Mission
To revolutionize prosthetic technology by integrating biomechanics, artificial intelligence, and user-centered design. We want to improve everyday life for amputees and ensure everyone can take a confident step forward.
Purpose
To research and develop prosthetic technologies with a focus on improving self-stabilization for lower-limb amputees. By pushing the limits of artificial intelligence technology, we strive to make prosthetics more adaptive and efficient.
Vision
TAK Robotics strives to create a world where every amputee has access to functional, quality prosthetics, transforming the standard of care and redefining the future of human movement.
About Prosthetics
Why They Matter:
A lower limb prosthetic is an artificial device designed to replace a missing leg or foot, often due to injury, illness, or congenital conditions. Though not everyone with these conditions needs a prosthetic, the right device can empower users and improve quality of life by:
-
Restoring basic mobility and balance
-
Enabling greater independence and self-sufficiency
-
Allowing for participation in daily activities
-
Reducing the risk of falls, strain, and secondary injuries
How They Fall Short
​While prosthetics are the standard solution for amputees, there is still significant room for improvement. Many prosthetics, especially standard designs, struggle with:
-
Limited adaptability to real-world terrain or user fatigue
-
Discomfort and pain resulting from long-term wear
-
Poor balance and instability, especially on uneven surfaces
-
Accounting for individual gait patterns. Customized designs can cost thousands and limit accessibility.
TAK's Role
Powered by Unity’s Machine Learning Algorithm, TAKA (the TAK Algorithm) continuously calibrates limb response based on its activity and environment. With this technology, it can:
-
Adjust in real time to walking speed, terrain, and user fatigue
-
Stabilize the user when standing, walking, or recovering from an imbalance
-
Learn and adapt to each user’s unique gait and movement pattern
-
Mimic human biomechanics for more fluid and intuitive movement
-
Adjusts pressure distribution and joint angles to reduce strain
