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17 results on '"Bergner, Florian"'

1. Tactile Hallucinations on Artificial Skin Induced by Homeostasis in a Deep Boltzmann Machine

Author

Deistler, Michael, Yener, Yagmur, Bergner, Florian, Lanillos, Pablo, and Cheng, Gordon

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Machine Learning, Quantitative Biology - Neurons and Cognition
Abstract

Perceptual hallucinations are present in neurological and psychiatric disorders and amputees. While the hallucinations can be drug-induced, it has been described that they can even be provoked in healthy subjects. Understanding their manifestation could thus unveil how the brain processes sensory information and might evidence the generative nature of perception. In this work, we investigate the generation of tactile hallucinations on biologically inspired, artificial skin. To model tactile hallucinations, we apply homeostasis, a change in the excitability of neurons during sensory deprivation, in a Deep Boltzmann Machine (DBM). We find that homeostasis prompts hallucinations of previously learned patterns on the artificial skin in the absence of sensory input. Moreover, we show that homeostasis is capable of inducing the formation of meaningful latent representations in a DBM and that it significantly increases the quality of the reconstruction of these latent states. Through this, our work provides a possible explanation for the nature of tactile hallucinations and highlights homeostatic processes as a potential underlying mechanism., Comment: Submitted to 2019 IEEE International Conference on Cyborg and Bionic Systems

Published
2019

3. Whole-Body Multicontact Haptic Human–Humanoid Interaction Based on Leader–Follower Switching: A Robot Dance of the “Box Step”

Author

Kobayashi, Taisuke, Dean-Leon, Emmanuel, Guadarrama-Olvera, Julio Rogelio, Bergner, Florian, Cheng, Gordon, Kobayashi, Taisuke, Dean-Leon, Emmanuel, Guadarrama-Olvera, Julio Rogelio, Bergner, Florian, and Cheng, Gordon

Abstract

For physical human–robot interaction (pHRI) where multi-contacts play a key role, both robustness to achieve robot-intended motion and adaptability to follow human-intended motion are fundamental. However, there are tradeoffs during pHRI when their intentions do not match. This paper focuses on bipedal walking control during pHRI, which handles such tradeoff when a human and a humanoid robot having different footsteps locations and durations. To resolve this, a force-reactive walking controller is proposed by adequately combining ankle and stepping strategies. The ankle strategy maintains the robot's intention based on an analytically-optimal center of pressure, leading the robot to oppose resistance to multiple contacts from the human. Based on the robot's kinodynamic constraints and/or the confidence of the robot's intention, the stepping strategy updates the robot's footsteps based on the human's intention implied by the multiple contact forces. Consequently, the proposed walking control on pHRI mutually exchanges human–robot intentions in real-time, thereby achieving coordinated steps. With a full-sized humanoid robot that is able to detect multi-contacts in real-time, we succeeded in performing a long-term “box-step” with multi-contacts pHRI, demonstrating the robustness of our approach.

Published
2023

4. Effiziente Realisierung einer großflächigen E-Skin basierend auf biologisch plausiblen Prinzipien

Author

Bergner, Florian, Cheng, Gordon (Prof., Ph.D.), and Someya, Takao (Prof., Ph.D.)

Subjects
Ingenieurwissenschaften, ddc:620
Abstract

The skin allows humans to interact with their surroundings safely. Despite the importance of skin to provide feedback for interactions, few autonomous machines are equipped with the sense of touch. This is due to the challenge to handle the high amount of multi-modal tactile information of large-area electronic skin. This thesis introduces novel biologically plausible methods allowing for the efficient handling of this information in complex systems whereby previous approaches failed. Die Haut befähigt Menschen sicher mit ihrer Umgebung zu interagieren. Obwohl der Tastsinn der Haut für das Feedback bei Interaktionen sehr wichtig ist, wird dieser bisher nur bei wenigen autonomen Maschinen verwendet. Grund sind die Herausforderungen bei der Verarbeitung umfangreicher, taktiler Informationen eines großflächigen, elektronischen Hautsystems. Diese Arbeit stellt daher neue, biologisch plausible Methoden vor, diese Informationen in komplexen Systemen effizient zu verarbeiten.

Published
2022

5. Efficient Realization of Large-Area E-Skin based on Biologically Plausible Principles

Author

Someya, Takao (Prof., Ph.D.), Cheng, Gordon (Prof., Ph.D.), Bergner, Florian, Someya, Takao (Prof., Ph.D.), Cheng, Gordon (Prof., Ph.D.), and Bergner, Florian

Abstract

The skin allows humans to interact with their surroundings safely. Despite the importance of skin to provide feedback for interactions, few autonomous machines are equipped with the sense of touch. This is due to the challenge to handle the high amount of multi-modal tactile information of large-area electronic skin. This thesis introduces novel biologically plausible methods allowing for the efficient handling of this information in complex systems whereby previous approaches failed., Die Haut befähigt Menschen sicher mit ihrer Umgebung zu interagieren. Obwohl der Tastsinn der Haut für das Feedback bei Interaktionen sehr wichtig ist, wird dieser bisher nur bei wenigen autonomen Maschinen verwendet. Grund sind die Herausforderungen bei der Verarbeitung umfangreicher, taktiler Informationen eines großflächigen, elektronischen Hautsystems. Diese Arbeit stellt daher neue, biologisch plausible Methoden vor, diese Informationen in komplexen Systemen effizient zu verarbeiten.

Published
2022

6. Efficient Realization of Large-Area E-Skin based on Biologically Plausible Principles

Author

Cheng, Gordon (Prof., Ph.D.), Cheng, Gordon (Prof., Ph.D.);Someya, Takao (Prof., Ph.D.), Bergner, Florian, Cheng, Gordon (Prof., Ph.D.), Cheng, Gordon (Prof., Ph.D.);Someya, Takao (Prof., Ph.D.), and Bergner, Florian

Abstract

The skin allows humans to interact with their surroundings safely. Despite the importance of skin to provide feedback for interactions, few autonomous machines are equipped with the sense of touch. This is due to the challenge to handle the high amount of multi-modal tactile information of large-area electronic skin. This thesis introduces novel biologically plausible methods allowing for the efficient handling of this information in complex systems whereby previous approaches failed., Die Haut befähigt Menschen sicher mit ihrer Umgebung zu interagieren. Obwohl der Tastsinn der Haut für das Feedback bei Interaktionen sehr wichtig ist, wird dieser bisher nur bei wenigen autonomen Maschinen verwendet. Grund sind die Herausforderungen bei der Verarbeitung umfangreicher, taktiler Informationen eines großflächigen, elektronischen Hautsystems. Diese Arbeit stellt daher neue, biologisch plausible Methoden vor, diese Informationen in komplexen Systemen effizient zu verarbeiten.

Published
2022

8. Whole-Body Multicontact Haptic Human–Humanoid Interaction Based on Leader–Follower Switching: A Robot Dance of the “Box Step”

Author

Kobayashi, Taisuke, Dean-Leon, Emmanuel, Guadarrama-Olvera, Julio Rogelio, Bergner, Florian, Cheng, Gordon, Kobayashi, Taisuke, Dean-Leon, Emmanuel, Guadarrama-Olvera, Julio Rogelio, Bergner, Florian, and Cheng, Gordon

Abstract

For physical human–robot interaction (pHRI) where multi-contacts play a key role, both robustness to achieve robot-intended motion and adaptability to follow human-intended motion are fundamental. However, there are tradeoffs during pHRI when their intentions do not match. This paper focuses on bipedal walking control during pHRI, which handles such tradeoff when a human and a humanoid robot having different footsteps locations and durations. To resolve this, a force-reactive walking controller is proposed by adequately combining ankle and stepping strategies. The ankle strategy maintains the robot's intention based on an analytically-optimal center of pressure, leading the robot to oppose resistance to multiple contacts from the human. Based on the robot's kinodynamic constraints and/or the confidence of the robot's intention, the stepping strategy updates the robot's footsteps based on the human's intention implied by the multiple contact forces. Consequently, the proposed walking control on pHRI mutually exchanges human–robot intentions in real-time, thereby achieving coordinated steps. With a full-sized humanoid robot that is able to detect multi-contacts in real-time, we succeeded in performing a long-term “box-step” with multi-contacts pHRI, demonstrating the robustness of our approach., identifier:2640-4567

Published
2021

9. Whole-Body Multicontact Haptic Human?Humanoid Interaction Based on Leader?Follower Switching: A Robot Dance of the “Box Step”

Author

10796452, Kobayashi, Taisuke, Dean-Leon, Emmanuel, Guadarrama-Olvera, Julio Rogelio, Bergner, Florian, Cheng, Gordon, 10796452, Kobayashi, Taisuke, Dean-Leon, Emmanuel, Guadarrama-Olvera, Julio Rogelio, Bergner, Florian, and Cheng, Gordon

Abstract

For physical human?robot interaction (pHRI) where multi-contacts play a key role, both robustness to achieve robot-intended motion and adaptability to follow human-intended motion are fundamental. However, there are tradeoffs during pHRI when their intentions do not match. This paper focuses on bipedal walking control during pHRI, which handles such tradeoff when a human and a humanoid robot having different footsteps locations and durations. To resolve this, a force-reactive walking controller is proposed by adequately combining ankle and stepping strategies. The ankle strategy maintains the robot's intention based on an analytically-optimal center of pressure, leading the robot to oppose resistance to multiple contacts from the human. Based on the robot's kinodynamic constraints and/or the confidence of the robot's intention, the stepping strategy updates the robot's footsteps based on the human's intention implied by the multiple contact forces. Consequently, the proposed walking control on pHRI mutually exchanges human?robot intentions in real-time, thereby achieving coordinated steps. With a full-sized humanoid robot that is able to detect multi-contacts in real-time, we succeeded in performing a long-term “box-step” with multi-contacts pHRI, demonstrating the robustness of our approach.

Published
2021

10. Whole-Body Multicontact Haptic Human?Humanoid Interaction Based on Leader?Follower Switching: A Robot Dance of the “Box Step”

Author

Kobayashi, Taisuke, 104, 10796452, Dean-Leon, Emmanuel, 10026, Guadarrama-Olvera, Julio Rogelio, 10027, Bergner, Florian, 10028, Cheng, Gordon, 10029, Kobayashi, Taisuke, 104, 10796452, Dean-Leon, Emmanuel, 10026, Guadarrama-Olvera, Julio Rogelio, 10027, Bergner, Florian, 10028, Cheng, Gordon, and 10029

Abstract

For physical human?robot interaction (pHRI) where multi-contacts play a key role, both robustness to achieve robot-intended motion and adaptability to follow human-intended motion are fundamental. However, there are tradeoffs during pHRI when their intentions do not match. This paper focuses on bipedal walking control during pHRI, which handles such tradeoff when a human and a humanoid robot having different footsteps locations and durations. To resolve this, a force-reactive walking controller is proposed by adequately combining ankle and stepping strategies. The ankle strategy maintains the robot's intention based on an analytically-optimal center of pressure, leading the robot to oppose resistance to multiple contacts from the human. Based on the robot's kinodynamic constraints and/or the confidence of the robot's intention, the stepping strategy updates the robot's footsteps based on the human's intention implied by the multiple contact forces. Consequently, the proposed walking control on pHRI mutually exchanges human?robot intentions in real-time, thereby achieving coordinated steps. With a full-sized humanoid robot that is able to detect multi-contacts in real-time, we succeeded in performing a long-term “box-step” with multi-contacts pHRI, demonstrating the robustness of our approach., journal article

Published
2021

12. 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

14. Interactive Force Control Based on Multimodal Robot Skin for Physical Human−Robot Collaboration.

Author

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

Subjects
HUMAN-robot interaction, IMPACT (Mechanics), INFORMATION retrieval, TOUCH, ROBUST control
Abstract

This work proposes and realizes a control architecture that can support the deployment of a large‐scale robot skin in a Human‐Robot Collaboration scenario. It is shown, how whole‐body tactile feedback can extend the capabilities of robots during dynamic interactions by providing information about multiple contacts across the robot's surface. Specifically, an uncalibrated skin system is used to implement stable force control while simultaneously handling the multi‐contact interactions of a user. The system formulates control tasks for force control, tactile guidance, collision avoidance, and compliance, and fuses them with a multi‐priority redundancy resolution strategy. The approach is evaluated on an omnidirectional mobile‐manipulator with dual arms covered with robot skin. Results are assessed under dynamic conditions, showing that multi‐modal tactile information enables robust force control while at the same time remaining responsive to a user's interactions. [ABSTRACT FROM AUTHOR]

Published
2022
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15. Whole‐Body Multicontact Haptic Human–Humanoid Interaction Based on Leader–Follower Switching: A Robot Dance of the "Box Step".

Author

Kobayashi, Taisuke, Dean-Leon, Emmanuel, Guadarrama-Olvera, Julio Rogelio, Bergner, Florian, and Cheng, Gordon

Subjects
HUMAN-robot interaction, BIPEDALISM, HUMANOID robots, ROBUST statistics, STRATEGIC planning
Abstract

For physical human–robot interaction (pHRI) where multi‐contacts play a key role, both robustness to achieve robot‐intended motion and adaptability to follow human‐intended motion are fundamental. However, there are tradeoffs during pHRI when their intentions do not match. This paper focuses on bipedal walking control during pHRI, which handles such tradeoff when a human and a humanoid robot having different footsteps locations and durations. To resolve this, a force‐reactive walking controller is proposed by adequately combining ankle and stepping strategies. The ankle strategy maintains the robot's intention based on an analytically‐optimal center of pressure, leading the robot to oppose resistance to multiple contacts from the human. Based on the robot's kinodynamic constraints and/or the confidence of the robot's intention, the stepping strategy updates the robot's footsteps based on the human's intention implied by the multiple contact forces. Consequently, the proposed walking control on pHRI mutually exchanges human–robot intentions in real‐time, thereby achieving coordinated steps. With a full‐sized humanoid robot that is able to detect multi‐contacts in real‐time, we succeeded in performing a long‐term "box‐step" with multi‐contacts pHRI, demonstrating the robustness of our approach. [ABSTRACT FROM AUTHOR]

Published
2022
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