Advanced Robotics Components

THE TECHNOLOGY BEHIND ATHLETE ROBOT WITH KING-FU SKILLS. 1. The robot is powered by advanced AI algorithms to learn and replicate martial arts techniques. 2. Its sensors detect and react to movements in real time, simulating a human opponent. 3. High-precision motors control the robot’s limbs, allowing swift, powerful strikes. 4. The robot's balance system uses gyroscopic technology to maintain perfect stance and form. 5. Its neural networks allow the robot to adapt and refine techniques through continuous practice. 6. The robot’s material construction includes lightweight alloys for speed and durability. 7. Advanced vision systems enable the robot to track and anticipate opponents' moves. 8. It utilizes machine learning to analyze martial arts videos, improving its own fighting style. 9. Force sensors in the limbs allow the robot to calculate the strength of its punches. 10. The robot’s movements are made highly fluid, mimicking human athletic grace. 11. It is equipped with a dynamic reflex system, responding instantly to threats. 12. A cutting-edge exoskeleton provides enhanced joint flexibility, aiding in kung-fu acrobatics. 13. The robot’s control system enables precise execution of complex combinations of strikes. 14. The AI system enables it to compete in martial arts tournaments against humans. 15. Real-time data processing ensures quick decision-making during high-speed action. 16. The robot’s endurance is tested through continuous combat simulations to build stamina. 17. It can perform acrobatic feats, such as flips and high kicks, with remarkable agility. 18. The robot’s internal hydraulics enable powerful and precise striking abilities. 19. It can learn new martial arts techniques by analyzing opponent strategies. 20. The robot is used to demonstrate the potential of AI in athletic performance and training.

In the robotic palm, both the coreless gear motor and the magnet play crucial roles. Here is an introduction to their applications: • Application of coreless gear motors: The coreless gear motor is a core driving component of the robotic palm. It features high torque, high responsiveness, high reliability, high efficiency, and low temperature rise. For example, the coreless motors from Leadshine have achieved higher torque and response speed through optimized electromagnetic schemes and winding technologies. They also adopt high-reliability components and have a long brushless service life, enabling the robotic palm to be more "dexterous" and "powerful". Additionally, they can reduce the burden on the battery and improve endurance. Moreover, the coreless motors from Dingzhi Technology, with characteristics of high efficiency, high rotation speed, and small size, perfectly meet the requirements of "small size and large torque" for the finger joints of humanoid robots. • Application of magnets: Magnets are an important part of the coreless motor, usually located on the rotor, mostly in arc or tile structures attached to the rotor. They are generally made of rare-earth permanent magnet materials such as neodymium-iron-boron and samarium-cobalt, which have high magnetization intensity and good magnetic properties. The magnetic field generated by the magnets interacts with the magnetic field generated by the current in the stator windings, thereby generating torque to drive the motor to rotate. In the robotic palm, the magnets adapted to the coreless motor need to be precision-machined to be embedded in limited space in an ultra-thin and miniaturized form, while ensuring uniform and stable magnetic force. Only in this way can they cooperate with the motor to achieve micron-level precise motion control.

NASA SBIR Ignite Funding Opportunity: #Robotics Subtopic I finally went and downloaded the topic pre-release, and I am thrilled to share that there is an NASA - National Aeronautics and Space Administration #SBIR ignite robotics subtopic this year! https://lnkd.in/gq_rQveg Subtopic I04.01: Modular, scalable robotic subcomponents to unlock scalable robotic manufacturing & assembly in remote, challenging environments One of the key challenges in robotics today is the lack of standard, modular subcomponents that enable robotics to scale (actuators, motors, tools, end-effectors, beams/tubes for arms, wheels, etc). To reduce the cost of robotics for manufacturing and assembly, NASA needs basic robotic components with standardized mechanical and/or electrical interfaces that are qualified for use on orbit as well as lunar and planetary environments. The components should have the following characteristics: • Reconfigurable with non-proprietary, standardized interfaces • Allows the use of custom components designed by the end user • Designed for use in remote or challenging environments • Optimized for cost-effective mass production • Ability to be quickly scaled NASA is especially interested in solutions that balance readiness for eventual space deployment with near-term manufacturability and commercial viability. While full qualification is not required at this stage, a plan for space environment compatibility and scalability will strengthen the proposal (such as exposure to dust, vacuum (lubricants especially), radiation, UV, thermal, gravity, atomic oxygen, etc). Additionally, component approaches that demonstrate a clear path towards a complete robotic system-level solution are preferred. Considerations: • Solutions designed to be robotically assembled are encouraged. • Solutions at a scale appropriate for small-sat or orbital/surface asset aggregation applications are of particular interest. • Robot architecture is non-specific (inchworm/climbing robots, rover-based systems, free-fliers or other) • Adapting and qualifying existing robotic elements and systems for NASA applications is encouraged. Existing hardware could be upgraded to take the key elements of the design and add the components to survive challenging environments. • Examples of desired improvements in capabilities: • protection from dust and/or resilience to dust getting into moving components including dust repellant technologies and coatings • solutions capable of a range of torques • optimized lubricants for wide temperature ranges and minimal mass loss and outgassing in vacuum • solutions that use lower cost metals in order to reduce overall cost • tough, conductive thermal coatings and treatments that can resist erosion or surface damage