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I'm just learning boolean algebra at the moment. I read that for XOR we can rearrange the expression

  1. (A + B) . ¬(A + B)

  2. = A.¬A + A.¬B + B.¬A + B.¬B

  3. = A.¬B + B.¬A

I can understand this but I'm unsure how I would proceed multiplying out an expression like

  • (A + B) . (¬A + ¬B).

If I just try and naively multiply out all the terms that will bring me to the same result as XOR but the truth table is different. What are the rules on multiplying out negated terms?

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This is a good question for – Robert Cartaino Dec 16 '09 at 19:11
Thanks. Didn't know about that site. These overflow sites seem to be springing up like wildfire now! – Martin Smith Dec 16 '09 at 19:21
All this time, I thought people were being sarcastic about the website, I never clicked it until now. – Anthony Forloney Dec 16 '09 at 19:22
To facilitate discussion, I've taken the liberty to number your formulae. They're now numbered "1", "2", "3" and "bullet" (best I could do with the markdown). – Carl Smotricz Dec 16 '09 at 19:32
up vote 3 down vote accepted

Your first expression isn't an xor, try making this substitution:

 Z = A+B 

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I don't know what good the substitution would do, but I believe you're right about the first expression not being an XOR. – Carl Smotricz Dec 16 '09 at 19:24
what do you get when you make the substitution in the first expression? – klochner Dec 16 '09 at 19:26
Ah, I see... you're demonstrating that (1) is always false. Yep, that could be part of the problem. – Carl Smotricz Dec 16 '09 at 19:33
Well spotted. That is actually a typo in the book I'm using I think. He originally states it as (A + B) . ¬(A.B) but then proceeds to start with (A + B) . ¬(A + B) in the multiplying out example. – Martin Smith Dec 16 '09 at 19:33
sounds like a typo to me. \bar{(A+B)} == ¬(A+B) – klochner Dec 16 '09 at 20:06

You think the truth table is different?

Try evaluating it yourself.

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Doh! I'm not sure how I convinced myself that they were different. So basically it should never make any difference then if the negation applies to the whole bracketed expression or individual component(s)? – Martin Smith Dec 16 '09 at 19:25
Oh no, big diff. That's what DeMorgan is all about. If you move the 'not' into the parentheses, you have to invert the conjunction inside the parentheses. – Carl Smotricz Dec 16 '09 at 19:27
Yes I had thought that I had got myself into trouble with doing something like that earlier. I'll try and revisit that example with the help of Wolfram Alpha! – Martin Smith Dec 16 '09 at 19:38

You need DeMorgan's Law

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You can throw this kinda thing at Wolfram Alpha. Here's what I did:

Please click on the link to view the results! Does that truth table look like what you thought it should, or not?

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Thanks very useful :-) – Martin Smith Dec 16 '09 at 19:36

Answers here are not clear to me. I believe there's a typo in how you typed #1. It is a contradiction:

  1. (A + B) * -(A + B)
  2. (A + B) * -A * -B
  3. -A * -B * A + -A * -B * B
  4. 0

If #1 were (A + B) * (-A + -B) instead:

  1. (A + B) * (-A + -B)
  2. -A * (A + B) + -B * (A + B)
  3. -A * A + -A * B + -B * A + -B * B
  4. -A * B + -B * A

That's how you distribute AND over OR.

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