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30 results on '"Kiss, Adam K."'

1. Control Barrier Functionals: Safety-critical Control for Time Delay Systems

Author

Kiss, Adam K., Molnar, Tamas G., Ames, Aaron D., and Orosz, Gabor

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

This work presents a theoretical framework for the safety-critical control of time delay systems. The theory of control barrier functions, that provides formal safety guarantees for delay-free systems, is extended to systems with state delay. The notion of control barrier functionals is introduced to attain formal safety guarantees, by enforcing the forward invariance of safe sets defined in the infinite dimensional state space. The proposed framework is able to handle multiple delays and distributed delays both in the dynamics and in the safety condition, and provides an affine constraint on the control input that yields provable safety. This constraint can be incorporated into optimization problems to synthesize pointwise optimal and provable safe controllers. The applicability of the proposed method is demonstrated by numerical simulation examples., Comment: Submitted to the International Journal of Robust and Nonlinear Control (JRNC). 25 pages, 3 figures

Published
2022

2. Input-to-State Safety with Input Delay in Longitudinal Vehicle Control

Author

Molnar, Tamas G., Alan, Anil, Kiss, Adam K., Ames, Aaron D., and Orosz, Gabor

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

Safe longitudinal control is discussed for a connected automated truck traveling behind a preceding connected vehicle. A controller is proposed based on control barrier function theory and predictor feedback for provably safe, collision-free behavior by taking into account the significant response time of the truck as input delay and the uncertainty of its dynamical model as input disturbance. The benefits of the proposed controller compared to control designs that neglect the delay or treat the delay as disturbance are shown by numerical simulations., Comment: Accepted to the 17th IFAC Workshop on Time Delay Systems. 6 pages, 3 figures

Published
2022

3. Safety-Critical Control with Input Delay in Dynamic Environment

Author

Molnar, Tamas G., Kiss, Adam K., Ames, Aaron D., and Orosz, Gábor

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

Endowing nonlinear systems with safe behavior is increasingly important in modern control. This task is particularly challenging for real-life control systems that must operate safely in dynamically changing environments. This paper develops a framework for safety-critical control in dynamic environments, by establishing the notion of environmental control barrier functions (ECBFs). The framework is able to guarantee safety even in the presence of input delay, by accounting for the evolution of the environment during the delayed response of the system. The underlying control synthesis relies on predicting the future state of the system and the environment over the delay interval, with robust safety guarantees against prediction errors. The efficacy of the proposed method is demonstrated by a simple adaptive cruise control problem and a more complex robotics application on a Segway platform., Comment: Accepted to the IEEE Transactions on Control Systems Technology (TCST). 14 pages, 7 figures

Published
2021

14. Control barrier functionals: Safety‐critical control for time delay systems

Author

Kiss, Adam K., Molnár, Tamás G., Ames, Aaron D., Orosz, Gábor, Kiss, Adam K., Molnár, Tamás G., Ames, Aaron D., and Orosz, Gábor

Abstract

This work presents a theoretical framework for the safety-critical control of time delay systems. The theory of control barrier functions, that provides formal safety guarantees for delay-free systems, is extended to systems with state delay. The notion of control barrier functionals is introduced, to attain formal safety guarantees by enforcing the forward invariance of safe sets defined in the infinite dimensional state space. The proposed framework is able to handle multiple delays and distributed delays both in the dynamics and in the safety condition, and provides an affine constraint on the control input that yields provable safety. This constraint can be incorporated into optimization problems to synthesize pointwise optimal and provable safe controllers. The applicability of the proposed method is demonstrated by numerical simulation examples.

Published
2023

17. Safety-Critical Control With Input Delay in Dynamic Environment

Author

Molnár, Tamás G., Kiss, Adam K., Ames, Aaron D., Orosz, Gábor, Molnár, Tamás G., Kiss, Adam K., Ames, Aaron D., and Orosz, Gábor

Abstract

Endowing nonlinear systems with safe behavior is increasingly important in modern control. This task is particularly challenging for real-life control systems that operate in dynamically changing environments. This article develops a framework for safety-critical control in dynamic environments, by establishing the notion of environmental control barrier functions (ECBFs). Importantly, the framework is able to guarantee safety even in the presence of input delay, by accounting for the evolution of the environment during the delayed response of the system. The underlying control synthesis relies on predicting the future state of the system and the environment over the delay interval, with robust safety guarantees against prediction errors. The efficacy of the proposed method is demonstrated by a simple adaptive cruise control (ACC) problem and a more complex robotics application on a Segway platform.

Published
2022

19. Certifying Safety for Nonlinear Time Delay Systems via Safety Functionals: A Discretization Based Approach

Author

Kiss, Adam K., Molnár, Tamás G., Bachrathy, Dániel, Ames, Aaron D., Orosz, Gábor, Kiss, Adam K., Molnár, Tamás G., Bachrathy, Dániel, Ames, Aaron D., and Orosz, Gábor

Abstract

In this paper, we consider the safety of continuous time control systems with input delays. Safety functionals are constructed that define safety sets in the infinite-dimensional state space. Time-discretization is used in order to compute safety sets in finite dimensions and it is shown that these sets approach an infinite-dimensional safety set as the time step is decreased. A simple example of a nonlinear scalar system is used to demonstrate the convergence of the proposed methods.

Published
2021

24. DYNAMIC CHARACTERIZATION OF MILLING BASED ON INTERRUPTED FEED MOTION.

Author

Kiss, Adam K. and Bachrathy, D.

Subjects
MACHINE tools, EXTRAPOLATION, MACHINING, FORECASTING
Abstract

This study presents an experimental method for detecting and avoiding chatter vibrations that occur during general milling processes. The main idea is to capture the so-called dominant spectral properties from the transient vibrations of the milling process, which gives a good approximation for its dynamical behavior and provides a quantitative measure of stability. To induce transient vibration, the machining process is momentarily interrupted. Therefore, the method offers the possibility that the stability limit can be forecasted by extrapolation from stable and accurate measurement points without reaching harmful vibration on the machine tool. We present laboratory tests with momentary interrupted straight tool path to demonstrate the applicability of the proposed method. [ABSTRACT FROM AUTHOR]

Published
2021
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26. Effects of Varying Dynamics of Flexible Workpieces in Milling Operations.

Author

Kiss, Adam K., Bachrathy, Daniel, and Stepan, Gabor

Subjects
*WORKPIECES, *FINITE element method, *COORDINATE transformations, *ANALYTICAL solutions, *TRANSFER functions
Abstract

In this study, surface error calculations and stability conditions are presented for milling operations in case of slender parts. The dynamic behavior of the flexible beam-type workpiece is modeled by means of finite element method (FEM), while the varying dynamical properties related to the feed motion as well as the material removal process are incorporated in the model. The FEM-generated direct frequency response function is verified through a closed-form solution based on the distributed transfer function method. Relative errors and convergence of the FEM are investigated based on the analytical solutions of the continuum model, from which appropriate element size and mode number can be selected for modal coordinate transformations. The pattern in the variation of the natural frequencies is explored using the analytical model in case of high radial depth of cut relative to the original cross section of the beam-like workpiece. Both the stability conditions and the resulted surface errors are predicted as a function of the tool position. The presented approach and the results are validated by laboratory tests. [ABSTRACT FROM AUTHOR]

Published
2020
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