A deep-network solution towards model-less obstacle avoidance

2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) Pub Date : 2016-10-01 DOI:10.1109/IROS.2016.7759428

L. Tai, Shaohua Li, Ming Liu

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引用次数: 177

Abstract

Obstacle avoidance is the core problem for mobile robots. Its objective is to allow mobile robots to explore an unknown environment without colliding into other objects. It is the basis for various tasks, e.g. surveillance and rescue, etc. Previous approaches mainly focused on geometric models (such as constructing local cost-maps) which could be regarded as low-level intelligence without any cognitive process. Recently, deep learning has made great breakthroughs in computer vision, especially for recognition and cognitive tasks. It takes advantage of the hierarchical models inspired by human brain structures. However, it is a fact that deep learning, up till now, has seldom been used for controlling and decision making. Inspired by the advantages of deep learning, we take indoor obstacle avoidance as example to show the effectiveness of a hierarchical structure that fuses a convolutional neural network (CNN) with a decision process. It is a highly compact network structure that takes raw depth images as input, and generates control commands as network output, by which a model-less obstacle avoidance behavior is achieved. We test our approach in real-world indoor environments. The new findings and results are reported at the end of the paper.

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面向无模型避障的深度网络解决方案

避障是移动机器人的核心问题。它的目标是允许移动机器人探索未知环境而不会碰撞到其他物体。它是各种任务的基础，例如监视和救援等。以前的方法主要集中在几何模型(如构建局部成本图)上，这可以被视为不需要任何认知过程的低水平智力。近年来，深度学习在计算机视觉方面取得了很大的突破，特别是在识别和认知任务方面。它利用了受人类大脑结构启发的分层模型。然而，到目前为止，深度学习还很少被用于控制和决策。受深度学习优势的启发，我们以室内避障为例，展示了将卷积神经网络(CNN)与决策过程融合的层次结构的有效性。它是一种高度紧凑的网络结构，以原始深度图像为输入，生成控制命令作为网络输出，从而实现无模型的避障行为。我们在真实的室内环境中测试了我们的方法。本文最后报告了新的发现和结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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