RESEARCH

Overview

We are actively researching anthropomorphic prosthetics and androids, integrating cutting-edge neuroscience, artificial intelligence, and robotics to develop highly responsive, lifelike systems that enhance both human mobility and interaction. Through neuromorphic computing and spiking neural networks, we strive to achieve more natural, intuitive control, ensuring seamless communication between artificial limbs, androids, and biological systems.
Our focus on non-invasive neural interfaces enables prosthetics to adapt dynamically to user intent, enhancing precision, comfort, and fluidity of motion. Meanwhile, our research on advanced sensory processing for androids aims to equip robotic entities with human-like awareness, allowing them to engage in complex tasks, interpret environmental stimuli, and interact intelligently with users. By bridging the gap between biomechanical engineering and AI-driven cognition, we are paving the way for next-generation assistive technologies and autonomous systems that are deeply integrated into daily life. Our work contributes to advancements in rehabilitation, human augmentation, and adaptive robotics, revolutionizing the way artificial systems complement and extend human capabilities.

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