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=== Locomotion Rehabilitation After Severe Spinal Cord Injury ===
=== Locomotion Rehabilitation After Severe Spinal Cord Injury ===

Revision as of 01:35, 12 January 2021

The Burdick Group Wiki Home Page
Robotics and Spinal Cord Therapy

Burdick Research Group: Robotics & BioEngineering

  • Our research group pursues both Robotics and BioEngineering related to spinal cord injury. Below you can find summaries of our current research efforts, links to recent papers, and summaries of past research efforts.

Current and Recent Research Topics

DARPA Subterranean Challenge

We are part of Team CoSTAR (lead by NASA/Jet Propulsion Laboratory, with partners MIT, KAIST, LTU), competing in the Subterranean Challenge (www.subtchallenge.com). See the Team's web site for the latest information.


SQUID1CAD.png SQUID2collage.png

SQUID: Self-Quick-Unfolding Investigative Drone

A SQUID drone can be launched in ballistically from a cannon or tube, unfold in mid-flight, and stabilize itself. To the left you can see a diagram of SQUID I and photographs of SQUID 2 in the folded and unfolded states.

Axel and DuAxel Rovers for extreme planetary terrains

Conventional robotic Martian explorers, such as Sojourner, Spirit, and Opportunity, have sufficient mobility to access ~60% of the Martian surface. However, some of the most interesting science targets occur in the currently inaccessible extreme terrains, such as steep craters, overhangs, loose soil, and layered stratigraphy. Access to extreme terrains on other planets (besides Mars) and moons is also of potential interest. In collaboration with JPL, we are developing the Axel and DuAxel rovers. Axel is a minimalist tethered robot that can ascend and descend vertical and steeps slopes, as well as navigate over large (relative to the body size) obstacles. In the DuAxel configuration, two Axels dock with a central module to form a self-contained 4-wheeled rover, which can then disassemble as needed to allow one or both Axels to descend into extreme terrain. The goal of this work is to develop and demonstrate the motion planning, novel mobility mechanisms, mobility analysis, and steep terrain sampling technologies that would allow Axel and DuAxel to be viable concepts for future scientific missions to extreme terrains.



Locomotion Rehabilitation After Severe Spinal Cord Injury

Approximately 250,000 people in the U.S. suffer from a major Spinal Cord Injury (SCI), and ~11,000 new people will be afflicted each year. Our lab collaborates with Prof. Reggie Edgerton at UCLA, Prof. Susan Harkema at Univ. of Louisville, and Prof. Y.C. Tai here at Caltech to develop new therapies and new technologies that hopefully one day will enable patients suffering from SCI to partially or fully recover the ability to walk. Currently, we focus on these topics:

  • Novel high density epidural spinal stimulating electrode arrays for locomotion recovery. For more on

this topic, see this link.

  • New robotic mechanisms for active rehabilitation of SCI in animal (mice and rat) models.
  • New adaptive training algorithms to optimize the rehabilitation afforded by robotic devices.
  • Drug therapies to improve locomotion recovery.

Recent Papers

Planning in Uncertain Environments

Probabilistic Search Strategies, IEEE Trans. Robotics, vol. 28, no.1, Feb. 2012, pp. 132-144.

  • Scott C. Livingston, Richard M. Murray, and Joel W. Burdick, Backtracking

Temporal Logic Synthesis for Uncertain Environments, Proc. IEEE Int. Conf. Robotics and Automation, May 2012, Minneapolis, MN.

Dextrous Manipulation

  • Paul Hebert, Nicolas Hudson, Jeremy Ma, Thomas Howard, Thomas Fuchs, Max Bajracharya, Joel Burdick,

Combined Shape, Appearance, and Silhouette for Simultaneous Manipulator and Object Tracking,Proc. IEEE Int. Conf. Robotics and Automation, May 2012, Minneapolis, MN.

Spinal Cord Injury (SCI) Rehabilitation

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Recent Research Topics

Here are a some recent research topics that were actively pursued in our group.

Human Detection & Tracking Using UWB Radar

While Ultra-Wide-Band (UWB) Radar has existed for decades, it has been more actively investigated in recent years as both an alternative wireless communication technology, as well as a biometric sensor because of its excellent ranging resolution, low power, and sensitivity to human motion. In collaboration with Prof. Hossein Hashimi at USC, we are investigating the use of UWB radar to detect and track human motion for safety and security applications.



Animal Tracking and Activity Recognition

We are interested in developing methods to automatically identify and classify "activities" in data streams, such as video sequences. A practical application and motivation for this work is automated tracking and recognition of biological organism behavior in controlled laboratory environments.

Sensor-Based Motion Planning and Sensor Processing

Sensor Based Planning incorporates sensor information, reflecting the current state of the environment, into a robot\'s planning process, as opposed to classical planning , where full knowledge of the world\'s geometry is assumed to be known prior to the planning event. Current and recent interests of our group include

  • Motion planning in Cluttered, Dynamic, and Uncertain environments
  • Sensor-based motion planning algorithms



Neural Prosthetics and Brain-Machine Interfaces

A neural prosthesis is a direct brain interface that enables a human, via the use of surgically implanted electrode arrays and associated computer decoding algorithms, to control external electromechanical devices by pure thought alone. In this manner, some useful motor functions that have been lost through disease or accident can be partially restored. Our lab collaborates with the laboratories of Prof. Richard Andersen and Prof. Y.C. Tai to develop neural prostheses and brain-machine interfaces. Our group focuses on these particular issues:

  • Autonomously Positioned (robotic) Neural Recording Electrodes. To optimize the quality of

the neural signal recorded by an extracellular electrode, the active recording site must be positioned very close (at least within 30 microns, and preferably a few microns from the soma) to the neural cell body. However, due to blood pressure variations, breathing, and mechanical shocks, the electrode-soma geometry varies significantly over time. We have developed algorithms which allow an actuated electrode to autonomously reposition itself in real time to maintain high quality neural recordings.

  • Neural decoding algorithms. A decoding algorithm attempts to decode, or decipher, the

intent of a paralyzed neural prosthetic user from the recorded electrode signals. Neural decoding has become a well developed subject. We have chosen to explore the concept of a supervisory decoder whose aim is to estimate the current cognitive and planning state of the prosthetic user. E.g., is the user awake? Do they want to use the prosthetic? Are they currently in the planning process? Do they want to execute the plan? Do the want to change or scrub the current prosthetic action? We have chosen to formulate the design of a supervisory decoder as a problem in hybrid system identification.