1 / 11

Logic 2 The conditional and biconditional

Logic 2 The conditional and biconditional. The Conditional Consider two statements, p and q. If p being true always leads to q being true, we have a conditional relationship “ if p is true then q is true”, “if p then q”, “p  q”. See Waner and Conenoble for other equivalent phrases.

sheryl
Download Presentation

Logic 2 The conditional and biconditional

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Logic 2The conditional and biconditional

  2. The Conditional • Consider two statements, p and q. • If p being true always leads to q being true, we have a conditional relationship “if p is true then q is true”, “if p then q”, “p q”. See Waner and Conenoble for other equivalent phrases. These all say the same thing, and have the following truth table: • P is the antecedent of hypothesis, q is the consequent or conclusion.

  3. Rules of the conditional • The only way p q is false is if p is true and q is false. Called a “broken promise.” • If p and q are both false, p q is true. • p q is true when p is false, no matter what the truth value of q. • True always implies true. If p and q are both true, then pq is true. • True can’t imply false. If p is true and q is false then pq is false. • False implies anything. If p is false, then pq is true no matter if q is true or not.

  4. The “switcheroo” law Show that p q  (p)q This is often important for proofs. This implies that p q is true if either p is false or if q is true. Using DeMorgan’s Law, this also means that p q  (p(q))

  5. Important equivalencies of p q if p then q is the same as p implies q q follows from p is the same as not p unless q q if p is the same as p only if q whenever p, q is the same as q whenever p p is sufficient for q is the same as q is necessary for p Notice how p being a sufficient condition for q makes q a necessary condition for p.

  6. Exercise: Show that the commutative law does not hold for the conditional, that is that p q is not equivalent to q p using a truth table. The statement p q is called the converse of q p, and q p is the converse of p q. They are not equivalent.

  7. Exercises Give an example where the converse of a conditional is not true. (Think advertising). Give an example when the converse of a conditional is true.

  8. Contrapositive The contrapositive of p q is (q) (p) Exercise 1: Use truth tables to show a statement and its contrapositive are equivalent. Exercise 2: Use switcheroo and other properties to show a statement and its contrapositive are equivalent. p q  (p)q  q(p)  (q)(p)  (q) (p) switcheroo; commutative; double neg; switcheroo

  9. Exercise 3: Give the converse and contrapositive of the statement If you study hard you will get a good grade. Explain how the contrapositive can be interpreted as true, but not necessarily the converse. Converse: If you get a good grade you studied hard. Contrapositive: If you don’t get a good grade, you did not study hard.

  10. Biconditional The biconditional, written pq, is defined to be the statement (p q)(q p). With the true table Exercise: Use truth tables to show that pq (p q)(q p).

  11. Common phrasings for the biconditional • p if and only if q • p is necessary and equivalent for q • p is equivalent to q

More Related