Researchers at Stanford University have developed a multilayered immiscible polymer system that can autonomously realign its layers to facilitate the healing process following damage.
Stanford inventors have created an audio-visual system with a radiotransparent screen provides a means for communication and visual distractions during procedures such as radiation therapy and radiation imaging.
Remotely operated robotic devices are becoming increasingly important in fields such as medicine, space and field research. However, their widespread application is hampered by distance between the robot and its operator which results in communication delays.
Researchers in the Stanford Robotics Lab have developed a dynamically adaptive workspace mapping control method that adjusts remote task resolution to keep haptic-robot (in real-world applications) or haptic-avatar (in virtual environment) interactions within the device works
Researchers in the Stanford Robotics Lab have developed a compact high-fidelity haptic teleoperation system which shows accurate and isotropic behavior in translation and rotation.
Stanford researchers have developed a technique to interpret contact events between a human and a device equipped with a force sensor. It can detect and classify distinct touch interactions such as tap, touch, grab, and slip.
Stanford researchers at the Okamura Lab have prototyped a new retraction device that can reverse growth of a soft growing robot without undesired buckling.
Stanford engineers at Zhenan Bao's laboratory have designed a compliance sensor which can identify softness (compliance) of touched objects and provide human-like sensation to robots and prosthetics.
Researchers in Dr. Cutkosky's laboratory have developed a gripper device that allows industrial robots to handle very soft or delicate objects. Effective handling of delicate objects remains a challenging problem in manufacturing.
Stanford researchers in the Biomimetics and Dexterous Manipulation Lab have patented a low cost, high performance multi-axis capacitive tactile sensor that measures all six components of force and torque.
Engineers in Prof. Mark Cutkosky's laboratory have developed patented electrostrictive elements that can support high loads over a long lifetime when used as variable suspension systems for robots, autonomous vehicles or prosthetics.
Researchers in Prof. Allison Okamura's laboratory have patented a small, simple tactile display that can automatically control both its surface geometry and its mechanical properties.
Stanford researchers at the Bao Lab have designed and fabricated a highly stretchable, tough, and self-healable material with high fatigue resistance applicable for electronic (e-) skin devices.
Researchers in Professor Zhenan Bao's group at Stanford University have developed capacitive tactile sensors used to detect static and dynamic forces with varying magnitudes and directions.