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I have a mechanical oscillation system defined by a n x n matrix with transfer functions tf( ... ).

W = minreal( [  tf( ... ) ... tf(...) ; ... ; tf( ... ) ... tf(...)  ];

In the following picture you can see some selected frequency responses. It shows various irregularites at high frequencies.

Bode diagram of oscillation system

As I combine this system in Simulink with other high-order systems, the required step-size has to be extremely low or my system is not stable. The simulation time then is tremendously high, which makes it impossible to validate the general funcionality of my model.

For this reason I'd like to apply a low-pass filter on my fransfer matrix, so I could use bigger steps for a faster simulation time. Is there a way to implement this either in my matlab code or within Simulink?

Finally I would like to adjust the threshold frequency depending on how much time I have and which accuracy is required.

I already did some research for appropriate solvers, without success. Any advice regarding solvers would help me as well.

This is the meager list of toolboxes I have available:

Control System Toolbox                                Version 9.3        (R2012a)
Simulink Control Design                               Version 3.5        (R2012a)
System Identification Toolbox                         Version 8.0        (R2012a)

Thank you in advance!

Edit: picture to illustrate the suggestion of @am304

Bode diagram for reduced system from 18th to 4th order

Bode diagram for reduced system from 18th to 4th order, low-pass in my case not required anymore.

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It sounds like you are using a fixed-step solver. I assume your transfer functions are continuous. I would use a variable-step solver, as this will allow the simulation to take larger time steps when it can. ode45 is the default, but if your system is stiff, use ode15s or ode23t. –  am304 Sep 3 '13 at 15:00
My system is stiff. The tolerances I have to define for ode15s or ode23t for a stable system are to tight to decrease my simulation time noticeable. Furthermore the model has to interact with a coupled FE-analysis, which is working with fixed steps. So I try to avaid variable step-sizes, but in the worst case I could solve this problem by editing the interface. –  thewaywewalk Sep 3 '13 at 15:07
Other suggestions: convert your matrix of transfer functions to a state-space system and use the state-space block from Simulink, I suspect it will be more efficient (certainly much more readable if n is large). Also, maybe look at reducing the order of your system (n) (see mathworks.co.uk/help/control/model-simplification-1.html for more details). –  am304 Sep 3 '13 at 15:09
@am304 your suggestion to reduce the order of my system seems to work perfectly for me as my high frequent magnitudes are very small anyway. So I would appreciate if you post it as an answer. BUT, for answering the general case of my question, still there could be need for a low-pass filter. I added a picture which illustrates, that the damping of high frequencies is propably not sufficient in any case. –  thewaywewalk Sep 3 '13 at 15:57
@am304 the use of balred caused a speedup of 35% the combination of balred and balreal (transformation to state space) finally got me a speed up of 83%. Thank you very much! –  thewaywewalk Sep 3 '13 at 16:11

2 Answers 2

up vote 1 down vote accepted

As suggested in the comments, convert your matrix of transfer functions to a state-space system and use the state-space block from Simulink, I suspect it will be more efficient (certainly much more readable if n is large).

Also, maybe look at reducing the order of your system (n) (see Model Simplification in the documentation for more details - in particular look for balred and balreal)

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I would advise against using tf objects, since they might have numerical problems for high-order systems. If you convert to zpk objects instead, you will see that the systems naturally gets factored into series of (complex) poles and zeros, which directly correspond to the resonant features you see in your spectrum. Instead of low-pass filtering, you could then simply throw away all poles or zeros that are above a certain threshold frequency. Something like this (untested):

T = tf(...)

%convert to zpk first
Z = zpk(T);
zero = Z.z{1};
pole = Z.p{1};

%calculate frequencies
zero_freq = abs(zero) / (2*pi);
pole_freq = abs(pole) / (2*pi);

%only keep poles and zeros below threshold frequency
Z.z{1} = zero(zero_freq < f_threshold);
Z.p{1} = pole(pole_freq < f_threshold);

Similar tricks might be possible with ss systems, but I don't have much experience with those.

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I don't get any effect. But if it would work and I understand you right, it would do exact the same like the suggestion above ("throwing away" poles and hence reduce the order)? Indeed I see the point that in this case I could choose the frequency instead of the order which makes it easier to specify exactly the applied simplification. Finally it should be possible to re-convert the system to a state space again, as I get that huge speed up. –  thewaywewalk Sep 4 '13 at 8:06
I guess the methods are somewhat similar, but again, I am not a big expert on ss systems. If you work with big MIMO systems, a ss description is probably better than using a matrix of tf / zpk systems. One difference is that the model simplification functions do stuff like removing pole-zero pairs that almost cancel (which are not necessary at high-frequency), using some complicated algorithm. My method just throws away all high frequency stuff, in a way that I can understand. With ss systems, I always find it bit hard to imagine what is going on, it is all complex mathematics. –  Bas Swinckels Sep 4 '13 at 8:25

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