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Suppose I've checked the identity below, how to implement it in Mathematica ?

(* {\[Alpha] \[Element] Reals, \[Beta] \[Element] Reals, \[Mu] \[Element] Reals, \[Sigma] > 0} *)

Integrate[CDF[NormalDistribution[0, 1], \[Alpha] + \[Beta] x] PDF[
NormalDistribution[\[Mu], \[Sigma]], 
x], {x, -\[Infinity], \[Infinity]}] -> CDF[NormalDistribution[0, 1], (\[Alpha] + 
\[Beta] \[Mu])/Sqrt[1 + \[Beta]^2 \[Sigma]^2]]
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1 Answer 1

up vote 6 down vote accepted

Most ways to do what you request would probably involve adding rules to built-in functions (such as Integrate, CDF, PDF, etc), which may not be a good option. Here is a slightly softer way, using the Block trick - based macro:

SetAttributes[withIntegrationRule, HoldAll];
withIntegrationRule[code_] :=
   Block[{CDF, PDF, Integrate, NormalDistribution},
        CDF[NormalDistribution[0, 1], \[Alpha]_ + \[Beta]_ x_] PDF[
           NormalDistribution[\[Mu]_, \[Sigma]_], x_], {x_, -\[Infinity], \[Infinity]}] :=
                CDF[NormalDistribution[0, 1], (\[Alpha] + \[Beta] \[Mu])/
                   Sqrt[1 + \[Beta]^2 \[Sigma]^2]];

Here is how we can use it:

withIntegrationRule[a=Integrate[CDF[NormalDistribution[0,1],\[Alpha]+\[Beta] x]

Out[28]= 1/2 Erfc[-((\[Alpha]+\[Beta] \[Mu])/(Sqrt[2] Sqrt[1+\[Beta]^2 \[Sigma]^2]))]   

When our rule does not match, it will still work, automatically switching to the normal evaluation route:

  Block[{$Assumptions = \[Alpha]>0&&\[Beta]==0&&\[Mu]>0&&\[Sigma]>0},
    withIntegrationRule[b=Integrate[CDF[NormalDistribution[0,1],\[Alpha]+\[Beta] x]

Out[36]= 1/4 (1+Erf[\[Alpha]/Sqrt[2]]) (1+Erf[\[Mu]/(Sqrt[2] \[Sigma])])

where I set \[Alpha] to 0 in assumptions to make the integration possible in a closed form.

Another alternative may be to implement your own special-purpose integrator.

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How can one release HoldAll such that it will work for the integral, say, of (CDF[NormalDistribution[0, 1], \[Alpha] + \[Beta] x] + CDF[NormalDistribution[0, 1], \[Gamma] + \[Delta] x]) PDF[NormalDistribution[\[Mu], \[Sigma]], x] ? I tried Distribute but it didin't work. –  b.gatessucks Sep 27 '11 at 6:32
@b.gatessucks This is not a problem of HoldAll. If I release that, the integral inside our macro will evaluate via its normal route before the macro sees it, which is what we don't want. Inside Block, however, all Blocked functions completely forget what they are. So, within this solution, the only choice is to add another rule to Integrate, such as Integarte[x_+y_,varlims_]:=Integrate[x,varlims]+Integrate[y,varlims]. Eventually, though, you'd end up re-implementing the whole Integrate, so it may make sense to constrain what you want to get from this, from the start. –  Leonid Shifrin Sep 27 '11 at 9:20

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