Yes, this is possible. In the case where `a`

is constant, I guess you called `scipy.integrate.odeint(fun, u0, t, args)`

where `fun`

is defined as in your question, `u0 = [x0, y0, z0]`

is the initial condition, `t`

is a sequence of time points for which to solve for the ODE and `args = (a, b, c)`

are the extra arguments to pass to `fun`

.

In the case where `a`

depends on time, you simply have to reconsider `a`

as a function, for example (given a constant `a0`

):

```
def a(t):
return a0 * t
```

Then you will have to modify `fun`

which computes the derivative at each time step to take the previous change into account:

```
def fun(u, t, a, b, c):
x = u[0]
y = u[1]
z = u[2]
dx_dt = a(t) * x + y * z # A change on this line: a -> a(t)
dy_dt = b * (y - z)
dz_dt = - x * y + c * y - z
return [dx_dt, dy_dt, dz_dt]
```

Eventually, note that `u0`

, `t`

and `args`

remain unchanged and you can again call `scipy.integrate.odeint(fun, u0, t, args)`

.

A word about the correctness of this approach. The performance of the approximation of the numerical integration is affected, I don't know precisely how (no theoretical guarantees) but here is a simple example which works:

```
import matplotlib.pyplot as plt
import numpy as np
import scipy as sp
import scipy.integrate
tmax = 10.0
def a(t):
if t < tmax / 2.0:
return ((tmax / 2.0) - t) / (tmax / 2.0)
else:
return 1.0
def func(x, t, a):
return - (x - a(t))
x0 = 0.8
t = np.linspace(0.0, tmax, 1000)
args = (a,)
y = sp.integrate.odeint(func, x0, t, args)
fig = plt.figure()
ax = fig.add_subplot(111)
h1, = ax.plot(t, y)
h2, = ax.plot(t, [a(s) for s in t])
ax.legend([h1, h2], ["y", "a"])
ax.set_xlabel("t")
ax.grid()
plt.show()
```

I Hope this will help you.