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Modeling Trajectories with Neural Ordinary Differential Equations

Yuxuan Liang, Kun Ouyang, Hanshu Yan, Yiwei Wang, Zekun Tong, Roger Zimmermann

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Abstract

Recent advances in location-acquisition techniques have generated massive spatial trajectory data. Recurrent Neural Networks (RNNs) are modern tools for modeling such trajectory data. After revisiting RNN-based methods for trajectory modeling, we expose two common critical drawbacks in the existing uses. First, RNNs are discrete-time models that only update the hidden states upon the arrival of new observations, which makes them an awkward fit for learning real-world trajectories with continuous-time dynamics. Second, real-world trajectories are never perfectly accurate due to unexpected sensor noise. Most RNN-based approaches are deterministic and thereby vulnerable to such noise. To tackle these challenges, we devise a novel method entitled TrajODE for more natural modeling of trajectories. It combines the continuous-time characteristic of Neural Ordinary Differential Equations (ODE) with the robustness of stochastic latent spaces. Extensive experiments on the task of trajectory classification demonstrate the superiority of our framework against the RNN counterparts.

Topics & Concepts

Recurrent neural networkTrajectoryOdeComputer scienceOrdinary differential equationRobustness (evolution)Artificial neural networkArtificial intelligenceMachine learningDifferential equationMathematicsApplied mathematicsMathematical analysisGeneAstronomyPhysicsChemistryBiochemistryTime Series Analysis and ForecastingTraffic Prediction and Management TechniquesAnomaly Detection Techniques and Applications