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CHAPTER 3 Logic.

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Presentation on theme: "CHAPTER 3 Logic."— Presentation transcript:

1 CHAPTER 3 Logic

2 Truth Tables for Negation, Conjunction, and Disjunction
3.3 Truth Tables for Negation, Conjunction, and Disjunction

3 Objectives Use the definitions of negation, conjunction, and disjunction. Construct truth tables. Determine the truth value of a compound statement for a specific case.

4 Truth Tables Negation (not): Opposite truth value from the statement.

5 Truth Tables Conjunction (and): Only true when both statements are true. Conjunction p q p  q T T T T F F F T F F

6 Truth Tables Disjunction (or): Only false when both statements are false. Disjunction p q p  q T T T T F F T F F F

7 Example: Using the Definitions of Negation, Conjunction, and Disjunction
Let p and q represent the following statements: p: 10 > 4 q: 3 < 5 Determine the truth value for each statement: a. p  q Since both are true, the conjunction is true. b. ~ p  q Since p is true, ~p is false, so the conjunction is false.

8 Example continued Let p and q represent the following statements: p: 10 > 4 q: 3 < 5 Determine the truth value for each statement: c. p  ~ q 10 > 4 is true or is false. A disjunction is false only when both components are false. Only one component is false, this is a true statement. d. ~p  ~q Since q is true, ~q is false. So, the disjunction is false.

9 Example: Constructing Truth Tables
Construct a truth table for ~(p  q) Step 1: First list the simple statements on top and show all the possible truth values. Step 2: Make a column for p  q and fill in the truth values. p q p  q T T T T F F F T F F

10 Example continued Step 3: Construct one more column for ~(p  q). The final column tells us that the statement is false only when both p and q are true. For example: p: Harvard is a college. (true) q: Yale is a college. (true) ~(p  q): It is not true that Harvard and Yale are colleges. A compound statement that is always true is called a tautology. Is this a tautology? NO p q p  q ~(p  q) T T T F T F F T F F

11 Example: Constructing a Truth Table
Construct a truth table for (~p  q)  ~q. p q ~p ~p  q ~q (~p  q)  ~q T T F T T F F T F F

12 Constructing a Truth Table with Eight Cases
There are eight different true-false combinations for compound statements consisting of three simple statements.

13 Example: Constructing a Truth Table with Eight Cases
Construct a truth table for the following statement: a. I study hard and ace the final, or I fail the course. b. Suppose that you study hard, you do not ace the final and you fail the course. Under these conditions, is this compound statement true or false? Solution: We represent our statements as follows: p: I study hard. q: I ace the final. r: I fail the course.

14 Example continued Writing the given statement in symbolic form:
The completed table is: The statement is True.

15 Determining Truth Values for Specific Cases
We can determine the truth value of a compound statement for a specific case in which the truth values of the simple statements are known, without constructing an entire truth table. Substitute the truth values of the simple statements into the symbolic form of the compound statement and use the appropriate definitions to determine the truth value of the compound statement.

16 Example: Determining the Truth Value of a Compound Statement
The bar graph shows the distribution of looks for American men and women, ranging from homely to strikingly attractive.

17 Example: Determining the Truth Value of a Compound Statement
Use the information in the bar graph to determine the truth value of the following statement: It is not true that 1% of American men are homely and more than half are average, or it is not true that 5% of American women are strikingly attractive.

18 Example continued We begin by assigning letters to the simple statements, using the graph to determine whether each simple statement is true or false. As always, we let these letters represent statements that are not negated.

19 Example continued Substitute the truth values for p, q, and r that we obtained from the bar graph to determine the truth value. ~(p  q)  ~r This is the given compound statement in symbolic form. ~(T  T)  ~F Substitute the truth value obtained from the graph. ~T  ~F Replace T  T with T. Conjunction is true when both parts are true. F  T Replace ~T with F and ~F with T. Negation gives the opposite truth value. T Replace F  T with T. Disjunction is true when at least one part is true. We conclude that the given statement is true.

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