I'll pretend the first one cannot be solved analytically so as to show how one would go about playing with a general ODE in mathematica.

Define

```
p1[n0_, a_, b_, uplim_: 10] :=(n /. First@NDSolve[
{n'[t] == b*n[t]^2 - a*n[t], n[0] == n0},n, {t, 0, uplim}]
```

which returns the solution of the ODE, i.e., `a = p1[.1, 2., 3.]`

and then e.g. `a[.3]`

tells you `n(.3)`

. One can then do something like

```
Show[Table[ans = p1[n0, 1, 1];
Plot[ans[t], {t, 0, 10}, PlotRange \[Rule] Full],
{n0, 0, 1, .05}], PlotRange \[Rule] {{0, 5}, {0, 1}}]
```

which plots a few solutions with different initial values:

or, to gain some insight into the solutions, one can interactively manipulate the values of `a`

, `b`

and `n0`

:

```
Manipulate[
ans = p1[n0, a, b];
Plot[ans[t], {t, 0, 10},PlotRange -> {0, 1}],
{{n0, .1}, 0, 1},
{{a, 1}, 0, 2},
{{b, 1}, 0, 2}]
```

which gives something like

with the controls active (i.e. you move them and the plot changes; try it live to see what I mean; note that you can set parameters for which the initial conditions gives diverging solutions).

Of course this can be made arbitrarily more complicated. Also in this particular case this ODE is easy enough to integrate analytically, but this numerical approach can be applied to generic ODEs (and many PDEs, too).