With the convenient availability of remote sensing data, how to make models to interpret complex remote sensing data attracts wide attention. In remote sensing data, hyperspectral images contain spectral information and LiDAR contains elevation information. Hence, more explorations are warranted to better fuse the features of different source data. In this paper, we introduce semantic understanding to dynamically fuse data from two different sources, extract features of HSI and LiDAR through different capsule network branches and improve self-supervised loss and random rigid rotation in Canonical Capsule to a high-dimensional situation. Canonical Capsule computes the capsule decomposition of objects by permutation-equivariant attention and the process is self-supervised by training pairs of randomly rotated objects. After fusing the features of HSI and LiDAR with semantic understanding, the unsupervised extraction of spectral-spatial-elevation fusion features is achieved. With two real-world examples of HSI and LiDAR fused, the experimental results show that the proposed multi-branch high-dimensional canonical capsule algorithm can be effective for semantic understanding of HSI and LiDAR. It indicates that the model can extract HSI and LiDAR data features effectively as opposed to existing models for unsupervised extraction of multi-source RS data.
翻译:随着遥感数据的方便提供,如何使模型能够解释复杂的遥感数据引起广泛的注意。在遥感数据中,超光谱图像含有光谱信息,而激光雷达含有高程信息。因此,有必要进行更多的探索,以更好地结合不同源数据的特性。在本文中,我们引入了对两种不同来源动态集成数据的语义理解:通过不同胶囊网络分支提取HSI和LIDAR的特性,并改进Canonical Capsule的自我监控损失和随机僵硬旋转到高维度状态。Canonical Capsule通过变异性等关注来计算物体的胶囊分解,这一过程由随机旋转的物体的训练配对自我监督。在使用HSI和LIDAR的特性后,通过语义理解,实现光谱-空间升动特性的不受监督的提取,并将HSI和LDAR熔化成两个真实世界级的例子。实验结果显示,拟议的多波段高分辨率阵列阵列阵列阵列阵列阵列阵列阵列阵列数据模型能够有效地了解高分辨率阵列的磁带数据。