[\<- 1.1](1.1.md) --- # 1.3 Propositional Equivalences p1 - Definition: We say propositinos `p` and `q` are **logically equivalent** if they have the **same truth table outputs** - Notated as `p≡q` (three lign equal sign) - kind of similar to `<->` - Defining terms using the conditional `p->q` - **Converse**: `q->p` (if q, then p) - **Inverse**: `┓p->┓q` - **Contrapositive**: `┓q->┓p` (if not q, then not p) - The original conditional and the contrapositive are equivalent - So are the converse and the inverse - Why is `p->q≡┓q->┓p` Reason 1: Truth Table |p|q|p->q|┓p|┓q|┓q->┓p| |-|-|----|--|--|------| |T|T|T |F |F |T |T|F|F |T |F |F |F|T|T |F |T |T |F|F|T |T |T |T - Since their truth table outputs are the same, these two statements are the same Reason 2: Logic/Venn Diagram - `p->q` -> "If we are in p, then we are in q" - `┓q->┓p` -> "If we are not in q, then we are not in p" - Both these statements describe the same venn diagram --- - Ex: Show `(p->q)^(q->p)≡p<->q Truth Table: |p|q|p->q|q->p|(p->q)^(q->p)|p<->q| |-|-|----|----|-------------|-----| |T|T|T |T |T |T | |T|F|F |T |F |F | |F|T|T |F |F |F | |F|F|T |T |T |T | - The output is logically equivalent since their truth table outputs are the same - Ex: Fill in the blank: ┓(I'm tall and I have black hair) ≡ I'm not tall _____ I don't have black hair - The negation is saying, "it is not the case that..." - The correct answer is `∨` (or) - Now use a truth table to show `┓(p^q)≡┓p∨┓q` Truth Table: |p|q|┓(p^q)|┓p∨┓q| |-|-|------|-----| |T|T|F |F | |T|F|T |T | |F|T|T |T | |F|F|T |T | - This example is true because of DeMorgan's Law - Ex: Use a truth table to show that `p->q≡┓p∨q` Truth Table: |p|q|p->q|┓p∨q| |-|-|----|----| |T|T|T |T | |T|F|F |F | |F|T|T |T | |F|F|T |T | --- # 1.3 Propositional Equivalences p2 ## Definitions - A proposition that is **always true** is a **tautology** - (tautology≡`T`) - e.g. `p∨┓p≡T` - A proposition that is **always false** is a **contradiction** - (contradiction≡`F`) - e.g. `p^┓p≡F` - A proposition that can be **true or false** is a **contingency** [Table of Common Equivalences](1.3.pdf) ### Ways to show p≡q 1. Truth Tables 2. Show `p<->q` is a tautology (multiple options) - with a truth table - by (3) 3. Use table of Common Equivalences (see link above)