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The (brief) documentation for scipy.integrate.ode says that two methods (dopri5 and dop853) have stepsize control and dense output. Looking at the examples and the code itself, I can only see a very simple way to get output from an integrator. Namely, it looks like you just step the integrator forward by some fixed dt, get the function value(s) at that time, and repeat.

My problem has pretty variable timescales, so I'd like to just get the values at whatever time steps it needs to evaluate to achieve the required tolerances. That is, early on, things are changing slowly, so the output time steps can be big. But as things get interesting, the output time steps have to be smaller. I don't actually want dense output at equal intervals, I just want the time steps the adaptive function uses.

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3 Answers 3

up vote 6 down vote accepted

I've been looking at this to try to get the same result. It turns out you can use a hack to get the step-by-step results by setting nsteps=1 in the ode instantiation. It will generate a UserWarning at every step (this can be caught and suppressed).

import numpy as np
from scipy.integrate import ode
import matplotlib.pyplot as plt
import warnings


def logistic(t, y, r):
    return r * y * (1.0 - y)

r = .01
t0 = 0
y0 = 1e-5
t1 = 5000.0

#backend = 'vode'
backend = 'dopri5'
#backend = 'dop853'

solver = ode(logistic).set_integrator(backend, nsteps=1)
solver.set_initial_value(y0, t0).set_f_params(r)
# suppress Fortran-printed warning
solver._integrator.iwork[2] = -1

sol = []
warnings.filterwarnings("ignore", category=UserWarning)
while solver.t < t1:
    solver.integrate(t1, step=True)
    sol.append([solver.t, solver.y])
warnings.resetwarnings()
sol = np.array(sol)

plt.plot(sol[:,0], sol[:,1], 'b.-')
plt.show()

result:

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That seems to do the job, alright. Now, if only I hadn't spent weeks porting my code to GSL... :) –  Mike Jan 22 '13 at 22:41
2  
It turns out you can suppress the Fortran-emitted warning with this little hack solver._integrator.iwork[2] = -1 (I'll edit the above code to show this). This sets a flag passed through the Fortran interface that suppresses printing to stdout. –  Tim D Jan 23 '13 at 21:35

The integrate method accepts a boolean argument step that tells the method to return a single internal step. However, it appears that the 'dopri5' and 'dop853' solvers do not support it.

The following code shows how you can get the internal steps taken by the solver when the 'vode' solver is used:

import numpy as np
from scipy.integrate import ode
import matplotlib.pyplot as plt


def logistic(t, y, r):
    return r * y * (1.0 - y)

r = .01

t0 = 0
y0 = 1e-5
t1 = 5000.0

backend = 'vode'
#backend = 'dopri5'
#backend = 'dop853'
solver = ode(logistic).set_integrator(backend)
solver.set_initial_value(y0, t0).set_f_params(r)

sol = []
while solver.successful() and solver.t < t1:
    solver.integrate(t1, step=True)
    sol.append([solver.t, solver.y])

sol = np.array(sol)

plt.plot(sol[:,0], sol[:,1], 'b.-')
plt.show()

Result: Plot of the solution

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1  
Yeah, I was afraid that was the case. I was hoping that there'd be an easy way to extend dopri5 and dop853, but my patience ends at fortran, so I think I'll just re-implement a time stepper. Seems a shame, though, that python is left without robust, efficient, and flexible integrators... –  Mike Oct 17 '12 at 14:59
    
I needed this same functionality while trying to convert a MATLAB script that uses ode45. I've submitted a ticket at Scipy.org Ticket#1820. –  Tim D Jan 22 '13 at 20:19
    
@Mike: Well, even with dopri5 and dop853 you could always store the value from inside the logistic function and just do a single call to the integrate method. (I'm going to post this as alternative answer.) –  balu Dec 1 at 17:00
    
On another note: I like it how the step=True feature isn't documented at all. –  balu Dec 1 at 17:01

Here's another option that should also work with dopri5 and dop853. Basically, the solver will call the logistic() function as often as needed to calculate intermediate values so that's where we store the results:

import numpy as np
from scipy.integrate import ode
import matplotlib.pyplot as plt

sol = []
def logistic(t, y, r):
    sol.append([t, y])
    return r * y * (1.0 - y)

r = .01

t0 = 0
y0 = 1e-5
t1 = 5000.0
# Maximum number of steps that the integrator is allowed 
# to do along the whole interval [t0, t1].
N = 10000

#backend = 'vode'
backend = 'dopri5'
#backend = 'dop853'
solver = ode(logistic).set_integrator(backend, nsteps=N)
solver.set_initial_value(y0, t0).set_f_params(r)

# Single call to solver.integrate()
solver.integrate(t1)
sol = np.array(sol)

plt.plot(sol[:,0], sol[:,1], 'b.-')
plt.show()
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There are three time steps involved here. The largest is the output time step; what ode outputs by default. Then we have the integrator's adaptive time step, which is where I want the output. The smallest is the intermediate time step that Runge-Kutta-style integrators (e.g., dopri5, dop853) use. That is, dopri5 will actually call logistic several times during intermediate steps taken to make up a single time step. My concern is that I believe those intermediate steps have lower-order accuracy; the y value is actually only first-order accurate in many cases. –  Mike Dec 1 at 17:36
    
"I believe those intermediate steps have lower-order accuracy" Oops, I thought logistic would be called with the integrator's adaptive time step. If not, my answer of course doesn't help. But are sure about that? –  balu Dec 1 at 17:43
    
The idea is to build up better approximations to the correct increment; combining the results of multiple calls allows you to cancel some error terms. In fact, now that I look at it, Wikipedia's article has a section explaining "The Runge-Kutta method", in which it shows that the function is evaluated at the step-midpoint twice with different values. So your sol would actually be storing two different y values for the same t value in some cases, because the first was less accurate. –  Mike Dec 1 at 17:52

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