How do I numerically solve an ODE in Python?


equation to solve

\ddot{u}(\phi) = -u + \sqrt{u}

with the following conditions

u(0) = 1.49907


\dot{u}(0) = 0

with the constraint

0 <= \phi <= 7\pi.

Then finally, I want to produce a parametric plot where the x and y coordinates are generated as a function of u.

The problem is, I need to run odeint twice since this is a second order differential equation. I tried having it run again after the first time but it comes back with a Jacobian error. There must be a way to run it twice all at once.

Here is the error:

odepack.error: The function and its Jacobian must be callable functions

which the code below generates. The line in question is the sol = odeint.

import numpy as np
from scipy.integrate import odeint
import matplotlib.pyplot as plt
from numpy import linspace

def f(u, t):
    return -u + np.sqrt(u)

times = linspace(0.0001, 7 * np.pi, 1000)
y0 = 1.49907
yprime0 = 0
yvals = odeint(f, yprime0, times)

sol = odeint(yvals, y0, times)

x = 1 / sol * np.cos(times)
y = 1 / sol * np.sin(times)




I am trying to construct the plot on page 9

Classical Mechanics Taylor

Here is the plot with Mathematica

mathematica plot

In[27]:= sol = 
 NDSolve[{y''[t] == -y[t] + Sqrt[y[t]], y[0] == 1/.66707928, 
   y'[0] == 0}, y, {t, 0, 10*\[Pi]}];

In[28]:= ysol = y[t] /. sol[[1]];

In[30]:= ParametricPlot[{1/ysol*Cos[t], 1/ysol*Sin[t]}, {t, 0, 
  7 \[Pi]}, PlotRange -> {{-2, 2}, {-2.5, 2.5}}]
import scipy.integrate as integrate
import matplotlib.pyplot as plt
import numpy as np

pi = np.pi
sqrt = np.sqrt
cos = np.cos
sin = np.sin

def deriv_z(z, phi):
    u, udot = z
    return [udot, -u + sqrt(u)]

phi = np.linspace(0, 7.0*pi, 2000)
zinit = [1.49907, 0]
z = integrate.odeint(deriv_z, zinit, phi)
u, udot = z.T
# plt.plot(phi, u)
fig, ax = plt.subplots()
ax.plot(1/u*cos(phi), 1/u*sin(phi))

enter image description here

| improve this answer | |
  • 1
    It should be zinit = [1.49907, 0] (misplaced dot). – jorgeca Apr 11 '13 at 21:50
  • 1
    @jorgeca: Thanks. I didn't realize the question had changed. – unutbu Apr 11 '13 at 22:18

The code from your other question is really close to what you want. Two changes are needed:

  • You were solving a different ODE (because you changed two signs inside function deriv)
  • The y component of your desired plot comes from the solution values, not from the values of the first derivative of the solution, so you need to replace u[:,0] (function values) for u[:, 1] (derivatives).

This is the end result:

import numpy as np
import matplotlib.pyplot as plt
from scipy.integrate import odeint

def deriv(u, t):
    return np.array([u[1], -u[0] + np.sqrt(u[0])])

time = np.arange(0.01, 7 * np.pi, 0.0001)
uinit = np.array([1.49907, 0])
u = odeint(deriv, uinit, time)

x = 1 / u[:, 0] * np.cos(time)
y = 1 / u[:, 0] * np.sin(time)

plt.plot(x, y)

However, I suggest that you use the code from unutbu's answer because it's self documenting (u, udot = z) and uses np.linspace instead of np.arange. Then, run this to get your desired figure:

x = 1 / u * np.cos(phi)
y = 1 / u * np.sin(phi)
plt.plot(x, y)
| improve this answer | |

You can use scipy.integrate.ode. To solve dy/dt = f(t,y), with initial condition y(t0)=y0, at time=t1 with 4th order Runge-Kutta you could do something like this:

from scipy.integrate import ode
solver = ode(f).set_integrator('dopri5')
solver.set_initial_value(y0, t0)
dt = 0.1
while t < t1:
    y = solver.integrate(t+dt)
    t += dt

Edit: You have to get your derivative to first order to use numerical integration. This you can achieve by setting e.g. z1=u and z2=du/dt, after which you have dz1/dt = z2 and dz2/dt = d^2u/dt^2. Substitute these into your original equation, and simply iterate over the vector dZ/dt, which is first order.

Edit 2: Here's an example code for the whole thing:

import numpy as np
import matplotlib.pyplot as plt

from numpy import sqrt, pi, sin, cos
from scipy.integrate import ode

# use z = [z1, z2] = [u, u']
# and then f = z' = [u', u''] = [z2, -z1+sqrt(z1)]
def f(phi, z):
    return [z[1], -z[0]+sqrt(z[0])]

# initialize the 4th order Runge-Kutta solver
solver = ode(f).set_integrator('dopri5')

# initial value
z0 = [1.49907, 0.]

values = 1000
phi = np.linspace(0.0001, 7.*pi, values)
u = np.zeros(values)

for ii in range(values):
    u[ii] = solver.integrate(phi[ii])[0] #z[0]=u

x = 1. / u * cos(phi)
y = 1. / u * sin(phi)

| improve this answer | |
  • Sure, I've added that as an edit. I prefer to use the more flexible scipy.integrate.ode instead of odeint, though it can be a bit more complicated to set up. – HenriV May 3 '13 at 13:35

scipy.integrate() does ODE integration. Is that what you are looking for?

| improve this answer | |

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.