Biconditional introduction: Difference between revisions

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Line 1: {{Short description\|Inference in propositional logic}} {{Infobox mathematical statement \| name = Biconditional introduction \| type = [[Rule of inference]] \| field = [[Propositional calculus]] \| statement = If <math>P \to Q</math> is true, and if <math>Q \to P</math> is true, then one may infer that <math>P \leftrightarrow Q</math> is true. \| symbolic statement = <math>\frac{P \to Q, Q \to P}{\therefore P \leftrightarrow Q}</math> }} {{Transformation rules}} In [[propositional calculus\|propositional logic]], '''biconditional introduction'''<ref>Hurley</ref><ref>Moore and Parker</ref><ref>Copi and Cohen</ref> is a [[~~validity~~Validity (logic)\|valid]] [[rule of inference]]. It allows for one to [[inference\|infer]] a [[Logical biconditional\|biconditional]] from two [[Material conditional\|conditional statements]]. The rule makes it possible to introduce a biconditional statement into a [[formal proof\|logical proof]]. If <math>P \to Q</math> is true, and if <math>Q \to P</math> is true, then one may infer that <math>P \leftrightarrow Q</math> is true. For example, from the statements "if I'm breathing, then I'm alive" and "if I'm alive, then I'm breathing", it can be inferred that "I'm breathing [[if and only if]] I'm alive". Biconditional introduction is the [[Converse (logic)\|converse]] of [[biconditional elimination]]. The rule can be stated formally as: :<math>\frac{P \to Q, Q \to P}{\therefore P \leftrightarrow Q}</math> Line 15 ⟶ 23: or as the statement of a truth-functional [[Tautology (logic)\|tautology]] or [[theorem]] of propositional logic: :<math>((P \to Q) \~~and~~land (Q \to P)) \to (P \leftrightarrow Q)</math> where <math>P</math>, and <math>Q</math> are propositions expressed in some [[formal system]].