深度学习融合超宽带雷达图谱的跌倒检测研究

何密 平钦文 戴然

何密, 平钦文, 戴然. 深度学习融合超宽带雷达图谱的跌倒检测研究[J]. 雷达学报, 2023, 12(2): 343–355. doi: 10.12000/JR22169
引用本文: 何密, 平钦文, 戴然. 深度学习融合超宽带雷达图谱的跌倒检测研究[J]. 雷达学报, 2023, 12(2): 343–355. doi: 10.12000/JR22169
HE Mi, PING Qinwen, and DAI Ran. Fall detection based on deep learning fusing ultrawideband radar spectrograms[J]. Journal of Radars, 2023, 12(2): 343–355. doi: 10.12000/JR22169
Citation: HE Mi, PING Qinwen, and DAI Ran. Fall detection based on deep learning fusing ultrawideband radar spectrograms[J]. Journal of Radars, 2023, 12(2): 343–355. doi: 10.12000/JR22169

深度学习融合超宽带雷达图谱的跌倒检测研究

DOI: 10.12000/JR22169
基金项目: 陆军军医大学校级课题(2019XYY04),国家部委基金(BLJ18J005)
详细信息
    作者简介:

    何 密,博士,副教授,硕士生导师,主要研究方向为智能生命遥感技术

    平钦文,学士,科研助理,主要研究方向为深度学习应用

    戴 然,硕士生,主要研究方向为雷达跌倒检测技术

    通讯作者:

    何密 hmcherry@126.com

  • 责任主编:金添 Corresponding Editor: JIN Tian
  • 中图分类号: TN957

Fall Detection Based on Deep Learning Fusing Ultrawideband Radar Spectrograms

Funds: Army Medical University-level Project (2019XYY04), The National Ministry Fundation (BLJ18J005)
More Information
  • 摘要: 相对于窄带多普勒雷达,超宽带雷达能够同时获取目标的距离和多普勒信息,更利于行为识别。为了提高跌倒行为的识别性能,该文采用调频连续波超宽带雷达在两个真实的室内复杂场景下采集36名受试者的日常行为和跌倒的回波数据,建立了动作种类丰富的多场景跌倒检测数据集;通过预处理,获取受试者的距离时间谱、距离多普勒谱和时间多普勒谱;基于MobileNet-V3轻量级网络,设计了数据级、特征级和决策级3种雷达图谱深度学习融合网络。统计分析结果表明,该文提出的决策级融合方法相对于仅用单种图谱、数据级和特征级融合的方法,能够提高跌倒检测的性能(显著性检验方法得到的所有P值<0.003)。决策级融合方法的5折交叉验证的准确率为0.9956,在新场景下测试的准确率为0.9778,具有良好的泛化能力。

     

  • 图  1  深度学习融合超宽带雷达图谱检测跌倒的整体研究框图

    Figure  1.  Overall research block diagram of deep learning fusing ultrawideband radar spectrograms for fall detection

    图  2  FMCW雷达发射和接收波形示意图

    Figure  2.  Schematic diagram of transmitting and receiving waveforms of the FMCW radar

    图  3  距离时间矩阵RT的排列示意图

    Figure  3.  Arrangement diagram of range-time matrix RT

    图  4  跌倒和行走的距离时间谱图

    Figure  4.  Range-time spectrograms of fall and walk

    图  5  距离多普勒矩阵RD的排列示意图

    Figure  5.  Arrangement diagram of range-Doppler matrix RD

    图  6  跌倒和行走的距离多普勒谱图

    Figure  6.  Range-Doppler spectrograms of fall and walk

    图  7  跌倒和行走的时间多普勒谱图

    Figure  7.  Time-Doppler spectrograms of fall and walk

    图  8  MobileNet-V3的核心结构

    Figure  8.  Core structure of MobileNet-V3

    图  9  数据级融合网络的结构示意图

    Figure  9.  Structure diagram of data level fusion network

    图  10  特征级融合网络的结构示意图

    Figure  10.  Structure diagram of feature level fusion network

    图  11  决策级融合网络的结构示意图

    Figure  11.  Structure diagram of decision level fusion network

    图  12  K波段UWB雷达跌倒检测系统

    Figure  12.  K band UWB radar fall detection system

    图  13  实测实验设计的日常行为与跌倒部分动作示意图

    Figure  13.  Schematic diagram of daily behaviors and a part of falls designed in the experiment

    图  14  实测实验多场景示意图

    Figure  14.  Multi-scene schematic diagram of the experiment

    图  15  仅用单图谱检测跌倒的5折交叉验证的准确率及交叉熵损失随训练轮数的变化曲线

    Figure  15.  Curves of accuracy and cross entropy loss of 5-fold cross-validation using one kind of spectrograms for fall detection

    图  16  融合方法检测跌倒的5折交叉验证的准确率及交叉熵损失随训练轮数的变化曲线

    Figure  16.  Curves of accuracy and cross entropy loss of 5-fold cross-validation using fusion methods for fall detection

    图  17  用场景2数据测试各种模型时得到的混淆矩阵

    Figure  17.  Confusion matrix obtained when testing various models using data of Scene 2

    1  K波段超宽带雷达跌倒检测图谱数据集-1.0发布网页

    1.  Release webpage of K band UWB radar spectrogram dataset-1.0 for fall detection

    表  1  MobileNet-V3网络和融合网络的大小及耗时对比

    Table  1.   Comparison of size and time consumption of MobileNet-V3 network and fusion networks

    网络类型训练耗时(h)网络大小(MB)测试平均耗时(s)
    MobileNet-V3(距离时间谱)0.28335.90820.0035
    数据级2.35005.90920.0030
    特征级1.544711.90720.0046
    决策级0.850017.72460.1030
    下载: 导出CSV

    表  2  跌倒检测5折交叉验证评价指标对比(场景1)

    Table  2.   Comparison of evaluation indicators for 5-fold cross-validation of fall detection (Scene 1)

    模型AcPrSeSpF1-score
    单种图谱距离时间谱0.99230.98990.98890.99500.9894
    距离多普勒谱0.98220.97120.97560.98560.9734
    时间多普勒谱0.98930.98340.98440.99170.9839
    融合方法数据级融合0.99330.99110.98890.99560.9900
    特征级融合0.98660.97570.98440.98780.9801
    决策级融合0.99560.99330.99330.99670.9933
    下载: 导出CSV

    表  3  不同模型之间跌倒检测性能的对比(场景2)

    Table  3.   Comparison of fall detection performance between different models (Scene 2)

    模型AcPrSeSpF1-score
    单种图谱距离时间谱0.95370.92350.93890.96110.9313
    距离多普勒谱0.91670.85710.90000.92500.8781
    时间多普勒谱0.95190.92310.93330.96110.9282
    融合方法数据级融合0.95740.97010.90000.98610.9337
    特征级融合0.94820.97500.86670.98890.9177
    决策级融合0.97780.98830.94440.99440.9659
    下载: 导出CSV
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出版历程
  • 收稿日期:  2022-08-16
  • 修回日期:  2022-10-05
  • 网络出版日期:  2022-10-16
  • 刊出日期:  2023-04-28

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