National Instruments NI MATRIXx Xmathの取扱説明書

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デバイス: National Instruments NI MATRIXx Xmath
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要旨

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内容要旨
ページ1に含まれる内容の要旨

TM
NI MATRIXx
TM
Xmath Model Reduction Module
Xmath Model Reduction Module
April 2007
370755C-01

ページ2に含まれる内容の要旨

Support Worldwide Technical Support and Product Information ni.com National Instruments Corporate Headquarters 11500 North Mopac Expressway Austin, Texas 78759-3504 USA Tel: 512 683 0100 Worldwide Offices Australia 1800 300 800, Austria 43 662 457990-0, Belgium 32 (0) 2 757 0020, Brazil 55 11 3262 3599, Canada 800 433 3488, China 86 21 5050 9800, Czech Republic 420 224 235 774, Denmark 45 45 76 26 00, Finland 385 (0) 9 725 72511, France 33 (0) 1 48 14 24 24, Germany 49 89 7413130, India 91 80

ページ3に含まれる内容の要旨

Important Information Warranty The media on which you receive National Instruments software are warranted not to fail to execute programming instructions, due to defects in materials and workmanship, for a period of 90 days from date of shipment, as evidenced by receipts or other documentation. National Instruments will, at its option, repair or replace software media that do not execute programming instructions if National Instruments receives notice of such defects during the warranty per

ページ4に含まれる内容の要旨

Conventions The following conventions are used in this manual: [ ] Square brackets enclose optional items—for example, [response]. Square brackets also cite bibliographic references. » The » symbol leads you through nested menu items and dialog box options to a final action. The sequence File»Page Setup»Options directs you to pull down the File menu, select the Page Setup item, and select Options from the last dialog box. This icon denotes a note, which alerts you to important information. b

ページ5に含まれる内容の要旨

Contents Chapter 1 Introduction Using This Manual.........................................................................................................1-1 Document Organization...................................................................................1-1 Bibliographic References ................................................................................1-2 Commonly Used Nomenclature ......................................................................1-2 Conventions.............

ページ6に含まれる内容の要旨

Contents Onepass Algorithm ......................................................................................... 2-18 Multipass Algorithm ...................................................................................... 2-20 Discrete-Time Systems ................................................................................... 2-21 Impulse Response Error .................................................................................. 2-22 Unstable System Approximation ..............

ページ7に含まれる内容の要旨

Contents fracred( ) ........................................................................................................................4-15 Restrictions......................................................................................................4-15 Defining and Reducing a Controller................................................................4-16 Algorithm ........................................................................................................4-18 Additional Bac

ページ8に含まれる内容の要旨

1 Introduction This chapter starts with an outline of the manual and some useful notes. It also provides an overview of the Model Reduction Module, describes the functions in this module, and introduces nomenclature and concepts used throughout this manual. Using This Manual This manual describes the Model Reduction Module (MRM), which provides a collection of tools for reducing the order of systems. Readers who are not familiar with Parameter Dependent Matrices (PDMs) should consult the Xm

ページ9に含まれる内容の要旨

Chapter 1 Introduction � Chapter 5, Utilities, describes three utility functions: hankelsv( ), stable( ), and compare( ). � Chapter 6, Tutorial, illustrates a number of the MRM functions and their underlying ideas. Bibliographic References Throughout this document, bibliographic references are cited with bracketed entries. For example, a reference to [VODM1] corresponds to a paper published by Van Overschee and De Moor. For a table of bibliographic references, refer to Appendix A, Bibliog

ページ10に含まれる内容の要旨

Chapter 1 Introduction Related Publications For a complete list of MATRIXx publications, refer to Chapter 2, MATRIXx Publications, Online Help, and Customer Support, of the MATRIXx Getting Started Guide. The following documents are particularly useful for topics covered in this manual: � MATRIXx Getting Started Guide • Xmath User Guide � Control Design Module � Interactive Control Design Module � Interactive System Identification Module, Part 1 � Interactive System Identification Module, Part

ページ11に含まれる内容の要旨

Chapter 1 Introduction As shown in Figure 1-1, functions are provided to handle four broad tasks: � Model reduction with additive errors � Model reduction with multiplicative errors � Model reduction with frequency weighting of an additive error, including controller reduction � Utility functions Functions Additive Error Multiplicative Frequency Weighted Model Reduction Model Reduction Model Reduction balmoore redschur ophank bst wtbalance truncate mulhank fracred balance mreduce Utility Functi

ページ12に含まれる内容の要旨

Chapter 1 Introduction Certain restrictions regarding minimality and stability are required of the input data, and are summarized in Table 1-1. Table 1-1. MRM Restrictions balance( ) A stable, minimal system balmoore ( ) A state-space system must be stable and minimal, having at least one input, output, and state bst( ) A state-space system must be linear, continuous-time, and stable, with full rank along the jω-axis, including infinity compare( ) Must be a state-space system fracred( ) A s

ページ13に含まれる内容の要旨

Chapter 1 Introduction � L approximation, in which the L norm of impulse response error (or, 2 2 by Parseval’s theorem, the L norm of the transfer-function error along 2 the imaginary axis) serves as the error measure � Markov parameter or impulse response matching, moment matching, covariance matching, and combinations of these, for example, q-COVER approximation � Controller reduction using canonical interactions, balanced Riccati equations, and certain balanced controller reduction algor

ページ14に含まれる内容の要旨

Chapter 1 Introduction � An inequality or bound is tight if it can be met in practice, for example 1 + logxx – ≤ 0 is tight because the inequality becomes an equality for x =1. Again, if F(jω) denotes the Fourier transform of some ft ()∈ L , the 2 Heisenberg inequality states, 2 ft () dt ∫ --- ---- ---- ---- ---- --- ---- ---- ---- --- ---- ---- ---- ---- --- ---- ---- ---- ---- --- ---- ---- ---- --- - ≤ 4π 12 ⁄ 12 ⁄ 2 2 2 2 t ft () dt ω Fj() ω dω ∫ ∫ 2 and the bound is tight since it is attai

ページ15に含まれる内容の要旨

Chapter 1 Introduction � The controllability grammian is also E[x(t)x′(t)] when the system · – x = Ax + Bw has been excited from time ∞ by zero mean white noise withEwt[] ()w′() s = Iδ() ts – . � The observability grammian can be thought of as measuring the information contained in the output concerning an initial state. · If x = Ax, y = Cxwith x(0) = x then: 0 ∞ y′() t yt ()dt = x′ Qx 0 0 ∫ 0 Systems that are easy to observe correspond to Q with large eigenvalues, and thus large output en

ページ16に含まれる内容の要旨

Chapter 1 Introduction � Suppose the transfer-function matrix corresponds to a discrete-time system, with state variable dimension n. Then the infinite Hankel matrix, 2 CB CAB CA B 2 CAB CA B H = 2 CA B has for its singular values the n nonzero Hankel singular values, together with an infinite number of zero singular values. The Hankel singular values of a (stable) all pass system (or all pass matrix) are all 1. Slightly different procedures are used for calculating the Hankel singular valu

ページ17に含まれる内容の要旨

Chapter 1 Introduction Internally Balanced Realizations Suppose that a realization of a transfer-function matrix has the controllability and observability grammian property that P = Q = Σ for some diagonal Σ. Then the realization is termed internally balanced. Notice that the diagonal entries σ of Σ are square roots of the eigenvalues of PQ, i that is, they are the Hankel singular values. Often the entries of Σ are assumed ordered with σ ≥ σ . i i+1 As noted in the discussion of grammians,

ページ18に含まれる内容の要旨

Chapter 1 Introduction This is almost the algorithm set out in Section II of [LHPW87]. The one difference (and it is minor) is that in [LHPW87], lower triangular Cholesky 1/2 1/2 factors of P and Q are used, in place of U S and U S in forming H c c O O in step 2. The grammians themselves need never be formed, as these Cholesky factors can be computed directly from A, B, and C in both continuous and discrete time; this, however, is not done in balmoore. The algorithm has the property that: –

ページ19に含まれる内容の要旨

Chapter 1 Introduction and also: –1 Reλ (A )<0 and Reλ() A – A A A < 0. i 11 12 22 21 i 22 Usually, we expect that, –1 Reλ() A « Reλ() A – A A A i 22 i 11 12 22 21 in the sense that the intuitive argument hinges on this, but it is not necessary. · Then a singular perturbation is obtained by replacing x by zero; this 2 means that: –1 –1 A x++ A x B u = 0 x = –A A x – A B u or 21 1 22 2 2 2 22 21 1 22 2 Accordingly, –1 –1 · x =() A = A A A x +() B – A A B u 1 11 12 22 21 1 1 12 22

ページ20に含まれる内容の要旨

Chapter 1 Introduction Similar considerations govern the discrete-time problem, where, x() k + 1 x () k B A A 1 1 1 11 12 = + uk () x() k + 1 x () k B A A 2 2 2 21 22 x () k 1 yk () = + Du() k C C 1 2 x () k 2 can be approximated by: –1 x() k + 1 =[] A + A() IA – A x () k + 1 11 12 22 21 1 –1 [] B + A() IA – B uk () 1 12 22 2 –1 y =[] C + C() IA – A x () k + k 1 2 22 21 1 –1 [] DC +() IA – B uk () 2 22 2 mreduce( ) can carry out singular perturbation. For further discussion, refer to Chapter 2,


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