1

I have this code to solve a simple first order ODE using odeint. I managed to plot the solution y(r), but I also want to plot the derivative y'= dy/dr. I know y' it is given by f(y,r), but I'm not sure how to call the function with the output of the integration. Thank you in advance.

    from math import sqrt
    from numpy import zeros,linspace,array
    from scipy.integrate import odeint
    import matplotlib.pylab as plt

    def f(y,r):
        f = zeros(1)
        f[0] = -(y[0]*(y[0]-1.0)/r)-y[0]*(2/r+\
        ((r/m)/(1-r**2/m))*(2*sqrt(1-r**2/m)-k)/(k-sqrt(1-r**2/m)))\
        -(1/(1-r**2/m))*(-l*(l+1)/r+\
         (3*r/m)*(k+2*sqrt(1-r**2/m))/(k-sqrt(1-r**2/m)))\
        +((4*r**3)/((m**2)*(1-r**2/m)))*(1/(k-sqrt(1-r**2/m))**2)
        return f

    m = 1.15            
    k = 3*sqrt(1-1/m)
    l = 2.0
    r = 1.0e-10                         
    rf = 1.0                         

    rspan = linspace(r,rf,1000)
    y0 = array([l])
    sol = odeint(f,y0,rspan)
    plt.plot(rspan,sol,'k:',lw=1.5)
1

From odeint documentation:

For new code, use scipy.integrate.solve_ivp to solve a differential equation.

I have modified your code in the following manner and obtained the figure below.

import matplotlib.pyplot as plt
from numpy import gradient, squeeze, sqrt
from scipy.integrate import solve_ivp


def fun(t, y):
    l = 2
    m = 1.15
    k = 3 * sqrt(1 - 1 / m)
    return (-y * (y - 1) / t - y * (2 / t + t / m / (1 - t ** 2 / m)
                                    * (2 * sqrt(1 - t ** 2 / m) - k)
                                    / (k - sqrt(1 - t ** 2 / m)))
            - 1 / (1 - t ** 2 / m) * (-l * (l + 1) / t + 3 * t / m
                                      * (k + 2 * sqrt(1 - t ** 2 / m))
                                      / (k - sqrt(1 - t ** 2 / m)))
            + 4 * t ** 3 / m ** 2 / (1 - t ** 2 / m)
            / (k - sqrt(1 - t ** 2 / m)) ** 2)


sol = solve_ivp(fun, t_span=[1e-10, 1], y0=[2], method='BDF',
                dense_output=True)
if sol.success is True:
    print(sol.t.shape, sol.y.shape)
    plt.plot(sol.t, squeeze(sol.y), color='xkcd:avocado',
             label='Scipy Solution')
    plt.plot(sol.t, fun(sol.t, squeeze(sol.y)), linestyle='dashed',
             color='xkcd:purple', label='Derivative Using the Function')
    plt.plot(sol.t, gradient(squeeze(sol.y), sol.t), linestyle='dotted',
             color='xkcd:bright orange', label='Derivative Using Numpy')
    plt.legend()
    plt.tight_layout()
    plt.savefig('so.png', bbox_inches='tight', dpi=300)
    plt.show()

enter image description here

To address the comment about squeeze, please see below (extracted from scipy.integrate.solve_ivp):

enter image description here

where n is defined according to:

enter image description here

6
  • What is squeeze? Why is it necessary?
    – gboffi
    Nov 14 '19 at 12:13
  • Doc is here (docs.scipy.org/doc/numpy/reference/generated/numpy.squeeze.html). After the if condition, if you execute print(sol.t.shape, sol.y.shape), you should get (32,) (1, 32), which shows that t is 1D while y is 2D. Therefore, squeeze is needed.
    – Patol75
    Nov 14 '19 at 12:21
  • I know... what I mean is that your answer is not complete.
    – gboffi
    Nov 14 '19 at 13:44
  • I think it's correct, I checked your code with my equation again and it works. I think you missed something when you rewrote the ODE. I did not know about the squeeze, thank you!
    – CamPos
    Nov 14 '19 at 20:56
  • @CamPos You are right, I had a * instead of a / in the before-last line. Would you mind accepting the answer (see here stackoverflow.com/help/someone-answers) if it helped you? Thank you.
    – Patol75
    Nov 14 '19 at 23:10

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