Gait-based human recognition based on millimetre wave multiple input multiple output radar point cloud constructed using velocity-depth-time

IF 1.4 4区 管理学 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Iet Radar Sonar and Navigation Pub Date : 2024-05-27 DOI:10.1049/rsn2.12577
Xianxian He, Yunhua Zhang, Xiao Dong
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Abstract

Gait recognition is to recognise different individuals based on their faint differences of gait characteristics, which is different from and more challengeable than the recognition of human activities based on relatively bigger differences between different motions. Existing millimetre-wave Multiple Input Multiple Output radar point cloud data contains time-varying three-dimensional spatial positions, velocity, and intensity information. How to enhance the accuracy of gait recognition by effectively utilising the available radar point cloud data has become an attractive research topic in recent years. A velocity-depth-time (VDT) based point cloud construction method for millimetre-wave Multiple Input Multiple Output radar is proposed for gait recognition application, which can not only alleviate the sparsity problem of mmWave point cloud but also make the constructed point cloud to exhibit temporal structural features of micro-motions, and therefore enable the successful application of PointNet++ to mmWave-MIMO point cloud gait recognition. New point clouds are constructed by the proposed method using public gait recognition datasets of 10 and 20 individuals from mmWave-MIMO radar, which are used to conduct gait recognition experiments using PointNet++. The results show that the point clouds constructed based on VDT are more conducive to the gait recognition task. Even using the classic PointNet++ model, which is not specially designed for radar point clouds, high recognition accuracy can be achieved for gait recognition tasks. The recognition accuracies are improved by 11% and 12% in this work for datasets of 10 and 20 individuals, respectively, compared with the 84% and 80% achieved by the traditional method using the same dataset and the same PointNet++ model, while the accuracies are improved by 5% and 12%, respectively, compared with the 90% and 80% achieved by the original dataset thesis method corresponding to 10-individual and 20-individual datasets.

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利用速度-深度-时间构建的毫米波多输入多输出雷达点云进行基于步态的人体识别
步态识别是根据步态特征的微弱差异来识别不同的个体,这与根据不同运动之间相对较大的差异来识别人类活动不同,也更具挑战性。现有的毫米波多输入多输出雷达点云数据包含时变的三维空间位置、速度和强度信息。如何有效利用现有的雷达点云数据来提高步态识别的准确性,已成为近年来颇具吸引力的研究课题。针对步态识别应用,提出了一种基于速度-深度-时间(VDT)的毫米波多输入多输出雷达点云构建方法,不仅能缓解毫米波点云的稀疏性问题,还能使构建的点云表现出微运动的时间结构特征,从而使 PointNet++ 成功应用于毫米波-MIMO 点云步态识别。本文利用 mmWave-MIMO 雷达的 10 人和 20 人公开步态识别数据集构建了新的点云,并使用 PointNet++ 进行了步态识别实验。结果表明,基于 VDT 构建的点云更有利于步态识别任务。即使使用并非专门为雷达点云设计的经典 PointNet++ 模型,步态识别任务也能达到很高的识别精度。与使用相同数据集和相同 PointNet++ 模型的传统方法所取得的 84% 和 80% 的识别率相比,本研究中 10 个个体和 20 个个体数据集的识别率分别提高了 11% 和 12%,而与对应 10 个个体和 20 个个体数据集的原始数据集论文方法所取得的 90% 和 80% 的识别率相比,本研究中的识别率分别提高了 5% 和 12%。
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来源期刊
Iet Radar Sonar and Navigation
Iet Radar Sonar and Navigation 工程技术-电信学
CiteScore
4.10
自引率
11.80%
发文量
137
审稿时长
3.4 months
期刊介绍: IET Radar, Sonar & Navigation covers the theory and practice of systems and signals for radar, sonar, radiolocation, navigation, and surveillance purposes, in aerospace and terrestrial applications. Examples include advances in waveform design, clutter and detection, electronic warfare, adaptive array and superresolution methods, tracking algorithms, synthetic aperture, and target recognition techniques.
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