# Simulating a spring/damper system in Yampa

I'm trying to use Yampa for some basic system simulation like I'd do in Simulink. In this case I want to simulate a spring and damper system, introduced by this simulink tutorial. I've written the following signal functions to represent the system:

``````system = time >>> force >>> displacement

force = constant (m * g)

displacement = feedback (-) (velocity >>> integral) (gain \$ k / m) 0
velocity     = feedback (-) integral                (gain \$ c / m) 0
``````

Where the `feedback` function creates a basic feedback loop and is implemented like this:

``````feedback op a b b0 = loopPre b0 inner
where inner = arr (uncurry op) >>> a >>> (identity &&& b)
``````

Oh, and:

``````gain x = arr (*x)
``````

With sensible positive constants, I get a wildly unstable system:

Is there something obviously wrong in the way I'm constructing feedback loops or applying the integration?

-

Change `integral` to `imIntegral 0`

``````displacement = feedback (-) (velocity >>> imIntegral 0) (gain \$ k / m) 0
velocity     = feedback (-) (imIntegral 0)            (gain \$ c / m) 0
``````

From spring.hs:

Something funny is happening in the integral function, changing to `imIntegral 0` gives the same curve as in matlab.
My guess is that `Integral` is delayed by one sample, since it doesn't have a starting value, changing the behaviour of the loop.
Excellent, thanks heaps for that! I had done some simple tests with `integral` so I didn't think that was an issue. By 'the scale is off', do you mean the horizontal axis? My code doesn't plot time, just the # of each data point. –  Daniel Buckmaster Oct 20 '13 at 21:39
Oh, of course. Try simulating a system that's just `time >>> integral >>> integral`. The first couple of samples are 0 while the integrators warm up. I had no idea that small delay would be enough to destroy the system stability. –  Daniel Buckmaster Oct 20 '13 at 23:11