In Preparation
The information below is preliminary and cannot be trusted! (v)
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Week of...
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Notes and Links
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Additions to the MAT 1100 web site no longer count towards good deed points
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1
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Sep 12
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About This Class, Tuesday - Non Commutative Gaussian Elimination, Thursday - NCGE completed, the category of groups, images and kernels.
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2
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Sep 19
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I'll be in Strasbourg, class was be taught by Paul Selick. See my summary.
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3
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Sep 26
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Class Photo, HW1, HW1 Submissions, HW 1 Solutions
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4
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Oct 3
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The Simplicity of the Alternating Groups
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5
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Oct 10
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HW2, HW 2 Solutions
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6
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Oct 17
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Groups of Order 60 and 84
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7
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Oct 24
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Extra office hours: Monday 10:30-12:30 (Dror), 5PM-7PM @ Huron 1028 (Stephen). Term Test on Tuesday. Summary for the midterm exam. Term Test - Sample Solutions
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8
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Oct 31
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HW3, HW 3 Solutions
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9
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Nov 7
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Monday-Tuesday is November Break, One Theorem, Two Corollaries, Four Weeks
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10
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Nov 14
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HW4, HW 4 Solutions
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11
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Nov 21
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12
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Nov 28
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HW5 and last week's schedule
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13
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Dec 5
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Tuesday - the Jordan form; UofT Fall Semester ends Wednesday; our Final Exam took place on Friday
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Register of Good Deeds
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Add your name / see who's in!
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See Non Commutative Gaussian Elimination
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This assignment is due at class time on Tuesday, November 29, 2011.
Solve the following questions
Problem 1. Prove that a ring is a PID iff it is a UFD in which for every non-zero .
Problem 2. (Selick) In a ring , and element is called "nilpotent" if for some positive , . Let be the set of all nilpotent elements of .
- Prove that if is commutative then is an ideal.
- Give an example of a non-commutative ring in which is not an ideal.
Problem 3. (comprehensive exam, 2009) Let be a commutative ring. Show that a polynomial is invertible in iff its constant term is invertible in and the rest of its coefficients are nilpotent.
Problem 4. (Lang) Show that the ring is a PID and hence a UFD. What are the units of that ring?
Problem 5. (Dummit and Foote) In , find the greatest common divisor of and , and express it as a linear combination of these two elements.
Problem 6. (Withdrawn, do not submit) Show that the quotient ring is not a UFD.