1D Self-Conditioned [A(v),B(v),C(v),D(v)]

Implement gain-scheduled state-space controller in self-conditioned form depending on one scheduling parameter

Libraries:
Aerospace Blockset / GNC / Control

Description

The 1D Self-Conditioned [A(v),B(v),C(v),D(v)] block implements a gain-scheduled state-space controller as defined in Algorithms.

The output from this block is the actuator demand, which you can input to an actuator block.

Limitations

If the scheduling parameter inputs to the block go out of range, they are clipped. The state-space matrices are not interpolated out of range.
This block requires the Control System Toolbox™ license.

Ports

Input

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y — Aircraft measurements
vector

Aircraft measurements, specified as a vector.

Data Types: double

v — Scheduling variable
vector

Scheduling variable, specified as a vector, ordered according to the dimensions of the state-space matrices.

Data Types: double

u_meas — Measured actuator position
vector

Measured actuator position, specified as a vector.

Data Types: double

Output

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u_dem — Actuator demands
vector

Actuator demands, specified as a vector.

Data Types: double

Parameters

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A-matrix(v) — A-matrix of the state-space implementation
`A` (default) | array

A-matrix of the state-space implementation. The A-matrix should have three dimensions, the last one corresponding to the scheduling variable v. For example, if the A-matrix corresponding to the first entry of v is the identity matrix, then A(:,:,1) = [1 0;0 1];.

Programmatic Use

Block Parameter: A

Type: character vector

Values: vector

Default: 'A'

B-matrix(v) — B-matrix of the state-space implementation
`B` (default) | array

B-matrix of the state-space implementation. The B-matrix should have three dimensions, the last one corresponding to the scheduling variable v. For example, if the B-matrix corresponding to the first entry of v is the identity matrix, then B(:,:,1) = [1 0;0 1];.

Programmatic Use

Block Parameter: B

Type: character vector

Values: vector

Default: 'B'

C-matrix(v) — C-matrix of the state-space implementation
`C` (default) | array

C-matrix of the state-space implementation. The C-matrix should have three dimensions, the last one corresponding to the scheduling variable v. For example, if the C-matrix corresponding to the first entry of v is the identity matrix, then C(:,:,1) = [1 0;0 1];.

Programmatic Use

Block Parameter: C

Type: character vector

Values: vector

Default: 'C'

D-matrix(v) — D-matrix of the state-space implementation
`D` (default) | array

D-matrix of the state-space implementation. The D-matrix should have three dimensions, the last one corresponding to the scheduling variable v. For example, if the D-matrix corresponding to the first entry of v is the identity matrix, then D(:,:,1) = [1 0;0 1];.

Programmatic Use

Block Parameter: D

Type: character vector

Values: vector

Default: 'D'

Scheduling variable breakpoints — Breakpoints for scheduling variable
`v_vec` (default) | vector

Vector of the breakpoints for the first scheduling variable. The length of v should be same as the size of the third dimension of A, B, C, and D.

Programmatic Use

Block Parameter: breakpoints_v

Type: character vector

Values: vector

Default: 'v_vec'

Initial state, x_initial — Initial states
`0` (default) | vector

Vector of initial states for the controller, that is, initial values for the state vector, x. It should have length equal to the size of the first dimension of A.

Programmatic Use

Block Parameter: x_initial

Type: character vector

Values: vector

Default: '0'

**Poles of A(v)-H(v)*C(v)** — Desired poles
`[-5 -2]` (default) | vector

Desired poles of A-HC, specified as a vector. The poles are assigned to the same locations for all values of the scheduling parameter v. Hence, the number of pole locations defined should be equal to the length of the first dimension of the A-matrix.

Programmatic Use

Block Parameter: vec_w

Type: character vector

Values: vector

Default:

'[-5
									-2]'

Algorithms

The block implements a gain-scheduled state-space controller as defined by the equations:

$\begin{array}{l} \dot{x} = A (v) x + B (v) y \\ u = C (v) x + D (v) y \end{array}$

in the self-conditioned form

$\begin{array}{l} \dot{z} = (A (v) - H (v) C (v)) z + (B (v) - H (v) D (V)) e + H (v) u_{m e a s} \\ u_{d e m} = C (v) z + D (v) e \end{array}$

This block implements a gain-scheduled version of the Self-Conditioned [A,B,C,D] block, where v is the parameter over which A, B, C, and D are defined. This type of controller scheduling assumes that the matrices A, B, C, and D vary smoothly as a function of v, which is often the case in aerospace applications.

References

[1] Kautsky, Nichols, and Van Dooren. "Robust Pole Assignment in Linear State Feedback." International Journal of Control, Vol. 41, Number 5, 1985, pp. 1129-1155.

1D Self-Conditioned [A(v),B(v),C(v),D(v)]

Description

Limitations

Ports

Input

y — Aircraft measurements
vector

v — Scheduling variable
vector

u_meas — Measured actuator position
vector

Output

u_dem — Actuator demands
vector

Parameters

A-matrix(v) — A-matrix of the state-space implementation
`A` (default) | array

Programmatic Use

B-matrix(v) — B-matrix of the state-space implementation
`B` (default) | array

Programmatic Use

C-matrix(v) — C-matrix of the state-space implementation
`C` (default) | array

Programmatic Use

D-matrix(v) — D-matrix of the state-space implementation
`D` (default) | array

Programmatic Use

Scheduling variable breakpoints — Breakpoints for scheduling variable
`v_vec` (default) | vector

Programmatic Use

Initial state, x_initial — Initial states
`0` (default) | vector

Programmatic Use

**Poles of A(v)-H(v)*C(v)** — Desired poles
`[-5 -2]` (default) | vector

Programmatic Use

Algorithms

References

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.

Version History

See Also

1D Self-Conditioned [A(v),B(v),C(v),D(v)]

Description

Limitations

Ports

Input

y — Aircraft measurements vector

v — Scheduling variable vector

u_meas — Measured actuator position vector

Output

u_dem — Actuator demands vector

Parameters

A-matrix(v) — A-matrix of the state-space implementation A (default) | array

Programmatic Use

B-matrix(v) — B-matrix of the state-space implementation B (default) | array

Programmatic Use

C-matrix(v) — C-matrix of the state-space implementation C (default) | array

Programmatic Use

D-matrix(v) — D-matrix of the state-space implementation D (default) | array

Programmatic Use

Scheduling variable breakpoints — Breakpoints for scheduling variable v_vec (default) | vector

Programmatic Use

Initial state, x_initial — Initial states 0 (default) | vector

Programmatic Use

Poles of A(v)-H(v)*C(v) — Desired poles [-5 -2] (default) | vector

Programmatic Use

Algorithms

References

Extended Capabilities

C/C++ Code Generation Generate C and C++ code using Simulink® Coder™.

Version History

See Also

y — Aircraft measurements
vector

v — Scheduling variable
vector

u_meas — Measured actuator position
vector

u_dem — Actuator demands
vector

A-matrix(v) — A-matrix of the state-space implementation
`A` (default) | array

B-matrix(v) — B-matrix of the state-space implementation
`B` (default) | array

C-matrix(v) — C-matrix of the state-space implementation
`C` (default) | array

D-matrix(v) — D-matrix of the state-space implementation
`D` (default) | array

Scheduling variable breakpoints — Breakpoints for scheduling variable
`v_vec` (default) | vector

Initial state, x_initial — Initial states
`0` (default) | vector

**Poles of A(v)-H(v)*C(v)** — Desired poles
`[-5 -2]` (default) | vector

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.