I would want to solve a differential equation in MATLAB

```
odeopts = odeset('MaxStep',dt);
[t,X] = ode113(@MyDiff,tSpan,X0,odeopts);
```

Here `dt`

, `MyDiff`

, `tSpan`

and `X0`

are defined earlier in the code. The problem is, that the discretisation step `dt`

is very small, while the total simulation time `tSpan(end)`

is very large. Furthermore, the solution is expected to become periodic from some time T with period `P`

. Here, the period `P`

is known a priori, while the time `T`

is not.

What I would want to do is to automatically stop the ode113-solver when the solution `X`

has become periodic, in order to save computational time. I would appreciate any thoughts on how I should do this.

My thoughts until now:

The first subproblem is how to stop the Matlab solver when periodicity is discovered. MATLAB has included the option to stop the ode113-solver by an event-function:

`odeopts = odeset('MaxStep',dt,'Events',MyEventFcn);`

However, `MyEventFcn`

has to be a function of `t`

and `X`

at the current time step. It seems impossible to determine periodicity by this information. The only way around seems to me to use a global parameter that includes the `X`

values at all previous time up to two times the expected period `P`

. However, this seems quite inelegant and inefficient to me, and I was hoping there is a better way.

- The second problem is how to determine that the solution
`X`

is periodic with period`P`

. At the moment I'm thinking that the best way is to use a threshold to the autocorrelation function,`xcorr(X)`

, but I'm not certain yet about the details, so any suggestions here would also be useful.

Edit: I implemented a solution, pretty much following my earlier thoughts, using a global variable to keep track of the X-values and using xcorr to detect periodicity. After thinking a while, this actually seems the most straightforward way to do it.