# Find zeros for solutions to differential equations in Mathematica

Given the following code:

``````s := NDSolve[{x''[t] == -x[t], x[0] == 1, x'[0] == 1}, x, {t, 0, 5 }]
Plot[Evaluate[{x[t]} /. s], {t, 0, 3}]
``````

This plots the solution to the differential equation. How would I numerically solve for a zero of x[t] where t ranges between 0 and 3?

-

But what if instead our s is "s := NDSolve[{x'[t]^2 == -x[t]^3 - x[t] + 1, x[0] == 0.5}, x, {t, 0, 5}]" Then the FindRoot function just gives back an error while the plot shows that there is a zero around 0.6 or so.

So:

``````s = NDSolve[{x'[t]^2 == -x[t]^3 - x[t] + 1, x[0] == 0.5},
x, {t, 0, 1}, Method -> "StiffnessSwitching"];
Plot[Evaluate[{x[t]} /. s], {t, 0, 1}]
FindRoot[x[t] /. s[[1]], {t, 0, 1}]
``````

``````{t -> 0.60527}
``````

Edit

Answering rcollyer's comment, the "second line" comes from the squared derivative, as in:

``````s = NDSolve[{x'[t]^2 == Sin[t], x[0] == 0.5}, x[t], {t, 0, Pi}];
Plot[Evaluate[{x[t]} /. s], {t, 0, Pi}]
``````

Coming from:

``````DSolve[{x'[t]^2 == Sin[t]}, x[t], t]
(*
{{x[t] -> C[1] - 2 EllipticE[1/2 (Pi/2 - t), 2]},
{x[t] -> C[1] + 2 EllipticE[1/2 (Pi/2 - t), 2]}}
*)
``````
-
where does the second line come from? – rcollyer Oct 2 '11 at 13:16
@rcollyer See edit – Dr. belisarius Oct 2 '11 at 15:56

`FindRoot` works

``````In[1]:=  FindRoot[x[t] /. s, {t, 0, 3}]
Out[1]:= {t -> 2.35619}
``````
-
But what if instead our s is "s := NDSolve[{x'[t]^2 == -x[t]^3 - x[t] + 1, x[0] == 0.5}, x, {t, 0, 5}]" Then the FindRoot function just gives back an error while the plot shows that there is a zero around 0.6 or so. – ADF Oct 2 '11 at 2:00
@LiKun, I didn't mention it, but there is no purpose for using `:=` (`SetDelayed`) here. It re-executes `NDSolve` every time `s` is accessed, but for your system that isn't necessary. Use `=` (`Set`) instead, then `s` will only be executed once. – rcollyer Oct 2 '11 at 2:14
@LiKun What is the error? it looks like there's a singularity that could be causing the error – Foo Bah Oct 2 '11 at 3:28
@FooBah, there can't be a singularity, its a 2nd order linear differential equation with general solution `a Sin[t] + b Cos[t]`. – rcollyer Oct 2 '11 at 4:18
@rcollyer I was referring to your second part: x'[t]^2 == -x[t]^3 - x[t] + 1 – Foo Bah Oct 2 '11 at 4:31