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I want an arbitrary function p[x] that integrates to 1 and for all x, 0 <= p[x] <= 1. Some kind of transformation rule?

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What do you mean by arbitrary? A kind of "random function"? – Karsten W. Aug 19 '10 at 21:27
Arbitrary as in I don't give it a definition. Opaque. – Sasha Aug 19 '10 at 22:52
How can you use something you have not defined? May I ask what the function is for? By integrates to 1, is that over [0,1] or R? – Per Alexandersson Aug 20 '10 at 10:25
I was hoping I could tell Mathematica that I have an opaque function p that integrates to 1 over R, and it could use that fact to simplify a more complex integral involving p. – Sasha Aug 31 '10 at 20:23

You could use ProbabilityDistribution for this together with an undefined function of x:

dist = ProbabilityDistribution[p[x], {x, -Infinity, Infinity}];

It now knows a few rules to apply:

  • continuous probability density: probability of a single value is zero

    In[26]:= Probability[x == 0, x \[Distributed] dist]
    Out[26]= 0
  • the probability of having a value at all

    In[28]:= Probability[x > 0 || x <= 0, x \[Distributed] dist]
    Out[28]= 1
  • The CDF at - infinity

    In[29]:= CDF[dist][-\[Infinity]]
    Out[29]= 0
  • The CDF at + infinity

    In[30]:= CDF[dist][\[Infinity]]
    Out[30]= 1
  • The PDF

    In[32]:= PDF[dist][x]
    Out[32]= p[x]
  • However, it doesn't assume the PDF of the distribution is normalized:

    In[33]:= Integrate[PDF[dist][x], {x, -Infinity, Infinity}]
    Out[33]= Integrate[p[x], {x, -Infinity, Infinity}]
  • The latter can be taught, defining an UpValue for p:

    p /: Integrate[p[x], {x, -Infinity, Infinity}] = 1;
  • Now it can integrate the PDF:

    In[4]:= Integrate[PDF[dist][x], {x, -Infinity, Infinity}]
    Out[4]= 1

You know that your second requirement, i.e. 0 <= p[x] <= 1, is not generally true for probability density functions, do you?

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In case you're just asking for examples of density functions (PDFs) that match your criteria, here are two (out of uncountably many):

p(x) = 1 if 0 < x < 1
       0 otherwise

p(x) = x/2 if 0 < x < 2
       0 otherwise

We could even generalize those slightly:

p(x) = 1/k if 0 < x < k
       0 otherwise

p(x) = 2x/k^2 if 0 < x < k
       0 otherwise

The latter works for k >= 2. We can even generalize that with another parameter to get a class of such functions with arbitrary exponent

p(x) = (a+1)/k^(a+1)*x^a if 0 < x < k
       0 otherwise

which works for all a > 1 and k > a+1.

For more interesting examples I think you'll need to give more criteria. You mention a transformation rule so perhaps you'd like to take an arbitrary bounded function on R1 and translate/scale it so that it's always between 0 and 1 and integrates to 1. That will have a straightforward answer as long as you can get the min, max, and integral of the given function. Go ahead and edit the question to ask that if that's indeed what you're looking for.

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