Showing total 5 results

1. Beyond decentralized wafer/reticle stage control design: A double-Youla approach for enhancing synchronized motion.

Author

Evers, Enzo, van de Wal, Marc, and Oomen, Tom

Subjects

*PARAMETERIZATION, *COUPLINGS (Gearing), *SCANNING systems, *ROBUST control, *ELECTRIC controllers

Abstract

Abstract Industrial wafer scanners often consists of multiple subsystems. Traditionally, these systems-of-systems are divided into manageable subproblems at the expense of the overall performance, that is determined by the synchronicity of the motions of the subsystems. The aim of this paper is to enhance overall system performance by posterior coupling of the controlled subsystems. A framework that relates to the Youla parameterization is developed that connects the additional control elements affinely to the overall system performance criterion. The resulting framework parametrizes all stabilizing bidirectional coupling controllers, and enables improved performance. Robust stability is subsequentially addressed through a double-Youla approach. Application to a wafer scanner confirms superior performance of the joint wafer stage and reticle stage performance, while maintaining full system robust stability. Highlights • An industrial case study on a state-of-the-art waferscanner application. • Improving overall system-of-systems performance by coupling sub-systems. • A double Youla parameterization, facilitating systematic coupling controller design. • Guaranteed stability for a bidirectionally coupled system. [ABSTRACT FROM AUTHOR]

Published

2019

2. Robust control of unmanned helicopters with high-order mismatched disturbances via disturbance-compensation-gain construction approach.

Author

Fang, Xing, Liu, Fei, and Ding, Zhengtao

Subjects

*HELICOPTERS, *ROBUST control, *FINITE element method, *COUPLINGS (Gearing), *ENGINEERING

Abstract

Abstract In this paper, a novel robust control strategy based on disturbance-compensation-gain (DCG) construction approach is proposed for small-scale unmanned helicopters in the presence of high-order mismatched disturbances. The overall control structure consists of two hierarchical layers. The inner-loop controller is to guarantee the stability of the unmanned helicopters subject to high-order mismatched disturbances. With the estimation of the disturbances and their successive derivatives via finite-time disturbance observer (FTDO), by properly designing some disturbance compensation gains, a novel robust controller is developed to remove the high-order mismatched disturbances from the output channels. The outer-loop controller is to produce flight commands for inner-loop system, as well as to track the reference trajectory, which is carried out with the dynamic inversion technique. The simulation results demonstrate that the unmanned helicopters are capable to perform flight missions autonomously with the proposed control strategy. [ABSTRACT FROM AUTHOR]

Published

2018

3. Distributed control of cluster lag consensus for first-order multi-agent systems on QUAD vector fields.

Author

Wang, Yi, Ma, Zhongjun, and Chen, Guanrong

Subjects

*MULTIAGENT systems, *ROBOTICS, *TOPOLOGY, *ROBUST control, *COUPLINGS (Gearing)

Abstract

Abstract This paper addresses the problem of cluster lag consensus for first-order multi-agent systems which can be formulated as moving agents in a capacity-limited network. A distributed control protocol is developed based on local information, and the robustness of the protocol is analyzed by using tools of Frobenius norm, Lyapunov functional and matrix theory. It is shown that when the root agents of the clusters are influenced by the active leader and the intra-coupling among agents is stronger enough, the multi-agent system will reach cluster lag consensus. Moreover, cluster lag consensus for multi-agent systems with a time-varying communication topology and heterogeneous multi-agent systems with a directed topology are studied. Finally, the effectiveness of the proposed protocol is demonstrated by some numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2018

4. Finite-horizon state estimation for time-varying complex networks with random coupling strengths under Round-Robin protocol.

Author

Niu, Yichun, Sheng, Li, Zou, Lei, Liu, Yurong, and Alsaadi, Fuad E.

Subjects

*COUPLINGS (Gearing), *ENGINEERING, *ROBUST control, *TELECOMMUNICATION systems, *ELECTRIC lines

Abstract

Abstract In this paper, the problem of finite-horizon H ∞ state estimation is investigated for a class of discrete time-varying complex networks with multiplicative noises and random coupling strengths. The network nodes and estimators are connected via a constrained communication network which allows only one node to send measurement data at each transmission instant. The Round-Robin protocol is introduced to determine which node obtains the access to the network at certain transmission instant. The aim of the addressed problem is to design a set of time-varying estimator parameters such that the prescribed H ∞ performance is guaranteed over a finite horizon. By using the stochastic analysis approach and completing-the-square method, sufficient conditions are derived for the existence of the desired estimators in terms of the solution to backward recursive Riccati difference equations. Finally, a numerical example is provided to validate the feasibility and effectiveness of the proposed results. [ABSTRACT FROM AUTHOR]

Published

2018

5. Predicting mobile machine tool dynamics by experimental dynamic substructuring.

Author

Law, Mohit, Rentzsch, Hendrik, and Ihlenfeldt, Steffen

Subjects

*MACHINE tools, *SUBSTRUCTURING techniques, *FREQUENCY response, *COUPLINGS (Gearing), *ROBUST control

Abstract

Predicting mobile machine tool dynamics prior to moving the machine to a new part and/or location is essential to guide first-time-right in situ machining solutions. This paper considers such a priori prediction of assembled dynamics under varying base/part/contact characteristics by applying dynamic substructuring procedures. Assembled dynamics are predicted by substructural coupling of the machine's known free-free response with the known response of any base/part measured at location. Since obtaining the machine's free-free response remains non-trivial, we instead extract the machine's dynamics using substructure decoupling procedures. Substructuring is carried out using measured frequency response functions. Methods are tested for robustness, and are experimentally validated. [ABSTRACT FROM AUTHOR]

Published

2016