Forecasting Unobserved Node States with spatio-temporal Graph Neural Networks

Andreas Roth, T. Liebig
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引用次数: 6

Abstract

Forecasting future states of sensors is key to solving tasks like weather prediction, route planning, and many others when dealing with networks of sensors. But complete spatial coverage of sensors is generally unavailable and would practically be infeasible due to limitations in budget and other resources during deployment and maintenance. Currently existing approaches using machine learning are limited to the spatial locations where data was observed, causing limitations to downstream tasks. Inspired by the recent surge of Graph Neural Networks for spatio-temporal data processing, we investigate whether these can also forecast the state of locations with no sensors available. For this purpose, we develop a framework, named Forecasting Unobserved Node States (FUNS), that allows forecasting the state at entirely unobserved locations based on spatio-temporal correlations and the graph inductive bias. FUNS serves as a blueprint for optimizing models only on observed data and demonstrates good generalization capabilities for predicting the state at entirely unobserved locations during the testing stage. Our framework can be combined with any spatio-temporal Graph Neural Network, that exploits spatio-temporal correlations with surrounding observed locations by using the network's graph structure. Our employed model builds on a previous model by also allowing us to exploit prior knowledge about locations of interest, e.g. the road type. Our empirical evaluation of both simulated and real-world datasets demonstrates that Graph Neural Networks are well-suited for this task.
时空图神经网络预测未观测节点状态
在处理传感器网络时,预测传感器的未来状态是解决天气预报、路线规划等任务的关键。但是,传感器的完全空间覆盖通常是不可能的,而且由于预算和其他资源在部署和维护期间的限制,实际上是不可行的。目前使用机器学习的现有方法仅限于观察数据的空间位置,从而限制了下游任务。受最近用于时空数据处理的图神经网络的启发,我们研究了这些网络是否也可以预测没有传感器可用的位置的状态。为此,我们开发了一个名为预测未观测节点状态(FUNS)的框架,该框架允许基于时空相关性和图归纳偏差预测完全未观测位置的状态。FUNS作为仅在观测数据上优化模型的蓝图,并展示了在测试阶段预测完全未观测位置的状态的良好泛化能力。我们的框架可以与任何时空图神经网络相结合,通过使用网络的图结构来利用与周围观测位置的时空相关性。我们所采用的模型建立在之前的模型之上,也允许我们利用关于感兴趣位置的先验知识,例如道路类型。我们对模拟和现实世界数据集的经验评估表明,图神经网络非常适合这项任务。
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