Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I wanted to store the different integration steps taken by the solver itself when I call it :


So I did a while loop and enabled the step option setting its value to True:

while solver1.successful() and solver1.t < t0+dt:

Then I plot y, the result of integration and here comes my issue. I have instabilities which appear in a located area :

y enabling the step option of the solver

I thought it was because of the loop or something like that so I checked the result removing the step :

while solver1.successful() and solver1.t < t0+dt:

And surprise ... I have the correct result :

y disabling the step option of the solver

It's a quite weird situation ... I'd be grateful if someone of your guys could help me with this issue.


To set the solver I do :

solver1 = ode(y_dot,jac).set_integrator('vode',with_jacobian=True)

And I store the result using .append()

share|improve this question
Can you show some more of your code, how you set up the solver and store the result for plotting? – silvado Mar 20 '13 at 15:36
Of course, I've just edited my question. – kuider Mar 21 '13 at 8:28
You still haven't shown how you are actually storing the current ODE state which you are plotting, presuming that the plots show one of the ODE state variables. – Nikolas Apr 2 '13 at 18:41

When you set step=True you are indirectly giving the vode._integrator.runner (a Fortran subroutine) an instruction to use itask=2, and the default is itask=1. You can get more details about this runner doing:


In SciPy 0.12.0 documentation you will not find an explanation about what is going on for the different itask=1 or itask=2, but you can find it here:

ITASK  = An index specifying the task to be performed.
!          Input only. ITASK has the following values and meanings.
!          1  means normal computation of output values of y(t) at
!             t = TOUT(by overshooting and interpolating).
!          2  means take one step only and return.
!          3  means stop at the first internal mesh point at or
!             beyond t = TOUT and return.
!          4  means normal computation of output values of y(t) at
!             t = TOUT but without overshooting t = TCRIT.
!             TCRIT must be input as RUSER(1). TCRIT may be equal to
!             or beyond TOUT, but not behind it in the direction of
!             integration. This option is useful if the problem
!             has a singularity at or beyond t = TCRIT.
!          5  means take one step, without passing TCRIT, and return.
!             TCRIT must be input as RUSER(1).
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.