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Leveraging Deep Learning for Visual Odometry Using Optical Flow

Tejas Pandey, Dexmont Peña, Jonathan Byrne, David Moloney

2021Sensors31 citationsDOIOpen Access PDF

Abstract

In this paper, we study deep learning approaches for monocular visual odometry (VO). Deep learning solutions have shown to be effective in VO applications, replacing the need for highly engineered steps, such as feature extraction and outlier rejection in a traditional pipeline. We propose a new architecture combining ego-motion estimation and sequence-based learning using deep neural networks. We estimate camera motion from optical flow using Convolutional Neural Networks (CNNs) and model the motion dynamics using Recurrent Neural Networks (RNNs). The network outputs the relative 6-DOF camera poses for a sequence, and implicitly learns the absolute scale without the need for camera intrinsics. The entire trajectory is then integrated without any post-calibration. We evaluate the proposed method on the KITTI dataset and compare it with traditional and other deep learning approaches in the literature.

Topics & Concepts

Visual odometryArtificial intelligenceComputer scienceOptical flowDeep learningConvolutional neural networkComputer visionOdometryPipeline (software)MonocularArtificial neural networkFeature (linguistics)TrajectoryPattern recognition (psychology)Image (mathematics)RobotPhysicsMobile robotAstronomyLinguisticsProgramming languagePhilosophyAdvanced Vision and ImagingRobotics and Sensor-Based LocalizationOptical measurement and interference techniques
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