ODE45, ODE113 How to get the step size in advance?

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Antillar
Antillar on 18 Aug 2011
Commented: Jan on 9 Oct 2017
Hi guys,
Is there any way to get the step size in advance from ODE45, ODE113?

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Answers (3)

Jan
Jan on 18 Aug 2011
No. These solver use adpative methods to determine the stepsize dynamically. Therefore you cannot get it without running the intergration.
Why do you need this?
  2 Comments
Antillar
Antillar on 18 Aug 2011
This is my dilemma:
I set my integration interval to say z=[0 5]. My initial conditions vary in discrete steps as a function of this length, i.e z0=[sech(z) tanh(z)].
Jan
Jan on 18 Aug 2011
I do not get the problem. You can define the interval and the initial conditions, because both do *not* depend on the stepsize.

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Friedrich
Friedrich on 18 Aug 2011
Hi,
ODE45 and ODE113 have variable step size and this size is choosen during solving. So there is no stepsize you can get.
  2 Comments
Antillar
Antillar on 18 Aug 2011
Thank you. Is there some way I can "tap" into the decision made by ODE?
Jan
Jan on 18 Aug 2011
Of course you can modify the stepsize control in a copy (!) of ode45.m. But this is really unsual and I cannot imagine a good reason to do this. Therefore I still assume, that you need something else.

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Floris
Floris on 6 Sep 2011
You can, if you so wish, set a maximum step size using odeset.
See: http://www.mathworks.se/help/techdoc/ref/odeset.html#f92-1039598
But this not really what you want, is it?
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Torsten
Torsten on 6 Oct 2017
Try a stiff solver, e.g. ODE15S.
Best wishes
Torsten.
Jan
Jan on 9 Oct 2017
@Nader: The step size is not reduced arbitrarily in the solver, but such, that the error bounds are not exceeded. If you set a minimal step size and the integrator cannot satisfy the local discretization error, it stops with an error message - and it should do so. Fording the integrator to use too large steps leads to inaccurate results. Therefore I disagree, that this "solves" the problem. In opposite: If this works with another tool, it hides the fact, that the problem is not solved, but that you obtain a rough and perhaps completely wrong result.
Maybe your ODE is stiff. Then follow Torsten's suggestion.
ODE integrators and local optimization tools are fragile. You can get a "final value" even if you drive the tools apart from their specifications. Calling this a "result" without an analysis of the sensitivity (measure how the trajectory reacts to small variations of the inputs or parameters) is not scientifically correct. You can find many publications with such mistakes.

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