MAE 121 Order Properties of the System (ℤ, +) Lecture 2 PDF

Summary

This lecture presents the order properties of the system (ℤ , +) explored through formal proofs, including the trichotomy property, transitivity property, antisymmetry property, addition compatibility property, and multiplication properties. The lecture explains the crucial role of the order properties in simplifying mathematical expressions, solving equations, and ensuring consistency in mathematical calculations.

Full Transcript

SCHOOL OF SCIENCE AND MATHEMATICS EDUCATION
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MAE 121
Order Properties of the System (ℤ,
+)
Exploring Integer Properties through
Formal Proofs
Mr. W Mangcengeza
Lecture 2
 Introduction
Understanding order properties is
fundamental in mathematics as they
support key operations and concepts.
These properties, such as commutative,
associative, and distributive, are
essential for simplifying expressions,
solving equations, and ensuring
consistency in calculations. They also
underpin more advanced mathematical
structures and enhance problem-solving
and logical reasoning skills. Mastery of
these properties is crucial for both basic
arithmetic and advanced mathematics.
 Trichotomy Property
Statement: For any a, b ∈ ℤ, one and
only one of the following is true: a <
b, a = b, or a > b.
Example: a = -3, b = 2
Proof outline
Proof of Trichotomy Property
For a, b ∈ ℤ, consider d = a - b
d > 0 implies a > b
d = 0 implies a = b
d < 0 implies a < b
One and only one of these cases is
true
 Transitivity Property
Statement: For any a, b, c ∈ ℤ, if a <
b and b < c, then a < c.
Example: a = -5, b = 0, c = 4
Proof outline
Proof of Transitivity Property
Assume a < b and b < c
b = a + m and c = b + n
c=a+m+n
Since m and n are positive, a < c
Proof of Transitivity Property
 Antisymmetry Property
Statement: For any a, b ∈ ℤ, if a < b,
then it is not the case that b < a. If a
≤ b and b ≤ a, then a = b.
Example: a = 3, b = 7
Proof outline
 Proof of Antisymmetry
Property
Assume a < b
There exists m > 0 such that b = a +
m
Assume b < a
There exists n > 0 such that a = b +
n
a = a + m + n implies 0 = m + n
Contradiction, thus a < b implies ¬(b
< a)
 Addition Compatibility
Property
Statement: For any a, b, c ∈ ℤ, if a <
b, then a + c < b + c.
Example: a = -2, b = 1, c = 3
Proof outline
 Proof of Addition Compatibility
Property
Assume a < b
There exists m > 0 such that b = a +
m
Add c to both sides: b + c = a + c +
m
Since m > 0, a + c < b + c
 Multiplication Compatibility
Property
Statement: For any a, b, c ∈ ℤ, if a <
b and c > 0, then a · c < b · c.
Example: a = 1, b = 4, c = 2
Proof outline
Proof of Multiplication Compatibility
Property
Assume a < b and c > 0
There exists m > 0 such that b = a +
m
Multiply by c: b · c = a · c + m · c
Since m, c > 0, a · c < b · c
 Reflection Questions
Why is the trichotomy property crucial for
defining a total order on ℤ?
How does the transitivity property help in
reasoning about the relative order of multiple
integers?
Can you think of a situation where the
antisymmetry property helps in proving equality?
Why is it important for the addition compatibility
property to hold in ordered sets?
What might happen if the multiplication
compatibility property did not hold for positive
integers?