Difference between revisions of "Proofs:Biconditionals"

A biconditional of two propositions P and Q takes the form " ${\displaystyle P}$ if and only if ${\displaystyle Q}$ ". This can also be written as ${\displaystyle P\iff Q}$, which is equivalent to ${\displaystyle P\implies Q\land Q\implies P}$. When proving a biconditional statement, we need to prove that ${\displaystyle P\implies Q}$ and ${\displaystyle Q\implies P}$ are true. Remember that the contrapositive of a conditional is logically equivalent to the conditional. Thus, " ${\displaystyle P\implies Q}$ and ${\displaystyle Q\implies P}$ " is logically equivalent to " ${\displaystyle P\implies Q}$ and ${\displaystyle \neg P\implies \neg Q}$ ", " ${\displaystyle Q\implies P}$ and ${\displaystyle \neg Q\implies \neg P}$ ", or " ${\displaystyle \neg P\implies \neg Q}$ and ${\displaystyle \neg Q\implies \neg P}$ ". Thus, we do have some options as to how to prove the two directions of a biconditional statement.

Example of a biconditional proof: "For ${\displaystyle x\in \mathbb {Z} ,3x+3}$ is odd if and only if ${\displaystyle x}$ is even". Let ${\displaystyle P}$ = "3x + 3 is odd" and ${\displaystyle Q}$ = "x is even".

If x is even, then 3x + 3 = 3(2k) + 3 for some integer k. 3(2k) + 3 = 3(2k + 1). 3 is odd and 2k+1 is odd, so their product is also odd. Thus, if x is even, 3x + 3 is odd. Therefore, the statement ${\displaystyle Q\implies P}$ is true.

If x is odd, then 3x + 3 = 3(2k + 1) + 3 for some integer k. 3(2k + 1) + 3 = 3(2k + 1 + 1) = 3(2k + 2) = 3(2)(k+1). Thus 3x + 3 is a multiple of 2 and is even if x is odd. So, the statement ${\displaystyle \neg Q\implies \neg P}$, which is logically equivalent to ${\displaystyle P\implies Q}$, is true.

Therefore, ${\displaystyle P\iff Q}$.

Resources

• Biconditional Statements, Mathematics LibreTexts
• Logical Biconditional, Wikipedia