>>> def f(x):
... return x*14.80461 + x*(-4.9233) + x*(10*0.4803)
>>> def vf(x):
... return [f(x), 0, 0]
>> xx = fsolve(vf, x0=[0,0,1])
Since the solution is not unique, different initial values for an unknown lead to different (valid) solutions.
EDIT: Why this works. Well, it's a dirty hack. It's just that
fsolve and its relatives deal with systems of equations. What I did here, I defined a system of three equations (
f(x) returns a three-element list) for three variables (
x has three elements). Now
fsolve uses a Newton-type algorithm to converge to a solution.
Clearly, the system is underdefined: you can specify arbitrary values of two variables, say,
x and find
x to satisfy the only non-trivial equation you have. You can see this explicitly by specifying a couple of initial guesses for
x0 and see different outputs, all of which satisfy
f(x)=0 up to a certain tolerance.