Parametric Identification Algorithm Using Chebyshev–Laguerre Functions

The authors propose an algorithm for identifying the parameters of a controlled asynchronous electric drive in real time, which provides calculation of stator and rotor resistances which change as a function of temperature. The algorithm is based on the analysis of a current tube of electric motor phase with the subsequent calculation of resistances.

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Adaptive Predictive Functional Control of X-Y Pedestal for LEO Satellite Tracking Using Laguerre Functions

Applied Sciences ◽

10.3390/app11219794 ◽

2021 ◽

Vol 11 (21) ◽

pp. 9794

Author(s):

Reza Dadkhah Tehrani ◽

Hadi Givi ◽

Daniel-Eugeniu Crunteanu ◽

Grigore Cican

Keyword(s):

System Identification ◽

Satellite Tracking ◽

Identification Algorithm ◽

Laguerre Functions ◽

Point Change ◽

Nonlinear Characteristics ◽

Predictive Functional Control ◽

Functional Control ◽

Adaptive Control Algorithm ◽

Leo Satellite

In this paper, Predictive Functional Control (PFC) is used for X-Y pedestal control for LEO satellite tracking. According to the nonlinear characteristics of the X-Y pedestal and pedestal model variation caused by its operating point change, the use of system identification algorithm, which is based on special types of orthonormal functions known as Laguerre functions, is presented. This algorithm is combined with PFC to obtain a novel adaptive control algorithm entitled Adaptive Predictive Functional Control (APFC). In this combination, Laguerre functions are utilized for system identification, while the PFC is the control law. An interesting feature of the proposed algorithm is its desirable performance against the interference effect of channel X and channel Y. The proposed APFC algorithm is compared with Proportional Integral Derivative (PID) controller using simulation results. The results confirm that the proposed controller improves the performance in terms of the pedestal model variations; that is, the controller is capable of adapting to the model changes desirably.

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Parametric Identification of Chaotic Base-Excited Double Pendulum Experiment

Design Engineering ◽

10.1115/imece2004-59836 ◽

2004 ◽

Cited By ~ 2

Author(s):

Yang Liang ◽

B. F. Feeny

Keyword(s):

Harmonic Balance ◽

Parametric Identification ◽

Identification Algorithm ◽

Double Pendulum ◽

Unstable Periodic Orbits ◽

Identification Process ◽

Response Data ◽

Regression Techniques ◽

Linearized System ◽

Pendulum Experiment

An improved parametric identification of chaotic systems was investigated for a double pendulum. From recorded experimental response data, the unstable periodic orbits were extracted and later used in a harmonic balance identification process. By applying digital filtering, digital differentiation and linear regression techniques for optimization, the results were improved. Verification of the related simulation system and linearized system also corroborated the success of the identification algorithm.

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Parametric Identification of Ship Maneuvering Models by Using Support Vector Machines

Journal of Ship Research ◽

10.5957/jsr.2009.53.1.19 ◽

2009 ◽

Vol 53 (01) ◽

pp. 19-30 ◽

Cited By ~ 9

Author(s):

W. L. Luo ◽

Z. J. Zou

Keyword(s):

Support Vector Machines ◽

Predictive Ability ◽

Parametric Identification ◽

Inner Product ◽

Support Vector ◽

Identification Algorithm ◽

Hydrodynamic Coefficients ◽

Ship Maneuvering ◽

Vector Machines ◽

Maneuvering Motion

System identification combined with free-running model tests or full-scale trials is one of the effective methods to determine the hydrodynamic coefficients in the mathematical models of ship maneuvering motion. By analyzing the available data, including rudder angle, surge speed, sway speed, yaw rate, and so forth, a method based on support vector machines (SVM) to estimate the hydrodynamic coefficients is proposed for conventional surface ships. The coefficients are contained in the expansion of the inner product of a linear kernel function. Predictions of maneuvering motion are conducted by using the parameters identified. The results of identification and simulation demonstrate the validity of the identification algorithm proposed. The simultaneous drift and multicollinearity are diminished by introducing an additional ramp signal to the training samples. Comparison between the simulated and predicted motion variables from different maneuvers shows good predictive ability of the trained SVM.

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On Response Prediction of Degrading Structures

Volume 3: 25th Computers and Information in Engineering Conference, Parts A and B ◽

10.1115/detc2005-84916 ◽

2005 ◽

Author(s):

C. H. Ng ◽

N. Ajavakom ◽

F. Ma

Keyword(s):

Structure Prediction ◽

Hysteresis Loops ◽

Response Prediction ◽

Parametric Identification ◽

Practical Significance ◽

Identification Algorithm ◽

Hysteretic Model ◽

Sea Waves ◽

Future Performance ◽

Brute Force Approach

All structures degrade when acted upon by cyclic forces associated with earthquakes, high winds, and sea waves. Identification and prediction of degradation is thus a problem of considerable practical significance in the field of engineering mechanics. Under cyclic excitations, system degradation manifests itself in the evolution of the associated hysteresis loops. In this paper, a robust identification algorithm is devised to generate hysteretic models of a deteriorating structure from its experimental load-displacement traces. This algorithm is based upon the generalized Bouc-Wen model and the latest theory of differential evolution, streamlined through global sensitivity analysis. It can account for strength degradation, stiffness degradation, and pinching characteristics in the evolution of hysteretic traces, whereby earlier studies in parametric identification of hysteresis are extended. In addition, it is shown experimentally that a hysteretic model obtained by identification can be used to predict the future performance of a degrading structure. Prediction of degradation through identification is a brute-force approach that offers a close representation of reality. There is not any method based upon the fundamental postulates of mechanics that can predict the response of a degrading structure well beyond its linear range.

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Carreau's Rheological Model and A.N. Tikhonov’s Regularization Method: Parametric Identification Based on a CFD model

Food Processing Techniques and Technology ◽

10.21603/2074-9414-2021-3-615-627 ◽

2021 ◽

pp. 615-627

Author(s):

Anatoly Khvostov ◽

Gazibeg Magomedov ◽

Victor Ryazhskikh ◽

Aleksey Kovalev ◽

Aleksey Zhuravlev ◽

...

Keyword(s):

Regularization Method ◽

Rheological Model ◽

Three Dimensional ◽

Parametric Identification ◽

Rheological Parameters ◽

Identification Algorithm ◽

Cfd Model ◽

Shear Rates ◽

Tikhonov’S Regularization ◽

Limiting Values

Introduction. Carreau's rheological model can describe the three-dimensional flows of non-Newtonian media. However, it requires modeling parameters for the viscosity of the medium at the limiting values of shear rates, which cannot be achieved by instrumental methods. The present article introduces a novel method that can identify the parameters of Carreau’s model using a regularization algorithm. Study objects and methods. The study featured fondant mass produced according to the traditional formulation for Creamy Fondant unglazed candies. Standard methods were used to describe the properties of the raw materials and semi-finished products, as well as methods of mathematical processing, modeling, and optimization. Results and its discussion. The research produced an algorithm based on A.N. Tikhonov’s regularization method of the parametric identification of Carreau's rheological model. The calculation residual was minimized by the viscometric measurements and the CFD model, which provided the calculation of the hydrodynamic flow regime at the limiting values of shear rates. The CFD model of a steady non-isothermal flow of a nonlinear viscous medium through a cylindrical capillary was based on the equations of conservation of mass, energy, and momentum. The rheological parameters of Carreau’s model were illustrated by the case of fondant mass. The error for the viscosity prediction did not exceed 14.07%. Conclusion. The parametric identification algorithm made it possible to evaluate the rheological parameters of structured liquid media with Carreau's rheological law in cases that lack experimental information on the behavior of the medium at limiting shear rates. The algorithm eliminated the computational problems typical of Ostwald and de Ville’s rheological model, which usually arise when solving practical problems of three-dimensional flows of non-Newtonian media with limiting viscosity values.

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Non-Parametric Identification of Structural Nonlinearity with Limited Input and Output Measurements

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.243-249.5403 ◽

2011 ◽

Vol 243-249 ◽

pp. 5403-5407 ◽

Cited By ~ 2

Author(s):

Ying Lei ◽

Yan Wu

Keyword(s):

Parametric Identification ◽

Least Square ◽

Frame Structure ◽

Identification Algorithm ◽

Recursive Least Square ◽

Restoring Force ◽

Input And Output ◽

Structural Nonlinearity ◽

Shear Frame ◽

Non Parametric

In this paper, a technique is proposed for non-parametric identification of structural nonlinearity with limited input and output measurements. The identification algorithm is based on the classical Kalman estimator for the displacement and the velocity responses and the recursive least square estimation for the unmeasured excitation and the restoring force. Two different models are used to simulate nonlinear structures: One is a 4-storey shear-frame structure with excitation on the top floor and the nonlinearity occurs at the bottom floor. The other is also a 4-storey shear-frame structure with both excitation and the nonlinearity at the top floor. Two numerical examples are carried out for the two kinds of models. Bouc-Wen hysteretic models are used to simulate the nonlinear impact. The simulation results demonstrate the efficiency of the proposed technique with limited output measurements.

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Stable algorithm of nonparametric identification in case of anomalous measurements

Вычислительные технологии ◽

10.25743/ict.2020.25.3.006 ◽

2020 ◽

pp. 46-53

Author(s):

Юрий Евгеньевич Воскобойников ◽

Василиса Андреевна Боева

Keyword(s):

Integral Equation ◽

Volterra Integral Equation ◽

Stable Solution ◽

Parametric Identification ◽

Identification Problem ◽

Cubic Splines ◽

Identification Algorithm ◽

Stable Algorithm ◽

Input And Output ◽

Derivatives Of

Математические модели многих технических систем имеют вид интегрального уравнения Вольтерра I рода с разностным ядром. Для таких систем задача идентификации заключается в построении оценки для импульсной переходной функции системы по измеренным (с шумами) значениям входного и выходного сигналов и является некорректно поставленной. В недавней работе авторов предложен устойчивый алгоритм идентификации, использующий аппарат сглаживающих кубических сплайнов для вычисления первых производных входного и выходного сигналов. К сожалению, сглаживающие кубические сплайны неудовлетворительно фильтруют аномальные измерения. Поэтому предложен двухшаговый алгоритм идентификации, на первом шаге которого аномальные измерения удаляются с использованием пространственно-локального фильтра, а затем строятся сглаживающие сплайны Volterra integral equation of the first kind often represents stationary dynamic systems. For such a model, the non-parametric identification problem reduces to the estimation of pulse transition characteristics (that is the kernel of integral equation) from the registered noise-contaminated values of input and output signals. To formulate stable solution for identification problem authors propose algorithm that estimates pulse transition characteristics by solving Volterra integral equation of the second kind and involving first derivatives of input and output signals application that corresponds to non-stable problem. Smoothing cubic splines employed in robust calculation of first derivatives allow finding a stable solution of identification problem even when input and output signals of system identified are essentially noise-contaminated. Unfortunately, measured values of input and output signals also contain anomalous measurements such as pulse noises, glitches, etc. Such measurements are poorly smoothable by splines that cause high levels of first derivatives errors and, conversely, significant pulse transition characteristics identification errors of dynamic system. For all the reasons aforementioned, in this paper authors present the new stable two-step identification algorithm in case of anomalous measurements. The first step of the algorithm is for non-linear local-spatial combined filtration procedure of input and output signals that helps to effectively remove anomalous measurements. At the second step, smoothing cubic splines are used to calculate stable first derivatives of previously filtered signals. An extensive computational experiment showed the effectiveness of the proposed algorithm, which allows solving the identification problem with acceptable accuracy in practice even at high intensity of anomalous measurements. The experimental results give reason to recommend this algorithm for solving practical problems of identifying stationary systems, the mathematical model of which is the Voltaire integral equation of the first kind with a difference kernel

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Nonlinear Identification Approach of Nonlinear Constitutive Model of Soil Material with Optimization Procedure

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.461.686 ◽

2012 ◽

Vol 461 ◽

pp. 686-689

Author(s):

Li Juan Cao ◽

Zi Chang Shangguan ◽

Shou Ju Li

Keyword(s):

Constitutive Model ◽

Model Identification ◽

Optimization Procedure ◽

Parametric Identification ◽

Identification Problem ◽

Identification Algorithm ◽

Nonlinear Constitutive Model ◽

Parameter Identification Problem ◽

Identification Approach ◽

Identification Techniques

Model identification of dynamic systems in the vibration engineering field has been followed with interest in recent years. A number of identification techniques on this topic are now available, such as parametric or non-parametric identification methods, time domain or frequency domain estimation approaches, etc. The identification approach of nonlinear constitutive model from input-output measurements is proposed. The inverse problem of material characterization is formulated as parameter identification problem that is solved by using optimization procedure. A set of parameters corresponding to the material property can be determined by minimizing objective function which accounts for experimental data and calculated responses of the mechanical model. The performances of the proposed identification approach were evaluated with simulating data. The effectiveness of identification approach is validated by numerical simulation. The investigation results show that the proposed identification algorithm poses good robustness and high identification precision.

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SEARCH ALGORITHM FOR THE PARAMETRIC IDENTIFICATION OF THE ELECTRIC DRIVE OF THE MONITORING SYSTEM

«System analysis and applied information science» ◽

10.21122/2309-4923-2017-2-39-46 ◽

2017 ◽

pp. 39-46

Author(s):

A. S. Abufanas ◽

A. A. Lobaty ◽

A. G. Shvedko

Keyword(s):

Monitoring System ◽

Electric Drive ◽

Output Signal ◽

Search Algorithm ◽

Parametric Identification ◽

Technical System ◽

Gradient Algorithm ◽

Identification Algorithm ◽

Deterministic Function ◽

The Right

The problem of parametric identification of a mathematical model of a technical system or a device is considered, which considers the electric drive of a monitoring system installed on an unmanned aerial vehicle. Identification of the parameters of elements of a complex technical system is an actual scientific task, since when developing a new technical system for its synthesis and research, it is necessary to have mathematical models of the elements of the system.It is proposed to solve the problem by applying the search gradient identification algorithm for a given objective residual function in the form of a difference in the output signal of the identified element of the system and its model. When solving the problem, the random character of the processes occurring in the system and at the output of the output signal meter is taken into account. The identification algorithm is developed on the basis of the representation of the model of parameters in the form of an ordinary vector-matrix equation, on the right side of which there is a model of the driving influence in the form of a given deterministic function of time. A general structural diagram of the parametric identification search system with a gradient algorithm is presented.As an example for evaluating the operability of the proposed algorithm, we consider the simplest model of an electric drive, given by a transfer function in the form of an inertial link. Qualitative illustrations of the operability of the proposed algorithm and quantitative characteristics of the signal and parameter changes of the identified object are presented.

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