Your search keyword '"LINEAR systems"' showing total 16 results

1. L 2 -L∞ Filter Design With Adjustable Convergence Rate for Linear Stochastic Systems.

Author

Zhang, Huasheng, Xia, Jianwei, Park, Ju H., Shen, Hao, and Chen, Jun

Subjects

*KALMAN filtering, *LINEAR systems, *TIME-varying systems, *STOCHASTIC systems, *SYMMETRIC matrices, *STOCHASTIC processes, *STABILITY criterion

Abstract

The $\mathcal {L}_{2}-\mathcal {L}_{\infty }$ filter design for linear stochastic time-varying delay systems based on the filter velocity constraint is considered in this dissertation. Different from existing $\mathcal {L}_{2}\,-\,\mathcal {L}_{\infty }$ performance analysis and filter design, a new criterion is proposed to make a more accurate judgment, which can not only guarantee the stability of the filtering error system with $\mathcal {L}_{2}-\mathcal {L}_{\infty }$ performance level but also can estimate the convergence speed of the filter. The ideal filter should has the same convergence speed as the original system, so as to ensure the rapid convergence of the error system, but also not to reduce the anti-interference ability and increase the bandwidth of the filter system. By the new filter design method, an ideal filter can be designed, which can regulate the convergence speed of the filter system to the desired effect. A simulation instance is provided to exhibit the validity of the new approach. [ABSTRACT FROM AUTHOR]

Published

2022

2. Constrained Iterative Learning Control for Linear Time-Varying Systems With Experimental Validation on a High-Speed Rack Feeder.

Author

Chu, Bing, Rauh, Andreas, Aschemann, Harald, Rogers, Eric, and Owens, David H.

Subjects

LINEAR control systems, ITERATIVE learning control, TIME-varying systems, LINEAR systems, FLEXIBLE structures

Abstract

Iterative learning control (ILC) applies to systems required to track the desired trajectory of finite duration repeatedly. This article considers constrained ILC design for linear time-varying systems, a problem with limited, in relative terms, results in the literature but not uncommon in practical applications. Different design algorithms are developed, and their convergence properties are established. An extension of these designs to point-to-point tracking tasks is given. A high-speed rack feeder typically used in automated warehouses is considered to verify the designs. It represents a flexible beam structure subject to kinematic constraints, such as a maximum velocity and a maximum acceleration with a vertically moving mass causing the time-varying characteristics. Experimental results demonstrate the effectiveness of the designs. [ABSTRACT FROM AUTHOR]

Published

2022

3. Noisy-Output-Based Direct Learning Tracking Control With Markov Nonuniform Trial Lengths Using Adaptive Gains.

Author

Shen, Dong and Saab, Samer S.

Subjects

*ITERATIVE learning control, *STOCHASTIC systems, *MARKOV processes, *LINEAR systems, *MACHINE learning

Abstract

In this article, a noisy-output-based direct learning tracking control is proposed for stochastic linear systems with nonuniform trial lengths. The iteration-varying trial length is modeled using a Markov chain for demonstration of the iteration dependence. The effect of the noisy output is asymptotically eliminated using a prior given decreasing gain sequence in the learning algorithm. Two alternative adaptive gains are presented for improving the tracking performance and the convergence speed. Both the mean-square and almost-sure convergence are provided. Numerical simulations on a four-degree-of-freedom robot arm are presented to illustrate the effectiveness of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2022

4. Finite-Time State Observer for a Class of Linear Time-Varying Systems With Unknown Inputs.

Author

Davila, Jorge, Tranninger, Markus, and Fridman, Leonid

Subjects

*TIME-varying systems, *LINEAR systems, *LINEAR operators

Abstract

A finite-time observer for a class of linear time-varying systems with bounded unknown inputs is presented in this note. The design of the observer exploits structural properties of the system and, through a linear operator, allows applying the robust exact differentiator in a block form without requiring additional stabilizing terms. The proposed observer provides an exact estimate of the states after a finite transient time despite the possible instability of the system and the effects of bounded unknown inputs. [ABSTRACT FROM AUTHOR]

Published

2022

5. Multivariable Nonadaptive Controller Design.

Author

Said Saab, Samer, Hauser, Michael, Ray, Asok, and Saab, Samer Said

Subjects

*TIME-varying systems, *LINEAR systems, *CLOSED loop systems, *SYSTEM dynamics, *INFORMATION modeling, *SELF-tuning controllers

Abstract

Although proportional-integral-derivative control remains one of the most common control schemes used in industry, its tuning still remains inadequately understood in many applications. This task becomes much more challenging when applied to multi-input multi-output (MIMO) systems. This article presents the design of a discrete-time robust multivariable (nonadaptive) tracking controller that comes with a simple structure, requires very limited information on the plant model, and is relatively easy to tune. In addition to being easy to tune and implement, an objective of this controller is to deal with a class of large-scale systems with complex dynamics. We analytically demonstrate the robustness and convergence of the closed-loop system for a class of MIMO linear time-varying systems. The overall superiority of the proposed controller is experimentally validated on a Barrett robot arm in a laboratory environment. The article also provides a stochastic framework of the general setting of the controller. Within this framework, two minimum mean square error optimal solutions of the controller are provided; one is designed for the case where the number of inputs is not greater than the number of outputs, and the other is for the antithesis. [ABSTRACT FROM AUTHOR]

Published

2021

6. On Necessary and Sufficient Conditions for Exponential Consensus in Dynamic Networks via Uniform Complete Observability Theory.

Author

Ma, Qichao, Qin, Jiahu, Yu, Xinghuo, and Wang, Long

Subjects

*LINEAR systems, *FUNCTIONAL analysis, *LINEAR statistical models, *SYMMETRIC matrices, *TIME-varying systems, *PSYCHOLOGICAL feedback

Abstract

In this article, we deal with the consensus problem of multiple partial-state coupled linear systems, which are neutrally stable. These systems communicate over dynamic undirected networks, which change continuously and can be disconnected at any time. We develop an analysis framework from uniform complete observability theory to work out the necessary and sufficient conditions for exponential consensus. It turns out that, with a suitably designed feedback matrix, exponential consensus can be realized globally and uniformly if and only if a jointly $(\delta,T)$ -connected condition and an observability condition relying only on system and input matrices are satisfied. A lower bound of the convergence rate is also provided. We figure out the proof by applying matrix analysis and linear functional analysis. A simulation example is presented to illustrate our theoretical findings. [ABSTRACT FROM AUTHOR]

Published

2021

7. Co-Design of Finite-Time Convergence and Noise Suppression: A Unified Neural Model for Time Varying Linear Equations With Robotic Applications.

Author

Xiao, Lin, Li, Shuai, Li, Kenli, Jin, Long, and Liao, Bolin

Subjects

*LINEAR equations, *GLOBAL analysis (Mathematics), *MATHEMATICAL decoupling, *RECURRENT neural networks, *LINEAR systems, *NOISE, *ROBOTICS

Abstract

Computing time-varying linear systems is widely encountered in engineering practice and scientific computation. Dynamic neural networks, as a class of modeling approaches, have been intensively explored in recent decades for solving linear equations. The time-varying nature of this problem and the noisy workspace for many engineering practice require two features of practical design: 1) fast convergence in time and 2) robustness against noises and disturbance. Existing solutions usually decouple the problem into two steps by designing a fast-convergent neural controller and then topped with an additional low-pass filter to reach noise robustness. However, due to the interplay of the mentioned two dynamical parts, the overall system may lose stability if the parameters are not well tuned. In this paper, we establish the first dynamical neural model for simultaneously achieving fast-convergence, particularly finite-time convergence, and noise-robustness, with the capability to reject the unknown noise when it is constant or varies slowly. To do so, a superior design formula activated by noise-tolerant nonlinear functions is proposed to enhance the capability of zeroing neural networks (ZNNs), achieving denoising and finite-time convergence in a unified design. According to this design formula, a novel recurrent neural network (RNN) with finite-time convergence and inherently noise-suppression performance [thus termed the finite-time robust RNN (FTRRNN)] is developed and applied to robotic motion tracking illustrated via time-varying linear equation system solving. Furthermore, theoretical analyses on the global stability, the finite-time convergence and the denoising ability of the proposed design formula and the corresponding FTRRNN model are presented in details. The upper bound on the convergence time is also analytically derived. A numerical example is supplied to verify the superior property of the FTRRNN model to the ZNN model according to the results of computing time-varying linear equation system in the presence of additive noises. Finally, an application to robotic motion tracking is presented to show that the presented FTRRNN model can successfully realize the ellipse-path tracking control of a planar two-link manipulator in front of the external disturbances, while the conventional ZNN model fails under the same conditions. [ABSTRACT FROM AUTHOR]

Published

2020

8. New Discrete-Time Models of Zeroing Neural Network Solving Systems of Time-Variant Linear and Nonlinear Inequalities.

Author

Shi, Yang and Zhang, Yunong

Subjects

*TIME-varying systems, *LINEAR systems, *ARTIFICIAL neural networks, *DISCRETE systems, *NUMERICAL differentiation

Abstract

In this paper, a new one-step-ahead numerical differentiation rule termed 5-instant discretization formula is proposed for the first-order derivative approximation with higher computational precision. Then, by exploiting the proposed formula to discretize the continuous-time zeroing neural network [or termed, continuous-time Zhang neural network (ZNN)] models, two new discrete-time zeroing neural network [or termed, discrete-time ZNN (DTZNN)] models are proposed, analyzed and investigated for solving systems of discrete time-variant inequalities, including the system of discrete time-variant linear inequalities and the system of discrete time-variant nonlinear inequalities. For comparative purposes, the recently developed Taylor-type DTZNN models and the widely used Euler-type DTZNN models are also presented. Theoretical analyses show that the proposed DTZNN models are convergent, and their steady-state residual errors have an $O(g^{4})$ pattern with $g$ denoting the sampling gap. Comparative numerical experimental results further substantiate the efficacy and superiority of the proposed DTZNN models for solving the systems of discrete time-variant inequalities. [ABSTRACT FROM AUTHOR]

Published

2020

9. Varying-Parameter Convergent-Differential Neural Solution to Time-Varying Overdetermined System of Linear Equations.

Author

Zhang, Zhijun, Zheng, Lunan, Qiu, Tairu, and Deng, Feiqi

Subjects

*LINEAR systems, *TIME-varying systems, *LINEAR equations, *RECURRENT neural networks, *SYSTEM identification

Abstract

To solve a time-varying overdetermined problem, a novel varying-parameter convergent-differential neural network (VP-CDNN) is proposed, designed, and discussed. Specifically, a vector-error function is first defined. Second, according to neural dynamic design method, an implicit-dynamic equation with a time-varying parameter is derived. Mathematics analysis and theoretical proof verify that the VP-CDNN can obtain the least-squares solution with a super exponential convergence rate. In addition, it is also proved that VP-CDNN can restrain the noise efficiently. Simulations among the VP-CDNN, gradient-based recurrent neural network and zeroing neural network verify that the VP-CDNN has faster speed, higher accuracy, and stronger robustness. At last, applications to data fitting and system identification further verify the high effectiveness and efficiency of the VP-CDNN. [ABSTRACT FROM AUTHOR]

Published

2020

10. Prescribed-Time Observers for Linear Systems in Observer Canonical Form.

Author

Holloway, John and Krstic, Miroslav

Subjects

*TIME-varying systems, *STABILITY criterion

Abstract

For linear systems in the observer canonical form, we introduce a state observer with time-varying gains that tend to infinity as time approaches a prescribed convergence time. The observer is shown to exhibit fixed-time stability with an arbitrary convergence time, which is prescribed by the user irrespective of initial conditions. The output estimation error injection terms are also shown to remain uniformly bounded and converge to zero at the prescribed time. [ABSTRACT FROM AUTHOR]

Published

2019

11. Linear Stochastic Approximation Algorithms and Group Consensus Over Random Signed Networks.

Author

Chen, Ge, Duan, Xiaoming, Mei, Wenjun, and Bullo, Francesco

Subjects

*STOCHASTIC convergence, *NUMERICAL analysis, *MULTIAGENT systems, *ALGORITHMS, *LINEAR algebra

Abstract

This paper studies linear stochastic approximation (SA) algorithms and their application to multiagent systems in engineering and sociology. As main contribution, we provide necessary and sufficient conditions for convergence of linear SA algorithms to a deterministic or random final vector. We also characterize the system convergence rate, when the system is convergent. Moreover, differing from non-negative gain functions in traditional SA algorithms, this paper considers also the case when the gain functions are allowed to take arbitrary real numbers. Using our general treatment, we provide necessary and sufficient conditions to reach consensus and group consensus for first-order discrete-time multiagent system over random signed networks and with state-dependent noise. Finally, we extend our results to the setting of multidimensional linear SA algorithms and characterize the behavior of the multidimensional Friedkin–Johnsen model over random interaction networks. [ABSTRACT FROM AUTHOR]

Published

2019

12. Necessary and Sufficient Conditions for Assignability of the Lyapunov Spectrum of Discrete Linear Time-Varying Systems.

Author

Babiarz, Artur, Banshchikova, Irina, Czornik, Adam, Makarov, Evgenii K., Niezabitowski, Michal, and Popova, Svetlana

Subjects

*LYAPUNOV exponents, *DISCRETE-time systems, *FEEDBACK control systems, *POLE assignment, *CLOSED loop systems

Abstract

We consider a version of the pole assignment problem for linear discrete time-varying systems with linear state feedback. Our aim is to prove that all the systems from the closure (in the topology of pointwise convergence) of all shifts of the original system have an assignable Lyapunov spectrum if and only if the original system is uniformly completely controllable. We also provide an example to show that uniform complete controllability is not a necessary condition for assignability of the Lyapunov spectrum of the original system. [ABSTRACT FROM AUTHOR]

Published

2018

13. A Class of Adaptive Extended State Observers for Nonlinear Disturbed Systems.

Author

Pu, Zhiqiang, Yuan, Ruyi, Yi, Jianqiang, and Tan, Xiangmin

Subjects

*DYNAMICS, *EIGENVALUE equations, *EIGENVALUES, *NONLINEAR analysis, *CANONICAL transformations

Abstract

This paper proposes a novel class of adaptive extended state observers (AESOs) that significantly expand the applications of extended state observers (ESOs) to nonlinear disturbed systems. An AESO is designed as a linear time-varying form that, as a result, combines both the advantages of theoretical completeness in a conventional linear ESO (LESO) and good practical performance in a conventional nonlinear ESO (NESO). To tune the time-varying observer gains, AESO error dynamics is first transformed into a canonical (phase-variable) form. Then, time-varying PD-eigenvalues are assigned for the canonical system based on differential algebraic spectral theory. Theorems for stability and estimate error bounds of the AESO are given in the presence of unknown disturbances. These theorems also offer some important guidelines for assigning the PD-eigenvalues. To demonstrate the effectiveness of this new observer, two representative applications, including a numerical single-input–single-output example and a practical multiple-input–multiple-output hypersonic vehicle application, are exemplified, and comparison simulations are conducted among AESO, LESO, and NESO. Future work is pointed out in the end. [ABSTRACT FROM PUBLISHER]

Published

2015

14. Homogeneity Based Uniform Stability Analysis for Time-Varying Systems.

Author

Rios, Hector, Efimov, Denis, Fridman, Leonid M., Moreno, Jaime A., and Perruquetti, Wilfrid

Subjects

*TIME-varying systems, *STABILITY theory, *NONLINEAR systems, *PROBLEM solving, *LINEAR systems, *NUMERICAL analysis

Abstract

The uniform stability notion for a class of nonlinear time-varying systems is studied using the homogeneity framework. It is assumed that the system is weighted homogeneous considering the time variable as a constant parameter, then several conditions of uniform stability for such a class of systems are formulated. The results are applied to the problem of adaptive estimation for a linear system. [ABSTRACT FROM AUTHOR]

Published

2016

15. Non-Asymptotic Kernel-Based Parametric Estimation of Continuous-Time Linear Systems.

Author

Pin, Gilberto, Assalone, Andrea, Lovera, Marco, and Parisini, Thomas

Subjects

*ASYMPTOTIC distribution, *KERNEL (Mathematics), *PARAMETER estimation, *CONTINUOUS time systems, *INVARIANTS (Mathematics), *DYNAMICAL systems, *STOCHASTIC convergence

Abstract

In this paper, a novel framework to address the problem of parametric estimation for continuous-time linear time-invariant dynamic systems is dealt with. The proposed methodology entails the design of suitable kernels of non-anticipative linear integral operators thus obtaining estimators showing, in the ideal case, “non-asymptotic” (i.e., “finite-time”) convergence. The analysis of the properties of the kernels guaranteeing such a convergence behaviour is addressed and a novel class of admissible kernel functions is introduced. The operators induced by the proposed kernels admit implementable (i.e., finite-dimensional and internally stable) state-space realizations. Extensive numerical results are reported to show the effectiveness of the proposed methodology. Comparisons with some existing continuous-time estimators are addressed as well and insights on the possible bias affecting the estimates are provided. [ABSTRACT FROM PUBLISHER]

Published

2016

16. Stabilization of Nonlinear Systems Nonlinearly Depending on Fast Time-Varying Parameters: An Immersion and Invariance Approach.

Author

Wang, Lei, Ortega, Romeo, Su, Hongye, and Liu, Zhitao

Subjects

*ADAPTIVE control systems, *TIME-varying systems, *NONLINEAR systems, *FEEDBACK control systems, *LYAPUNOV functions

Abstract

The problem of stabilization of nonlinear systems, which depend nonlinearly on fast time-varying parameters, is considered in the technical note. It is assumed that, if the plant parameters were known, a static state-feedback controller that achieves the stabilization objective with a Lyapunov-like function that is independent of the parameters is known. A constructive procedure to update the unknown parameters of the controller, based on the immersion and invariance approach, is proposed. The main contribution of the paper is to show that the proposed controller guarantees global convergence to zero of the systems state for arbitrary time variations of the plant parameters provided the controller parameters are bounded. To ensure the latter condition, an assumption, that in the single parameter case is strictly weaker than the monotonicity condition invoked in previous studies, is imposed. Stabilization is achieved via a, rather unique, combination of gradient-like parameter estimation and the construction of a monotonic signal that counters the deleterious effect of the parameter variations. Several simulation examples illustrate the applicability of the suggested method. [ABSTRACT FROM AUTHOR]

Published

2015