Spatial-temporal forecasting has attracted tremendous attention in a wide range of applications, and traffic flow prediction is a canonical and typical example. The complex and long-range spatial-temporal correlations of traffic flow bring it to a most intractable challenge. Existing works typically utilize shallow graph convolution networks (GNNs) and temporal extracting modules to model spatial and temporal dependencies respectively. However, the representation ability of such models is limited due to: (1) shallow GNNs are incapable to capture long-range spatial correlations, (2) only spatial connections are considered and a mass of semantic connections are ignored, which are of great importance for a comprehensive understanding of traffic networks. To this end, we propose Spatial-Temporal Graph Ordinary Differential Equation Networks (STGODE). Specifically, we capture spatial-temporal dynamics through a tensor-based ordinary differential equation (ODE), as a result, deeper networks can be constructed and spatial-temporal features are utilized synchronously. To understand the network more comprehensively, semantical adjacency matrix is considered in our model, and a well-design temporal dialated convolution structure is used to capture long term temporal dependencies. We evaluate our model on multiple real-world traffic datasets and superior performance is achieved over state-of-the-art baselines.
翻译:在一系列广泛的应用中,空间时空预报吸引了巨大的注意,交通流量预测是一个典型的典型的典型例子。交通流量的复杂和长距离空间时空相关关系使其面临最棘手的挑战。现有工程通常分别使用浅微图形变异网络(GNNs)和时间提取模块,以模拟空间和时间依赖性。然而,这些模型的代表性能力有限,原因是:(1)浅色GNNs无法捕捉远程空间关系,(2)只考虑空间连接,忽视了大量的语义连接,这对全面理解交通网络非常重要。为此,我们提议建立空间时空图普通差异分布式网络(STODE),具体地说,我们通过基于成分数的普通差异方程式(ODE)捕捉空间时空动态,因此,可以建造更深的网络,同时利用空间时空特征。为了更全面地理解网络,我们模型中考虑了对网络的语义连接矩阵,对全面理解,对全面理解的通信网络非常重要。我们为此,我们提出了空间时空图普通差异分布网(STOD-S-D-D-D-D-D-Simlax-Simal-Simaltraviewdal-de Staxy) lax lax