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Development of a haptic device for implementing dynamic feedback of virtual handshakes

2024-04-01  ~  2024-12-31
PROJECTHandShakingMotion CaptureHuman Motion AnalysisEngineeringEccentric Rotating Mass

Period : 2024-04-01 ~ 2024-12-31

Total Budget : 80,000,000 KRW

Goal of This Project

  • Build a diverse dataset of handshake motions using integrated sensor data.- Design and develop an upper
  • limb exoskeleton robot for delivering dynamic force feedback.
  • Develop communication and power supply systems for implementing various handshake motions.
  • Create a trajectory generation and impedance control algorithm for user-specific handshake motion.
  • Construct an exoskeleton robot system in a virtual environment and develop associated communication technologies.

Importance of the Research

  • Current haptic devices are primarily limited to hand-based applications.Expanding technology to other body parts is essential to enhance immersion and provide diverse user experiences.
  • Haptic devices often provide limited force feedback, restricting their application. Integrating stronger force output in wearable robots is critical.
  • Existing wearable robots mainly focus on rehabilitation or assistance, lacking high responsiveness necessary for advanced haptic applications. s- Heavy weight in both wearable and haptic devices hampers user convenience. Therefore, developing lightweight wearable robots integrated with haptic functionality is imperative.

Research Content and Scope

1. Development of a General Handshake Motion Dataset Using Integrated Sensor Data

  • Classify handshake motion based on trajectory cycles and sizes.
  • Analyze joint loads and torques during handshake motions using a human body simulation tool.

2. Design and Development of an Upper-Limb Exoskeleton Robot for Dynamic Force Feedback

  • Conceptual design based on analyzed joint loads and actuator selection.
  • Detailed design and manufacturing of the upper-limb exoskeleton robot.

3. Development of Communication and Power Supply Systems for Various Handshake Motions

  • Establish communication environment and platform considering wearability.
  • Develop a power supply system for implementing virtual environments.

4. Development of Impedance Control Algorithm for Trajectory Following in Handshakes

  • Implement a trajectory generation algorithm tailored to user-specific handshake angles.
  • Use impedance control to generate customized handshake vibration by following the trajectory.

5. Development of Exoskeleton Robot System and Communication Technologies in Virtual Environments

  • Build a communication environment between Robot Operating System (ROS) and Unity.
  • Enable remote interactions through the implementation of the exoskeleton robot in Unity.

Participating Researchers

Funding