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) - eta + zeta)/tau,\ (gamma[1,1]*xi(t-theta) - eta + zeta)/tau,\ (gamma[2,2]*xi(t-theta) - eta + zeta)/tau,\ ( beta[3,0]*pastEta(t-theta) \ + beta[3,1]*pastEta(t-theta) \ + beta[3,2]*pastEta(t-theta) -eta+ zeta)/tau,\ ( beta[4,3]*pastEta(t-theta) \ + beta[4,2]*pastEta(t-theta) - eta + zeta)/tau])
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:
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.