01985nas a2200253 4500000000100000000000100001008004100002260001200043653001600055653002100071653000900092653002400101653001600125100001700141700001500158700001700173700001700190245012400207856008100331300001000412490000600422520128900428022001401717 2022 d c09/202210aCompression10aDynamic Strategy10aMaps10aHyperspectral Image10aMulti-Depth1 aShaoming Pan1 aXiaoLin Gu1 aYanwen Chong1 aYuanyuan Guo00aContent-Based Hyperspectral Image Compression Using a Multi-Depth Weighted Map With Dynamic Receptive Field Convolution uhttps://www.ijimai.org/journal/sites/default/files/2022-08/ijimai_7_5_10.pdf a85-920 v73 aIn content-based image compression, the importance map guides the bit allocation based on its ability to represent the importance of image contents. In this paper, we improve the representational power of importance map using Squeeze-and-Excitation (SE) block, and propose multi-depth structure to reconstruct non-important channel information at low bit rates. Furthermore, Dynamic Receptive Field convolution (DRFc) is introduced to improve the ability of normal convolution to extract edge information, so as to increase the weight of edge content in the importance map and improve the reconstruction quality of edge regions. Results indicate that our proposed method can extract an importance map with clear edges and fewer artifacts so as to provide obvious advantages for bit rate allocation in content-based image compression. Compared with typical compression methods, our proposed method can greatly improve the performance of Peak Signal-to-Noise Ratio (PSNR), structural similarity (SSIM) and spectral angle (SAM) on three public datasets, and can produce a much better visual result with sharp edges and fewer artifacts. As a result, our proposed method reduces the SAM by 42.8% compared to the recently SOTA method to achieve the same low bpp (0.25) on the KAIST dataset. a1989-1660