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I hope you have some useful tip for me to approach the following task:

I wrote some simple python snippet to plot probability density functions. In my particular case, let them represent class-conditional probabilities for some parameter x.

So, I am wondering if there is an clever approach (i.e., module) in Python (maybe via a NumPy or SciPy function or method) to solve a simple equation for parameter x. E.g.,

pdf(x, mu=10, sigma=3**0.5) / pdf(x, mu=20, sigma=2**0.5) = 1
# get x

Right now, I can only thing of an brute force approach where I use something like x = np.arange(0, 50, 0.000001) and keep the x value in the vector that yields the closest value for 1 when calculating the ratio pdf1/pdf2.

Below is the code I wrote to calculate the pdf and plot the ratio:

def pdf(x, mu=0, sigma=1):
    """Calculates the normal distribution's probability density 
        function (PDF).  

    """
    term1 = 1.0 / ( math.sqrt(2*np.pi) * sigma )
    term2 = np.exp( -0.5 * ( (x-mu)/sigma )**2 )
    return term1 * term2


x = np.arange(0, 100, 0.05)

pdf1 = pdf(x, mu=10, sigma=3**0.5)
pdf2 = pdf(x, mu=20, sigma=2**0.5)

# ...
# ratio = pdf1 / pdf2
# plt.plot(x, ratio)

Thanks!

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    Sounds like you need a book on numerical methods more than Python programming advice. Here is a tip -- recast the equation to something like [pdf(x,...)/pdf(x...)] - 1 = 0 and solve that by minimisation or root finding instead.
    – talonmies
    Feb 12, 2014 at 6:52
  • 1
    I think that if you write down the equation on a piece of paper, you can fairly straightforwardly solve this without numerical methods.
    – user707650
    Feb 12, 2014 at 7:00
  • Sure, but I want to implement it into Python code, since I want to plot those points directly with the accompanied graphs.
    – user2489252
    Feb 12, 2014 at 20:19
  • @talonmies Sounds good! So for the minimization would scipy.optimize.minimize() be the way to go? EDIT: Just found another one that might be even better suited for this problem: scipy.optimize.minimize_scalar()
    – user2489252
    Feb 12, 2014 at 20:25
  • You are right, an analytical solution really is more appropriate here. However, I is good to know about these alternatives like minimization for different tasks. I will do both and compare the results. Thanks.
    – user2489252
    Feb 12, 2014 at 20:34

2 Answers 2

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In general, it sounds like you need the scalar root-finding functions: http://docs.scipy.org/doc/scipy/reference/optimize.html

But as others have pointed out, it seems like there is an analytical solution.

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Since you have a nice closed-form equation, you can solve it with SymPy.

I plugged in values for mu and sigma and entered this into Sympy Gamma:

 solve(1.0 / ( sqrt(2*pi) *(3**0.5) ) * exp( -0.5 * ( (x-10)/(3**0.5) )**2 ) /  (1.0 / ( sqrt(2*pi) *(2**0.5) ) * exp( -0.5 * ( (x-20)/(2**0.5) )**2 ))-1,x)

The result: 15.4554936768195

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