If you have the symbolic toolbox in MATLAB, you can do the following

```
syms x
x=solve('x^2*exp(-x)=y')
x=
(-2)*lambertw(k, -((-1)^l*y^(1/2))/2)
```

Here `lambertw`

is the solution to `y=x*exp(x)`

, which is available as a function in MATLAB. So you can now define a function as,

```
t=@(y,k,l)(-2)*lambertw(k, -((-1)^l*y^(1/2))/2)
```

`lambertw`

is a multivalued function with several branches. The variable `k`

lets you choose a branch of the solution. You need the principal branch, hence `k=0`

. `l`

(lower case L) is just to pick the appropriate square root of `y`

. We need the positive square root, hence `l=0`

. Therefore, you can get the value of `t`

or the time for any value of `y`

by using the function.

So using your example, `t(0.3,0,0)`

gives `0.8291`

.

**EDIT**

I forgot that there are two branches of the solution that give you real outputs (gnovice's answer reminded me of that). So, for both solutions, use

```
t(0.3,[0,-1],0)
```

which gives `0.8921`

and `3.9528`

.