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arxiv: 1902.07830 · v4 · pith:LZGNR2XYnew · submitted 2019-02-21 · 💻 cs.RO

Deep Multi-modal Object Detection and Semantic Segmentation for Autonomous Driving: Datasets, Methods, and Challenges

classification 💻 cs.RO
keywords autonomousdeepdrivingchallengesdetectionfusemethodsmulti-modal
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Recent advancements in perception for autonomous driving are driven by deep learning. In order to achieve robust and accurate scene understanding, autonomous vehicles are usually equipped with different sensors (e.g. cameras, LiDARs, Radars), and multiple sensing modalities can be fused to exploit their complementary properties. In this context, many methods have been proposed for deep multi-modal perception problems. However, there is no general guideline for network architecture design, and questions of "what to fuse", "when to fuse", and "how to fuse" remain open. This review paper attempts to systematically summarize methodologies and discuss challenges for deep multi-modal object detection and semantic segmentation in autonomous driving. To this end, we first provide an overview of on-board sensors on test vehicles, open datasets, and background information for object detection and semantic segmentation in autonomous driving research. We then summarize the fusion methodologies and discuss challenges and open questions. In the appendix, we provide tables that summarize topics and methods. We also provide an interactive online platform to navigate each reference: https://boschresearch.github.io/multimodalperception/.

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Cited by 3 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

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    cs.LG 2019-03 accept novelty 8.0

    nuScenes provides the first public autonomous-driving dataset that includes synchronized 360-degree data from cameras, radars, and lidar together with 3D bounding-box annotations across 1000 scenes.

  2. Trajectory-Aware Adaptive Inference in Object Detection Models

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  3. Analyzing the Cross-Sensor Portability of Neural Network Architectures for LiDAR-based Semantic Labeling

    cs.CV 2019-07 unverdicted novelty 4.0

    A new CNN architecture for LiDAR semantic labeling achieves higher cross-sensor portability with a reported 10 percentage point IoU gain over a reference method.