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.

`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`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