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Transcript
1.1 Patterns and Inductive
Reasoning
Objectives/Assignment:


Find and describe patterns.
Use inductive reasoning to make reallife conjectures.
Finding & Describing Patterns

Geometry, like much of mathematics and
science, developed when people began
recognizing and describing patterns. In this
course, you will study many amazing patterns
that were discovered by people throughout
history and all around the world. You will
also learn how to recognize and describe
patterns of your own. Sometimes, patterns
allow you to make accurate predictions.
Ex. 1: Describing a Visual
Pattern

1
Sketch the next figure in the pattern.
2
3
4
5
Ex. 1: Describing a Visual
Pattern - Solution

The sixth figure in the pattern has 6
squares in the bottom row.
5
6
Ex. 2: Describing a Number
Pattern
Describe a pattern in the sequence of
numbers. Predict the next number.
a.
1, 4, 16, 64
Many times in number pattern, it is
easiest listing the numbers vertically
rather than horizontally.

Ex. 2: Describing a Number
Pattern
How do you get to


a.
Describe a pattern
in the sequence of
numbers. Predict
the next number.
1
4
16
64
the next number?


That’s right. Each
number is 4 times
the previous
number. So, the
next number is
256, right!!!
Ex. 2: Describing a Number
Pattern
How do you get to


b.
Describe a pattern
in the sequence of
numbers. Predict
the next number.
-5
-2
4
13


the next number?
That’s right. You
add 3 to get to the
next number, then
6, then 9. To find
the fifth number,
you add another
multiple of 3 which
is +12 or
25, That’s right!!!
Goal 2: Using Inductive
Reasoning

1.
2.
Much of the reasoning you need in
geometry consists of 3 stages:
Look for a Pattern: Look at several
examples. Use diagrams and tables to
help discover a pattern.
Make a Conjecture. Use the example
to make a general conjecture. Okay,
what is that?
Goal 2: Using Inductive
Reasoning
A conjecture is an unproven statement
that is based on observations. Discuss
the conjecture with others. Modify
the conjecture, if necessary.
3. Verify the conjecture. Use logical
reasoning to verify the conjecture is
true IN ALL CASES. (You will do this in
Chapter 2 and throughout the book).

Ex. 3: Making a Conjecture

Find a pattern for each sequence. Use the
pattern to show the next two terms.
17, 23, 29, 35, 41, _______,
_______
Ex. 4: Making a Conjecture

Find a pattern for each sequence. Use the
pattern to show the next two terms.
12, 14, 18, 24, 32, ______, _______
Ex. 5: Making a Conjecture

Find a pattern for each sequence. Use the
pattern to show the next two terms.
2, -4, 8, -16, 32, _______,
_______
Ex. 6: Making a Conjecture

Find a pattern for each sequence. Use the
pattern to show the next two terms.
1, 2, 4, 7, 11, 16, _______,
_______
Note:

To prove that a conjecture is true, you
need to prove it is true in all cases. To
prove that a conjecture is false, you
need to provide a single counter
example. A counterexample is an
example that shows a conjecture is
false.
Ex. 4: Finding a
counterexample

Show the conjecture is false by finding
a counterexample.
Conjecture: For all real numbers x, the
expressions x2 is greater than or equal
to x.
Ex. 4: Finding a
counterexample- Solution
Conjecture: For all real numbers x, the
expressions x2 is greater than or equal to x.

The conjecture is false. Here is a
counterexample: (0.5)2 = 0.25, and 0.25 is
NOT greater than or equal to 0.5. In fact,
any number between 0 and 1 is a
counterexample.
Note:

Not every conjecture is known to be
true or false. Conjectures that are not
known to be true or false are called
unproven or undecided.
Ex. 5: Examining an
Unproven Conjecture


In the early 1700’s, a Prussian mathematician
names Goldbach noticed that many even
numbers greater than 2 can be written as the
sum of two primes.
Specific cases:
4=2+2
6=3+3
8=3+5
10 = 3 + 7
12 = 5 + 7
14 = 3 + 11
16 = 3 + 13
18 = 5 + 13
20 = 3 + 17
Ex. 5: Examining an
Unproven Conjecture


Conjecture: Every even number greater than
2 can be written as the sum of two primes.
This is called Goldbach’s Conjecture. No one
has ever proven this conjecture is true or
found a counterexample to show that it is
false. As of the writing of this text, it is
unknown if this conjecture is true or false. It
is known; however, that all even numbers up
to 4 x 1014 confirm Goldbach’s Conjecture.
Ex. 6: Using Inductive
Reasoning in Real-Life

Moon cycles. A full moon occurs when
the moon is on the opposite side of
Earth from the sun. During a full moon,
the moon appears as a complete circle.
Ex. 6: Using Inductive
Reasoning in Real-Life


Use inductive reasoning and the
information below to make a conjecture
about how often a full moon occurs.
Specific cases: In 2005, the first six full
moons occur on January 25, February
24, March 25, April 24, May 23 and
June 22.
Ex. 6: Using Inductive Reasoning
in Real-Life - Solution



A full moon occurs every 29 or 30 days.
This conjecture is true. The moon revolves
around the Earth approximately every 29.5
days.
Inductive reasoning is very important to the
study of mathematics. You look for a pattern
in specific cases and then you write a
conjecture that you think describes the
general case. Remember, though, that just
because something is true for several specific
cases does not prove that it is true in general.
Ex. 6: Using Inductive
Reasoning in Real-Life - NOTE

Inductive reasoning is very important to
the study of mathematics. You look for
a pattern in specific cases and then you
write a conjecture that you think
describes the general case. Remember,
though, that just because something is
true for several specific cases does not
prove that it is true in general.
Homework—

Page 6-10
(1-16, 25-28, 31-39)