Iterative rational Krylov algorithm
The iterative rational Krylov algorithm (IRKA), is an iterative algorithm, useful for model order reduction (MOR) of single-input single-output (SISO) linear time-invariant dynamical systems.[1] At each iteration, IRKA does an Hermite type interpolation of the original system transfer function. Each interpolation requires solving shifted pairs of linear systems, each of size ; where is the original system order, and is the desired reduced model order (usually ).
The algorithm was first introduced by Gugercin, Antoulas and Beattie in 2008.[2] It is based on a first order necessary optimality condition, initially investigated by Meier and Luenberger in 1967.[3] The first convergence proof of IRKA was given by Flagg, Beattie and Gugercin in 2012,[4] for a particular kind of systems.
MOR as an optimization problem[]
Consider a SISO linear time-invariant dynamical system, with input , and output :
Applying the Laplace transform, with zero initial conditions, we obtain the transfer function , which is a fraction of polynomials:
Assume is stable. Given , MOR tries to approximate the transfer function , by a stable rational transfer function , of order :
A possible approximation criterion is to minimize the absolute error in norm:
This is known as the optimization problem. This problem has been studied extensively, and it is known to be non-convex;[4] which implies that usually it will be difficult to find a global minimizer.
Meier–Luenberger conditions[]
The following first order necessary optimality condition for the problem, is of great importance for the IRKA algorithm.
Theorem ([2][Theorem 3.4] [4][Theorem 1.2]) — Assume that the optimization problem admits a solution with simple poles. Denote these poles by: . Then, must be an Hermite interpolator of , through the reflected poles of :
Note that the poles are the eigenvalues of the reduced matrix .
Hermite interpolation[]
An Hermite interpolant of the rational function , through distinct points , has components:
where the matrices and may be find by solving dual pairs of linear systems, one for each shift [4][Theorem 1.1]:
IRKA algorithm[]
As can be seen from the previous section, finding an Hermite interpolator of , through given points, is relatively easy. The difficult part is to find the correct interpolation points. IRKA tries to iteratively approximate these "optimal" interpolation points.
For this, it starts with arbitrary interpolation points (closed under conjugation), and then, at each iteration , it imposes the first order necessary optimality condition of the problem:
1. find the Hermite interpolant of , through the actual shift points: .
2. update the shifts by using the poles of the new :
The iteration is stopped when the relative change in the set of shifts of two successive iterations is less than a given tolerance. This condition may be stated as:
As already mentioned, each Hermite interpolation requires solving shifted pairs of linear systems, each of size :
Also, updating the shifts requires finding the poles of the new interpolant . That is, finding the eigenvalues of the reduced matrix .
Pseudocode[]
The following is a pseudocode for the IRKA algorithm [2][Algorithm 4.1].
algorithm IRKA input: , , closed under conjugation % Solve primal systems % Solve dual systems while relative change in {} > tol % Reduced order matrix % Update shifts, using poles of % Solve primal systems % Solve dual systems end while return % Reduced order model
Convergence[]
A SISO linear system is said to have symmetric state space (SSS), whenever: This type of systems appear in many important applications, such as in the analysis of RC circuits and in inverse problems involving 3D Maxwell's equations.[4] For SSS systems with distinct poles, the following convergence result has been proven:[4] "IRKA is a locally convergent fixed point iteration to a local minimizer of the optimization problem."
Although there is no convergence proof for the general case, numerous experiments have shown that IRKA often converges rapidly for different kind of linear dynamical systems.[1][4]
Extensions[]
IRKA algorithm has been extended by the original authors to multiple-input multiple-output (MIMO) systems, and also to discrete time and differential algebraic systems [1][2][Remark 4.1].
See also[]
References[]
- ^ Jump up to: a b c "Iterative Rational Krylov Algorithm". MOR Wiki. Retrieved 3 June 2021.
- ^ Jump up to: a b c d S. Gugercin, A.C. Antoulas, C. Beattie (2008), Model Reduction for Large-Scale Linear Dynamical Systems, Journal on Matrix Analysis and Applications, vol.30, no.2, SIAM, pp. 609–638
|volume=
has extra text (help)CS1 maint: multiple names: authors list (link) - ^ L. Meier; D.G. Luenberger (1967), Approximation of linear constant systems, IEEE Transactions on Automatic Control, 12, no.5, pp. 585–588
- ^ Jump up to: a b c d e f g G. Flagg; C. Beattie; S. Gugercin (2012), Convergence of the Iterative Rational Krylov Algorithm, Systems & Control Letters, vol.61, no.6, pp. 688–691
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External links[]
- Numerical analysis
- Mathematical modeling