VM-MODNet: Vehicle Motion aware Moving Object Detection for Autonomous Driving

Moving object Detection (MOD) is a critical task in autonomous driving as moving agents around the ego-vehicle need to be accurately detected for safe trajectory planning. It also enables appearance agnostic detection of objects based on motion cues. There are geometric challenges like motion-parall...

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Veröffentlicht in:	arXiv.org 2021-07
Hauptverfasser:	Rashed, Hazem, Ahmad El Sallab, Yogamani, Senthil
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Sprache:	eng
Schlagworte:	Mathematical analysis Motion compensation Motion perception Moving object recognition Parallax Tensors Trajectory planning
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creator	Rashed, Hazem Ahmad El Sallab Yogamani, Senthil
description	Moving object Detection (MOD) is a critical task in autonomous driving as moving agents around the ego-vehicle need to be accurately detected for safe trajectory planning. It also enables appearance agnostic detection of objects based on motion cues. There are geometric challenges like motion-parallax ambiguity which makes it a difficult problem. In this work, we aim to leverage the vehicle motion information and feed it into the model to have an adaptation mechanism based on ego-motion. The motivation is to enable the model to implicitly perform ego-motion compensation to improve performance. We convert the six degrees of freedom vehicle motion into a pixel-wise tensor which can be fed as input to the CNN model. The proposed model using Vehicle Motion Tensor (VMT) achieves an absolute improvement of 5.6% in mIoU over the baseline architecture. We also achieve state-of-the-art results on the public KITTI_MoSeg_Extended dataset even compared to methods which make use of LiDAR and additional input frames. Our model is also lightweight and runs at 85 fps on a TitanX GPU. Qualitative results are provided in https://youtu.be/ezbfjti-kTk.
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subjects	Mathematical analysis Motion compensation Motion perception Moving object recognition Parallax Tensors Trajectory planning
title	VM-MODNet: Vehicle Motion aware Moving Object Detection for Autonomous Driving
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