Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm using Scipy 14.0 to solve a system of ordinary differential equations describing the dynamics of a gas bubble rising vertically (in the z direction) in a standing still fluid because of buoyancy forces. In particular, I have an equation expressing the rising velocity U as a function of bubble radius R, i.e. U=dz/dt=f(R), and one expressing the radius variation as a function of R and U, i.e. dR/dT=f(R,U). All the rest appearing in the code below are material properties. I'd like to implement something to account for the physical constraint on z which, obviously, is limited by the liquid height H. I consequently implemented a sort of z<=H constraint in order to stop integration in advance if needed: I used set_solout in order to do so. The situation is that the code runs and gives good results, but set_solout is not working at all (it seems like z_constraint is never called actually...). Do you know why? Is there somebody with a more clever idea, may be also in order to interrupt exactly when z=H (i.e. a final value problem) ? is this the right way/tool or should I reformulate the problem?

thanks in advance

Emi

from scipy.integrate import ode 

Db0 = 0.001 # init bubble radius
y0, t0 = [ Db0/2 , 0. ], 0. #init conditions
H = 1

def y_(t,y,g,p0,rho_g,mi_g,sig_g,H):
    R = y[0] 
    z = y[1]
    z_ = ( R**2 * g * rho_g ) / ( 3*mi_g )  #velocity
    R_ = ( R/3 * g * rho_g * z_ ) / ( p0 + rho_g*g*(H-z) + 4/3*sig_g/R ) #R dynamics    
    return [R_, z_]

def z_constraint(t,y):
    H = 1  #should rather be a variable..
    z = y[1] 
    if z >= H:
        flag = -1 
    else:
        flag = 0
    return flag

r = ode( y_ )
r.set_integrator('dopri5')
r.set_initial_value(y0, t0)
r.set_f_params(g, 5*1e5, 2000, 40, 0.31, H)
r.set_solout(z_constraint)

t1 = 6
dt = 0.1

while r.successful() and r.t < t1:
    r.integrate(r.t+dt)
share|improve this question

1 Answer 1

You're running into this issue. For set_solout to work correctly, it must be called right after set_integrator, before set_initial_value. If you introduce this modification into your code (and set a value for g), integration will terminate when z >= H, as you want.

To find the exact time when the bubble reached the surface, you can make a change of variables after the integration is terminated by solout and integrate back with respect to z (rather than t) to z = H. A paper that describes the technique is M. Henon, Physica 5D, 412 (1982); you may also find this discussion helpful. Here's a very simple example in which the time t such that y(t) = 0.5 is found, given dy/dt = -y:

import numpy as np
from scipy.integrate import ode

def f(t, y):
    """Exponential decay: dy/dt = -y."""
    return -y

def solout(t, y):
    if y[0] < 0.5:
        return -1
    else:
        return 0

y_initial = 1
t_initial = 0

r = ode(f).set_integrator('dopri5')
r.set_solout(solout)
r.set_initial_value(y_initial, t_initial)

# Integrate until solout constraint violated
r.integrate(2)

# New system with t as independent variable: see Henon's paper for details.
def g(y, t):
    return -1.0/y

r2 = ode(g).set_integrator('dopri5')
r2.set_initial_value(r.t, r.y)

r2.integrate(0.5)

y_final = r2.t
t_final = r2.y

# Error: difference between found and analytical solution
print t_final - np.log(2)
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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