Image 1 - The humanoid robot Rollin' Justin is a platform for research in service robotics. Applications for the system are, in particular, household work and assisting astronauts in space.

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Rollin' Justin

company logo for DLR DLR

Country: Germany

Year: 2008

Summary

The humanoid robot Rollin' Justin is a platform for research in service robotics. Applications for the system are, in particular, household work and assisting astronauts in space.

Status: Prototype, Research

Operation: Autonomous, Semi-autonomous, Teleoperation

Robot Type / Domain: Research, Service, Other, Space

Tasks: household work, assisting astronauts in space, service

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The humanoid robot Rollin' Justin is a platform for research in service robotics. Areas of application for the system are, in particular, household work and assisting astronauts in space.
The robot was first presented to the public in 2008.

System description

Rollin' Justin’s compliant light-weight arms and four-finger hands make it an ideal platform for research into sensitive, ambidextrous manipulation. The mobile base allows autonomous operation over a long range. Motion detection sensors and stereo cameras enable 3D reconstruction of the robot’s environment. Unstructured, variable and dynamic environments require the robot to act independently and without human support. On the other hand, the robot must be able to work safely with people. Its multiple actuated degrees of freedom allow Rollin' Justin to pursue several goals at the same time while complying with a task hierarchy. For example, the robot can serve beverages while observing the environment, moving without singularity, avoiding collisions, compliantly responding to collisions with the environment – all without spilling the drinks.

Mechatronic Design

The system design uses preliminary works of the institute, namely the DLR Light Weight Robot III (LWR III) and the DLR Hand II. The torso based on LWR technology and the mobile platform enlarge the workspace of the arms and hands. The overall design resembles a human-like shape.

Mobile Manipulation

Many houseworks require to manipulate tools over wide areas. The most relevant example for such a task is cleaning, where a cleaning device needs to be guided along a dirty surface. Reasoning about an appropriate parameterization of the task is thereby essential.

Compliant Whole-Body Manipulation

Reactive, multi-objective mobile manipulation on Rollin' Justin is realized by imposing a task hierarchy via null space projections. Higher priority tasks are executed while lower priority tasks are only accomplished if enough kinematic redundancy is left.

Autonomous Task Planning and Execution

Solving arbitrary manipulation tasks is a key feature for humanoid service robots. Different objects require different handling methods. Therefore, a modular system architecture has been developed to autonomously solve manipulation tasks from the object point of view.

Technical Specifications

Max. Size: 1.91H (mm)

Max. Size: 0.075H (in)

Max. Payload: 20 kg (per arm)

Max. Payload: 44.092 lbs (per arm)

Weight: 200 kg

Weight: 440.925 lbs

Max. Locomotion Speed: 2 m/s

Max. Locomotion Speed: 6.562 ft/s

Max. Slope: N/A

Battery Operated? Yes

Average Runtime: 1 hr(s)

Max. Runtime: N/A

Battery Recharge Time: N/A

Locomotion Type: Wheels/Tracks

DOFs per Arm: 7

DOFs per Leg: N/A

DOFs (total): 51

IP Rating: N/A

Operating Temperature: N/A

Open-source? N/A

Price: N/A

Show more specs

Working space: From the floor to a height of 2.7 m

Degrees of freedom: 51 (platform: 8, arms: 2 × 7, hands: 2 × 12, neck: 2, torso: 3)

Special features: • Compliant, hierarchical whole-body control • Semi-autonomy for terrestrial and extraterrestrial applications

Sensors: • Torque sensors in nearly all joints • 2 balance sensors (IMU) • 2 stereo cameras, 5 RGB-D cameras

No more specs to show.

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References

Publications

You can find a complete list of all publications associated with Rollin' Justin on our Publications Page. A selection of recent publications:

Schmaus et al., “Knowledge Driven Orbit-to-Ground Teleoperation of a Robot Coworker”, IEEE Robotics and Automation Letters, 5 (1), Seiten 143-150. IEEE - Institute of Electrical and Electronics Engineers. DOI: 10.1109/LRA.2019.2948128 ISSN 2377-3766, 2020.
Bauer et al., “Probabilistic Effect Prediction through Semantic Augmentation and Physical Simulation”, In: IEEE International Conference on Robotics and Automation ICRA, Seiten 9278-9284. IEEE International Conference on Robotics and Automation (ICRA), 31. May - 31. Aug 2020, Paris, France. DOI: 10.1109/ICRA40945.2020.9197477, 2020.
Vogel et al., "An Ecosystem for Heterogeneous Robotic Assistants in Caregiving", accepted for publication in IEEE Robotics and Automation Magazine (RAM), 2020.
Sewtz et al., “Robust MUSIC-Based Sound Source Localization in Reverberant and Echoic Environments”, In: 2020 IEEE International Conference on Intelligent Robots and Systems. IEEE/RSJ International Conference on Robots and Systems IROS, Las Vegas, USA, 2020.
Leidner, “Cognitive Reasoning for Compliant Robot Manipulation”, Springer Tracts in Advanced Robotics, 127. Springer. ISBN 978-3-030-04857-0. ISSN 1610-7438, 2019.
Lii et al., „The Robot as an Avatar or Co-worker? An Investigation of the Different Teleoperation Modalities through the KONTUR-2 and METERON SUPVIS Justin Space Telerobotic Missions”, In: Proceedings of the International Astronautical Congress, IAC. 69th International Astronautical Congress (IAC), Bremen, Germany, 1-5 Oct 2018, Bremen, Germany, 2018.

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