《系統(tǒng)辨識理論及應(yīng)用英文》主要闡述系統(tǒng)辨識的基本原理以及應(yīng)用。《系統(tǒng)辨識理論及應(yīng)用英文》共分14章。第1章至第4章為緒論、系統(tǒng)辨識常用輸入信號、線性系統(tǒng)的經(jīng)典辨識方法和動態(tài)系統(tǒng)的典范表達式,主要回顧和介紹了與系統(tǒng)的辨識有關(guān)的一些基礎(chǔ)知識。第5章至第12章為最小二乘法辨識、極大似然法辨識、時變參數(shù)辨識方法、多輸入—多輸出系統(tǒng)的辨識、其他一些辨識方法、隨機時序列模型的建立、系統(tǒng)結(jié)構(gòu)辨識和閉環(huán)系統(tǒng)辨識等,介紹了系統(tǒng)辨識常用基本方法,是系統(tǒng)辨識的主要內(nèi)容。第13章和第14章分別介紹了系統(tǒng)辨識在飛行器參數(shù)辨識中的應(yīng)用和神經(jīng)網(wǎng)絡(luò)在系統(tǒng)辨識中的應(yīng)用。
Chapter 1 introduction
1.1 Classification of Mathematic Models of System and Modelling Methods
1.1.1 Signification of Model
1.1.2 Representation Forms of Models
1.1.3 Classification of Mathematic Models
1.1.4 Basic Methods to Establish Mathematic Model
1.1.5 Basic Principles Followed for Modeling
1.2 Definition, Content and Procedure of Identification
1.2.1 Definition of Identification
1.2.2 Content and Procedure of Identification
1.3 Error Criteria Usually Used in Identification
1.3.1 Output Error Criterion
1.3.2 Input Error Criterion
1.3.3 Generalized Error Criterion
1.4 Classification of System Identification
1.4.1 Off-line Identification
1.4.2 On-line Identification
Problems
Chapter 2 Commonly Used Input Signals for System Identification
.2.1 Selective Criteria of Input Signal for System Identification
2.2 White noises and Its Generating Methods
2.2.1 White Noise Process
2.2.2 White Noise Sequence
2.2.3 Generating Methods of White Noise Sequence
2.3 Generation of Pseudorandom Binary Sequence-M-Sequence and Its Properties
2.3.1 Pseudorandom Noise
2.3.2 Generating Method of M-Sequence
2.3.3 Properties of M-Sequence
2.3.4 Autocorrelation Function of Two-Level M-Sequence
2.3.5 Power Spectral Density of Two-Level M-Sequence
Problems
Chapter 3 Classical Identification Methods of Linear System
3.1 Identify Impulse Response of Linear System by Use of M-Sequence
3.2 Obtain Transfer Function from Impulse Function
3.2.1 Transfer Function G(s) of Continuous System
3.2.2 Transfer Function of Discrete System—Impulse Transfer Function G(z-1)
Problems
Chapter 4 Canonical Expression of Dynamic Systems
4.1 Parsimony Principle
4.2 Representations of Difference Equation and State Equation of Linear System
4.2.1 Representation of Difference Equation of Linear Time-Invariant System
4.2.2 Representation of State Equation of Linear System
4.3 Deterministic Canonical State Equations
4.3.1 Controllable Form of Canonical State Equation I
4.3.2 Controllable Form of Canonical State Equation II
4.3.3 Observable Form of Canonical State Equation I
4.3.4 Observable Form of Canonical State Equation II
4.3.5 Observable Form of Canonical State Equation I of Mimo System
4.3.6 Observable Form of Canonical State Equation II of Mimo System
4.4 Deterministic Canonical Difference Equations
4.5 Stochastic Canonical State Equations
4.6 Stochastic Canonical Difference Equations
4.7 Prediction Error Equation
Problems
Chapter 5 Least-Squares Identification
5.1 Least Square Method
5.1.1 Algorithns of Least-Square Estimation
5.1.2 Input Signals for Least-Squares Estimation
5.1.3 Probability Properties of Least-Squares Estimation
5.2 A Kind of Least Squres Which Need Not Invert Matrix
5.3 Recursive Least Squares
5.4 Auxiliary Variable Method
5.5 Recursive Auxiliary Variable Method
5.6 Generalized Least Squares
5.7 An Alternative Generalized Least Squares Technique (Hsia Method)
5.8 Extended Matrix Method
5.9 Multistage Least Squares
5.9.1 The First Algorithm
5.9.2 The Second Algorithm
5.9.3 The Third Algorithm
5.10 Fast Multistage Least Squares
Problems
Chapter 6 Maximum-Likelihood Identification
Chapter 8 Identification of Multi-Input Multi-Output Systems
Chapter 9 Some Other Kinds of Identification Methods
Chapter 10 Establishment of Random Time Series Models
Chapter 11 Structure Identification of System
Chapter 12 Identification of Closed-Loop System
Chapter 13 Application of System Identification to Parameter Identification of Aircraft
Chapter 14 Applicatiom of Neural Network to System Identification
References