Please login to create your UC TechAlerts.
Request a new password for
Required
Find technologies available for licensing from all ten University of California (UC) campuses.
No technologies match these criteria. Schedule UC TechAlerts to receive an email when technologies are published that match this search. Click on the Save Search link above
A Novel Lockable Spring-Loaded Prismatic Spine To Support Agile Quadrupedal Locomotion
Brief description not available
Adaptive Lidar Odometry And Mapping For Precision Agriculture
A Portable Agricultural Robot For Continuous Apparent Soil Electrical Conductivity Measurements
Robotic Leaf Detection And Extraction System
Soft Bodied Hexapedal Robot
Prof. Konstantinos Karydis’ lab at the University of California, Riverside has developed a soft hexapedal robot (SoRx) that may serve as a new tool to applications where operation over rough and/or unstructured terrain is required. For example when looking for survivors in the aftermath of an earthquake this soft legged robot may be easily deployed. Operation in such terrains still challenges more rigid legged robots; instead, soft legged robots could squeeze and bend to overcome obstacles and fit into crevices to explore their environment. Other uses of SoRX may include educational and recreational applications. Fig 1: shows that SoRX maintains stable locomotion on an unstable platform that is oscillating in the X-Y plane at speeds comparable to the robot’s forward speed,
Drone Collision Recovery System
Prof. Konstantinos Karydis’ lab at the University of California, Riverside has developed a new active resilient quadrotor (ARQ), which incorporates passive springs within its frame to absorb shocks and survive collisions. Each arm of the quadrotor is equipped with sensors to accurately and rapidly detect the location (in the drone’s frame) and intensity of a collision. In addition, a recovery controller that enables the drone to sustain flight after collision with objects like wall, poles, or moving objects. The technology has been proven on the quadrotor however it may be applied to drones with more than four arms. Fig 1: Instances of the novel ARQ drone detecting and recovering from colllisions in (a) and (b) and from collision with a wall (c) and (d). Fig 2: shows ARQ detecting and recovering from a passive collision. (a) ARQ hovers. (b) Collision starts and the ARQ arm absorbs the shock. (c) recovery control starts and there is a body interfering with the ARQ’s flight path. (d) ARQ is stabilized and hovering again.