STCGAT: Spatial-temporal causal networks for complex urban road traffic
flow prediction
- URL: http://arxiv.org/abs/2203.10749v1
- Date: Mon, 21 Mar 2022 06:38:34 GMT
- Title: STCGAT: Spatial-temporal causal networks for complex urban road traffic
flow prediction
- Authors: Wei Zhao, Shiqi Zhang, Bing Zhou, Bei Wang
- Abstract summary: Traffic data are highly nonlinear and have complex spatial correlations between road nodes.
Existing approaches usually use fixed traffic road network topology maps and independent time series modules to capture Spatial-temporal correlations.
We propose a new prediction model which captures the spatial dependence of the traffic network through a Graph Attention Network(GAT) and then analyzes the causal relationship of the traffic data.
- Score: 12.223433627287605
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Traffic forecasting is an essential component of intelligent transportation
systems. However, traffic data are highly nonlinear and have complex spatial
correlations between road nodes. Therefore, it is incredibly challenging to dig
deeper into the underlying Spatial-temporal relationships from the complex
traffic data. Existing approaches usually use fixed traffic road network
topology maps and independent time series modules to capture Spatial-temporal
correlations, ignoring the dynamic changes of traffic road networks and the
inherent temporal causal relationships between traffic events. Therefore, a new
prediction model is proposed in this study. The model dynamically captures the
spatial dependence of the traffic network through a Graph Attention
Network(GAT) and then analyzes the causal relationship of the traffic data
using our proposed Causal Temporal Convolutional Network(CTCN) to obtain the
overall temporal dependence. We conducted extensive comparison experiments with
other traffic prediction methods on two real traffic datasets to evaluate the
model's prediction performance. Compared with the best experimental results of
different prediction methods, the prediction performance of our approach is
improved by more than 50%. You can get our source code and data through
https://github.com/zhangshqii/STCGAT.
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