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h_inf
Continuous time H-infinity (central) controller
Syntax
[Sk, ro] = h_inf(P, r, romin, romax, nmax) [Sk, rk, ro] = h_inf(P, r, romin, romax, nmax)
Arguments
- P
a continuous-time linear dynamical system ("augmented" plant given in state-space form or in transfer form)
- r
size of the
P22plant i.e. 2-vector[#outputs,#inputs]- romin,romax
a priori bounds on
rowithro=1/gama^2; (romin=0usually)- nmax
integer, maximum number of iterations in the gama-iteration.
Description
h_inf computes H-infinity optimal controller for the
continuous-time plant P.
The partition of P into four sub-plants is given through
the 2-vector r which is the size of the 22 part of P.
P is given in state-space
e.g. P=syslin('c',A,B,C,D) with A,B,C,D = constant matrices
or P=syslin('c',H) with H a transfer matrix.
[Sk,ro]=H_inf(P,r,romin,romax,nmax) returns
ro in [romin,romax] and the central
controller Sk in the same representation as
P.
(All calculations are made in state-space, i.e conversion to state-space is done by the function, if necessary).
Invoked with three LHS parameters,
[Sk,rk,ro]=H_inf(P,r,romin,romax,nmax) returns
ro and the Parameterization of all stabilizing
controllers:
a stabilizing controller K is obtained by
K=lft(Sk,r,PHI) where PHI is a linear
system with dimensions r' and satisfy:
H_norm(PHI) < gamma. rk (=r) is the
size of the Sk22 block and ro = 1/gama^2
after nmax iterations.
Algorithm is adapted from Safonov-Limebeer. Note that P is assumed to be
a continuous-time plant.
See also
Authors
F.Delebecque INRIA (1990)
History
| Version | Description |
| 5.4.0 | Sl is now checked for
continuous time linear dynamical system. This modification
has been introduced by this commit |
| Report an issue | ||
| << h_cl | H-infini | h_inf_st >> |