Unsupervised attributed graph representation learning is challenging since both structural and feature information are required to be represented in the latent space. Existing methods concentrate on learning latent representation via reconstruction tasks, but cannot directly optimize representation and are prone to oversmoothing, thus limiting the applications on downstream tasks. To alleviate these issues, we propose a novel graph embedding framework named Deep Manifold Attributed Graph Embedding (DMAGE). A node-to-node geodesic similarity is proposed to compute the inter-node similarity between the data space and the latent space and then use Bergman divergence as loss function to minimize the difference between them. We then design a new network structure with fewer aggregation to alleviate the oversmoothing problem and incorporate graph structure augmentation to improve the representation's stability. Our proposed DMAGE surpasses state-of-the-art methods by a significant margin on three downstream tasks: unsupervised visualization, node clustering, and link prediction across four popular datasets.
翻译:未经监督的图表代表性学习具有挑战性,因为需要将结构和特征信息在潜在空间中体现。现有方法侧重于通过重建任务学习潜在代表性,但不能直接优化代表性,容易过度缓解,从而限制下游任务的应用。为了缓解这些问题,我们提议了一个新的图形嵌入框架,名为“深曼分属性图形嵌入”(DMAGE),建议采用节点到节点的大地测量相似性,以计算数据空间与潜在空间之间的交近性,然后将伯格曼的差异作为损失函数,以尽量减少它们之间的差异。然后我们设计一个新的网络结构,以较少的聚合来缓解过度缓解过度移动的问题,并纳入图形结构的增强,以提高代表性的稳定性。我们提议的DMAGE在以下三项下游任务上大大超越了最先进的方法:未受监督的视觉化、节点组合和将四个流行数据集的预测联系起来。