# using scipy odeint on equations with a phase shifted variable

Basically... I need a way to include a phase shift in my differential equations. That is, I have in the definition of my system function which returns dY/dt something like Y(t-3). Like this differential equation:

``````dY/dt = a*Y(t) + b*Y(t-tau)
``````

Now if I try to write this as the system definition function for passing to scipy.odeint, I am lost:

``````def eqtnSystem(A,t):
Y   = A
a   = 1
b   = 5
tau = 3
return a*Y + b*???       # how do I Y(t-tau) ?
``````

That's basically it. I really hope there is an easy answer, but I couldn't seem to track one down.

Specifically... I am attempting to numerically calculate the solution for the system defined by the following function:

``````def etaFunc(A,t):
#...definition of all those constants is here...
return array([(gamma[0,0]*xi(t-theta[0])[0] - eta[0] + zeta[0])/tau[0],\
(gamma[1,1]*xi(t-theta[1])[1] - eta[1] + zeta[1])/tau[1],\
(gamma[2,2]*xi(t-theta[2])[2] - eta[2] + zeta[2])/tau[2],\
(   beta[3,0]*pastEta(t-theta[3])[0] \
+ beta[3,1]*pastEta(t-theta[4])[1] \
+ beta[3,2]*pastEta(t-theta[5])[2] -eta[3]+ zeta[3])/tau[3],\
(   beta[4,3]*pastEta(t-theta[6])[3] \
+ beta[4,2]*pastEta(t-theta[7])[2] - eta[4] + zeta[4])/tau[4]])
``````

This function is then later given to odeint like this:

``````ETA = integrate.odeint(etaFunc,initCond,time)
``````

and then I can get out each individual component of ETA (like eta_0) like this: `ETA[:,0]`.

The problem I am having here, is with `pastEta(t-theta[?])`. For right now, this is a function which attempts to find already calculated values of eta (for when `start_time < t-theta[?] < t` and `theta[?] > 0`. This isn't working very well.

I see in this case I could find each component of eta individually and then get calculated values for previously calculated eta components (eta_0,eta_1,eta_2) to calculate eta_3 and similarly for eta_4, but this is not ideal since it takes away the ability for me to 'plug-and-play' any general formulas.

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## 2 Answers

There are a number of existing libraries and examples for doing this.

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Thanks so much! I missed all these somehow; I'll call it 'delay' from now on. –  7yl4r Apr 4 '13 at 19:23
+1: These methods appear to use the approach that I described in my answer, but save the need to build it oneself, so they are much to be preferred. –  Simon Apr 4 '13 at 20:01
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One way to do this with `integrate.odeint()` would be to run `integrate.odeint()` for many short time intervals between your starting time and your ending time, storing the time value and the output Y value after each short interval in lists. That would let you interpolate the Y value in the lists using scipy.interpolate.interp1d(), for instance, each time you needed `Y(t-3)`.

You only end up with an approximate value for `Y(t-3)` if you do it this way, of course, but if the time intervals are close enough together, this approach might be satisfactory for you. After all, the `Y(t)` values calculated by numerical ODE solvers are approximate too.

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Ah yes... this could work so long as the phase shift is negative. I'm surprised odeint doesn't have any built-in functionality for this though. It seems like it would be a fairly common problem. –  7yl4r Apr 4 '13 at 15:11
@7yl4r: The problem is harder if it involves a positive phase shift because the ODE is no longer solvable as an initial value problem and different methods are required. –  Simon Apr 4 '13 at 19:55
That makes sense now. Thanks so much for your help. –  7yl4r Apr 6 '13 at 16:56
@7yl4r: You could now accept your preferred answer by checking or ticking the one that you've found most useful. If you don't have a strong preference for either answer, I'd suggest accepting pv's answer because it is more immediately useful than mine. –  Simon Apr 6 '13 at 20:23
Thanks Simon. I found them both very useful - yours for the concept, and pv's for the implementation. –  7yl4r Apr 10 '13 at 2:35
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