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Paper detail

Evaluating the Practicality of Learned Image Compression

Learned image compression has achieved extraordinary rate-distortion performance in PSNR and MS-SSIM compared to traditional methods. However, it suffers from intensive computation, which is intolerable for real-world applications and leads to its limited industrial application for now. In this paper, we introduce neural architecture search (NAS) to designing more efficient networks with lower latency, and leverage quantization to accelerate the inference process. Meanwhile, efforts in engineering like multi-threading and SIMD have been made to improve efficiency. Optimized using a hybrid loss of PSNR and MS-SSIM for better visual quality, we obtain much higher MS-SSIM than JPEG, JPEG XL and AVIF over all bit rates, and PSNR between that of JPEG XL and AVIF. Our software implementation of LIC achieves comparable or even faster inference speed compared to jpeg-turbo while being multiple times faster than JPEG XL and AVIF. Besides, our implementation of LIC reaches stunning throughput of 145 fps for encoding and 208 fps for decoding on a Tesla T4 GPU for 1080p images. On CPU, the latency of our implementation is comparable with JPEG XL.

preprint2022arXivOpen access
Hongjiu YuQiancheng SunJin HuXingyuan XueJixiang LuoDailan HeYilong LiPengbo WangYuanyuan WangYaxu DaiYan WangHongwei Qin
eess.IVComputer Vision
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Hongjiu YuQiancheng SunJin HuXingyuan XueJixiang LuoDailan HeYilong LiPengbo WangYuanyuan WangYaxu DaiYan WangHongwei Qin

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