# solving for integration limits numerically?

I am trying to locate a region under the curve of two functions such that the area of this region equals a given number `m`. For example, by integrating the two functions:

``````f(x) = 3x - 3x^2
g(x) = x
``````

symbolically from a to b, and equating each to m (e.g. m=1/3). The system can be solved to find the values of a and b:

``````1.5 b^2 - b^3 - 1.5 a^2 + a^3 = 1/3
0.5 b^2 - 0.5 a^2 = 1/3
``````

The positive solution I got to this is approximately: `a = 0.364823, b = 0.894294`

Now, my question is: how can I find a and b if f and g were given to me as vectors (or arrays in python) instead of symbolic functions? I know how to use `trapz()` to find areas for vectors but I don't know if there is a way to use it to find `a` and `b` in the above problem numerically.

Thanks!

-

You can try sympy

``````>>> from sympy import *
>>> x,a,b = symbols('x a b')
>>> fx = "3*x - 3*x**3"
>>> gx = "x"
>>> m = 1/3
>>> int_fx = integrate(fx, (x,a,b))
3*a**4/4 - 3*a**2/2 - 3*b**4/4 + 3*b**2/2
>>> int_gx = integrate(gx, (x,a,b))
-a**2/2 + b**2/2
>>> solve([Eq(int_fx, m), Eq(int_gx, m)],(a, b))
[(-0.577350269189626, -1.00000000000000), (-0.577350269189626, 1.00000000000000), (0.577350269189626, -1.00000000000000), (0.577350269189626, 1.00000000000000)]
``````

By the way, I am having hard time to understand how you managed to get a definite integral solution of

``````1.5 b^2 - b^3 - 1.5 a^2 + a^3 = 1/3
``````

for

``````f(x) = 3x - 3x^3
``````

within

``````[a,b]
``````
-
Sorry, it should have been f(x) = 3x - 3x^2 instead of 3x - 3x^3. Thanks for the code by the way, but I actually understand how to code that in python/matlab when fx and gx are 'symbolic'. My question was how to gain equivalent results if fx and gx were given only as vectors (i.e. points) instead of symbolic functions?? –  user1583416 Dec 15 '12 at 19:00
@user1583416: Can you rephrase your original question? The original question deals with symbolic –  Abhijit Dec 15 '12 at 19:02
I used the symbolic example only to show what I want to accomplish equivalently in numeric (i.e. to find a and b that make area under curve of f and g equal to value m, where f and g are given as vectors (points)). –  user1583416 Dec 15 '12 at 19:11

I think you need to look at integral equations: Numerical Recipes and SO, for example.

-