Your search keyword '"Bergner, Florian"' showing total 2 results

1. Tactile‐Based Negotiation of Unknown Objects during Navigation in Unstructured Environments with Movable Obstacles.

Author

Armleder, Simon, Dean‐Leon, Emmanuel, Bergner, Florian, Guadarrama Olvera, Julio Rogelio, and Cheng, Gordon

Abstract

Traditional robot navigation passively plans/replans to avoid any contact with obstacles in the scene. This limits the obtained solutions to the collision‐free space and leads to failures if the path to the goal is obstructed. In contrast, humans actively modify their environment by repositioning objects if it assists locomotion. This article aims to bring robots closer to such abilities by providing a framework to detect and clear movable obstacles to continue navigation. The approach leverages a multimodal robot skin that provides both local proximity and tactile feedback regarding physical interactions with the surroundings. This multimodal contact feedback is employed to adapt the robot's behavior when interacting with object surfaces and regulating applied forces. This enables the robot to remove bulky obstacles from its path and solves otherwise infeasible navigation problems. The system's ability is demonstrated in simulation and real‐world scenarios involving movable and nonmovable obstacles. [ABSTRACT FROM AUTHOR]

Published

2024

2. Design and Realization of an Efficient Large-Area Event-Driven E-Skin

Author

Bergner, Florian, Dean-Leon, Emmanuel, and Cheng, Gordon

Subjects

Wearable Electronic Devices, Computers, Touch, event-driven systems, send-on-delta principle, Humans, lcsh:TP1-1185, Robotics, lcsh:Chemical technology, large-area skin systems, Article, tactile sensing, e-skin

Abstract

The sense of touch enables us to safely interact and control our contacts with our surroundings. Many technical systems and applications could profit from a similar type of sense. Yet, despite the emergence of e-skin systems covering more extensive areas, large-area realizations of e-skin effectively boosting applications are still rare. Recent advancements have improved the deployability and robustness of e-skin systems laying the basis for their scalability. However, the upscaling of e-skin systems introduces yet another challenge&mdash, the challenge of handling a large amount of heterogeneous tactile information with complex spatial relations between sensing points. We targeted this challenge and proposed an event-driven approach for large-area skin systems. While our previous works focused on the implementation and the experimental validation of the approach, this work now provides the consolidated foundations for realizing, designing, and understanding large-area event-driven e-skin systems for effective applications. This work homogenizes the different perspectives on event-driven systems and assesses the applicability of existing event-driven implementations in large-area skin systems. Additionally, we provide novel guidelines for tuning the novelty-threshold of event generators. Overall, this work develops a systematic approach towards realizing a flexible event-driven information handling system on standard computer systems for large-scale e-skin with detailed descriptions on the effective design of event generators and decoders. All designs and guidelines are validated by outlining their impacts on our implementations, and by consolidating various experimental results. The resulting system design for e-skin systems is scalable, efficient, flexible, and capable of handling large amounts of information without customized hardware. The system provides the feasibility of complex large-area tactile applications, for instance in robotics.

Published

2020