A six-degree-of-freedom platform (also known as a six-degree-of-freedom parallel robot or motion
platform) simulates complex spatial motion using six independent degrees of freedom (X/Y/Z translation
and pitch/roll/yaw rotation). Its core application areas include:
1. Industry and Manufacturing
Precision Positioning: Used for micron-level high-precision machining, optical equipment calibration, and
semiconductor manufacturing.
Automated Testing: Simulates the dynamic performance and durability of components such as automo
tive suspensions and tires.
Robotics: Serves as the foundation for industrial robots, enabling research into motion control and
perception technologies.
2. Simulation Training
Driving Simulation: Dynamically simulates the cockpits of cars, trains, tanks, and other vehicles to impro
ve operator skills.
Flight/Ship Simulation: Recreates scenarios such as aircraft attitudes and ship turbulence for pilot and
crew training.
3. Scientific Research and Healthcare
Scientific Research Experiments: Material mechanics testing, earthquake simulation, and biomedical
research.
Medical Rehabilitation: Surgical simulation training and patient rehabilitation exercise assistance.
4. Entertainment and Consumption
Dynamic Experience: Racing games, roller coaster simulations, and cinematic special effects seats.
Virtual Reality: Integrating somatosensory devices to enhance the immersive interactive experience.
5. Aerospace and Military
Space Docking: Simulating high-precision docking missions for spacecraft and aerial refueling tankers.
Military Training: Combat simulations of fighter jets, submarines, and other equipment.
6. Stability and Vibration Isolation
Precision Equipment Protection: Isolating electron microscopes and IC manufacturing equipment from
environmental vibrations.
This technology relies on the coordinated control of six actuators, using mathematical models to calcula
te spatial trajectories and drive the platform to achieve the target motion.
