About

The Intelligent Motion Lab studies planning and control for dynamic, high-dimensional systems in complex environments. Applications include intelligent vehicles, robot manipulation, legged locomotion, human-robot interaction, robot- and computer-assisted medicine.

IML is directed by Prof. Kris Hauser and is part of the Duke University Pratt School of Engineering.

Openings

IML is currently accepting applications for new PhD students. Candidates should contact Kris Hauser for more information.

Research Spotlight

First tele-nursing experiments with TRINA 1.0

Selected Projects

Tele-nursing robots

Summary (click to show)
Our lab is developing the Tele-Robotic Intelligent Nursing Assistant (TRINA), a remote-controlled robot to perform common nursing duties inside hazardous clinical areas, which could reduce infection risk to healthcare workers by minimizing exposure to contagions and other biohazards. They could also reduce infection risk to immunocompromise patients. Apart from the engineering challenge, we are addressing scientific questions regarding human-robot interfaces, haptics, and semi-autonomous control and planning algorithms.
tele-nursing, assisted teleoperation, real-time planning, human-robot interaction
NSF RAPID, NSF CAREER

Cooperative motion planning for human-operated robots

Summary (click to show)
This project explores the hypothesis that advances in robot motion planning algorithms will lead to improved intuitiveness, safety, and task performance of human-centered robots such as intelligent vehicles, tele-surgery systems, search-and-rescue robots, and household robots. Existing planning techniques lead to awkward and unintuitive interaction with humans. To bridge this gap, we are developing cooperative motion planning algorithms that reason about users' intended goals and then take control of a robot's low level motion to achieve those goals.
NSF CAREER, IU Faculty Research Support Program

DRC-Hubo: a ladder-climbing humanoid robot for the DARPA Robotics Challenge

Summary (click to show)
As part of the 2013 DARPA Robotics Challenge, we are developing ladder- and stair- climbing skills for humanoid robots that may be used in disaster relief and industrial maintenance scenarios. Such tasks are challenging because they require upper-body strength, multi-limbed balance coordination, and fine motions for obstacle avoidance. We developed planners that can carefully deliberate about the robot's physical capabilities, and applied them planner-aided design to establish specifications for a new robot, DRC-Hubo. Using our software, DRC-Hubo is able to autonomously mount, climb, and dismount stairs and ladders. This project is conducted as part of Team HUBO, a multi-university team led by Drexel University.
DARPA Robotics Challenge (Track A)

Intelligent clinical decision support using Markov decision processes

Summary (click to show)
The explosion in the amount of medical data available in Electronic Health Records (EHRs) provides an opportunity for computers to aid clinicians in providing effective, affordable healthcare. We are investigating Markov Decision Process techniques that are able to recommend patient-specific treatment plans in the presence of noisy and incomplete observations. Like a real doctor, the system is able to reason in the space of belief states, integrating uncertainties and contingencies into its plans. Results on a 5,807 patient dataset involving clinical depression as well as co-occuring conditions suggest that the decisions made by an AI system can improve patient outcomes from 30-35% while reducing costs by 50-55%.
NSF Smart and Connected Health Program

For a complete list, please see the research page.