Flexible Space Structures: Difference between revisions

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Description

The flexible space structure benchmark^[1] is a procedural modal model which represents structural dynamics with a selectable number actuators and sensors. This model is used for truss structures in space environments i.e. the COFS-1 (Control of Flexible Structures) mast flight experiment.

Model

In modal form the flexible space structure model for $K$ modes, $M$ actuators and $Q$ sensors is of second order and given by:

\ddot{ν} (t) = (2 ξ \circ ω) \circ \dot{ν} (t) + (ω \circ ω) \circ ν = B u (t)

y (t) = C_{r} \dot{ν} (t) + C_{d} ν (t)

with the parameters $ξ \in ℝ_{> 0}^{K}$ (damping ratio), $ω \in ℝ_{> 0}^{K}$ (natural frequency) and using the Hadamard product $\circ$ . The first order representation follows for $x (t) = (\dot{ν} (t), ω_{1} ν_{1}, \dots, ω_{K} ν_{K})$ by:

\dot{x} (t) = A x (t) + B u (t)

y (t) = C x (t)

with the matrices:

A : = (\begin{matrix} A_{1} \\ ⋱ \\ A_{K} \end{matrix}), B : = (\begin{matrix} B_{1} \\ ⋮ \\ B_{K} \end{matrix}), C : = (\begin{matrix} C_{1} & \dots & C_{K} \end{matrix}),

and their components:

A_{k} : = (\begin{matrix} - 2 ξ_{k} ω_{k} & - ω_{k} \\ ω_{k} & 0 \end{matrix}), B_{k} : = (\begin{matrix} b_{k} \\ 0 \end{matrix}), C_{k} : = (\begin{matrix} c_{r k} & \frac{c_{d k}}{ω_{k}} \end{matrix}),

where $b_{k} \in ℝ^{1 \times M}$ and $c_{r k}, c_{d k} \in ℝ^{Q \times 1}$ .

Benchmark Specifics

For this benchmark the system matrix is block diagonal and thus chosen to be sparse. The parameters $ξ$ and math>\omega</math> are sampled from a uniform random distributions $𝒰_{[0, \frac{1}{1000}]}^{K}$ and $𝒰_{[0, 100]}^{K}$ respectively. The components of the input matrix $b_{k}$ are sampled form a uniform random distribution $𝒰_{[0, 1]}$ , while the output matrix $C$ is sampled from a uniform random distribution $𝒰_{[0, 10]}$ completely w.l.o.g, since if the components of $C_{d}$ are random their scaling can be ignored.

Data

The following Matlab code assembles the above described $A$ , $B$ and $C$ matrix for a given number of modes $K$ .

function [A,B,C] = fss(K,M,Q)

    rand('seed',1009);
    xi = rand(1,K)*0.001;	% Sample damping ratio
    omega = rand(1,K)*100;	% Sample natural frequencies

    A_k = cellfun(@(p) sparse([-2.0*p(1)*p(2),-p(2);p(2),0]), ...
                  num2cell([xi;omega],1),'UniformOutput',0);

    A = blkdiag(A_k{:});

    B = kron(rand(K,M),[1;0]);

    C = 10.0*rand(Q,2*K);
end

Reference

↑ W. Gawronski and T. Williams, "Model Reduction for Flexible Space Structures", Journal of Guidance 14(1): 68--76, 1991

Contact

Christian Himpe

[1] W. Gawronski and T. Williams, "Model Reduction for Flexible Space Structures", Journal of Guidance 14(1): 68--76, 1991

[1]

@@ Line 8: / Line 8: @@
 ==Description==
-The '''flexible space structure''' benchmark<ref>W. Gawronski and T. Williams, "<span class="plainlinks">[http://doi.org/10.2541/3.20606 Model Reduction for Flexible Space Structures]</span>", Journal of Guidance 14(1): 68--76, 1991</ref> is a procedural modal model which represents structural dynamics with a selectable number actuators and sensors.
+The '''flexible space structure''' benchmark<ref>W. Gawronski and T. Williams, "<span class="plainlinks">[http://doi.org/10.2514/3.20606 Model Reduction for Flexible Space Structures]</span>", Journal of Guidance 14(1): 68--76, 1991</ref> is a procedural modal model which represents structural dynamics with a selectable number actuators and sensors. This model is used for truss structures in space environments i.e. the COFS-1 (Control of Flexible Structures) mast flight experiment.
 ==Model==
@@ Line 41: / Line 41: @@
 The parameters <math>\xi</math> and math>\omega</math> are sampled from a uniform random distributions <math>\mathcal{U}_{[0,\frac{1}{1000}]}^K</math> and <math>\mathcal{U}_{[0,100]}^K</math> respectively.
 The components of the input matrix <math>b_k</math> are sampled form a uniform random distribution <math>\mathcal{U}_{[0,1]}</math>,
-while the output matrix <math>C</math> is sampled from a uniform random distribution <math>\mathcal{U}^{}_[0,10]</math> completely w.l.o.g, since if the components of <math>C_d</math> are random their scaling can be ignored.
+while the output matrix <math>C</math> is sampled from a uniform random distribution <math>\mathcal{U}_{[0,10]}</math> completely w.l.o.g, since if the components of <math>C_d</math> are random their scaling can be ignored.