of learned volumetric image compression still remains unexplored. In this paper, we propose the first end-to-end learning framework for volumetric image compression by extending the advanced techniques of 2D image compression to volumetric images. Specifically, a convolutional autoencoder is used to compress 3D image cubes, and the non-local attention models are embedded in the convolutional autoencoder to jointly capture local and global correlations. Both hyperprior and autoregressive models are used to perform the conditional probability estimation in entropy coding. To reduce model complexity, we introduce a convolutional long short-term memory network for the autoregressive model based on channel-wise prediction. Experimental results on volumetric mouse brain images show that the proposed method outperforms JPEG2000-3D, HEVC and state-of-the-art 2D methods.
体积端到端优化压缩脑图像
脑体积图像的量迅速增加,需要大量的存储和传输资源,因此迫切需要探索一种高效的体积压缩方法。近年来,基于深度学习的二维(2D)自然图像压缩方法取得了进展,但学习的体积图像压缩领域仍未得到探索。在本文中,我们通过将2D图像压缩的先进技术扩展到体积图像,提出了第一个用于体积图像压缩的端到端学习框架。具体而言,采用卷积自编码器对三维图像立方体进行压缩,并将非局部注意模型嵌入到卷积自编码器中,以共同捕获局部和全局相关性。采用超先验模型和自回归模型对熵编码中的条件概率进行估计。为了降低模型复杂度,我们引入了一个基于通道预测的卷积长短期记忆网络。实验结果表明,该方法优于JPEG2000-3D、HEVC和最先进的2D方法。
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