Samuel Rader scite author profile

major goal of humanoid robotics is to enable safe and reliable human-robot collaboration in realworld scenarios. In this article, we present ARMAR-6, a new high-performance humanoid robot for various tasks, including but not limited to grasping, mobile manipulation, integrated perception, bimanual collaboration, compliant-motion execution, and natural language understanding. We describe how the requirements arising from these tasks influenced our major design decisions, resulting in vertical integration during the joint hardware and software development phases. In particular, the entire hardware-including its structure, sensor-actuator units, and low-level controllers-as well as its perception, grasping and manipulation skills, task coordination, and the entire software architecture were all developed by one team of engineers. Component interaction is facilitated by our software framework ArmarX, which

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ARMAR-6: A Collaborative Humanoid Robot for Industrial Environments

Asfour

Kaul

Wächter

et al. 2018

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Design of a high-performance humanoid dual arm system with inner shoulder joints

Rader

Kaul

Fischbach

et al. 2016

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Highly integrated sensor-actuator-controller units for modular robot design

Rader

Kaul

Weiner

et al. 2017

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Designing Prosthetic Hands With Embodied Intelligence: The KIT Prosthetic Hands

et al. 2022

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Hand prostheses should provide functional replacements of lost hands. Yet current prosthetic hands often are not intuitive to control and easy to use by amputees. Commercially available prostheses are usually controlled based on EMG signals triggered by the user to perform grasping tasks. Such EMG-based control requires long training and depends heavily on the robustness of the EMG signals. Our goal is to develop prosthetic hands with semi-autonomous grasping abilities that lead to more intuitive control by the user. In this paper, we present the development of prosthetic hands that enable such abilities as first results toward this goal. The developed prostheses provide intelligent mechatronics including adaptive actuation, multi-modal sensing and on-board computing resources to enable autonomous and intuitive control. The hands are scalable in size and based on an underactuated mechanism which allows the adaptation of grasps to the shape of arbitrary objects. They integrate a multi-modal sensor system including a camera and in the newest version a distance sensor and IMU. A resource-aware embedded system for in-hand processing of sensory data and control is included in the palm of each hand. We describe the design of the new version of the hands, the female hand prosthesis with a weight of 377 g, a grasping force of 40.5 N and closing time of 0.73 s. We evaluate the mechatronics of the hand, its grasping abilities based on the YCB Gripper Assessment Protocol as well as a task-oriented protocol for assessing the hand performance in activities of daily living. Further, we exemplarily show the suitability of the multi-modal sensor system for sensory-based, semi-autonomous grasping in daily life activities. The evaluation demonstrates the merit of the hand concept, its sensor and in-hand computing systems.

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Samuel Rader

ARMAR-6: A High-Performance Humanoid for Human-Robot Collaboration in Real-World Scenarios

ARMAR-6: A Collaborative Humanoid Robot for Industrial Environments

Design of a high-performance humanoid dual arm system with inner shoulder joints

Highly integrated sensor-actuator-controller units for modular robot design

Designing Prosthetic Hands With Embodied Intelligence: The KIT Prosthetic Hands

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