# Python: Finding multiple roots of nonlinear equation

Assume the following function:

`f(x) = x * cos(x-4)`

With `x = [-2.5, 2.5]` this function crosses `0` at `f(0) = 0` and `f(-0.71238898) = 0`.

This was determined with the following code:

``````import math
from scipy.optimize import fsolve
def func(x):
return x*math.cos(x-4)
x0 = fsolve(func, 0.0)
# returns [0.]
x0 = fsolve(func, -0.75)
# returns [-0.71238898]
``````

What is the proper way to use `fzero` (or any other Python root finder) to find both roots in one call? Is there a different `scipy` function that does this?

`fzero` reference

• Maybe my math is hazy, but isn't `f(0) = 2` there? Commented Oct 24, 2012 at 17:48
• @mayhewr. Looks like your math is not that hazy. ;) Commented Oct 24, 2012 at 17:52
• @strimp099: f(x) is totally different from func(x). So which one are you trying to solve? Commented Oct 24, 2012 at 18:15
• Sorry, very sloppy. Updated f(x) Commented Oct 24, 2012 at 18:31
• This series of message in the Scipy mailing list might be relevant: mail.scipy.org/pipermail/scipy-user/2007-September/013870.html Commented Oct 24, 2012 at 18:43

I once wrote a module for this task. It's based on chapter 4.3 from the book Numerical Methods in Engineering with Python by Jaan Kiusalaas:

``````import math

def rootsearch(f,a,b,dx):
x1 = a; f1 = f(a)
x2 = a + dx; f2 = f(x2)
while f1*f2 > 0.0:
if x1 >= b:
return None,None
x1 = x2; f1 = f2
x2 = x1 + dx; f2 = f(x2)
return x1,x2

def bisect(f,x1,x2,switch=0,epsilon=1.0e-9):
f1 = f(x1)
if f1 == 0.0:
return x1
f2 = f(x2)
if f2 == 0.0:
return x2
if f1*f2 > 0.0:
print('Root is not bracketed')
return None
n = int(math.ceil(math.log(abs(x2 - x1)/epsilon)/math.log(2.0)))
for i in range(n):
x3 = 0.5*(x1 + x2); f3 = f(x3)
if (switch == 1) and (abs(f3) >abs(f1)) and (abs(f3) > abs(f2)):
return None
if f3 == 0.0:
return x3
if f2*f3 < 0.0:
x1 = x3
f1 = f3
else:
x2 =x3
f2 = f3
return (x1 + x2)/2.0

def roots(f, a, b, eps=1e-6):
print ('The roots on the interval [%f, %f] are:' % (a,b))
while 1:
x1,x2 = rootsearch(f,a,b,eps)
if x1 != None:
a = x2
root = bisect(f,x1,x2,1)
if root != None:
pass
print (round(root,-int(math.log(eps, 10))))
else:
print ('\nDone')
break

f=lambda x:x*math.cos(x-4)
roots(f, -3, 3)
``````

`roots` finds all roots of `f` in the interval [`a`, `b`].

• thanks for the script. in python version 2.x math.ceil returns a float, so you need to convert n to int(n) Commented Feb 4, 2015 at 8:10
• @halex you're my hero Commented Jun 10, 2020 at 13:14

Define your function so that it can take either a scalar or a numpy array as an argument:

``````>>> import numpy as np
>>> f = lambda x : x * np.cos(x-4)
``````

Then pass a vector of arguments to `fsolve`.

``````>>> x = np.array([0.0, -0.75])
>>> fsolve(f,x)
array([ 0.        , -0.71238898])
``````
• How do you pass in the jacobian in such a case if we wanted to?. Just passing in `jac=jac` with an analytical jacobian gives a `TypeError: Shape mismatch`. Commented Aug 2, 2017 at 21:22

In general (i.e. unless your function belongs to some specific class) you can't find all the global solutions - these methods usually do local optimization from given starting points.

However, you can switch math.cos() with numpy.cos() and that will vectorize your function so it can solve for many values at once, e.g. fsolve(func, np.arange(-10,10,0.5)).

• And if your functions belong to a specific class, there's this: openopt.org/interalg
– pv.
Commented Oct 24, 2012 at 21:13