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Apparently, getting a non-negative solution from an ODE solver is non-trivial. In Matlab, there is the NonNegative option for certain solvers to get a non-negative solution. Is there a similar option in scipy?

If not, what is the "best" way of imposing a non-negativity constraint? At the moment, I have something like the following:

def f(x, t, params):
     ... ... ...
     ... ... ...
     x_dot[(x <= 0) * (x_dot <= 0)] = 0.0
     return x_dot
... ... ...
x = odeint(f, x0, t, args=params)

However, this leads to numerical instabilities. I've needed to set mxstep to 1e8 and hmin=1e-15.

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As the links you pointed to make clear, there isn't necessarily an easy solution. What is the nature of your nonnegative solution, and why does it cause a problem? There are at least three possibilities: (1) the solution converges to a stable equilibrium at 0, but because of normal numerical errors, it goes slightly below 0 (and may oscillate around 0) (e.g. dx/dt = -2*x); (2) 0 is a "semi-stable" equilibrium, so if the solution goes negative, it blows up (e.g. dx/dt = -x**2); (3) the differential equation is not defined for negative x (e.g. dx/dt = -sqrt(x). –  Warren Weckesser Jan 26 '14 at 19:36
(3): the ODE is not defined for negative x because of a square root. –  carmichael561 Jan 26 '14 at 20:48
I impose similar constraints to you and haven't run into any problems. Can you post your ODE system? –  boyfarrell Mar 8 '14 at 16:37

1 Answer 1

The problem is not merely that you have to avoid square rooting the negative x. The problem is that the "best" way of imposing the constraint still depends on what your system's application is and what behavior you assume to be "reasonable". If your system does not have an equilibrium at 0 then your problem may be ill-posed. What could be the meaning for it to move at non-zero speed into the negative-x domain? If the interpretation is that the solution should stay at zero, then you actually no longer have an ODE system as your intended model: you have a hybrid dynamical system with a non-smooth component, i.e. when the trajectory x(t) hits 0 at t = t_1, it must stay at x(t) for all t > t_1. This can be easily achieved with a proper dynamical systems package such as PyDSTool.

Alternatively, x=0 is a stable equilibrium and you simply need to prevent evaluation of f for x<0. This can also be hacked with event detection.

In either case, event detection at x=0 is tricky when your f is undefined for x<0. There are few standard ODE solvers that can literally be forced to avoid evaluating in a sub-domain under all circumstances, and most event detection will involve evaluations on either side of a boundary. A pragmatic solution is to choose a small number for x below which it is safe (in the context of your application) to declare x = 0. Then make the event detect when x reaches that (which, given that you can control the step size to stay small enough) should prevent x ever being evaluated at a negative value. Then you'd make a condition to make x = 0 after that point, if that is the behavior you want. Again, that's a bit of fuss in scipy/python but you can do it. It's also fairly easy to set up the desired behavior in PyDSTool, which I'd be willing to advise you on if you post in its help forums.

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