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An algorithm for robust stability analysis

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Title: An algorithm for robust stability analysis


1
An algorithm for robust stability analysis
  • By
  • Prof. P. S. V. Nataraj

2
Objectives
  • Introduction
  • Proposed algorithm
  • Application Mass spring damper system
  • Conclusion

3
Introduction
  • Let P be a family of real nth order polynomials
  • where s is the complex variable, q??l is a
    vector of physical parameters occurring
    nonlinearly in the coefficients of polynomial in
    P and Q0 ??l is a bounding box for q, given as
  • We wish to find if the above polynomial family is
    robustly stable, that is, if

4
Introduction (Contd)
  • Most of the current robust analysis methods are
    for the case of the polynomial coefficients
    having affine or multilinear dependencies on the
    parameters q
  • More recently, Garloff and co-workers proposed
    Bernstein polynomial based robust stability
    analysis methods for the case of polynomial
    parametric dependencies.
  • Here we present an algorithm to analyze the
    robust stability of polynomials with nonlinear
    parametric dependencies.
  • The proposed algorithm is based on the powerful
    tool of interval analysis.

5
Introduction (Contd)
  • At least one member of the polynomial family
    should be stable for the test.
  • Let ??? denote the frequency variable.
  • Expressing the polynomial p(j?,q) in terms of its
    even and odd parts gives
  • p(j?,q) pe(?2,q) j?p0(?2,q) .
  • By the continuous dependency of the zeros of a
    polynomial on its coefficients, the entire
    polynomial family in p is robustly stable if and
    only if
  • 0?( pe(?2,q),p0(?2,q)), q ?Q0, ??? .

6
Introduction (Contd)
  • Let x (?2,q), f(x) (pe(x), p0(x))
  • X denotes the interval vector corresponding to x,
    with X0 ? x Q0
  • If F is any inclusion function of f, then it
    follows from the inclusion property of interval
    analysis that, for any X ? X0 , the zero
    exclusion test is sufficient to check for robust
    stability.
  • i.e.,
  • 0? F(X) ? 0?f(x), x ? X

7
Proposed Algorithm
  • Input An inclusion function F of f, the initial
    box
  • X0 ? I(?l 1)
  • Output The message the system is robustly
    stable' or the system is not robustly stable'.
  • BEGIN Algorithm
  • Set X X0, initialize list L X
  • Remove all boxes from list L and evaluate F over
    all the boxes
  • (interval zero exclusion test) Discard all boxes
    for which 0? F(X)
  • For any box, if the width of F(X) is within
    machine precision, then print the system is not
    robustly stable' and EXIT algorithm.

8
Proposed Algorithm contd
  • Bisect all boxes in coordinate direction k,
    getting subboxes V1,V2 such that X V1?V2
  • Deposit all these subboxes in L.
  • If the list L is empty, then print the system is
    robustly stable' and EXIT algorithm. Else, go to
    step 2.
  • EXIT Algorithm
  • Remark In the proposed algorithm, function
    evaluations, zero exclusion checks, width checks,
    and bisections on all boxes in an iteration are
    performed concurrently using vectorized interval
    arithmetic operations.
  • Remark In the proposed algorithm, step 5, we
    have used randomized bisection to find out the
    coordinate direction K

9
Application Mass spring damper system
  • This example is given by Ackerman and Sienel
  • where u is a force accelerating the mass m2,
    position y1 is the measured variable.

10
Application contd
  • The values of the parameters vary over the
    intervals
  • Using the pole-placement technique for the
    nominal plant, a minimum-phase and stable third
    order compensator of the form is designed as

11
Application contd
  • ?10 variation in the coefficients of the
    compensator are assumed
  • The characteristic polynomial of the complete
    feedback system is given by

12
Application contd
  • This polynomial has thirteen parameters with
    multilinear parametric dependencies where
  • The initial frequency interval is 0,5000.
  • Computations are done on a Pentium III, 800MHZ
    machine with 500MB RAM using INTLAB
  • The algorithm is able to report in 0.14 seconds
    that the system is robustly stable.
  • Convex Hull Bernstein algorithm of Garloff et al
    took about 80 seconds on a HP 9000/755 work
    station.

13
Conclusions
  • A simple and direct method is presented for
    robust stability analysis of polynomials having
    nonlinear parametric dependencies.
  • We demonstrated the effectiveness of the proposed
    algorithm on a physical example with thirteen
    uncertain parameters.
  • By considering the difficult and general class of
    nonlinear parametric dependencies, we believe
    that the proposed method fills in a significant
    gap in the robust stability analysis literature

14
Thank You
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