In addition to SciPy methods `odeint`

and `ode`

that were already mentioned, it now has `solve_ivp`

which is newer and often more convenient. A complete example, encoding `[v11, v22, v12]`

as an array `v`

:

```
from scipy.integrate import solve_ivp
def rhs(s, v):
return [-12*v[2]**2, 12*v[2]**2, 6*v[0]*v[2] - 6*v[2]*v[1] - 36*v[2]]
res = solve_ivp(rhs, (0, 0.1), [2, 3, 4])
```

This solves the system on the interval `(0, 0.1)`

with initial value `[2, 3, 4]`

. The result has independent variable (s in your notation) as `res.t`

:

```
array([ 0. , 0.01410735, 0.03114023, 0.04650042, 0.06204205,
0.07758368, 0.0931253 , 0.1 ])
```

These values were chosen automatically. One can provide `t_eval`

to have the solution evaluated at desired points: for example, `t_eval=np.linspace(0, 0.1)`

.

The dependent variable (the function we are looking for) is in `res.y`

:

```
array([[ 2. , 0.54560138, 0.2400736 , 0.20555144, 0.2006393 ,
0.19995753, 0.1998629 , 0.1998538 ],
[ 3. , 4.45439862, 4.7599264 , 4.79444856, 4.7993607 ,
4.80004247, 4.8001371 , 4.8001462 ],
[ 4. , 1.89500744, 0.65818761, 0.24868116, 0.09268216,
0.0345318 , 0.01286543, 0.00830872]])
```

With Matplotlib, this solution is plotted as `plt.plot(res.t, res.y.T)`

(the plot would be smoother if I provided `t_eval`

as mentioned).

Finally, if the system involved equations of order higher than 1, one would need to use reduction to a 1st order system.

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