Commutative algebra homework

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last update: 02 March 2012

Homework problems

HW: Let $G$ be a (commutative?) topological group with a fundamental system of neighborhoods of 0 which are subgroups, $0 \subseteq \dots \subseteq G_{n + 1} \subseteq G_{n} \subseteq \dots \subseteq G_{2} \subseteq G_{1} .$ Show that the completion of $G$ $\hat{G} ≃ \lim_{\leftarrow} \frac{G}{G_{n}}$ by showing that a sequence in $G$ is coherent if and only if it is Cauchy.

HW: Let $S$ be a set and let $n \in ℤ_{> 0} .$

Define relation on $S$ , equivalence relation on $S$ , and equivalence class and give some illustrative examples.
Define partition of $S$ and partition of $n$ and give some illustrative examples.
State and prove a theorem which makes precise the concept that equivalence relations and partitions are interchangable.

HW: Define the notion of a function $f : X \to Y$ as a subset of $X \times Y$ .

		Hint:
	Consider the graph of $f$ and write down precise conditions for a subset $S$ of $X \times Y$ to be the graph of a function. $□$

HW:

Define isomorphism of sets, and $f$ is bijective and give some illustrative examples.
Prove that a function $f : X \to Y$ is an isomorphism of sets if and only if $f$ is bijective.

HW: Let $X$ and $Y$ be topological spaces. Let $a \in X$ and let $f : X \to Y$ be a function.

Define $f$ is continuous at $x = a$ and give some illustrative examples.
Define $\lim_{x \to a} f (x)$ and give some illustrative examples.
Prove the following fundamental theorem: $f is continuous at x = a \Leftrightarrow \lim_{x \to a} f (x) = f (a) .$

Week 1 Problems

Lecture 2 - 29/02/2012

HW: Show that $ℤ_{(0)} = ℚ .$

HW: Expand $\tan t$ as a power series beginning with $t .$

Lecture 3 - 02/03/2012

HW: Do the exercises on the p-adic numbers page.

HW: Using the definition of the ring of fractions with denominators in $S$ from the lectures, prove that $=$ is an equivalence relation, that $+ : A [S^{- 1}] \times A [S^{- 1}] \to A [S^{- 1}]$ is well defined, that $\cdot : A [S^{- 1}] \times A [S^{- 1}] \to A [S^{- 1}]$ is well defined, and $A [S^{- 1}]$ with $+$ and $\cdot$ is a ring.

Week 2 Problems

Lecture 2 - 07/03/2012

HW: Show that $\begin{array}{rrcl} S^{- 1} u : & S^{- 1} M : & \to & S^{- 1} N : \\ \frac{m}{s} & \mapsto & \frac{u (m)}{s} \end{array}$ is an $A [S^{- 1}] -$ module homomorphism.

HW: Show that $S^{- 1}$ is a functor (i.e. $S^{- 1} (u_{1} \circ u_{2}) = S^{- 1} (u_{1}) \circ S^{- 1} (u_{2})$ ).

Lecture 3 - 09/03/2012

HW: Let $f : V \to E$ be a linear transformation from a vector space $V$ into an algebra $E .$ Suppose that if $v \in V$ then $f {(v)}^{2} = 0 .$ Show that if $v_{1}, v_{2} \in V$ then $f (v_{1}) f (v_{2}) = - f (v_{2}) f (v_{1}) .$

HW: Compute the dimension of $S^{k} (V) .$

HW: Determine (make precise) the definition of $sgn (σ),$ as used in the construction of $Λ (V) .$

Week 3 Problems

Lecture 1 - 12/03/2012

HW: Show that if $G$ is a cyclic group then $G ≃ ℤ$ or $G ≃ ℤ / r ℤ$ for some $r \in ℤ_{\geq 0} .$

HW: Show that the group $G_{r, r, 2}$ can be presented by generators $s_{1}, s_{2}$ with relations $s_{1}^{2} = 1, s_{2}^{2} = 1, \underset{r factors}{\underset{⏟}{s_{1} s_{2} s_{1} \dots}} = \underset{r factors}{\underset{⏟}{s_{2} s_{1} s_{2} \dots}}$

Notes and References

References

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