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{{14-1100/Navigation}} |
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{{14-1100/Navigation}} |
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{{In Preparation}} |
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This assignment is due at class time on Thursday, November 20, 2011. |
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This assignment is due at class time on Thursday, November 20, 2011. |
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===Solve the following questions=== |
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===Solve the following questions=== |
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'''Problem 1.''' (Klein's 1983 course) |
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'''Problem 1.''' Prove that a ring <math>R</math> is a PID iff it is a UFD in which <math>\gcd(a,b)\in\langle a, b\rangle</math> for every non-zero <math>a,b\in R</math>. |
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# Show that the ideal <math>I=\langle 3,\, x^3-x^2+2x-1\rangle</math> inside the ring <math>{\mathbb Z}[x]</math> is not principal. |
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# Is <math>{\mathbb Z}[x]/I</math> a domain? |
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'''Problem 2.''' (Lang) Show that the ring <math>{\mathbb Z}[i]=\{a+ib\colon a,b\in{\mathbb Z}\}\subset{\mathbb C}</math> is a PID and hence a UFD. What are the units of that ring? |
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'''Problem 2.''' Prove that a ring <math>R</math> is a PID iff it is a UFD in which <math>\gcd(a,b)\in\langle a, b\rangle</math> for every non-zero <math>a,b\in R</math>. |
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'''Problem 3.''' (Dummit and Foote) In <math>{\mathbb Z}[i]</math>, find the greatest common divisor of <math>85</math> and <math>1+13i</math>, and express it as a linear combination of these two elements. |
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'''Problem 3.''' (Lang) Show that the ring <math>{\mathbb Z}[i]=\{a+ib\colon a,b\in{\mathbb Z}\}\subset{\mathbb C}</math> is a PID and hence a UFD. What are the units of that ring? |
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'''Problem 4.''' (Hard!) Show that the quotient ring <math>{\mathbb Q}[x,y]/\langle x^2+y^2-1\rangle</math> is not a UFD. |
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'''Problem 4.''' (Dummit and Foote) In <math>{\mathbb Z}[i]</math>, find the greatest common divisor of <math>85</math> and <math>1+13i</math>, and express it as a linear combination of these two elements. |
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'''Problem 5.''' (Klein's 1983 course) Show that <math>{\mathbb Z}[\sqrt{10}]</math> is not a UFD. |
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'''Problem 6.''' (Hard!) Show that the quotient ring <math>{\mathbb Q}[x,y]/\langle x^2+y^2-1\rangle</math> is not a UFD. |
Latest revision as of 12:21, 6 November 2014
Welcome to Math 1100!
(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; Monday - Non Commutative Gaussian Elimination; Thursday - the category of groups, automorphisms and conjugations, images and kernels.
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| 2
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Sep 15
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Monday - coset spaces, isomorphism theorems; Thursday - simple groups, Jordan-Holder decomposition series.
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Sep 22
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Monday - alternating groups, group actions, The Simplicity of the Alternating Groups, HW1, HW 1 Solutions, Class Photo; Thursday - group actions, Orbit-Stabilizer Thm, Class Equation.
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Sep 29
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Monday - Cauchy's Thm, Sylow 1; Thursday - Sylow 2.
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Oct 6
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Monday - Sylow 3, semi-direct products, braids; HW2; HW 2 Solutions; Thursday - braids, groups of order 12, Braids
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Oct 13
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No class Monday (Thanksgiving); Thursday - groups of order 12 cont'd.
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Oct 20
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Term Test; Term Test Solutions on Monday, HW3; HW 3 Solutions; Thursday - solvable groups, rings: defn's & examples.
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Oct 27
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Monday - functors, Cayley-Hamilton Thm, ideals, iso thm 1; Thursday - iso thms 2-4, integral domains, maximal ideals, One Theorem, Three Corollaries, Five Weeks
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Nov 3
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Monday - prime ideals, primes & irreducibles, UFD's, Euc.Domain PID, Thursday - Noetherian rings, PIDUFD, Euclidean Algorithm, modules: defn & examples, HW4, HW 4 Solutions
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Nov 10
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Monday - R is a PID iff R has a D-H norm, R-modules, direct sums, every f.g. module is given by a presentation matrix, Thursday - row & column reductions plus, existence part of Thm 1 in 1t3c5w handout.
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Nov 17
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Monday-Tuesday is UofT's Fall Break, HW5, Thursday - 1t3c5w handout cont'd, JCF Tricks & Programs handout
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Nov 24
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Monday - JCF Tricks & Programs cont'd, tensor products, Thursday - tensor products cont'd
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Dec 1
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End-of-Course Schedule; Monday - tensor products finale, extension/reduction of scalars, uniqueness part of Thm 1 in 1t3c5w, localization & fields of fractions; Wednesday is a "makeup Monday"!; Notes for Studying for the Final Exam Glossary of terms
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Dec 15
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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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See Non Commutative Gaussian Elimination
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This assignment is due at class time on Thursday, November 20, 2011.
Solve the following questions
Problem 1. (Klein's 1983 course)
- Show that the ideal
inside the ring ![{\displaystyle {\mathbb {Z} }[x]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/e080fddb4f8b99adc91d4b678074184a78b306f1)
is not principal.
- Is
![{\displaystyle {\mathbb {Z} }[x]/I}](https://wikimedia.org/api/rest_v1/media/math/render/svg/3e0d523ee9cb85ab2b3ef004cd039aedde51e280)
a domain?
Problem 2. Prove that a ring 
is a PID iff it is a UFD in which 
for every non-zero 
.
Problem 3. (Lang) Show that the ring ![{\displaystyle {\mathbb {Z} }[i]=\{a+ib\colon a,b\in {\mathbb {Z} }\}\subset {\mathbb {C} }}](https://wikimedia.org/api/rest_v1/media/math/render/svg/aaf6c02172f2bb115542d48db5c7d622beffc54b)
is a PID and hence a UFD. What are the units of that ring?
Problem 4. (Dummit and Foote) In ![{\displaystyle {\mathbb {Z} }[i]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/2409dcaf0c37bf7184798dfd10f4a2da70d980ec)
, find the greatest common divisor of 
and 
, and express it as a linear combination of these two elements.
Problem 5. (Klein's 1983 course) Show that ![{\displaystyle {\mathbb {Z} }[{\sqrt {10}}]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/4905152d1bea6d8056ac5d833d387feac8fea859)
is not a UFD.
Problem 6. (Hard!) Show that the quotient ring ![{\displaystyle {\mathbb {Q} }[x,y]/\langle x^{2}+y^{2}-1\rangle }](https://wikimedia.org/api/rest_v1/media/math/render/svg/d481fae3a288f265081fd3b5d7a904520ba9a71f)
is not a UFD.
