We began at the interface of biology and engineering—developing advanced prosthetics that restored motion, strength, and autonomy to human beings. But our journey didn’t stop at restoration. It evolved into reinvention.

Today, our biomedical foundation drives breakthroughs in full-scale robotics: from intelligent manipulators to autonomous subsystems. We understand the body—so we know how to build machines that move like bodies. And more importantly, how to control them.

Humanoid robots represent one of the greatest challenges in modern robotics: machines that must move with human-like coordination, adapt to human environments, and operate with minimal oversight.

We build humanoid systems from the ground up—mechanically, electronically, and algorithmically. Our robots aim to walk, grasp, balance, and interact in complex environments with lifelike dexterity and precision.

Whether it's a bipedal system navigating dynamic terrain or a robotic hand replicating fine motor skills, every motion is informed by anatomy and guided by advanced control systems.

Humanoid robotics is not imitation. It’s collaboration—refined.

Our prosthetic systems are designed not just to replace what's been lost—but to surpass it. With bioadaptive control, responsive actuation, and sensor-driven feedback loops, our devices offer a fluid, almost subconscious interface between the human nervous system and the robotic limb.

We build systems that learn from the user’s motion, muscle signals, and intent—creating a personal, adaptive partnership between user and machine.

Whether it’s a shoulder-disarticulation prosthesis or a myoelectric hand, every device is built to restore freedom, not just function.

Where control becomes instinctive—and technology becomes invisible.

Our research in haptics closes the final gap between humans and machines: the ability to feel.

Through advanced tactile sensors, force feedback, and neurosensory interfaces, we bring texture, resistance, and pressure back into the loop—whether for prosthetic users or remote robotic operators.

From wearable haptic skins to real-time feedback for manipulators, we give machines a sense of touch—and users a sense of presence.

Real control starts with real sensation.

Control is the quiet engine behind every robotic success—and the steepest cliff in humanoid design. When you move beyond simple kinematics into systems with dozens of degrees of freedom, traditional control theory breaks down. That’s where we come in.

Our control architecture blends model-based planning, learning algorithms, real-time optimization, and intent prediction. Whether it’s interpreting EMG signals for prosthetics, or full-body planning for humanoid locomotion, our systems are built to understand complexity—and act with confidence.

True control isn’t about removing the human. It’s about amplifying them.

Every one of our systems is designed to operate in partnership with a human operator—reading cues, adapting to goals, and minimizing the friction between decision and execution. We treat robotics as a cooperative intelligence problem—not just an automation problem.

From intuitive prosthetic control to multi-modal human-robot interfaces, we believe the future isn’t robots working for humans. It’s robots working with humans.

Intelligence, amplified. Collaboration, redesigned.