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134 results on '"Sloth, Christoffer"'

1. Minimizing Conservatism in Safety-Critical Control for Input-Delayed Systems via Adaptive Delay Estimation

Author

Kim, Yitaek, Das, Ersin, Kim, Jeeseop, Ames, Aaron D., Burdick, Joel W., and Sloth, Christoffer

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Input delays affect systems such as teleoperation and wirelessly autonomous connected vehicles, and may lead to safety violations. One promising way to ensure safety in the presence of delay is to employ control barrier functions (CBFs), and extensions thereof that account for uncertainty: delay adaptive CBFs (DaCBFs). This paper proposes an online adaptive safety control framework for reducing the conservatism of DaCBFs. The main idea is to reduce the maximum delay estimation error bound so that the state prediction error bound is monotonically non-increasing. To this end, we first leverage the estimation error bound of a disturbance observer to bound the state prediction error. Second, we design two nonlinear programs to update the maximum delay estimation error bound satisfying the prediction error bound, and subsequently update the maximum state prediction error bound used in DaCBFs. The proposed method ensures the maximum state prediction error bound is monotonically non-increasing, yielding less conservatism in DaCBFs. We verify the proposed method in an automated connected truck application, showing that the proposed method reduces the conservatism of DaCBFs., Comment: This paper has been submitted to ECC 2025 for possible publication

Published
2024

2. Robust Adaptive Safe Robotic Grasping with Tactile Sensing

Author

Kim, Yitaek, Kim, Jeeseop, Li, Albert H., Ames, Aaron D., and Sloth, Christoffer

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

Robotic grasping requires safe force interaction to prevent a grasped object from being damaged or slipping out of the hand. In this vein, this paper proposes an integrated framework for grasping with formal safety guarantees based on Control Barrier Functions. We first design contact force and force closure constraints, which are enforced by a safety filter to accomplish safe grasping with finger force control. For sensory feedback, we develop a technique to estimate contact point, force, and torque from tactile sensors at each finger. We verify the framework with various safety filters in a numerical simulation under a two-finger grasping scenario. We then experimentally validate the framework by grasping multiple objects, including fragile lab glassware, in a real robotic setup, showing that safe grasping can be successfully achieved in the real world. We evaluate the performance of each safety filter in the context of safety violation and conservatism, and find that disturbance observer-based control barrier functions provide superior performance for safety guarantees with minimum conservatism. The demonstration video is available at https://youtu.be/Cuj47mkXRdg.

Published
2024

3. Towards Measuring the Ease of Robotic Disassembly

Author

Sloth, Christoffer, Iturrate, Iñigo, 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, Secchi, Cristian, editor, and Marconi, Lorenzo, editor

Published
2024
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4. Fast robust peg-in-hole insertion with continuous visual servoing

Author

Haugaard, Rasmus Laurvig, Langaa, Jeppe, Sloth, Christoffer, and Buch, Anders Glent

Subjects
Computer Science - Robotics
Abstract

This paper demonstrates a visual servoing method which is robust towards uncertainties related to system calibration and grasping, while significantly reducing the peg-in-hole time compared to classical methods and recent attempts based on deep learning. The proposed visual servoing method is based on peg and hole point estimates from a deep neural network in a multi-cam setup, where the model is trained on purely synthetic data. Empirical results show that the learnt model generalizes to the real world, allowing for higher success rates and lower cycle times than existing approaches.

Published
2020

5. In-Hand Pose Refinement Based on Contact Point Information

Author

Iturrate, Iñigo, Kim, Yitaek, Kramberger, Aljaz, Sloth, Christoffer, Ceccarelli, Marco, Series Editor, Agrawal, Sunil K., Advisory Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Petrič, Tadej, editor, Ude, Aleš, editor, and Žlajpah, Leon, editor

Published
2023
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7. Nonnegative Polynomial with no Certificate of Nonnegativity in the Simplicial Bernstein Basis

Author

Sloth, Christoffer

Subjects
Mathematics - Numerical Analysis, Computer Science - Systems and Control
Abstract

This paper presents a nonnegative polynomial that cannot be represented with nonnegative coefficients in the simplicial Bernstein basis by subdividing the standard simplex. The example shows that Bernstein Theorem cannot be extended to certificates of nonnegativity for polynomials with zeros at isolated points.

Published
2017

9. Completeness of Lyapunov Abstraction

Author

Wisniewski, Rafael and Sloth, Christoffer

Subjects
Computer Science - Systems and Control
Abstract

In this work, we continue our study on discrete abstractions of dynamical systems. To this end, we use a family of partitioning functions to generate an abstraction. The intersection of sub-level sets of the partitioning functions defines cells, which are regarded as discrete objects. The union of cells makes up the state space of the dynamical systems. Our construction gives rise to a combinatorial object - a timed automaton. We examine sound and complete abstractions. An abstraction is said to be sound when the flow of the time automata covers the flow lines of the dynamical systems. If the dynamics of the dynamical system and the time automaton are equivalent, the abstraction is complete. The commonly accepted paradigm for partitioning functions is that they ought to be transversal to the studied vector field. We show that there is no complete partitioning with transversal functions, even for particular dynamical systems whose critical sets are isolated critical points. Therefore, we allow the directional derivative along the vector field to be non-positive in this work. This considerably complicates the abstraction technique. For understanding dynamical systems, it is vital to study stable and unstable manifolds and their intersections. These objects appear naturally in this work. Indeed, we show that for an abstraction to be complete, the set of critical points of an abstraction function shall contain either the stable or unstable manifold of the dynamical system., Comment: In Proceedings HAS 2013, arXiv:1308.4904

Published
2013
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10. Timed Game Abstraction of Control Systems

Author

Sloth, Christoffer and Wisniewski, Rafael

Subjects
Computer Science - Systems and Control
Abstract

This paper proposes a method for abstracting control systems by timed game automata, and is aimed at obtaining automatic controller synthesis. The proposed abstraction is based on partitioning the state space of a control system using positive and negative invariant sets, generated by Lyapunov functions. This partitioning ensures that the vector field of the control system is transversal to the facets of the cells, which induces some desirable properties of the abstraction. To allow a rich class of control systems to be abstracted, the update maps of the timed game automaton are extended. Conditions on the partitioning of the state space and the control are set up to obtain sound abstractions. Finally, an example is provided to demonstrate the method applied to a control problem related to navigation.

Published
2010

11. Proofs for an Abstraction of Continuous Dynamical Systems Utilizing Lyapunov Functions

Author

Sloth, Christoffer and Wisniewski, Rafael

Subjects
Computer Science - Systems and Control
Abstract

In this report proofs are presented for a method for abstracting continuous dynamical systems by timed automata. The method is based on partitioning the state space of dynamical systems with invariant sets, which form cells representing locations of the timed automata. To enable verification of the dynamical system based on the abstraction, conditions for obtaining sound, complete, and refinable abstractions are set up. It is proposed to partition the state space utilizing sub-level sets of Lyapunov functions, since they are positive invariant sets. The existence of sound abstractions for Morse-Smale systems and complete and refinable abstractions for linear systems are proved.

Published
2010

24. Dynamics Modeling of Robot Joints with Asymmetric Load-Dependent Friction⁎⁎This work was supported by Innovation Fund Denmark [ref no. 1044-00187B] and Universal Robots A/S.

Author

Graabæk, Søren, Poulsen, Niels K., and Sloth, Christoffer

Abstract

This paper presents a strain wave gear model intended for industrial robots that are operated in both forward drive and backward drive under different load conditions. We show that a simple joint model captures the joint dynamics well at one load, but fails to capture the joint dynamics when the load is changed. Similarly, the simple model cannot capture the efficiency of the joint in both forward drive and backward drive. We propose a tooth model with sliding friction to resolve these issues. This model is simple to simulate and can thus be used for real-time control; the proposed model captures the load dependent friction and difference in efficiency in backward drive and forward drive. We validate the simulation performance of the tooth models on data from a Universal Robots UR10e robot with different payloads which shows an improvement compared to the standard rigid joint model.

Published
2024
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39. Towards Reversible Dynamic Movement Primitives

Author

Iturrate, Inigo, primary, Sloth, Christoffer, additional, Kramberger, Aljaz, additional, Petersen, Henrik Gordon, additional, Ostergaard, Esben Hallundbak, additional, and Savarimuthu, Thiusius Rajeeth, additional

Published
2019
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40. Towards easy setup of robotic assembly tasks.

Author

Sloth, Christoffer, Kramberger, Aljaž, and Iturrate, Iñigo

Subjects
*ROBOTIC assembly, *FLEXIBLE manufacturing systems, *SURGICAL robots, *MEDICAL robotics, *TASKS, *ROBOTS
Abstract

There is a growing need for adaptive robotic assembly systems that are fast to setup and reprogram when new products are introduced. The World Robot Challenge at World Robot Summit 2018 was centered around the challenge of setting up a flexible robotic assembly system aiming at changeover times below 1 day. This paper presents a method for programming robotic assembly tasks that was initiated in connection with the World Robot Challenge that enables fast and easy setup of robotic insertion tasks. We propose to program assembly tasks by demonstration, but instead of using the taught behavior directly, the demonstration is merged with assembly primitives to increase robustness. In contrast to other programming by demonstration approaches, we perform not only one demonstration but a sequence of four sub-demonstrations that are used to extract the desired robot trajectory in addition to parameters for the assembly primitive. The proposed assembly strategy is compared to a standard dynamic movement primitive and experiments show that the proposed assembly strategy increases the robustness towards pose uncertainties and significantly reduces the applied forces during the execution of the assembly task. [ABSTRACT FROM AUTHOR]

Published
2020
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42. Towards synthesis of polynomial controllers - a multi-affine approach

Author

Ribard, Nicolas, Wisniewski, Rafael, and Sloth, Christoffer

Subjects
TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY, ComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATION
Abstract

In the paper, we strive to develop an algorithm that simultaneously computes a polynomial control and a polynomial Lyapunov function. This ensures asymptotic stability of the designed feedback system. The above problem is translated to a certificate of positivity. To this end, we use the representation of the given control system in Bernstein basis. Subsequently, the control synthesis problem is reduced to finite number of evaluations of a polynomial on vertices of cubes in the space of parameters representing admissible controls and Lyapunov functions.

Published
2016

44. Towards Safe Robotic Surgical Systems

Author

Sloth, Christoffer and Wisniewski, Rafael

Abstract

A proof of safety is paramount for an autonomous robotic surgical system to ensure that it does not cause trauma to patients. However, a proof of safety is rarely constructed, as surgical systems are too complex to be dealt with by most formal verification methods. In this paper, we design a controller for motion compensation in beating-heart surgery, and prove that it is safe, i.e., the surgical tool is kept within an allowable distance and orientation of the heart. We solve the problem by simultaneously finding a control law and a barrier function. The motion compensation system is simulated from several initial conditions to demonstrate that the designed control system is safe for every admissible initial condition.

Published
2015
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45. p-Safe Analysis of Stochastic Hybrid Processes.

Author

Wisniewski, Rafael, Bujorianu, Manuela L., and Sloth, Christoffer

Subjects
STOCHASTIC analysis, STOCHASTIC processes, MARKOV processes, STOCHASTIC systems, MOMENTS method (Statistics), POISSON processes, MARTINGALES (Mathematics)
Abstract

We develop a method for determining whether a stochastic system is safe, i.e., whether its trajectories reach unsafe states. Specifically, we define and solve a probabilistic safety problem for Markov processes. Based on the knowledge of the extended generator, we are able to develop an evolution equation, as a system of integral equations, describing the connection between unsafe and initial states. Subsequently, using the moment method, we approximate the infinite-dimensional optimization problem searching for the largest set of safe states by a finite-dimensional polynomial optimization problem. In particular, we address the above safety problem to a special class of stochastic hybrid processes, namely piecewise-deterministic Markov processes. These are characterized by deterministic dynamics and stochastic jumps, where both the time and the destination of the jumps are stochastic. In addition, the jumps can be both spontaneous (in the style of a Poisson process) and forced (governed by guards). In this case, the extended generator of this process and its corresponding martingale problem turn out to be defined on a rather restricted domain. To circumvent this difficulty, we bring the generalized differential formula of this process into the evolution equation and, subsequently, formulate a polynomial optimization. [ABSTRACT FROM AUTHOR]

Published
2020
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