Search

Your search keyword '"Gienger, Michael"' showing total 278 results
Start Over Author "Gienger, Michael"

Refine your results

more »

more »

more »

more »
278 results on '"Gienger, Michael"'

1. Affordance-based Robot Manipulation with Flow Matching

Author

Zhang, Fan and Gienger, Michael

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

We present a framework for assistive robot manipulation, which focuses on two fundamental challenges: first, efficiently adapting large-scale models to downstream scene affordance understanding tasks, especially in daily living scenarios where gathering multi-task data involving humans requires strenuous effort; second, effectively learning robot trajectories by grounding the visual affordance model. We tackle the first challenge by employing a parameter-efficient prompt tuning method that prepends learnable text prompts to the frozen vision model to predict manipulation affordances in multi-task scenarios. Then we propose to learn robot trajectories guided by affordances in a supervised Flow Matching method. Flow matching represents a robot visuomotor policy as a conditional process of flowing random waypoints to desired robot trajectories. Finally, we introduce a real-world dataset with 10 tasks across Activities of Daily Living to test our framework. Our extensive evaluation highlights that the proposed prompt tuning method for learning manipulation affordance with language prompter achieves competitive performance and even outperforms other finetuning protocols across data scales, while satisfying parameter efficiency. Learning multi-task robot trajectories with a single flow matching policy also leads to consistently better performance than alternative behavior cloning methods, especially given multimodal robot action distributions. Our framework seamlessly unifies affordance model learning and trajectory generation with flow matching for robot manipulation.

Published
2024

2. Tulip Agent -- Enabling LLM-Based Agents to Solve Tasks Using Large Tool Libraries

Author

Ocker, Felix, Tanneberg, Daniel, Eggert, Julian, and Gienger, Michael

Subjects
Computer Science - Artificial Intelligence, Computer Science - Robotics, H.3.3, I.2.6, I.2.8, I.2.9
Abstract

We introduce tulip agent, an architecture for autonomous LLM-based agents with Create, Read, Update, and Delete access to a tool library containing a potentially large number of tools. In contrast to state-of-the-art implementations, tulip agent does not encode the descriptions of all available tools in the system prompt, which counts against the model's context window, or embed the entire prompt for retrieving suitable tools. Instead, the tulip agent can recursively search for suitable tools in its extensible tool library, implemented exemplarily as a vector store. The tulip agent architecture significantly reduces inference costs, allows using even large tool libraries, and enables the agent to adapt and extend its set of tools. We evaluate the architecture with several ablation studies in a mathematics context and demonstrate its generalizability with an application to robotics. A reference implementation and the benchmark are available at github.com/HRI-EU/tulip_agent., Comment: 19 pages, 4 figures

Published
2024

3. Efficient Symbolic Planning with Views

Author

Hasler, Stephan, Tanneberg, Daniel, and Gienger, Michael

Subjects
Computer Science - Robotics
Abstract

Robotic planning systems model spatial relations in detail as these are needed for manipulation tasks. In contrast to this, other physical attributes of objects and the effect of devices are usually oversimplified and expressed by abstract compound attributes. This limits the ability of planners to find alternative solutions. We propose to break these compound attributes down into a shared set of elementary attributes. This strongly facilitates generalization between different tasks and environments and thus helps to find innovative solutions. On the down-side, this generalization comes with an increased complexity of the solution space. Therefore, as the main contribution of the paper, we propose a method that splits the planning problem into a sequence of views, where in each view only an increasing subset of attributes is considered. We show that this view-based strategy offers a good compromise between planning speed and quality of the found plan, and discuss its general applicability and limitations., Comment: 6 pages

Published
2024

4. Learning Deep Dynamical Systems using Stable Neural ODEs

Author

Sochopoulos, Andreas, Gienger, Michael, and Vijayakumar, Sethu

Subjects
Computer Science - Robotics
Abstract

Learning complex trajectories from demonstrations in robotic tasks has been effectively addressed through the utilization of Dynamical Systems (DS). State-of-the-art DS learning methods ensure stability of the generated trajectories; however, they have three shortcomings: a) the DS is assumed to have a single attractor, which limits the diversity of tasks it can achieve, b) state derivative information is assumed to be available in the learning process and c) the state of the DS is assumed to be measurable at inference time. We propose a class of provably stable latent DS with possibly multiple attractors, that inherit the training methods of Neural Ordinary Differential Equations, thus, dropping the dependency on state derivative information. A diffeomorphic mapping for the output and a loss that captures time-invariant trajectory similarity are proposed. We validate the efficacy of our approach through experiments conducted on a public dataset of handwritten shapes and within a simulated object manipulation task., Comment: Paper currently under review

Published
2024

5. Generating consistent PDDL domains with Large Language Models

Author

Smirnov, Pavel, Joublin, Frank, Ceravola, Antonello, and Gienger, Michael

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

Large Language Models (LLMs) are capable of transforming natural language domain descriptions into plausibly looking PDDL markup. However, ensuring that actions are consistent within domains still remains a challenging task. In this paper we present a novel concept to significantly improve the quality of LLM-generated PDDL models by performing automated consistency checking during the generation process. Although the proposed consistency checking strategies still can't guarantee absolute correctness of generated models, they can serve as valuable source of feedback reducing the amount of correction efforts expected from a human in the loop. We demonstrate the capabilities of our error detection approach on a number of classical and custom planning domains (logistics, gripper, tyreworld, household, pizza).

Published
2024

6. Impact-Aware Bimanual Catching of Large-Momentum Objects

Author

Yan, Lei, Stouraitis, Theodoros, Moura, João, Xu, Wenfu, Gienger, Michael, and Vijayakumar, Sethu

Subjects
Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control
Abstract

This paper investigates one of the most challenging tasks in dynamic manipulation -- catching large-momentum moving objects. Beyond the realm of quasi-static manipulation, dealing with highly dynamic objects can significantly improve the robot's capability of interacting with its surrounding environment. Yet, the inevitable motion mismatch between the fast moving object and the approaching robot will result in large impulsive forces, which lead to the unstable contacts and irreversible damage to both the object and the robot. To address the above problems, we propose an online optimization framework to: 1) estimate and predict the linear and angular motion of the object; 2) search and select the optimal contact locations across every surface of the object to mitigate impact through sequential quadratic programming (SQP); 3) simultaneously optimize the end-effector motion, stiffness, and contact force for both robots using multi-mode trajectory optimization (MMTO); and 4) realise the impact-aware catching motion on the compliant robotic system based on indirect force controller. We validate the impulse distribution, contact selection, and impact-aware MMTO algorithms in simulation and demonstrate the benefits of the proposed framework in real-world experiments including catching large-momentum moving objects with well-defined motion, constrained motion and free-flying motion.

Published
2024

7. To Help or Not to Help: LLM-based Attentive Support for Human-Robot Group Interactions

Author

Tanneberg, Daniel, Ocker, Felix, Hasler, Stephan, Deigmoeller, Joerg, Belardinelli, Anna, Wang, Chao, Wersing, Heiko, Sendhoff, Bernhard, and Gienger, Michael

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, I.2.8, I.2.9
Abstract

How can a robot provide unobtrusive physical support within a group of humans? We present Attentive Support, a novel interaction concept for robots to support a group of humans. It combines scene perception, dialogue acquisition, situation understanding, and behavior generation with the common-sense reasoning capabilities of Large Language Models (LLMs). In addition to following user instructions, Attentive Support is capable of deciding when and how to support the humans, and when to remain silent to not disturb the group. With a diverse set of scenarios, we show and evaluate the robot's attentive behavior, which supports and helps the humans when required, while not disturbing if no help is needed., Comment: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) 2024

Published
2024

8. LaMI: Large Language Models for Multi-Modal Human-Robot Interaction

Author

Wang, Chao, Hasler, Stephan, Tanneberg, Daniel, Ocker, Felix, Joublin, Frank, Ceravola, Antonello, Deigmoeller, Joerg, and Gienger, Michael

Subjects
Computer Science - Robotics, Computer Science - Human-Computer Interaction
Abstract

This paper presents an innovative large language model (LLM)-based robotic system for enhancing multi-modal human-robot interaction (HRI). Traditional HRI systems relied on complex designs for intent estimation, reasoning, and behavior generation, which were resource-intensive. In contrast, our system empowers researchers and practitioners to regulate robot behavior through three key aspects: providing high-level linguistic guidance, creating "atomic actions" and expressions the robot can use, and offering a set of examples. Implemented on a physical robot, it demonstrates proficiency in adapting to multi-modal inputs and determining the appropriate manner of action to assist humans with its arms, following researchers' defined guidelines. Simultaneously, it coordinates the robot's lid, neck, and ear movements with speech output to produce dynamic, multi-modal expressions. This showcases the system's potential to revolutionize HRI by shifting from conventional, manual state-and-flow design methods to an intuitive, guidance-based, and example-driven approach. Supplementary material can be found at https://hri-eu.github.io/Lami/, Comment: 10 pages, 6 figures

Published
2024
Full Text
View/download PDF

9. CoPAL: Corrective Planning of Robot Actions with Large Language Models

Author

Joublin, Frank, Ceravola, Antonello, Smirnov, Pavel, Ocker, Felix, Deigmoeller, Joerg, Belardinelli, Anna, Wang, Chao, Hasler, Stephan, Tanneberg, Daniel, and Gienger, Michael

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

In the pursuit of fully autonomous robotic systems capable of taking over tasks traditionally performed by humans, the complexity of open-world environments poses a considerable challenge. Addressing this imperative, this study contributes to the field of Large Language Models (LLMs) applied to task and motion planning for robots. We propose a system architecture that orchestrates a seamless interplay between multiple cognitive levels, encompassing reasoning, planning, and motion generation. At its core lies a novel replanning strategy that handles physically grounded, logical, and semantic errors in the generated plans. We demonstrate the efficacy of the proposed feedback architecture, particularly its impact on executability, correctness, and time complexity via empirical evaluation in the context of a simulation and two intricate real-world scenarios: blocks world, barman and pizza preparation.

Published
2023

10. Predictive and Robust Robot Assistance for Sequential Manipulation

Author

Stouraitis, Theodoros and Gienger, Michael

Subjects
Computer Science - Robotics
Abstract

This paper presents a novel concept to support physically impaired humans in daily object manipulation tasks with a robot. Given a user's manipulation sequence, we propose a predictive model that uniquely casts the user's sequential behavior as well as a robot support intervention into a hierarchical multi-objective optimization problem. A major contribution is the prediction formulation, which allows to consider several different future paths concurrently. The second contribution is the encoding of a general notion of constancy constraints, which allows to consider dependencies between consecutive or far apart keyframes (in time or space) of a sequential task. We perform numerical studies, simulations and robot experiments to analyse and evaluate the proposed method in several table top tasks where a robot supports impaired users by predicting their posture and proactively re-arranging objects.

Published
2023

11. Communicating Robot's Intentions while Assisting Users via Augmented Reality

Author

Wang, Chao, Stouraitis, Theodoros, Belardinelli, Anna, Hasler, Stephan, and Gienger, Michael

Subjects
Computer Science - Robotics, Computer Science - Human-Computer Interaction
Abstract

This paper explores the challenges faced by assistive robots in effectively cooperating with humans, requiring them to anticipate human behavior, predict their actions' impact, and generate understandable robot actions. The study focuses on a use-case involving a user with limited mobility needing assistance with pouring a beverage, where tasks like unscrewing a cap or reaching for objects demand coordinated support from the robot. Yet, anticipating the robot's intentions can be challenging for the user, which can hinder effective collaboration. To address this issue, we propose an innovative solution that utilizes Augmented Reality (AR) to communicate the robot's intentions and expected movements to the user, fostering a seamless and intuitive interaction.

Published
2023

12. Learning Type-Generalized Actions for Symbolic Planning

Author

Tanneberg, Daniel and Gienger, Michael

Subjects
Computer Science - Artificial Intelligence, Computer Science - Robotics
Abstract

Symbolic planning is a powerful technique to solve complex tasks that require long sequences of actions and can equip an intelligent agent with complex behavior. The downside of this approach is the necessity for suitable symbolic representations describing the state of the environment as well as the actions that can change it. Traditionally such representations are carefully hand-designed by experts for distinct problem domains, which limits their transferability to different problems and environment complexities. In this paper, we propose a novel concept to generalize symbolic actions using a given entity hierarchy and observed similar behavior. In a simulated grid-based kitchen environment, we show that type-generalized actions can be learned from few observations and generalize to novel situations. Incorporating an additional on-the-fly generalization mechanism during planning, unseen task combinations, involving longer sequences, novel entities and unexpected environment behavior, can be solved., Comment: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) 2023

Published
2023

13. A Glimpse in ChatGPT Capabilities and its impact for AI research

Author

Joublin, Frank, Ceravola, Antonello, Deigmoeller, Joerg, Gienger, Michael, Franzius, Mathias, and Eggert, Julian

Subjects
Computer Science - Artificial Intelligence, Computer Science - Computation and Language, Computer Science - Human-Computer Interaction, Computer Science - Machine Learning, Computer Science - Robotics, I.2, I.7
Abstract

Large language models (LLMs) have recently become a popular topic in the field of Artificial Intelligence (AI) research, with companies such as Google, Amazon, Facebook, Amazon, Tesla, and Apple (GAFA) investing heavily in their development. These models are trained on massive amounts of data and can be used for a wide range of tasks, including language translation, text generation, and question answering. However, the computational resources required to train and run these models are substantial, and the cost of hardware and electricity can be prohibitive for research labs that do not have the funding and resources of the GAFA. In this paper, we will examine the impact of LLMs on AI research. The pace at which such models are generated as well as the range of domains covered is an indication of the trend which not only the public but also the scientific community is currently experiencing. We give some examples on how to use such models in research by focusing on GPT3.5/ChatGPT3.4 and ChatGPT4 at the current state and show that such a range of capabilities in a single system is a strong sign of approaching general intelligence. Innovations integrating such models will also expand along the maturation of such AI systems and exhibit unforeseeable applications that will have important impacts on several aspects of our societies.

Published
2023

14. Learning from Few Demonstrations with Frame-Weighted Motion Generation

Author

Sun, Jianyong, Kober, Jens, Gienger, Michael, and Zhu, Jihong

Subjects
Computer Science - Robotics
Abstract

Learning from Demonstration (LfD) enables robots to acquire versatile skills by learning motion policies from human demonstrations. It endows users with an intuitive interface to transfer new skills to robots without the need for time-consuming robot programming and inefficient solution exploration. During task executions, the robot motion is usually influenced by constraints imposed by environments. In light of this, task-parameterized LfD (TP-LfD) encodes relevant contextual information into reference frames, enabling better skill generalization to new situations. However, most TP-LfD algorithms typically require multiple demonstrations across various environmental conditions to ensure sufficient statistics for a meaningful model. It is not a trivial task for robot users to create different situations and perform demonstrations under all of them. Therefore, this paper presents a novel algorithm to learn skills from few demonstrations. By leveraging the reference frame weights that capture the frame importance or relevance during task executions, our method demonstrates excellent skill acquisition performance, which is validated in real robotic environments., Comment: Accepted by ISER. For the experiment video, see https://youtu.be/JpGjk4eKC3o

Published
2023

15. Understanding the Uncertainty Loop of Human-Robot Interaction

Author

Leusmann, Jan, Wang, Chao, Gienger, Michael, Schmidt, Albrecht, and Mayer, Sven

Subjects
Computer Science - Human-Computer Interaction, Computer Science - Robotics, H.5.2
Abstract

Recently the field of Human-Robot Interaction gained popularity, due to the wide range of possibilities of how robots can support humans during daily tasks. One form of supportive robots are socially assistive robots which are specifically built for communicating with humans, e.g., as service robots or personal companions. As they understand humans through artificial intelligence, these robots will at some point make wrong assumptions about the humans' current state and give an unexpected response. In human-human conversations, unexpected responses happen frequently. However, it is currently unclear how such robots should act if they understand that the human did not expect their response, or even showing the uncertainty of their response in the first place. For this, we explore the different forms of potential uncertainties during human-robot conversations and how humanoids can, through verbal and non-verbal cues, communicate these uncertainties.

Published
2023

16. Robotic Fabric Flattening with Wrinkle Direction Detection

Author

Qiu, Yulei, Zhu, Jihong, Della Santina, Cosimo, Gienger, Michael, and Kober, Jens

Subjects
Computer Science - Robotics, Computer Science - Computer Vision and Pattern Recognition
Abstract

Deformable Object Manipulation (DOM) is an important field of research as it contributes to practical tasks such as automatic cloth handling, cable routing, surgical operation, etc. Perception is considered one of the major challenges in DOM due to the complex dynamics and high degree of freedom of deformable objects. In this paper, we develop a novel image-processing algorithm based on Gabor filters to extract useful features from cloth, and based on this, devise a strategy for cloth flattening tasks. We also evaluate the overall framework experimentally and compare it with three human operators. The results show that our algorithm can determine the direction of wrinkles on the cloth accurately in simulation as well as in real robot experiments. Furthermore, our dewrinkling strategy compares favorably to baseline methods. The experiment video is available on https://sites.google.com/view/robotic-fabric-flattening/home, Comment: Accepted by the 18th International Symposium on Experimental Robotics (ISER 2023)

Published
2023

18. Explainable Human-Robot Training and Cooperation with Augmented Reality

Author

Wang, Chao, Belardinelli, Anna, Hasler, Stephan, Stouraitis, Theodoros, Tanneberg, Daniel, and Gienger, Michael

Subjects
Computer Science - Human-Computer Interaction
Abstract

The current spread of social and assistive robotics applications is increasingly highlighting the need for robots that can be easily taught and interacted with, even by users with no technical background. Still, it is often difficult to grasp what such robots know or to assess if a correct representation of the task is being formed. Augmented Reality (AR) has the potential to bridge this gap. We demonstrate three use cases where AR design elements enhance the explainability and efficiency of human-robot interaction: 1) a human teaching a robot some simple kitchen tasks by demonstration, 2) the robot showing its plan for solving novel tasks in AR to a human for validation, and 3) a robot communicating its intentions via AR while assisting people with limited mobility during daily activities.

Published
2023
Full Text
View/download PDF

19. Do You Need a Hand? -- a Bimanual Robotic Dressing Assistance Scheme

Author

Zhu, Jihong, Gienger, Michael, Franzese, Giovanni, and Kober, Jens

Subjects
Computer Science - Robotics
Abstract

Developing physically assistive robots capable of dressing assistance has the potential to significantly improve the lives of the elderly and disabled population. However, most robotics dressing strategies considered a single robot only, which greatly limited the performance of the dressing assistance. In fact, healthcare professionals perform the task bimanually. Inspired by them, we propose a bimanual cooperative scheme for robotic dressing assistance. In the scheme, an interactive robot joins hands with the human thus supporting/guiding the human in the dressing process, while the dressing robot performs the dressing task. We identify a key feature that affects the dressing action and propose an optimal strategy for the interactive robot using the feature. A dressing coordinate based on the posture of the arm is defined to better encode the dressing policy. We validate the interactive dressing scheme with extensive experiments and also an ablation study. The experiment video is available on https://sites.google.com/view/bimanualassitdressing/home

Published
2023
Full Text
View/download PDF

20. Robotic Fabric Flattening with Wrinkle Direction Detection

Author

Qiu, Yulei, Zhu, Jihong, Della Santina, Cosimo, Gienger, Michael, Kober, Jens, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, and Ang Jr, Marcelo H., editor

Published
2024
Full Text
View/download PDF

21. Learning from Few Demonstrations with Frame–Weighted Motion Generation

Author

Sun, Jianyong, Kober, Jens, Gienger, Michael, Zhu, Jihong, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, and Ang Jr, Marcelo H., editor

Published
2024
Full Text
View/download PDF

22. Explainable Human-Robot Interaction for Imitation Learning in Augmented Reality

Author

Belardinelli, Anna, Wang, Chao, Gienger, Michael, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Piazza, Cristina, editor, Capsi-Morales, Patricia, editor, Figueredo, Luis, editor, Keppler, Manuel, editor, and Schütze, Hinrich, editor

Published
2024
Full Text
View/download PDF

23. ROS-PyBullet Interface: A Framework for Reliable Contact Simulation and Human-Robot Interaction

Author

Mower, Christopher E., Stouraitis, Theodoros, Moura, João, Rauch, Christian, Yan, Lei, Behabadi, Nazanin Zamani, Gienger, Michael, Vercauteren, Tom, Bergeles, Christos, and Vijayakumar, Sethu

Subjects
Computer Science - Robotics, Computer Science - Machine Learning
Abstract

Reliable contact simulation plays a key role in the development of (semi-)autonomous robots, especially when dealing with contact-rich manipulation scenarios, an active robotics research topic. Besides simulation, components such as sensing, perception, data collection, robot hardware control, human interfaces, etc. are all key enablers towards applying machine learning algorithms or model-based approaches in real world systems. However, there is a lack of software connecting reliable contact simulation with the larger robotics ecosystem (i.e. ROS, Orocos), for a more seamless application of novel approaches, found in the literature, to existing robotic hardware. In this paper, we present the ROS-PyBullet Interface, a framework that provides a bridge between the reliable contact/impact simulator PyBullet and the Robot Operating System (ROS). Furthermore, we provide additional utilities for facilitating Human-Robot Interaction (HRI) in the simulated environment. We also present several use-cases that highlight the capabilities and usefulness of our framework. Please check our video, source code, and examples included in the supplementary material. Our full code base is open source and can be found at https://github.com/cmower/ros_pybullet_interface.

Published
2022

24. Learning Task-Parameterized Skills from Few Demonstrations

Author

Zhu, Jihong, Gienger, Michael, and Kober, Jens

Subjects
Computer Science - Robotics
Abstract

Moving away from repetitive tasks, robots nowadays demand versatile skills that adapt to different situations. Task-parameterized learning improves the generalization of motion policies by encoding relevant contextual information in the task parameters, hence enabling flexible task executions. However, training such a policy often requires collecting multiple demonstrations in different situations. To comprehensively create different situations is non-trivial thus renders the method less applicable to real-world problems. Therefore, training with fewer demonstrations/situations is desirable. This paper presents a novel concept to augment the original training dataset with synthetic data for policy improvements, thus allows learning task-parameterized skills with few demonstrations., Comment: Accepted by the IEEE Robotics and Automation Letters

Published
2022

25. Distilled Domain Randomization

Author

Brosseit, Julien, Hahner, Benedikt, Muratore, Fabio, Gienger, Michael, and Peters, Jan

Subjects
Computer Science - Machine Learning, Computer Science - Robotics
Abstract

Deep reinforcement learning is an effective tool to learn robot control policies from scratch. However, these methods are notorious for the enormous amount of required training data which is prohibitively expensive to collect on real robots. A highly popular alternative is to learn from simulations, allowing to generate the data much faster, safer, and cheaper. Since all simulators are mere models of reality, there are inevitable differences between the simulated and the real data, often referenced as the 'reality gap'. To bridge this gap, many approaches learn one policy from a distribution over simulators. In this paper, we propose to combine reinforcement learning from randomized physics simulations with policy distillation. Our algorithm, called Distilled Domain Randomization (DiDoR), distills so-called teacher policies, which are experts on domains that have been sampled initially, into a student policy that is later deployed. This way, DiDoR learns controllers which transfer directly from simulation to reality, i.e., without requiring data from the target domain. We compare DiDoR against three baselines in three sim-to-sim as well as two sim-to-real experiments. Our results show that the target domain performance of policies trained with DiDoR is en par or better than the baselines'. Moreover, our approach neither increases the required memory capacity nor the time to compute an action, which may well be a point of failure for successfully deploying the learned controller., Comment: shared first authorship between Julien Brosseit, Benedikt Hahner, and Fabio Muratore

Published
2021

26. Robot Learning from Randomized Simulations: A Review

Author

Muratore, Fabio, Ramos, Fabio, Turk, Greg, Yu, Wenhao, Gienger, Michael, and Peters, Jan

Subjects
Computer Science - Robotics, Computer Science - Machine Learning
Abstract

The rise of deep learning has caused a paradigm shift in robotics research, favoring methods that require large amounts of data. Unfortunately, it is prohibitively expensive to generate such data sets on a physical platform. Therefore, state-of-the-art approaches learn in simulation where data generation is fast as well as inexpensive and subsequently transfer the knowledge to the real robot (sim-to-real). Despite becoming increasingly realistic, all simulators are by construction based on models, hence inevitably imperfect. This raises the question of how simulators can be modified to facilitate learning robot control policies and overcome the mismatch between simulation and reality, often called the 'reality gap'. We provide a comprehensive review of sim-to-real research for robotics, focusing on a technique named 'domain randomization' which is a method for learning from randomized simulations., Comment: submitted to Frontiers in Robotics and AI

Published
2021

27. Set-based State Estimation with Probabilistic Consistency Guarantee under Epistemic Uncertainty

Author

Li, Shen, Stouraitis, Theodoros, Gienger, Michael, Vijayakumar, Sethu, and Shah, Julie A.

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Robotics
Abstract

Consistent state estimation is challenging, especially under the epistemic uncertainties arising from learned (nonlinear) dynamic and observation models. In this work, we propose a set-based estimation algorithm, named Gaussian Process-Zonotopic Kalman Filter (GP-ZKF), that produces zonotopic state estimates while respecting both the epistemic uncertainties in the learned models and aleatoric uncertainties. Our method guarantees probabilistic consistency, in the sense that the true states are bounded by sets (zonotopes) across all time steps, with high probability. We formally relate GP-ZKF with the corresponding stochastic approach, GP-EKF, in the case of learned (nonlinear) models. In particular, when linearization errors and aleatoric uncertainties are omitted and epistemic uncertainties are simplified, GP-ZKF reduces to GP-EKF. We empirically demonstrate our method's efficacy in both a simulated pendulum domain and a real-world robot-assisted dressing domain, where GP-ZKF produced more consistent and less conservative set-based estimates than all baseline stochastic methods., Comment: Published at IEEE Robotics and Automation Letters, 2022. Video: https://www.youtube.com/watch?v=CvIPJlALaFU Copyright: 2022 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any media, including reprinting/republishing for any purposes, creating new works, for resale or redistribution, or reuse of any copyrighted component of this work

Published
2021

28. Challenges and Outlook in Robotic Manipulation of Deformable Objects

Author

Zhu, Jihong, Cherubini, Andrea, Dune, Claire, Navarro-Alarcon, David, Alambeigi, Farshid, Berenson, Dmitry, Ficuciello, Fanny, Harada, Kensuke, Kober, Jens, Li, Xiang, Pan, Jia, Yuan, Wenzhen, and Gienger, Michael

Subjects
Computer Science - Robotics
Abstract

Deformable object manipulation (DOM) is an emerging research problem in robotics. The ability to manipulate deformable objects endows robots with higher autonomy and promises new applications in the industrial, services, and healthcare sectors. However, compared to rigid object manipulation, the manipulation of deformable objects is considerably more complex, and is still an open research problem. Addressing DOM challenges demand breakthroughs in almost all aspects of robotics, namely hardware design, sensing, (deformation) modeling, planning, and control. In this article, we review recent advances and highlight the main challenges when considering deformation in each sub-field. A particular focus of our paper lies in the discussions of these challenges and proposing future directions of research.

Published
2021

29. Multi-mode Trajectory Optimization for Impact-aware Manipulation

Author

Stouraitis, Theodoros, Yan, Lei, Moura, João, Gienger, Michael, and Vijayakumar, Sethu

Subjects
Computer Science - Robotics
Abstract

The transition from free motion to contact is a challenging problem in robotics, in part due to its hybrid nature. Additionally, disregarding the effects of impacts at the motion planning level often results in intractable impulsive contact forces. In this paper, we introduce an impact-aware multi-mode trajectory optimization (TO) method that combines hybrid dynamics and hybrid control in a coherent fashion. A key concept is the incorporation of an explicit contact force transmission model in the TO method. This allows the simultaneous optimization of the contact forces, contact timings, continuous motion trajectories and compliance, while satisfying task constraints. We compare our method against standard compliance control and an impact-agnostic TO method in physical simulations. Further, we experimentally validate the proposed method with a robot manipulator on the task of halting a large-momentum object.

Published
2020

30. Data-efficient Domain Randomization with Bayesian Optimization

Author

Muratore, Fabio, Eilers, Christian, Gienger, Michael, and Peters, Jan

Subjects
Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

When learning policies for robot control, the required real-world data is typically prohibitively expensive to acquire, so learning in simulation is a popular strategy. Unfortunately, such polices are often not transferable to the real world due to a mismatch between the simulation and reality, called 'reality gap'. Domain randomization methods tackle this problem by randomizing the physics simulator (source domain) during training according to a distribution over domain parameters in order to obtain more robust policies that are able to overcome the reality gap. Most domain randomization approaches sample the domain parameters from a fixed distribution. This solution is suboptimal in the context of sim-to-real transferability, since it yields policies that have been trained without explicitly optimizing for the reward on the real system (target domain). Additionally, a fixed distribution assumes there is prior knowledge about the uncertainty over the domain parameters. In this paper, we propose Bayesian Domain Randomization (BayRn), a black-box sim-to-real algorithm that solves tasks efficiently by adapting the domain parameter distribution during learning given sparse data from the real-world target domain. BayRn uses Bayesian optimization to search the space of source domain distribution parameters such that this leads to a policy which maximizes the real-word objective, allowing for adaptive distributions during policy optimization. We experimentally validate the proposed approach in sim-to-sim as well as in sim-to-real experiments, comparing against three baseline methods on two robotic tasks. Our results show that BayRn is able to perform sim-to-real transfer, while significantly reducing the required prior knowledge., Comment: Accepted at RA-L / ICRA

Published
2020
Full Text
View/download PDF

31. Assessing Transferability from Simulation to Reality for Reinforcement Learning

Author

Muratore, Fabio, Gienger, Michael, and Peters, Jan

Subjects
Computer Science - Robotics, Computer Science - Machine Learning
Abstract

Learning robot control policies from physics simulations is of great interest to the robotics community as it may render the learning process faster, cheaper, and safer by alleviating the need for expensive real-world experiments. However, the direct transfer of learned behavior from simulation to reality is a major challenge. Optimizing a policy on a slightly faulty simulator can easily lead to the maximization of the `Simulation Optimization Bias` (SOB). In this case, the optimizer exploits modeling errors of the simulator such that the resulting behavior can potentially damage the robot. We tackle this challenge by applying domain randomization, i.e., randomizing the parameters of the physics simulations during learning. We propose an algorithm called Simulation-based Policy Optimization with Transferability Assessment (SPOTA) which uses an estimator of the SOB to formulate a stopping criterion for training. The introduced estimator quantifies the over-fitting to the set of domains experienced while training. Our experimental results on two different second order nonlinear systems show that the new simulation-based policy search algorithm is able to learn a control policy exclusively from a randomized simulator, which can be applied directly to real systems without any additional training.

Published
2019
Full Text
View/download PDF

32. Large-Scale System Monitoring Experiences and Recommendations Workshop paper: HPCMASPA 2018

Author

Ahlgren, Ville, Andersson, Stefan, Brandt, Jim, Cardo, Nicholas P, Chunduri, Sudheer, Enos, Jeremy, Fields, Parks, Gentile, Ann, Gerber, Richard, Gienger, Michael, Greenseid, Joe, Greiner, Annette, Hadri, Bilel, He, Yun, Hoppe, Dennis, Kaila, Urpo, Kelly, Kaki, Klein, Mark, Kristiansen, Alex, Leak, Steve, Mason, Mike, Pedretti, Kevin, Piccinali, Jean-Guillaume, Repik, Jason, Rogers, Jim, Salminen, Susanna, Showerman, Mike, Whitney, Cary, and Williams, Jim

Subjects
Distributed Computing and Systems Software, Information and Computing Sciences, HPC monitoring, monitoring architecture, system administration
Abstract

Monitoring of High Performance Computing (HPC) platforms is critical to successful operations, can provide insights into performance-impacting conditions, and can inform methodologies for improving science throughput. However, monitoring systems are not generally considered core capabilities in system requirements specifications nor in vendor development strategies. In this paper we present work performed at a number of large-scale HPC sites towards developing monitoring capabilities that fill current gaps in ease of problem identification and root cause discovery. We also present our collective views, based on the experiences presented, on needs and requirements for enabling development by vendors or users of effective sharable end-to-end monitoring capabilities.

Published
2018

34. Monitoring in the Clouds: Comparison of ECO2Clouds and EXCESS Monitoring Approaches

Author

Skvortsov, Pavel, Hoppe, Dennis, Tenschert, Axel, and Gienger, Michael

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

With the increasing adoption of private cloud infrastructures by providers and enterprises, the monitoring of these infrastructures is becoming crucial. The rationale behind monitoring is manifold: reasons include saving energy, lowering costs, and better maintenance. In the e-Science sector, moreover, the collection of infrastructure and application-specific data at high resolutions is immanent. In this paper, we present two monitoring approaches implemented throughout two European projects: ECO2Clouds and EXCESS. The ECO2Clouds project aims to minimize CO2 emissions caused by the execution of applications on the cloud infrastructure. In order to allow for eco-aware deployment and scheduling of applications, the ECO2Clouds monitoring framework provides the necessary set of metrics on different layers including physical, virtual and application layer. In turn, the EXCESS project introduces new energy-aware execution models that improve energy-efficiency on a software level. Having in-depth knowledge about the energy consumption and overall behavior of applications on a given infrastructure, subsequent executions can be optimized to save energy. To achieve this goal, the EXCESS monitoring framework provides APIs allowing developers to collect application-specific data in addition to infrastructure data at run-time. We perform a comparative analysis of both monitoring approaches, and highlighting use cases including a hybrid approach which benefits from both monitoring solutions., Comment: 2nd International Workshop on Dynamic Resource Allocation and Management in Embedded, High Performance and Cloud Computing DREAMCloud 2016 (arXiv:cs/1601.04675)

Published
2016

35. Learning Sequential Force Interaction Skills

Author

Manschitz, Simon, Gienger, Michael, Kober, Jens, Peters, Jan, Manschitz, Simon, Gienger, Michael, Kober, Jens, and Peters, Jan

Abstract

Learning skills from kinesthetic demonstrations is a promising way of minimizing the gap between human manipulation abilities and those of robots. We propose an approach to learn sequential force interaction skills from such demonstrations. The demonstrations are decomposed into a set of movement primitives by inferring the underlying sequential structure of the task. The decomposition is based on a novel probability distribution which we call Directional Normal Distribution. The distribution allows infering the movement primitive’s composition, i.e., its coordinate frames, control variables and target coordinates from the demonstrations. In addition, it permits determining an appropriate number of movement primitives for a task via model selection. After finding the task’s composition, the system learns to sequence the resulting movement primitives in order to be able to reproduce the task on a real robot. We evaluate the approach on three different tasks, unscrewing a light bulb, box stacking and box flipping. All tasks are kinesthetically demonstrated and then reproduced on a Barrett WAM robot.

Published
2024

42. Adaptive assistive robotics: a framework for triadic collaboration between humans and robots

Author

Gordon, Daniel F. N., Christou, Andreas, Stouraitis, Theodoros, Gienger, Michael, and Vijayakumar, Sethu

Subjects
optimal control, ergonomics, optimization
Abstract

Robots and other assistive technologies have a huge potential to help society in domains ranging from factory work to healthcare. However, safe and effective control of robotic agents in these environments is complex, especially when it involves close interactions and multiple actors. We propose an effective framework for optimizing the behaviour of robots and complementary assistive technologies in systems comprising a mix of human and technological agents with numerous high-level goals. The framework uses a combination of detailed biomechanical modelling and weighted multi-objective optimization to allow for the fine tuning of robot behaviours depending on the specification of the task at hand. We illustrate our framework via two case studies across assisted living and rehabilitation scenarios, and conduct simulations and experiments of triadic collaboration in practice. Our results indicate a marked benefit to the triadic approach, showing the potential to improve outcome measures for human agents in robot-assisted tasks.

Published
2023

48. Cloud and Network Facilities Federation in BonFIRE

Author

García-Pérez, David, Lorenzo del Castillo, Juan Ángel, Al-Hazmi, Yahya, Martrat, Josep, Kavoussanakis, Konstantinos, Hume, Alastair C., López, Celia Velayos, Landi, Giada, Wauters, Tim, Gienger, Michael, Margery, David, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Kobsa, Alfred, editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Weikum, Gerhard, editor, an Mey, Dieter, editor, Alexander, Michael, editor, Bientinesi, Paolo, editor, Cannataro, Mario, editor, Clauss, Carsten, editor, Costan, Alexandru, editor, Kecskemeti, Gabor, editor, Morin, Christine, editor, Ricci, Laura, editor, Sahuquillo, Julio, editor, Schulz, Martin, editor, Scarano, Vittorio, editor, Scott, Stephen L., editor, and Weidendorfer, Josef, editor

Published
2014
Full Text
View/download PDF

50. Do You Need a Hand? – A Bimanual Robotic Dressing Assistance Scheme

Author

Zhu, Jihong, Gienger, Michael, Franzese, Giovanni, and Kober, Jens

Abstract

Developing physically assistive robots capable of dressing assistance has the potential to significantly improve the lives of the elderly and disabled population. However, most robotics dressing strategies considered a single robot only, which greatly limited the performance of the dressing assistance. In fact, healthcare professionals perform the task bimanually. Inspired by them, we propose a bimanual cooperative scheme for robotic dressing assistance. In the scheme, an interactive robot joins hands with the human thus supporting/guiding the human in the dressing process while the dressing robot performs the dressing task. We identify a key feature: the elbow angle that affects the dressing action and propose an optimal strategy for the interactive robot using the feature. A dressing coordinate based on the posture of the arm is defined to better encode the dressing policy. We validate the interactive dressing scheme with extensive experiments and also an ablation study.

Published
2024
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results