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Is there a way to check if an expression contains complex expressions / imaginary numbers?

The documentation says that you can't check if an expression contains I because of how it is interpreted. I have also tried ImaginaryQ[expr_] := expr != Conjugate[expr] and Simplify[expr] =!= Simplify[Conjugate[expr]], but it does not yield accurate results. I have also tried to use MemberQ[expr, Complex], but that does not seem to work either.

I posted some examples into a notebook: http://www.eacousineau.com/download/complex-test.nb

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Do you need to check for expressions like (-1)^(1/3) or just explicit Complex[a, b] == a + I b objects which Yoda's answer addresses? –  Simon Jun 29 '11 at 22:16
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3 Answers 3

up vote 6 down vote accepted

How about

ImaginaryQ[expr_] := ! FreeQ[expr, _Complex]

Using it on two of your examples:

imExpr = a Sin[a + 2 I];
ImaginaryQ@imExpr
(* True *)

reExpr = a Sin[a^2 + a];
ImaginaryQ@reExpr
(* False *)
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That works perfectly! But why is the form argument for FreeQ a pattern, _Complex, instead of just a symbol, Complex? –  eacousineau Jul 4 '11 at 3:58
    
Complex is the head for all complex numbers & expressions. So we use a pattern _Complex to capture anything with that Head. If you used the symbol Complex instead, this example: FreeQ[{a,b,Complex},Complex] will return False, eventhough Complex is not a complex number... FreeQ[{a,b,Complex},_Complex] returns True as it should. –  r.m. Jul 4 '11 at 4:06
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I would not use MemberQ[expr, Complex] because that should give True for real numbers. Or rather, Element[expr, Complexes] would—I'm not sure what, if anything, your version would do. What about

Not[Element[expr, Reals]]

or

Im[expr] != 0

?

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2  
MemberQ[expr, Complex] does not return True for reals because it is a structural question, not a mathematical one –  acl Jun 29 '11 at 17:50
    
@Charles: The command is Im –  r.m. Jun 29 '11 at 18:47
    
@yoda: Thanks, corrected. Mathematica is something like my 10th language and I get confused every so often. –  Charles Jun 29 '11 at 18:50
    
@Charles: Yes, that's a mistake I make often too :) For me it's more common with Real because, Real is a valid head in Mathematica and the syntax coloring won't highlight it, whereas I catch Imag instantly because it's undefined and shows up as blue. –  r.m. Jun 29 '11 at 18:54
    
@yoda, @Charles and how about Trace vs Tr, especially with something along the lines of f[i_] := i^2; Trace[Table[f[i], {i, 1, 10}, {j, 1, 10}]] (page of stuff) vs f[i_] := i^2; Tr[Table[f[i], {i, 1, 10}, {j, 1, 10}]] (385)... –  acl Jun 29 '11 at 18:58
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To be clear as to why MemberQ[expr,Complex] will not necessarily return True for reals (and may or may not return True for complex expressions). MemberQ is not asking if something is a member of the set of reals or anything like that.

MemberQ[expr,form] returns True if one of the elements of level 1 of expr matches form. Level 1 is what you get second from top if you do TreeForm. Also, by default, MemberQ does not look at heads. Thus:

l = List[1 + I];
MemberQ[l, Complex, Heads -> True]
MemberQ[List@l, Complex, Heads -> True]
(*
-> 
True
False
*)

(the Heads->True part is to make MemberQ also look at heads of expressions). To understand why, look at TreeForm@l and Treeform[List@l]:

enter image description here

Thus, there is a Complex at the first level in the first case, and no Complex at level 1 in the second. This is why we get True and False above. One can use

MemberQ[List@l, Complex, -1, Heads -> True]
(*
-> True
*)

to match on all levels.

Finally, to see that MemberQ really is a structural question, try MemberQ[1 + Exp[3*I], Complex, Heads -> True] which gives False even though the first argument is obviously complex.

So to sum up, MemberQ has little to do with mathematics; it's a construct to test patterns in lists (or any expression, the head does not matter).

In any case, if one is going to use structural tests, FreeQ is the easiest way, while Element is the way to do this with mathematical tests.

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@yoda sure, I wouldn't use Element either as I think of it as an assertion rather than a test. I was commenting on the answer stating that MemberQ[expr, Complex] should not be used because that should give True for real numbers, which I felt reflected a lack of distinction between structural and mathematical operations (ie, MemberQ is not about being or not being a member of a mathematical set) –  acl Jun 29 '11 at 19:03
    
@yoda: If Mathematica were smart enough, Not[Element[a + b I, Reals]] would return something like b = 0. I would think Element[a + I b, Complexes] would return True. (All this is assuming that we tell Math'ca that a and b are Reals.) –  Charles Jun 29 '11 at 19:04
    
Yes of course. I meant to post that to the other answer. I've done that and removed this :) –  r.m. Jun 29 '11 at 19:05
    
Good explanation! –  Charles Jun 29 '11 at 19:08
    
@Charles Thanks! By the way, what you want is more what Reduce does than Elements; thus Reduce[a + b*I \[Element] Reals, {a, b}] or Reduce[a + b*I \[Element] Reals && a \[Element] Reals && b \[Element] Reals, {a, b}] –  acl Jun 29 '11 at 19:12
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