Intelligent Learning Algorithms for Active Vibration Control

Madkour, A.A.M., Hossain, M. Alamgir, Dahal, Keshav P.

January 2007

Yes / This correspondence presents an investigation into the comparative performance of an active vibration control (AVC) system using a number of intelligent learning algorithms. Recursive least square (RLS), evolutionary genetic algorithms (GAs), general regression neural network (GRNN), and adaptive neuro-fuzzy inference system (ANFIS) algorithms are proposed to develop the mechanisms of an AVC system. The controller is designed on the basis of optimal vibration suppression using a plant model. A simulation platform of a flexible beam system in transverse vibration using a finite difference method is considered to demonstrate the capabilities of the AVC system using RLS, GAs, GRNN, and ANFIS. The simulation model of the AVC system is implemented, tested, and its performance is assessed for the system identification models using the proposed algorithms. Finally, a comparative performance of the algorithms in implementing the model of the AVC system is presented and discussed through a set of experiments.

Adaptive systems

Fuzzy neural networks

Intelligent control

System identification

Vibration control

Recursive estimation

FINITE SAMPLE GUARANTEES FOR LEARNING THE DYNAMICS OF SYSTEMS

Lei Xin (17410485)

20 November 2023

<p dir="ltr">The problem of system identification is to learn the system dynamics from data. While classical system identification theories focused primarily on achieving asymptotic consistency, recent efforts have sought to characterize the number of samples needed to achieve a desired level of accuracy in the learned model. This thesis focuses on finite sample analysis for identifying/learning dynamical systems.</p><p dir="ltr">In the first part of this thesis, we provide novel results on finite sample analysis for learning different linear systems. We first consider the system identification problem of a fully observed system (i.e., all states of the system can be perfectly measured), leveraging data generated from an auxiliary system that shares ``similar" dynamics. We provide insights on the benefits of using the auxiliary data, and guidelines on selecting the weight parameter during the model training process. Subsequently, we consider the system identification problem for a partially observed autonomous linear system, where only a subset of states and multiple short trajectories of the system can be observed. We present a finite sample error bound and characterize the learning rate. </p><p dir="ltr">In the second part of this thesis, we explore the practical usage of finite sample analysis under several different scenarios. We first consider a parameter learning problem in a distributed setting, where a group of agents wishes to collaboratively learn the underlying model. We propose a distributed parameter estimation algorithm and provide finite time bounds on the estimation error. We show that our analysis allows us to determine a time at which the communication can be stopped (due to the costs associated with communications), while meeting a desired estimation accuracy. Subsequently, we consider the problem of online change point detection for a linear system, where the user observes data in an online manner, and the goal is to determine when the underlying system dynamics change. We provide an online change point detection algorithm, and a data-dependent threshold that allows one to achieve a pre-specified upper bound on the probability of making a false alarm. We further provide a finite-sample-based lower bound for the probability of detecting a change point with a certain delay.</p><p dir="ltr">Finally, we extend the results to linear model identification from non-linear systems. We provide a data acquisition algorithm followed by a regularized least squares algorithm, along with an associated finite sample error bound on the learned linearized dynamics. Our error bound demonstrates a trade-off between the error due to nonlinearity and the error due to noise, and shows that one can learn the linearized dynamics with arbitrarily small error given sufficiently many samples.</p>

Signal processing

Control engineering

Distributed systems and algorithms

System Identification

Machine Learning

Multi Agent System

System Identification of a Cantilever Beam with Interferometer Measurement Using Adaptive Filters

Kochavi, Jordan D

01 June 2022

Laser interferometry, commonly used in high-precision motion control systems, is rarely adopted in experimental vibration analysis because its installation and mounting is invasive to dynamical systems. However, metrology systems that already utilize laser interferometry, such as profilometry in semiconductor manufacturing, may benefit from interferometer feedback for signal processing. This study investigates the use of laser interferometry for system identification through a piezoelectrically actuated cantilevered beam. The model of the beam including piezo actuators and optical measurement components are established through the Euler-Bernoulli beam theory. From the method of separation of variables, the continuous system is transformed into a discrete system represented in a state-space form. By performing the Laplace transformation of the state-space form, we obtain the analytical transfer function of interferometer displacement versus actuator input, which is then validated numerically and experimentally. Adaptive filters based on FIR and IIR are designed to identify the transfer function. Because of the slow convergence of such filters, a recursive LMS algorithm is designed to accelerate computation. It is experimentally demonstrated that the precision measurement of interferometer can lead to highly accurate results of system identification.

Interferometer

System Identification

Adaptive Filter

Piezoceramic

Acoustics, Dynamics, and Controls

Mechanical Engineering

Motion Control of an Open Container with Slosh Constraints

Karnik, Kedar B.

19 December 2008

No description available.

Engineering

Mechanical Engineering

Motion Control

Sliding Mode Control

SMC

Slosh

System Identification

Determination of the Compressive Response of the Pediatric Thorax Utilizing System Identification Techniques

Icke, Kyle J.

January 2014

No description available.

Biomechanics

Biomedical Engineering

Biomedical Research

injury biomechanics

thorax

chest

system identification

mass

damping

stiffness

Development of an Effective System Identification and Control Capability for Quad-copter UAVs

Wei, Wei

09 June 2015

No description available.

Aerospace Materials

Quad-copter

system identification

flight control

fuzzy logic

handling quality

multi-copter

Six Degree-of-Freedom Modeling of an Uninhabited Aerial Vehicle

Calhoun, Sean M.

31 August 2006

No description available.

Engineering, Aerospace

UAV

Unmanned Vehicle

6-DOF Model

System Identification

Brumby

A two-stage method for system identification from time series

Nadsady, Kenneth Allan

January 1998

No description available.

Hankel Matrix Singular Values

Eigenvalue Realization Algorithm

NEURAL ADAPTIVE NONLINEAR TRACKING USING TRAJECTORY LINEARIZATION

Liu, Yong

02 August 2007

No description available.

Nonlinear Control

Neural Network

Adaptive Control

Trajectory Linearization Control

System Identification

Development of a magnetic suspension system and its applications in nano-imprinting and nano-metrology

Kuo, Shih-Kang

06 August 2003

No description available.

Engineering, Mechanical

magnetic suspension

motion control

nano-metrology

nano-imprinting

system identification

disturbance observer