# How do I force ode45 to take steps of exactly 0.01 on the T axis?

I'm using Matlab to solve a differential equation. I want to force ode45 to take constant steps, so it always increments 0.01 on the T axis while solving the equation. How do I do this?

ode45 is consistently taking optimized, random steps, and I can't seem to work out how to make it take consistent, small steps of 0.01. Here is the code:

``````options= odeset('Reltol',0.001,'Stats','on');

%figure(1);
%clf;
init=[xo yo zo]';
tspan=[to tf];
%tspan = t0:0.01:tf;

[T,Y]=ode45(name,tspan,init,options);
``````
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Based on the documentation for the ode functions, you should be able to do what you have indicated in the commented-out line:

``````tspan = to:0.01:tf;  %# Obtain solutions at specific times
[T,Y] = ode45(name,tspan,init,options);
``````

EDIT:

With respect to the accuracy of solutions when fixed step sizes are used, refer to this excerpt from the above link:

Specifying `tspan` with more than two elements does not affect the internal time steps that the solver uses to traverse the interval from `tspan(1)` to `tspan(end)`. All solvers in the ODE suite obtain output values by means of continuous extensions of the basic formulas. Although a solver does not necessarily step precisely to a time point specified in `tspan`, the solutions produced at the specified time points are of the same order of accuracy as the solutions computed at the internal time points.

So, even when you specify that you want the solution at specific time points, the solvers are still internally taking a number of adaptive steps between the time points that you indicate, coming close to the values at those fixed time points.

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You're right, the docs do suggest that each value can be specified, even though the article I link to suggests it cannot. Unfortunately I can't open my interpreter at the moment to try this out as I'm away from the University network (and licence server!) – Brendan Mar 30 '10 at 23:21
@Brenden: The documentation you link to doesn't actually appear to say you can't have values of the solution returned at specific time points for ODE45. Note the additional information I added above from the documentation. – gnovice Mar 30 '10 at 23:47

ODE45 (speak four-five not fortyfive) calculates the optimal stepsize and even goes back in time if the error is to large, check Runge-Kutta if you are interested. As a user you don't notice this since the output of ODE will be interpolated such that is suits the tspan vector. So if you set tspan to 0:1E-5:1 and you want to integrate a easy ODE such as dydt=-y ODE45 will make a few steps but the vektor you get out of the ode will be in time steps declared in tspan i.e. 1E-5. If you want to integrate the stiff equation dydt=1E2*(1-y)*y ODE45 will make large and very tiny steps but the output will be the same, for the later you should use ode15s because ODE45 can't handle stiff systems.

Hope this helps

cheers Marco

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Welcome to Stack Overflow. Please read Stack Overflow: How to answer – Our Man In Bananas Jul 4 '14 at 11:28
Good answer. Thanks for the info! – Contango Jul 7 '14 at 4:47

Well, you cannot ensure that it will ONLY calculate those steps, but you can ensure the maximum step size (and if you do it small enough you can are almost sure that you have all the desired times and take just those samples):

``````options= odeset('MaxStep',1);
[t,s] = ode45(@myode,tspan,[0;0],options);
``````

to know more you can go to here:

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Your script does not indicate fixed-step size, It only shows that solution will be printed based on the time-step provided. Try check the solution structure of the ODE and you will realize that in fact, it uses a different timestep.

The best way to get it to use a fixed timestep is to ensure that both RelTol and AbsTol are large enough.

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This can be done just need to use a few more commands.

NEW:

```````options= odeset('Reltol',0.001,'Stats','on');

%figure(1);
%clf;
init=[xo yo zo]';
to=some number;
tf= some number;
nsteps= number of points you want function evaluated on.
tspan = linspace(t0,tf, nsteps);

[T,Y]=ode45(@function,tspan,init,options);`
``````

You can verify that it took the number points that you wanted using the command size(variable).

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`ode45` invariably uses adaptive step size, the documentation addresses this issue and recommends other solvers instead for fixed step size - see `ode4` (fourth order Runge-Kutta) which is a fairly safe bet for solving most odes - at least according to Numerical Recipes

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