基于兴趣倾向机制的仿生SLAM算法

陈孟元; 张玉坤; 田德红; 丁陵梅

doi:10.11999/JEIT210313

基于兴趣倾向机制的仿生SLAM算法

doi: 10.11999/JEIT210313

陈孟元^{1, 2, ,},
张玉坤¹,
田德红¹,
丁陵梅¹

1.
安徽工程大学电气工程学院芜湖 241000
2.
高端装备先进感知与智能控制教育部重点实验室芜湖 241000

基金项目: 国家自然科学基金(61903002)，芜湖市科技计划项目(2020yf59)，安徽工程大学-鸠江区产业协同创新专项基金(2021cyxtb8)，安徽工程大学中青年拔尖人才项目，安徽省高校协同创新项目(GXXT-2021-050)

详细信息

作者简介:
陈孟元：男，1984年生，博士，副教授，硕士生导师，主要研究方向为移动机器人SLAM、目标跟踪及路径规划

张玉坤：男，1995年生，硕士生，主要研究方向为移动机器人SLAM

田德红：男，1995年生，硕士生，主要研究方向为移动机器人SLAM

丁陵梅：女，1994年生，硕士生，主要研究方向为移动机器人SLAM

通讯作者:
陈孟元　mychen@ahpu.edu.cn

中图分类号: TP242.6
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- 被引次数: 0
出版历程
- 收稿日期: 2021-04-15
- 修回日期: 2021-06-24
- 录用日期: 2021-11-05
- 网络出版日期: 2021-11-15
- 刊出日期: 2022-05-25

Bionic SLAM Algorithm Based on Interest Tendency Mechanism

1.
School of Electrical Engineering, Anhui Polytechnic University, Wuhu 241000, China
2.
Key Laboratory of Advanced Perception and Intelligent Control of High-end Equipment, Wuhu 241000, China

Funds: The National Natural Science Foundation of China (61903002), The Science and Technology Planning Project of Wuhu, Anhui Province (2020yf59), The Anhui Polytechnic University-Jiujiang District Industry Collaborative Innovation Special Foundation (2021cyxtb8), The Middle-aged and Top-notch Talent Project of Anhui Polytechnic University, The University Synergy Innovation Program of Anhui Province (GXXT-2021-050)

摘要

摘要: 该文针对同时定位与地图创建(SLAM)闭环检测算法易受复杂环境因素干扰，导致定位误差较大、闭环检测精度低等问题，受哺乳动物空间认知机理启发，提出一种基于兴趣倾向机制的仿生SLAM算法。采用反Hebbian网络(Lateral Anti-Hebbian Networkm, LAHN)对网格细胞进行建模，通过不规则复杂环境边界信息对网格细胞进行校正来提高算法定位精度。利用兴趣倾向机制对提取的显著性区域进行兴趣赋值，减小冗余显著性区域带来的影响，提高系统闭环准确率。将位置感知模型获取的位置信息与视觉感知模板相关联构建认知地图。在公开数据集及真实环境中进行测试，测试结果表明该文算法在构建认知地图的准确率、实时性以及对环境的适应能力具有优势。
- 同时定位与地图构建 /
- 认知地图 /
- 显著性区域 /
- 网格细胞 /
- 位置细胞
Abstract: To address the problem that Simultaneous Location And Mapping (SLAM) closed-loop detection algorithms are easily disturbed by complex environmental factors, resulting in large localization errors and low closed-loop detection accuracy, a bionic SLAM algorithm based on the interest tendency mechanism is proposed, inspired by the spatial cognitive mechanism of mammals. The grid cells are modelled using the Lateral Anti-Hebbian Network (LAHN), which improves the accuracy of the algorithm by correcting the grid cells with irregular and complex environmental boundary information. The tendency of interest mechanism is used to score the extracted areas of significance, reduce the impact of redundant significant areas and improve the accuracy of the system’s closed-loop detection. A cognitive map is constructed by correlating the location information obtained from the location-aware model with a visual perception template. The results of the tests on the public dataset and the real environment show that the proposed algorithm has advantages in terms of accuracy, real time performance and adaptability to the environment.
- Simultaneous Localization And Mapping (SLAM) /
- Cognitive map /
- Area of significance /
- Grid cells /
- Place cells

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图 1 认知地图构建

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图 2 网格细胞分布图

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图 3 融合自注意力机制的卷积神经网络结构

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图 4 图像特征提取示意图

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图 5 TUM部分序列轨迹对比图

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图 6 KITTI部分序列轨迹对比图

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图 7 硬件平台及真实实验环境场景

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图 8 移动机器人路径图

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图 9 视觉里程计与本文算法定位误差对比图

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表 1 融合自注意力机制的卷积神经网络参数设置

序号	区域划分	层类型	卷积核	步长	深度	激活函数
0	编码器	Convolution	7×7	1	64	ReLU
1	编码器	Convolution	3×3	2	128	ReLU
2	编码器	Convolution	3×3	2	256	ReLU
3	中间区	Residual Block	3×3	1	256	ReLU
4	中间区	Residual Block	3×3	1	256	ReLU
5	中间区	Residual Block	3×3	1	256	ReLU
6	中间区	Residual Block	3×3	1	256	ReLU
7	中间区	Residual Block	3×3	2	256	ReLU
8	中间区	Residual Block	3×3	2	256	ReLU
9	解码器	Deconvlution	3×3	2	128	ReLU
10	解码器	Self-Attention	–	–	–	–
11	解码器	Deconvlution	3×3	1	64	ReLU
12	解码器	Convolution	7×7	1	3	Tanh
13	解码器	Interest Propensity	–	–	–	–

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表 2 各算法在TUM数据集上的结果对比

序列	轨迹均方根误差（RMSE/m）			单帧图像处理时间（ms）			闭环准确率（%）
序列	ORB-SLAM	RatSLAM	本文算法	ORB-SLAM	RatSLAM	本文算法	ORB-SLAM	RatSLAM	本文算法
fr2/coke	0.056	0.068	0.042	129	211	145	83.4	74.2	88.1
fr2/sphere	0.037	0.043	0.031	135	198	162	82.5	73.4	86.5
fr1/plant	0.052	0.065	0.039	146	230	168	84.2	74.2	89.2
fr1/desk	0.063	0.075	0.051	134	218	153	82.6	72.8	85.1

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表 3 各算法在KITTI数据集上的结果对比

序列	相对平移误差（m）			相对旋转误差（°）			耗时（min）
序列	ORB-SLAM	RatSLAM	本文算法	ORB-SLAM	RatSLAM	本文算法	ORB-SLAM	RatSLAM	本文算法
00	8.31	10.59	5.45	3.24	4.34	2.85	9.73	15.96	10.87
01	10.75	12.37	10.42	3.45	3.67	3.02	2.38	3.53	2.97
02	9.59	12.51	7.21	4.82	5.13	3.65	11.44	17.86	13.15
03	12.24	14.12	12.25	5.95	6.58	6.02	1.75	2.91	2.24
04	4.52	5.34	4.25	2.76	3.67	3.71	0.57	0.91	0.71
05	3.82	4.81	2.65	2.02	3.27	1.58	5.48	10.17	7.87
06	3.21	5.72	1.91	1.72	1.94	1.13	2.42	4.42	3.06

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表 4 主要参数设置

变量名称	参数	数值
运行速度	$ v $	1 m/s
方向变化范围	$ \mathop \theta \nolimits^{} $	[0, 2π]
位置采样点	$ {n_s} $	1000
网格细胞总数	$ \mathop N\nolimits_{} $	260

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