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Biomimetics and Dextrous Manipulation Lab

Welcome to the Biomimetics and Dexterous Manipulation Lab! This website is primarily intended as a shared electronic notebook for BDML members. Visitors are welcome to peruse the public pages.                     BDML Twitter, BDML YouTube, Lab News


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Our Project?: Put a sentence or two about your project here.

Adhesion and Applications: Grasping and climbing vertical surfaces with gecko-inspired controllable, directional dry adhesives. Research includes crawling and climbing robots (and people), new adhesives and manufacturing methods, and new applications such as 网站系统维护中,敬请期待!:2021-6-15 · 系统维护公告 尊敬的厦门网网友: 2021年5月20日21时至6月25日12时,海峡社区、海峡博客平台进行系统维护升级,系统将暂停访问,由此给您带来的不便敬请谅解。 and manipulation in space.

Mobile Manipulation

OPPO 手机vnp的服务器地址填加速软件: Research includes underwater hand and grasp analysis and tactile sensing for hands and feet.

Multi-limbed climbing also involves grasping surfaces and manipulating the robot's own body. To be uncommented with these pages are ready Adhesive manipulation is also useful for free-fliers in space and for manufacturing applications.

Medical Robotics

Medical Devices and Robotics: include instrumented tools and manipulators for MRI-guided interventions. Optical fibers with Bragg gratings provide measurement of dynamic forces and temperature. Other robotics work involves measuring forces and tissue slippage in robot-assisted surgery (RAS). Medical device design and modeling includes new compliant devices for the treatment of cardiomyopathy.

Multi-Modal Robots: Bio-inspired robots that can transition between various kinds of locomotion, from jumping to flying to climbing vertical walls using adhesives and microspines. This has grown out of our efforts in both 手机vnp的服务器地址怎么填 and OPPO 手机vnp的服务器地址填加速软件, as well as our OPPO 手机vnp的服务器地址填加速软件 project.

OPPO 手机vnp的服务器地址填加速软件

Automotive Haptics: haptic feedback (skin stretch) implemented in the car to communicate information related to navigation, safety, road conditions, and autonomous functionality. Related to previous work in Wearable Haptics: feedback for altering dynamic motions such as jogging or walking, to reduce the chance of injury or delay the progression of osteoarthritis.

Tunable Spring

Tunable compliance and damping: structures based on electroactive polymer actuators with electrically-tunable stiffness and damping properties for use in dynamic systems. Projects include control of damping through electrical boundary conditions and control of stiffness through design geometry and electrical activation as well as applications to the perching UAV.

Manufacturing and Prototyping: manufacturing and prototyping methods are an important part of what we do for all our other projects. These pages collect information about some of the processes, equipment and materials we work with

大陆手机怎么用ins

Human-safe and human-centered robotics: design tools and methods to mitigate impact damage during unintended human-robot interactions. Projects include collaboration with Prof. Oussama Khatib in the Computer Science Department on the Stanford Safety Robot, incorporation of capacitive skin sensors into robotic platforms for collision detection and post impact behaviors.

Stroke Rehabilitation: We seek to optimize metrics for stroke recovery and understand the effects of proprioceptive deficit and augmentation on motor control. We are currently designing experimentation to characterize the effects of sensory deficits on single-joint motor control and developing unobtrusive wearable devices to augment clinical functional tests and ultimately provide a take-home therapeutic device to improve functional outcomes.

Older projects are described on the Previous BDML Wiki System


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Page last modified on June 24, 2020, at 12:29 PM