10-1100/Homework Assignment 4: Difference between revisions

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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>.
'''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>.

'''Problem 2.''' (Selick) In a ring <math>R</math>, and element <math>x</math> is called "nilpotent" if for some positive <math>n</math>, <math>x^n=0</math>. Let <math>\eta(R)</math> be the set of all nilpotent elements of <math>R</math>.
# Prove that if <math>R</math> is commutative then <math>\eta(R)</math> is an ideal.
# Give an example of a non-commutative ring <math>R</math> in which <math>\eta(R)</math> is not an ideal.

'''Problem 3.''' (comprehensive exam, 2009) Let <math>A</math> be a commutative ring. Show that a polynomial <math>f\in A[x]</math> is invertible in <math>A[x]</math> iff its constant term is invertible in <math>A</math> and the rest of its coefficients are nilpotent.

'''Problem 4.''' (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?

'''Problem 5.''' (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.

'''Problem 6.''' Show that the quotient ring <math>{\mathbb Q}[x,y]/\langle x^2+y^2-1\rangle</math> is not a UFD.

'''Problem 7.''' (Dummit and Foote) Prove that the quotient of a PID by a prime ideal is again a PID.

Revision as of 21:28, 16 November 2010

In Preparation

The information below is preliminary and cannot be trusted! (v)

This assignment is due at class time on Tuesday, November 30, 2010.

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 .

  1. Prove that if is commutative then is an ideal.
  2. 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. Show that the quotient ring is not a UFD.

Problem 7. (Dummit and Foote) Prove that the quotient of a PID by a prime ideal is again a PID.