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Chapter 2.1
Inductive Reasoning and Conjecture
Vocabulary
Conjecture – A conjecture is an educated guess based on known information.
Inductive Reasoning – This is reasoning based on a number of examples to arrive at a plausible generalization or prediction.
Counter Example – This is an example that shows that a conjecture is false.
Inductive ReasoningLet us look at this pattern:
What do you notice about the pattern?
What can you predict about the next picture?
It is going to have the same shape as the last picture with…
another column of four boxes.
Keys
The key to inductive reasoning is to find a pattern.
Look at example #1 in the book.
From the pattern, you can make a conjecture.
Sometimes the conjectures are wrong.
These conjectures are proved wrong by a counterexample.
When this happens you need to look for another pattern.
Counterexample
A counterexample is an example used to prove a conjecture is false. (Wrong)
It only takes one counterexample to prove a conjecture wrong.
So, good conjectures are “always true”
While bad conjectures can be “sometimes true and sometimes false.”
ExampleLet us look at some observations:A Ford Mustang has two doors.A Pontiac Solstice has two doors.A Saturn Sky has two doors.A BMW Z4 has two doors.From this pattern I can make a conjecture that “All cars have two doors”.Is this ALWAYS true?Counterexample: A Pontiac Grand Am is a car that has four doors.
Chapter 2.2
Logic
Truth Values
A statement can have only two truth values. That is the statement is either: True (Implying always true) or
False (Implying not always true).A statement can not be both True and False.Take the statement: All cars have two doors. That is false b/c we found a counterexample to refute it’s validity.
Negation
We can negate a statement by putting the word “not” in it someplace.The negation of a true statement makes is now false.The negation of a false statement makes it now true.We use ~ to indicate “not”“All cars have two doors” becomes “Not all cars have two doors”The original statement was false, when we negate it, it becomes true.
Compound Statement
Just like in English, you can put two statements together and make one compound statement.
You can do this by making the compound statement either a conjunction or a disjunction.
The compound statement also has a truth value as a whole.
Conjunction (Λ)
The key word for a conjunction is and.
Take two statements:
All cars have two doors.
All birds fly.
To make a conjunction from these two statements you simply put and in between them.
All cars have two doors and all birds fly.
In order for a conjunction to be true both statements have to be true.
Disjunction (V)
The key word for disjunction is or. Take the same two statements:
All cars have two doors.All birds fly.
To make a disjunction from these two statements you simply put or in between them.All cars have two doors or all birds fly.In order for a disjunction to be true only one statement has to be true.
Truth Value of Conjunctions
Just like statements, conjunctions also have a truth value.Conjunctions – both statements must be true before the conjunction is true.Raleigh is in NC and NYC is in New York.Both statements are true so conjunction is True.Raleigh is in NC and NYC is in Michigan.Only one statement is true so the conjunction is false.
Truth Value of Disjunctions
Just like statements, disjunctions also have a truth value.
Disjunctions – only one statement must be true before the disjunction is true.
Raleigh is in NC or NYC is in New York.
Both statements are true so disjunction is True.
Raleigh is in NC or NYC is in Michigan.
Only one statement is true so the disjunction is true.
Truth Tables
P Q PΛQ
T T T
T F F
F T F
F F F
P Q PVQ
T T T
T F T
F T T
F F F
Conjunctions Disjunctions
Truth Table (H)
P Q R ~P ~PΛQ (~PΛQ)VR
T T T
T T F
T F T
F T T
T F F
F T F
F F T
F F F
F
F
F
T
F
T
F
F
T
F
T
T
F
T
T
F
F
F
F
T
F
T
T
T
A B
Venn DiagramsVenn Diagrams are diagrams with pictures to portray Conjunctions and Disjunctions.The overlapping portion or the two ovals is your Conjunction.The two ovals combined is your Disjunction.
Conjunction AΛB
Disjunction AVB
Blue Shade ~AΛ~B
Chapter 2.3
Conditional Statements
Conditional Statements
Conditional Statements can be written in If-Then form.Essentially, an If-Then statement says “The If must be satisfied, before the Then can happen.”Example: If you pass this class, then you can move on to Alg II.What do you need to complete before you move on to Alg II?
Conditional Statements (Con’t)
Conditional Statements have two parts.
The part that follows the “IF” is called the Hypothesis.
The part that follows the “Then” is called the Conclusion.
If it is raining outside,
then I will carry my umbrella.
Hypothesis
Conclusion
Conditional Statements (Con’t)
Conditional statements don’t always have to have an If – Then in the statement.It can be put in though.Example: A Right Angle is an angle that measures 90° (Definition of a Right Angle)Does this have an If-Then in it?Can we rewrite it to have an If-Then?If an angle is a Right Angle, then the angle has a measure of 90°
Converse, Inverse and Contrapositive
Conditional Converse
Inverse Contrapositive
Write the conditional statement here.
P → Q Q → P
Switch the order of the Q and the P.
Negate the conditional statement here.
~P → ~Q ~Q → ~P
Negate the Converse statement here.
Example
Conditional Converse
Inverse Contrapositive
If two angles are rightangles, then they’re congruent.
If two angles are congruentthen they’re right angles.
If two angles are notright angles, then they’re not congruent.
If two angles are not congruent, then they’re not right angles.
(P → Q)
(~P → ~Q)
(Q → P)
(~Q → ~P)
Truth?
Conditional Converse
Inverse Contrapositive
If two angles are rightangles, then they’re congruent.
If two angles are congruentthen they’re right angles.
If two angles are notright angles, then they’re not congruent.
If two angles are not congruent, then they’re not right angles.
(T)
(F)
(F)
(T)
For all False statements – provide a Counter Ex
Truth?
If the conditional statement is a Definition – then all four conditionals will be true.
If the conditional is true, then the contrapositive is also true.
If the converse if false, then the inverse is false.
Biconditional Statements (H)
The biconditional statement is the conjunction of the conditional and converse statements.
(P→Q)Λ(Q→P) gives you (P↔Q)
Biconditional statements have the key term “if and only if” in it.
See pg 81.
Chapter 2.4
Deductive Reasoning
Deductive Reasoning
Deductive reasoning is very different than Inductive reasoning.
In Inductive reasoning we used patterns to predict an outcome.
In Deductive reasoning we use theorems, definitions, postulates and corollaries to reach a conclusion.
Two types of deductive reasoning is the Law of Detachment and the Law of Syllogism.
Law of Detachment
The Law of Detachment follows a distinct pattern.Using the LOD we have three steps1) Write the Conditional Statement – this is usually a definition or theorem.2) State a specific case of the Hypothesis of the conditional statement being satisfied.3) State a specific case of the Conclusion being satisfied.
LOD Example1) If an angle is a right angle, then the angle measures 90° (This is the definition of a right angle)2) Angle A is a right angle. (This talks specifically about a certain angle. Notice it satisfies the Hypothesis of the conditional statement?)3) m<A = 90° (This talks about a specific angle. It satisfies the conclusion of the conditional statement.
LOD Example
1) If two angles are supplementary, then the sum of their measures equals 180°
2) <A and <B are supplementary,
3) m<A + m<B = 180
Law of Syllogism
Just like LOD, LOS has a specific pattern.Unlike LOD, LOS has THREE conditional statements. If P→QIf Q→RIf P→RNotice where the Q’s are?Notice they are on the diagonal… it is as if they were crossed out and only the P and R remain.
SummaryLOD
Step 1 If – Then conditional statement
Step 2Specific Example of Hypothesis being satisfied.
Step 3Specific example of conclusion being satisfied
LOS
Step 1If – Then conditional statement
Step 2If – Then conditional statement (C of 1 is H of 2.
Step 3If – Then conditional statement (H of 1 is H of 3 and C of 2 is C of 3)
Chapter 2.5
Postulates and Paragraph Proofs
Postulates
Postulates are statements that describe a fundamental relationship between basic terms.
Postulates are accepted to be true.
Postulates are used in deductive reasoning.
Basic Postulates
Through any two points there exists exactly one line.Through any three noncollinear points there exists exactly one plane.A line contains at least two points.A plane contains at least three noncollinear points.If two points lie in a plane then the entire line lies in the plane.
Basic Postulates (Con’t)
If two lines intersect then they intersect at exactly one point.
If two planes intersect then they intersect at exactly one line.
Proofs
A proof is a LOGICAL argument in which each statement is supported by a postulate, theorem, definition or corollary.There are three types of proofs that we will deal with in this class.Two are “Formal” and one is “Informal”.The informal proof is a paragraph proof.You have done these in English.The two formal proofs are “Two Column” and “Flow” Proofs.
Key ElementsThere are five key elements essential for a good proof.
State the Theorem or Conjecture to be proven.
List the Given information.
If possible, draw a figure or diagram to illustrate the given information.
State what is to be proved.
Develop a System of deductive reasoning to get you from the conjecture to the end.
Drive to the Mall?
If you were at JHS, what directions would you give to a person (not from Jax) to get to the Jacksonville Mall?How detailed would it need to be?
Very detailed – can’t take anything for grantedCan you leave any steps out?
You can’t skip steps – if you don’t tell them to turn on Western Extension – then what?Do you need to follow traffic regulations?
You can’t break any laws b/c you’ll get a ticket or worse – you’ll end up in jail.
Theorem
Once a statement of conjecture is proved true then it can be called a Theorem.Go to page R1 in the back of the book.This section contains all the theorems, postulates and corollaries that we will use in this class.I strongly suggest that you read them every night so you can commit them to memory.The more you know in this class the easier it will be.
Chapter 2.6
Algebraic Proof
Algebraic Proof
Before we start on geometric proofs let us practice algebraic proofs .
Building blocks of all proofs are theorems, definitions, postulates and corollaries.
Algebraic building blocks are the properties of equality for real numbers.
Properties if Equality for Real Numbers
Reflexive Property – For every number a, a = a.Symmetric Property – For all numbers a and b, if a = b, then b = a.Transitive Property – For all numbers a, b and c, if a = b and b = c, then a = c.Addition/Subtraction Property – For all numbers a, b and c, if a = b, then a + c = b + c and a – c = b – c.
Properties of Equality for Real Numbers
Multiplication/Division Property – For all numbers a, b and c, if a = b, then ac = bc and a/c = b/c.
Substitution Property – For all numbers a and b, if a = b then a may be replaced by b in any equation and expression.
Distributive Property – For all numbers a, b, and c, a(b + c) = ab + ac.
Two Column Proof
The two column proof derives it’s name b/c it has two columns.Two columns are Statements and Reasons.
Statement Reason
x = 5 Given
5 = x Symmetric Prop
Think of this in If-Thenform.
H
CThese two statements satisfy the LOD of the If-Then form.
Example #1Given: 3(x – 2) = 42 Prove x = 16
Statement Reason
3(x – 2) = 42 Given3x – 6 = 42 Distribution Prop
3x – 6 + 6 = 42 + 6 Add/Subt Prop
3x = 48 Substitution Prop
3x/3 = 48/3 Mult/Div Prop
x = 16 Substitution Prop
H
CH
CH
CH
CH
C
Geometric ProofsSegments
ReflexiveAB = AB
SymmetricIf AB = BC, then BC = AB
TransitiveIf AB = BC and BC = CD
then AB = CD
Angles
Reflexivem<ABC = m<ABC
SymmetricIf m<ABC = m<XYZ,then m<XYZ = m<ABC
TransitiveIf m<1 = m<2 and m<2 = m<3
then m<1 = m<3
Hints
Some important Hints for Proofs
Your first statement is always the given.
The last statement is always what you want to prove.
Look for what changed from one statement to another…. Think of a Theorem, Postulate, Definition or Corollary that would let you go from one to the other.
Chapter 2.7
Proving Segment Relationships
Segment Addition Postulate
The Segment Addition Postulate (SAP) is a very important postulate b/c it allows you to break one segment into two smaller ones, or if the three points are collinear, it allows you to make one big segment out of two little ones.
If B is between A and C, then AB + BC = AC.
AB
C
Example of SAP
Statement Reason
Given: AB = CDProve: AC = BD
A B C D
AB = CD Given
What do you need to do to AB to make it AC?What do you need to do to CD to make it BD?
BC = BC Reflexive PropAB + BC = CD + BC Addition Prop
AB + BC = ACBC + CD = BD
SAP
AC = BD Substitution
Another ExampleGiven: AC = BDProve: AB = CD
A B C D
Statement Reason
AC = BD GivenAB + BC = ACBC + CD = BD
SAP
AB + BC = BC + CD SubstitutionBC = BC Reflexive Prop
AB = CD Add/Subt Prop
Big Difference
There is a big difference between the Segment Addition Postulate (SAP) and the Add/Subt Property.The SAP takes two little segments and makes one big segment from it.Or, takes one big segment and breaks it down into two little segments.Add/Subt adds or subtracts the same thing from each side of the equal sign.
Segment CongruenceCongruence of Segments is Reflexive, Symmetric and Transitive.
Reflexive –
Symmetric –
Transitive –
AB ABif AB CD
then CD AB
if AB CD
and CD DE
then AB DE
Chapter 2.8
Proving Angle Relationships
Angle Addition PostulateThe Angle Addition Postulate (AAP) is exactly like the SAP except you’re using angles.
The AAP takes two adjacent angles and allows you to add them together.
Or, it allows you to divide one big angle into two smaller angles.
AB
CD
m<ADC =m<ADB + m<BDC
Same Process In Proof
Statement Reason
Given: m<1 = m<2Prove: m<EBD= m<CBA
12 AB
CD
E
m<1 = m<2 Given
m<3 = m<3 Reflexive
m<1 + m<3 = m<2 + m<3
3
Add/Subt Propm<1 + m<3 = m<EBDm<2 + m<3 = m<CBA
AAP
m<EBD = m<CBA Substitution
Angle TheoremsSupplement Theorem – If two angles are Linear Pair, then they are supplementary.
Complement Theorem – If the non common sides of two adjacent angles are perpendicular, then the two adjacent angles are complementary.
1 2<1 & <2 are LP, <1 & <2 are Supp.
34
<3 & <4’s non-common sides are | so, <3 & <4 are comp.
Angle Theorems (Con’t)
Angles Supplementary to the same angle (or congruent angles) are congruent.
Angles Complementary to the same angle (or congruent angles) are congruent.
1 2 3
<1 & <2 are Supp. <2 & <3 are Supp.<1 is congruent to <3.
Angle Theorems (Con’t)
Vertical Angle Theorem – If two angles are vertical angles, then they’re congruent.
12
34
1 3 2 4
Right Angle Theorems
Perpendicular Lines intersect to form four right angles.All Right Angles are congruent.Perpendicular Lines form congruent, adjacent angles.If two angles are congruent and supplementary, then they’re right angles.If two congruent angles form a linear pair, then they’re right angles.