Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

FullSimplify fails to recognize that:

 a*Conjugate[b] + b*Conjugate[a] = 2 Re[a*b]  

I have some very complex equations that could be simplified greatly if Mathematica could recognize this simple identity

(and that a*Conjugate[b] - b*Conjugate[a] = 2 Im[a*b]).

See, Mathematica will not finish solving my equations when written in

a*Conjugate[b] +b*Conjugate[a] form, 

but I could at the very least write my final equations in an extremely descriptive and compact form if Mathematica recognized this. The actual expressions look like:

-((I q1 + q2)/(I q0 + Sqrt[-q0^2 + q1^2 + q2^2 + q3^2])) -
 (Conjugate[q1] + I Conjugate[q2])/
 (Conjugate[q0] + I Conjugate[Sqrt[-q0^2 + q1^2 + q2^2 + q3^2]]) 

I would do this myself, but there are 16 of such expressions and they form 4 sets of coupled systems. Since one sign error would render my work useless, I would strongly prefer an automated process.

share|improve this question

4 Answers 4

The identity you gave, b Conjugate[a] + a Conjugate[b] == 2 Re[a b], is only true if at least one of a and b is real:

In[7]:= Simplify[
 Reduce[a*Conjugate[b] + b*Conjugate[a] == 2 Re[a*b], {a, b}]]

Out[7]= Im[a] == 0 || Im[b] == 0

If this additional condition is in fact true in your application then you could give it to Simplify or FullSimplify as an assumption, as their second argument. For example:

In[14]:= FullSimplify[Im[a*Conjugate[b] + b*Conjugate[a]], 
 Im[a] == 0 || Im[b] == 0]

Out[14]= 0

By the way, here is one example when the identity is not true:

In[1]:= FindInstance[
 a*Conjugate[b] + b*Conjugate[a] != 2 Re[a*b], {a, b}]

Out[1]= {{a -> -I, b -> -I}}
share|improve this answer
    
In M'ma 7, I've found that Assuming[{...}, sequence_of_simplification_functions [ _stuff ] ] is much less annoying that passing assumptions in to each of the simplification functions. (And substantially less prone to cut/paste errors.) –  Eric Towers Oct 24 '10 at 4:01
    
Of course, you can also set the global $Assumptions –  Simon Oct 24 '10 at 5:07

First pass: Use ComplexExpand[].

    In := Simplify[ ComplexExpand[ a Conjugate[b] + b Conjugate[a], {a, b} ] ]
    Out = 2 (Im[a] Im[b] + Re[a] Re[b])

For more fun, look at ComplexityFunction, although I find that a lot of trial and error is involved in tuning FullSimplify.

share|improve this answer
2  
Be careful with ComplexExpand. As explained in its documentation (reference.wolfram.com/mathematica/ref/ComplexExpand.html), it explicitly assumes that all variables are real. This is often very useful, but it is not a correct assumption in this case. –  Andrew Moylan Oct 24 '10 at 2:13
2  
@Andrew Moylan: While true, the second argument to ComplexExpand is a list of symbols to be treated as Complex. Thus the {a,b}, above. –  Eric Towers Oct 24 '10 at 3:58
    
Ah quite right, my mistake. I didn't read your post carefully enough, sorry. –  Andrew Moylan Oct 24 '10 at 11:17

I think the correct identity should be:

a*Conjugate[b] + b*Conjugate[a] == 2 Re[Conjugate[a]*b]

It's always true:

In[1]:= FullSimplify[a*Conjugate[b] + b*Conjugate[a] == 2 Re[Conjugate[a]*b]]

Out[1]= True
share|improve this answer

Is your identity correct? I'm getting different numbers for two sides

{a*Conjugate[b] + b*Conjugate[a], 2 Re[a*b]} /. {a -> RandomComplex[],b -> RandomComplex[]}
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.