Humanoid Robot Teleoperation Through 3-D Pose Estimation

被引:0
|
作者
Cruz-Silva, Jacobo E. [1 ]
Sivaraman, R. [2 ]
Montiel-Perez, J. Yalja [1 ]
Sossa-Azuela, J. Humberto [1 ]
Lopez-Bonilla, J. [3 ]
机构
[1] Natl Polytech Inst, Comp Res Ctr, Ave Juan De Dios Batiz S-N,Nueva Ind Vallejo, Mexico City 07738, Mexico
[2] Dwaraka Doss Goverdhan Doss Vaishnav Coll, Dept Math, Chennai, India
[3] Natl Polytech Inst, Sime Zacatenco, EDIF 4,1 Piso,Coll Lindavista, Mexico City 07738, Mexico
来源
CONTEMPORARY MATHEMATICS | 2024年 / 5卷 / 03期
关键词
fuzzy control; human body; kinematics; modeling; NAO robot; Roll-Pitch-Yaw; speed profile;
D O I
10.37256/cm.5320243523
中图分类号
O29 [应用数学];
学科分类号
070104 ;
摘要
The knowledge of how the human motions is performed helps to understand how the human body works. This paper presents a method to estimate the human limbs angles through a kinematic model depicted by Roll-PitchYaw rotationmatrix and the mimic of those angles on a humanoid robot. The advantage of this model is the detailed representation of each joint movement in the coordinate axes (x, y, z). The angles estimation is made with the information provided by algorithms of artificial vision and artificial intelligence. In order to reduce the latency between the human motion capture and robot motions, a fuzzy logic controller is implemented in order to control each robot joint. The final robot limbs angles are compared with the human angles in order to obtain the final error between those measurements. This method shows a similar result on the arms posture regarding previous works.
引用
收藏
页码:3886 / 3899
页数:14
相关论文
共 50 条
  • [31] 3-Dimensional pose sensor algorithm for humanoid robot
    Lee, Ah-Lam
    Kim, Jung-Han
    CONTROL ENGINEERING PRACTICE, 2010, 18 (10) : 1173 - 1182
  • [32] A teleoperation system to control the humanoid robot using an RGB-D sensor
    Shelomentcev, E. E.
    Aleksandrova, T. V.
    INTERNATIONAL CONFERENCE ON MECHANICAL ENGINEERING, AUTOMATION AND CONTROL SYSTEMS 2015 (MEACS2015), 2016, 124
  • [33] Constrained, Networked Inertial Navigation for Human and Humanoid Robot Feet Pose Estimation
    Le, Leonardo
    Gebre-Egziabher, Demoz
    PROCEEDINGS OF THE 2016 IEEE/ION POSITION, LOCATION AND NAVIGATION SYMPOSIUM (PLANS), 2016, : 76 - 84
  • [34] Pose estimation and 3-D modeling from video by volume feedback
    Avanaki, AN
    Hamidzadeh, B
    Kossentini, F
    VISUAL COMMUNICATIONS AND IMAGE PROCESSING 2003, PTS 1-3, 2003, 5150 : 1131 - 1142
  • [35] Learning 3-D Human Pose Estimation from Catadioptric Videos
    Liu, Chenchen
    Li, Yongzhi
    Ma, Kangqi
    Zhang, Duo
    Bao, Peijun
    Mu, Yadong
    PROCEEDINGS OF THE THIRTIETH INTERNATIONAL JOINT CONFERENCE ON ARTIFICIAL INTELLIGENCE, IJCAI 2021, 2021, : 852 - 859
  • [36] Real-time yoga pose classification with 3-D pose estimation model with LSTM
    Srivastava, Ratnesh Prasad
    Umrao, Lokendra Singh
    Yadav, Ramjeet Singh
    MULTIMEDIA TOOLS AND APPLICATIONS, 2024, 83 (11) : 33019 - 33030
  • [37] Multiview Video-Based 3-D Hand Pose Estimation
    Khaleghi L.
    Sepas-Moghaddam A.
    Marshall J.
    Etemad A.
    IEEE Transactions on Artificial Intelligence, 2023, 4 (04): : 896 - 909
  • [38] Object pose estimation for robotic control with 3-D range data
    Li, ST
    Zhao, DM
    MACHINE VISION AND THREE-DIMENSIONAL IMAGING SYSTEMS FOR INSPECTION AND METROLOGY, 2001, 4189 : 179 - 190
  • [39] Real-time yoga pose classification with 3-D pose estimation model with LSTM
    Ratnesh Prasad Srivastava
    Lokendra Singh Umrao
    Ramjeet Singh Yadav
    Multimedia Tools and Applications, 2024, 83 : 33019 - 33030
  • [40] Panoramic View Reconstruction for Stereoscopic Teleoperation of a Humanoid Robot
    Theofilis, Konstantinos
    Orlosky, Jason
    Nagai, Yukie
    Kiyokawa, Kiyoshi
    2016 IEEE-RAS 16TH INTERNATIONAL CONFERENCE ON HUMANOID ROBOTS (HUMANOIDS), 2016, : 242 - 248
12345