Conditioned Human Trajectory Prediction using Iterative Attention Blocks
- URL: http://arxiv.org/abs/2206.14442v1
- Date: Wed, 29 Jun 2022 07:49:48 GMT
- Title: Conditioned Human Trajectory Prediction using Iterative Attention Blocks
- Authors: Aleksey Postnikov, Aleksander Gamayunov, Gonzalo Ferrer
- Abstract summary: We present a simple yet effective pedestrian trajectory prediction model aimed at pedestrians positions prediction in urban-like environments.
Our model is a neural-based architecture that can run several layers of attention blocks and transformers in an iterative sequential fashion.
We show that without explicit introduction of social masks, dynamical models, social pooling layers, or complicated graph-like structures, it is possible to produce on par results with SoTA models.
- Score: 70.36888514074022
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Human motion prediction is key to understand social environments, with direct
applications in robotics, surveillance, etc. We present a simple yet effective
pedestrian trajectory prediction model aimed at pedestrians positions
prediction in urban-like environments conditioned by the environment: map and
surround agents. Our model is a neural-based architecture that can run several
layers of attention blocks and transformers in an iterative sequential fashion,
allowing to capture the important features in the environment that improve
prediction. We show that without explicit introduction of social masks,
dynamical models, social pooling layers, or complicated graph-like structures,
it is possible to produce on par results with SoTA models, which makes our
approach easily extendable and configurable, depending on the data available.
We report results performing similarly with SoTA models on publicly available
and extensible-used datasets with unimodal prediction metrics ADE and FDE.
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