You need to observe that the first equation once differentiated with respect to `t`

can be used to substitute for `v[t]`

. But then the second equation becomes a ODE of second order and requires to be supplied with another extra initial condition. We will give

```
v[0]==x'[0]==some number
```

Then after solving this ODE for `x`

you can recover `v[t]==x'[t]`

I give you the solution in term of a `Manipulate`

so that geometrically the situation becomes clear to you.

```
(* First equation *)
v[t] = x'[t];
(*
Differentiate this equation once and substitute
for v[t] in the second equation
*)
Manipulate[
With[{u = Constant, der = derval},
res = NDSolve[{x''[t] == -x[t] - u*x'[t]^3, x[0.] == 2,x'[0.] == der},
x, {t, 0., 30.}] // First;
Plot[Evaluate[{x[t], v[t]} /. res], {t, 0, 30}, PlotRange -> All,
Frame -> True,Axes -> None, ImageSize -> 600]
],
{{Constant, 0.,TraditionalForm@(u)}, 0.,3, .1},
{{derval, -3., TraditionalForm@(v[0] == x'[0])}, -3, 3, .1}
]
```

Hope this helps you but next time before you ask you need to brush up the theory first as you can see the question you asked concerns very basic and elementary Mathematics not Mathematica programming. Good luck!!