ctrbf
Calculates the controllability staircase form.
Syntax
[ABAR, BBAR, CBAR, T, K] = ctrbf(A, B, C)
[ABAR, BBAR, CBAR, T, K] = ctrbf(A, B, C, TOL)
Inputs
- A
- The state matrix (n x n), where n is the number of states.
- B
- The input matrix (n x p), where p is the number of inputs.
- C
- The output matrix (q x n), where q is the number of outputs.
- TOL
- The tolerance scalar. Default = size(A,1)*norm(A,1)*eps().
Outputs
- ABAR
- The controllability staircase state matrix.
- BBAR
- The controllability staircase input matrix.
- CBAR
- The controllability staircase output matrix.
- T
- The similarity transform matrix.
- K
- A vector containing the number of controllable states factored from the transformation matrix.
Examples
Matrices as input:
A = [10 5; 9 -20];
B = [3 -10; 10 -2];
C = [25 0; 0 15];
[Abar, Bbar, Cbar, T, k] = ctrbf(A, B, C);
Abar = [Matrix] 2 x 2
10 5
9 -20
Bbar = [Matrix] 2 x 2
3 -10
10 -2
Cbar = [Matrix] 2 x 2
25 0
0 15
T = [Matrix] 2 x 2
1 0
0 1
k = [Matrix] 1 x 2
2 0
%The decomposed system Abar shows an uncontrollable mode located at -20 and controllable modes at 10, 5 and 9.
Inputs from the state-space model:
sys_tf=tf([1],[1 5 6 0]);
sys=ss(sys_tf);
[Abar, Bbar, Cbar, T, k] = ctrbf(sys.a, sys.b, sys.c)
Abar = [Matrix] 3 x 3
0 1 0
0 0 -2
0 3 -5
Bbar = [Matrix] 3 x 1
0.00000
0.00000
0.50000
Cbar = [Matrix] 1 x 3
-1 0 0
T = [Matrix] 3 x 3
0 0 -1
0 -1 0
1 0 0
k = [Matrix] 1 x 3
1 1 1
%The decomposed system Abar shows an uncontrollable modes located at -2 and -5 and controllable modes at 1 and 3.
Comments
[ABAR,BBAR,CBAR,T,K] = ctrbf(A,B,C) calculates the controllability staircase form.