Towards extreme learning machine framework for lane detection on unmanned mobile robot

Robotic Intelligence and Automation Pub Date : 2022-04-29 DOI:10.1108/aa-10-2021-0125

Yingpeng Dai, Jiehao Li, Junzheng Wang, Jing Li, Xu Liu

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Abstract

Purpose

This paper aims to focus on lane detection of unmanned mobile robots. For the mobile robot, it is undesirable to spend lots of time detecting the lane. So quickly detecting the lane in a complex environment such as poor illumination and shadows becomes a challenge.

Design/methodology/approach

A new learning framework based on an integration of extreme learning machine (ELM) and an inception structure named multiscale ELM is proposed, making full use of the advantages that ELM has faster convergence and convolutional neural network could extract local features in different scales. The proposed architecture is divided into two main components: self-taught feature extraction by ELM with the convolution layer and bottom-up information classification based on the feature constraint. To overcome the disadvantages of poor performance under complex conditions such as shadows and illumination, this paper mainly solves four problems: local features learning: replaced the fully connected layer, the convolutional layer is used to extract local features; feature extraction in different scales: the integration of ELM and inception structure improves the parameters learning speed, but it also achieves spatial interactivity in different scales; and the validity of the training database: a method how to find a training data set is proposed.

Findings

Experimental results on various data sets reveal that the proposed algorithm effectively improves performance under complex conditions. In the actual environment, experimental results tested by the robot platform named BIT-NAZA show that the proposed algorithm achieves better performance and reliability.

Originality/value

This research can provide a theoretical and engineering basis for lane detection on unmanned robots.

查看原文本刊更多论文

无人移动机器人车道检测的极限学习机框架研究

本文主要研究无人移动机器人的车道检测问题。对于移动机器人来说，花费大量的时间进行车道检测是不可取的。因此，在光照不足和阴影等复杂环境下快速检测车道成为一项挑战。设计/方法/方法:充分利用极限学习机(ELM)收敛速度快和卷积神经网络可以提取不同尺度局部特征的优势，提出了一种基于极限学习机(ELM)和多尺度ELM初始结构相结合的学习框架。该体系结构分为两个主要部分:基于卷积层的ELM自学习特征提取和基于特征约束的自下而上信息分类。为了克服在阴影、光照等复杂条件下性能较差的缺点，本文主要解决了四个问题:局部特征学习:用卷积层代替全连接层提取局部特征;不同尺度下的特征提取:ELM与初始结构的融合在提高参数学习速度的同时，实现了不同尺度下的空间交互性;针对训练数据库的有效性问题，提出了一种寻找训练数据集的方法。在各种数据集上的实验结果表明，该算法有效地提高了复杂条件下的性能。在实际环境中，机器人平台BIT-NAZA的实验结果表明，本文提出的算法具有更好的性能和可靠性。独创性/价值本研究可为无人机器人的车道检测提供理论和工程基础。

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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Robotic Intelligence and Automation

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