Scilab 5.4.1
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Please note that the recommended version of Scilab is 2025.0.0. This page might be outdated.
See the recommended documentation of this function
projsl
linear system projection
Calling Sequence
[slp]=projsl(sl,Q,M)
Arguments
- sl,slp
syslin
lists- Q,M
matrices (projection factorization)
Description
slp
= projected model of sl
where Q*M
is the full rank
factorization of the projection.
If (A,B,C,D)
is the representation of sl
, the projected model
is given by (M*A*Q,M*B,C*Q,D)
.
Usually, the projection Q*M
is obtained as the spectral projection
of an appropriate auxiliary matrix W
e.g. W
= product
of (weighted) gramians or product of Riccati equations.
Examples
rand('seed',0);sl=ssrand(2,2,5);[A,B,C,D]=abcd(sl);poles=spec(A) [Q,M]=pbig(A,0,'c'); //keeping unstable poles slred=projsl(sl,Q,M);spec(slred('A')) sl('D')=rand(2,2); //making proper system trzeros(sl) //zeros of sl wi=inv(sl); //wi=inverse in state-space [q,m]=psmall(wi('A'),2,'d'); //keeping small zeros (poles of wi) i.e. abs(z)<2 slred2=projsl(sl,q,m); trzeros(slred2) //zeros of slred2 = small zeros of sl // Example keeping second order modes A=diag([-1,-2,-3]); sl=syslin('c',A,rand(3,2),rand(2,3));[nk2,W]=hankelsv(sl) [Q,M]=pbig(W,nk2(2)-%eps,'c'); //keeping 2 eigenvalues of W slr=projsl(sl,Q,M); //reduced model hankelsv(slr)
See Also
- pbig — eigen-projection
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