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Following code returns different values for NExpectation and Expectation. If I try the same for NormalDistribution[] I get convergence erors for NExpectation (but the final result is still 0 for all of them). What is causing the problem?

U[x_] := If[x >= 0, Sqrt[x], -Sqrt[-x]]

N[Expectation[U[x], x \[Distributed] NormalDistribution[1, 1]]]

NExpectation[U[x], x \[Distributed] NormalDistribution[1, 1]]

Output:

    -0.104154
     0.796449
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1  
I think it might be a branch-cut issue in the Bessel functions... Interestingly, if I use U[x_] := Piecewise[{{Sqrt[x], x >= 0}, {-Sqrt[-x], x < 0}}] instead of the If construct, then the NExpectation gives the same value, but N[Expectation[...]] returns the obviously wrong complex result: -0.104154 - 0.104154 I. –  Simon Dec 19 '11 at 13:35
1  
@Simon, it looks like it is an Integrate bug. With v[x_]:=Piecewise[{{Sqrt[x], x >= 0}, {-Sqrt[-x], x < 0}}], if you try N@Expectation[v[x], x \[Distributed] NormalDistribution[1.0, 1.], Method -> "Integrate"] you get -0.104154 - 0.104154 I. If you change the method, N@Expectation[v[x], x \[Distributed] NormalDistribution[1.0, 1.], Method -> "Moment"] gives 0.796449. –  kguler Dec 19 '11 at 14:15
    
@kguler: Yeah, I noticed my original guess wasn't quite right. See my answer for a more complete discussion... –  Simon Dec 19 '11 at 14:18

2 Answers 2

I think it might actually be an Integrate bug.

Let's define your

U[x_] := If[x >= 0, Sqrt[x], -Sqrt[-x]]

and the equivalent

V[x_] := Piecewise[{{Sqrt[x], x >= 0}, {-Sqrt[-x], x < 0}}]

which are equivalent over the reals

FullSimplify[U[x] - V[x], x \[Element] Reals] (* Returns 0 *)

For both U and V, the analytic Expectation command uses the Method option "Integrate" this can be seen by running

Table[Expectation[U[x], x \[Distributed] NormalDistribution[1, 1], 
  Method -> m], {m, {"Integrate", "Moment", "Sum", "Quantile"}}]

Thus, what it's really doing is the integral

Integrate[U[x] PDF[NormalDistribution[1, 1], x], {x, -Infinity, Infinity}]

which returns

(Sqrt[Pi] (BesselI[-(1/4), 1/4] - 3 BesselI[1/4, 1/4] + 
   BesselI[3/4, 1/4] - BesselI[5/4, 1/4]))/(4 Sqrt[2] E^(1/4))

The integral for V

Integrate[V[x] PDF[NormalDistribution[1, 1], x], {x, -Infinity, Infinity}]

gives the same answer but multiplied by a factor of 1 + I. This is clearly a bug.

The numerical integral using U or V returns the expected value of 0.796449:

NIntegrate[U[x] PDF[NormalDistribution[1, 1], x], {x, -Infinity, Infinity}]

This is presumably the correct solution.


Edit: The reason that kguler's answer returns the same value for all versions is because the u[x_?NumericQ] definition prevents the analytic integrals from being performed so Expectation is unevaluated and reverts to using NExpectation when asked for its numerical value..


Edit 2: Breaking down the problem a little bit more, you find

In[1]:= N@Integrate[E^(-(1/2) (-1 + x)^2) Sqrt[x] , {x, 0, Infinity}]
         NIntegrate[E^(-(1/2) (-1 + x)^2) Sqrt[x] , {x, 0, Infinity}]

Out[1]= 0. - 0.261075 I   
Out[2]= 2.25748

In[3]:= N@Integrate[Sqrt[-x] E^(-(1/2) (-1 + x)^2) , {x, -Infinity, 0}]
         NIntegrate[Sqrt[-x] E^(-(1/2) (-1 + x)^2) , {x, -Infinity, 0}]

Out[3]= 0.261075    
Out[4]= 0.261075

Over both the ranges, the integrand is real, non-oscillatory with an exponential decay. There should not be any need for imaginary/complex results.

Finally note that the above results hold for Mathematica version 8.0.3. In version 7, the integrals return 1F1 hypergeometric functions and the analytic result matches the numeric result. So this bug (which is also currently present in Wolfram|Alpha) is a regression.

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Yes, looks like Integrate returns different results: N[Integrate[ U[x] PDF[NormalDistribution[1, 1], x], {x, -Infinity, Infinity}]] returns -0.104154, but NIntegrate[ U[x] PDF[NormalDistribution[1, 1], x], {x, -Infinity, Infinity}] returns 0.796449 –  Michal Dec 19 '11 at 13:57
2  
@Michal: Yep! That's basically what I said. I suggest you submit a bug report to Wolfram Research and see what they think... (P.S. Welcome to stackoverflow. Please upvote any answers and questions you find useful. And follow the new Mathematica site proposal.) –  Simon Dec 19 '11 at 13:58
    
@Michal, There is actually another issue here: If and Piecewise behave quite differently as arguments to other functions like Integrate. Both in version 7 and version 8, you will get the same results with the function U[x]. You need to use Simon's V[x] or PiecewiseExpand@U[x] to convert If to Piecewise. Otherwise, Integrate[If[cond,expr1,expr2]... always gives Integrate[expr2 ...]. –  kguler Dec 19 '11 at 16:07

If you change the argument of your function u to avoid evaluation for non-numeric values all three methods gives the same result:

u[x_?NumericQ] := If[x >= 0, Sqrt[x], -Sqrt[-x]] ;
Expectation[u[x], x \[Distributed] NormalDistribution[1, 1]] // N;
N[Expectation[u[x], x \[Distributed] NormalDistribution[1, 1]]] ;
NExpectation[u[x], x \[Distributed] NormalDistribution[1, 1]];
{% === %% === %%%, %}

with the result {True, 0.796449}

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1  
It's important to point out here that this method essentially forces the use of NExpectation in both cases. I believe when Expectation fails to evaluate symbolically, applying an N to it just switches to the methods used by NExpectation. At least this is the case for other functions like (N)Integrate. –  Szabolcs Dec 19 '11 at 14:26

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