Pedestrian trajectory prediction with convolutional neural networks

Pedestrain Trajectories

Abstract

Predicting the future trajectories of pedestrians is a challenging problem that has a range of application, from crowd surveillance to autonomous driving. In literature, methods to approach pedestrian trajectory prediction have evolved, transitioning from physics-based models to data-driven models based on recurrent neural networks. In this work, we propose a new approach to pedestrian trajectory prediction, with the introduction of a novel 2D convolutional model. This new model outperforms recurrent models, and it achieves state-of-the-art results on the ETH and TrajNet datasets. We also present an effective system to represent pedestrian positions and powerful data augmentation techniques, such as the addition of Gaussian noise and the use of random rotations, which can be applied to any model. As an additional exploratory analysis, we present experimental results on the inclusion of occupancy methods to model social information, which empirically show that these methods are ineffective in capturing social interaction.

Publication
In Pattern Recognition

Acknowledgements: This work is the result of Simone Zamboni’s master thesis project carried out at SCANIA Autonomous Transport Systems. We thank the support of the industry partner, SCANIA, and the support of the university partner, KTH.

Simone Zamboni
Simone Zamboni
Machine Learning Research Engineer

Engineer passionate about large language models and robotics.