My colleagues are correct, but I think there is more that can be said. First, to your actual question. The output of `NDSolve`

is a list of the form

```
{{x[t]->InterpolatingFunction[...]}, {x[t]->InterpolatingFunction[...]}, ...}
```

where the second and subsequent replacement rules are only there if more than one solution is present. I have never encountered a case using `NDSolve`

where that is true, but it makes the answer consistent with `Solve`

, where multiple solutions is not uncommon. Therefor, with only one solution, you have a double list, i.e.

```
{{x[t]->InterpolatingFunction[...]}}
```

As per Mr. Wizard, you can use `First`

, or you can use `Part`

, i.e.

```
NDSolve[ ... ][[ 1 ]]
```

which is my preferred method, although it is slightly more difficult to read and may obscure your intent. You should be aware that the `InterpolatingFunction`

that `NDSolve`

returns is a function, and it will accept variables directly. So, the variables on the left hand side of the declarations

```
x[t_] = x[t] /. s
```

and from Belisarius

```
xr[u_] := ((x[t] /. s[[1]]) /. t -> u)
```

are superfluous at best, and the second one requires the replacement to occur every time `xr`

is used. Instead, you can declare

```
x = x[t] /. s
```

and then writing `x[t]`

afterwards will return `IntepolatingFunction[t]`

, exactly like you want. Then, as Belisarius points out, you can use it, or its derivative, in `Plot`

directly, instead of first building a table of values and feeding them into `ListPlot`

.

**Edit**: when I first posted this, I didn't notice a quirk with `NDSolve`

. If you explicitly solve for `x[t]`

not `x`

, then `NDSolve`

returns `InterpolatingFunction[...][t]`

, but if you just solve for `x`

you get what I posted. This quirk allows both the OP's and Belisarius's solutions to function, otherwise the replacement shouldn't occur.