12-240/Classnotes for Tuesday September 11

DBN: Classes: 2012-13: 12-240 / Navigation

#	Week of...	Notes and Links
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1	Sep 10	About This Class, Tuesday, Thursday
2	Sep 17	HW1, Tuesday, Thursday, HW1 Solutions
3	Sep 24	HW2, Tuesday, Class Photo, Thursday
4	Oct 1	HW3, Tuesday, Thursday
5	Oct 8	HW4, Tuesday, Thursday
6	Oct 15	Tuesday, Thursday
7	Oct 22	HW5, Tuesday, Term Test was on Thursday. HW5 Solutions
8	Oct 29	Why LinAlg?, HW6, Tuesday, Thursday, Nov 4 is the last day to drop this class
9	Nov 5	Tuesday, Thursday
10	Nov 12	Monday-Tuesday is UofT November break, HW7, Thursday
11	Nov 19	HW8, Tuesday,Thursday
12	Nov 26	HW9, Tuesday , Thursday
13	Dec 3	Tuesday UofT Fall Semester ends Wednesday
F	Dec 10	The Final Exam (time, place, style, office hours times)
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In this course, we will be focusing on both a practical side and a theoretical side.

Practical Side

1. Solving complicated systems of equations, such as:

5x_{1}-2x_{2}+x_{3}=9\!

x_{1}+x_{2}-x_{3}=-2\!

2x_{1}+9x_{2}-3x_{3}=-4\!

2. We can turn the above into a matrix!

{\begin{pmatrix}5&-2&1\\-1&1&-1\\2&9&-3\end{pmatrix}}=A

Theory Side

3. "The world doesn't come with coordinates." We will learn to do all of this in a coordinate-free way.

4. We'll learn to do all of this over other sets of numbers and fields.

Hidden Agenda

5. We'll learn the process of pure mathematics by doing it. We'll learn about:

Abstraction
Generalization
Definitions
Theorems
Proofs
Notation
Logic

A number system has specific properties of the real numbers.

Real Numbers

A set, $\mathbb {R} \!$ , with:

Two binary operations, addition and multiplication.
Two special elements, 0 and 1.

The real numbers have some special properties:

Commutative Laws

$\mathbb {R} 1$

\forall \ a,b\ \epsilon \ \mathbb {R} \quad a+b=b+a\!

\forall \ a,b\ \epsilon \ \mathbb {R} \quad ab=ba\!

Associative Laws

$\mathbb {R} 2$

\forall \ a,b,c\ \epsilon \ \mathbb {R} \quad (a+b)+c=a+(b+c)\!

\forall \ a,b,c\ \epsilon \ \mathbb {R} \quad (ab)\cdot c=a\cdot (bc)\!

Existence of "Units"

$\mathbb {R} 3$

\forall \ a\ \epsilon \ \mathbb {R} \quad a+0=a\!

\forall \ a\ \epsilon \ \mathbb {R} \quad a\cdot 1=a\!

Existence of Negatives/Inverses

$\mathbb {R} 4$

\forall \ a\ \epsilon \ \mathbb {R} \ \exists \ b\ \epsilon \ \mathbb {R} \quad a+b=0\!

\forall \ a\ \epsilon \ \mathbb {R} \ \exists \ b\ \epsilon \ \mathbb {R} \quad a\cdot b=1\!

Distributive Law

$\mathbb {R} 5$

\forall \ a,b,c\ \epsilon \ \mathbb {R} \quad (a+b)\cdot c=ac+bc\!

An example of a property that follows from the earlier ones:

a^{2}-b^{2}=(a+b)(a-b)\!

We can define subtraction and squaring from the properties covered above.

An example of a property that does not follow from the earlier ones:

The existence of square roots:

\forall \ a\ \exists \ b\ \quad b^{2}=a\ or\ b^{2}=-a\!

We can construct a set that has all of the 5 properties described above, but for which this property does not follow.

This set is the rational numbers.

There is a rational number $a\!$ where there is no $b$ in the set.

This is because ${\sqrt {2}}$ is irrational.

Fields

The properties we have been discussing aren't restricted to only the real numbers.

They are also properties of:

Rational numbers
Complex numbers
Others

Let's construct an abstract universe where these properties hold.

Definition: Field

A field is a set, $\mathbb {F}$ $\mathbb {F}$ , with:
- Two binary operations, addition and multiplication.
- Two special elements, 0 and 1, where 0 does not equal 1.
- All of the above mentioned properties hold.

Now, instead of speaking of $\mathbb {R} 1,\ \mathbb {R} 2,\ \mathbb {R} 3,\ \mathbb {R} 4,\ \mathbb {R} 5$ , we can speak of $\mathbb {F} 1,\ \mathbb {F} 2,\ \mathbb {F} 3,\ \mathbb {F} 4,\ \mathbb {F} 5$ .

We have abstracted!

Examples of Fields

Take $\mathbb {F} =\mathbb {R}$

Take $\mathbb {F} =\mathbb {Q}$ (Rational numbers)

The complex numbers. $\mathbb {C} =\lbrace a+bi\quad a,b\ \epsilon \ \mathbb {R} \rbrace$

The above fields have an infinite number of elements. We can also have finite fields:

$\mathbb {F} =\mathbb {F} _{2}=\mathbb {Z} /2=\lbrace 0,1\rbrace$ $\mathbb {F} =\mathbb {F} _{2}=\mathbb {Z} /2=\lbrace 0,1\rbrace$
- There are only 2 elements.
- You can think of 0 as even and 1 as odd, which will help you construct the tables below.
- You can also think of the results below as the remainder of the operations when divided by 2. (mod 2)

+	0	1
0	0	1
1	1	0

x	0	1
0	0	0
1	0	1

$\mathbb {F} =\mathbb {F} _{3}=\mathbb {Z} /3=\lbrace 0,1,2\rbrace$

+	0	1	2
0	0	1	2
1	1	2	0
2	2	0	1

x	1	2
0	0	0
1	1	2
2	2	1

$\mathbb {F} =\mathbb {F} _{5}=\mathbb {Z} /5=\lbrace 0,1,2,3,4\rbrace$ $\mathbb {F} =\mathbb {F} _{5}=\mathbb {Z} /5=\lbrace 0,1,2,3,4\rbrace$
- Not going to bother making the tables here.

$\mathbb {F} _{4}$ $\mathbb {F} _{4}$ is not a field.
- It does not have the property $\mathbb {R} 5$ .

2\cdot 0=0

2\cdot 1=2

2\cdot 2=0

2\cdot 3=2

We never got a 1.

If the subscript is a prime number, it is a field.

Theorem:

1.

Let F be a field.

\forall a,b,c\ \epsilon \ \mathbb {F} \quad a+b=c+b

"Cancellation Lemma"

\Rightarrow a=c

2.

ab=cb,b\neq 0

\Rightarrow a=c

We'll cover 3-11 next class!

Proof of 1:

Let

a,b,c\ \epsilon \ \mathbb {F}

by

\mathbb {F} 4\ \exists \ d\ \epsilon \ \mathbb {F} \quad b+d=0

so with this d,

a+b=c+b\!

and so

(a+b)+d=(c+b)+d\!

so by

\mathbb {F} 2

,

a+(b+d)=c+(b+d)\!

so

a+0=c+0\!

so by

\mathbb {F} 3\quad a=c\!

\Box

Scanned Notes by Sina.zoghi

Sina.zoghi - I have linked your notes below, so that you and other can see how such scanned notes may be linked. Though I'm afraid the quality of the scans is rather low - they are of low contrast and there is too much "white space" around each page. So the thumbnails are barely readable. If you'd be able to re-upload better scans (under the same filenames) that will be great. Drorbn 09:14, 12 September 2012 (EDT)