Welcome to Math 240! (additions to this web site no longer count towards good deed points)
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Week of...
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Notes and Links
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1
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Sep 8
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About This Class, What is this class about? (PDF, HTML), Monday, Wednesday
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2
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Sep 15
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HW1, Monday, Wednesday, TheComplexField.pdf,HW1_solutions.pdf
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3
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Sep 22
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HW2, Class Photo, Monday, Wednesday, HW2_solutions.pdf
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4
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Sep 29
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HW3, Wednesday, Tutorial, HW3_solutions.pdf
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5
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Oct 6
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HW4, Monday, Wednesday, Tutorial, HW4_solutions.pdf
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6
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Oct 13
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No Monday class (Thanksgiving), Wednesday, Tutorial
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7
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Oct 20
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HW5, Term Test at tutorials on Tuesday, Wednesday
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8
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Oct 27
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HW6, Monday, Why LinAlg?, Wednesday, Tutorial
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9
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Nov 3
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Monday is the last day to drop this class, HW7, Monday, Wednesday, Tutorial
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10
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Nov 10
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HW8, Monday, Tutorial
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11
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Nov 17
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Monday-Tuesday is UofT November break
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12
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Nov 24
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HW9
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13
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Dec 1
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Wednesday is a "makeup Monday"! End-of-Course Schedule, Tutorial
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F
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Dec 8
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The Final Exam
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Register of Good Deeds
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Add your name / see who's in!
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We went over "What is this class about?" (PDF, HTML), then over "About This Class", and then over the first few properties of real numbers that we will care about.
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Dror's notes above / Students' notes below
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The Real Numbers
The real numbers are a set with 2 binary operations + and *, defined as follows:
in addition to 2 special elements such that , with the following properties:
The Commutative Law
R1: For every , we have:
(commutative law for addition)
(commutative law for multiplication)
The Associative Law
R2: For every , we have:
This is not true for a number of other sets in our lives! For example, the associative law does not hold for the English language. Consider the phrase "pretty little girls": "(pretty little) girls" does not mean the same thing as "pretty (little girls)".
So the associative property does not hold for the English language.
Existence of Units
R3: For every :
(additive unit)
(multiplicative unit)
Wednesday September 10th 2014 - Fields
The real numbers: A set |R with +,x : |R x |R -> |R & are elements of |R
such that
R1: For every that are elements of |R , and
R2: For every that are elements of |R, and
R3: For every that is an element of |R, and
R4: For every a that is an element of |R there exists b that is an element of |R such that
& for every a that is an element of |R and there exists b that is an element |R such that
R5: For every that are elements of |R,
follows from R1-R5
The following is true for the Real Numbers but does not follow from R1-R5
For every a that is an element of |R there exists an that is an element of |R such that
However we can see that it does not follow from R1-R5 because we can find a field that obeys R1-R5 yet does not follow the above rule.
An example of this is the Rational Numbers |Q. In |Q take and there does not exist such that or
The Definition Of A Field:
A "Field" is a set F along with a pair of binary operations +,x : FxF -> F and along with a pair that are elements of F such that and such that R1-R5 hold.
R1: For every that are elements of F , and
R2: For every that are elements of F, and
R3: For every that is an element of F, and
R4: For every that is an element of F there exists that is an element of F such that
& for every that is an element of F and there exists that is an element F such that
R5: For every that are elements of F,
Example
1. |R is a field (real numbers)
2. |Q is a field (rational numbers)
3. |C is a field (complex numbers)
4. F = {0, 1}
- insert table of addition and multiplication*
Proposition: F is a Field
checking F5
etc...
F = {0 , 1} = F2 = Z/2
Do the same for F7
- insert table of addition and multiplication*
"Like remainders when you divide by 7"
"like remainders mod 7'
Theorem (that shall remain unproved) :
For every prime number P, FP = {0 , 1 , 2 , ... , p-1 }
along with + & x defined as above
is a field.
Theorem: (basic properties of Fields)
Let F be a Field, and let a , b , c denote elements of F
Then:
1.
"Cancellation" still holds
2.
3. If is an element of F and satisfies for every , then
4. If is "like 1" then
... to be continued...