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I need to show that the expression:

~(A XOR B)

is equivilant to

(~A XOR B)

using boolean algebra.

I really have no idea how to start, any help would be appreciated.

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closed as off topic by Oliver Charlesworth, Don Roby, Ken White, Lucero, bensiu Feb 4 '13 at 5:22

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1  
Construct a truth table for each expression. – Oliver Charlesworth Feb 4 '13 at 1:22
    
Maybe start with this: what is (A XOR ~A)? – sam hocevar Feb 4 '13 at 1:23
    
As it says in the OP I need to use Boolean algebra to show they are equivilant. A truth table does show it is equivilant but not using Boolean algebra. – user1795609 Feb 4 '13 at 1:26
2  
There is a rule to expand (A XOR B) to get 2 simpler clauses that make use of only the OR and AND operator. Once you reach this step, you can "move" the NOT operator in, do some manipulation, and use the same rule you used to write your expression back in terms of XOR. – lightalchemist Feb 4 '13 at 1:32
up vote 2 down vote accepted

In order to show that two logical expressions are equivalent, you may proceed in two different ways.

  1. Write a truth table for each of the expressions and then, if the resulting functional truth values are the same, then the expressions are equivalent;

  2. Equivalence is the same as implication in both directions;

    A <=> B is equivalent to (A => B) AND (B => A)

    So, what you need is try to get (~A xor B) from ~(A xor B) and vice versa.

    • ~(A xor B) =
    • by definition of xor + negation = ~ ( (~A and B) or (A and ~B) ) =
    • by De Morgan law = ~ (~A and B) and ~(A and ~B) =
    • by De Morgan law again = (A or ~B) and (~A or B) =
    • by applying distributive law = (A and ~A) or (A and B) or (~B and ~A) or (~B and B) =
    • ignore contradictions = (A and B) or (~B and ~A) =
    • apply definition of xor in another direction = ~A xor B.

    the end

    The same procedure must be done in the other direction ( get ~(A xor B) from (~A xor B) ). Then the proof will be complete.

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