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%Copied (mostly) from Fall 2019 (groups) and Fall 2021 (rings and linear algebra).

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\markright{\tiny \copyright 20\examyear\ by California State University.  Unauthorized distribution of this material will result in civil and criminal prosecution.}

{\bf \semester\ 20\examyear\  -- Algebra Comprehensive Exam} \hfill \mbox{\hskip 5mm Name: \rule{1.1in}{.005 in}}

\vskip 3mm

Choose six problems total, including at least two from Part I and two from Part II.  Enter the numbers of the problems you want graded here:

\begin{center}\begin{tabular}{|l|c|c|c|c|c|c|l|} \hline
Problems & \makebox[.5cm] & \makebox[.5cm] & \makebox[.5cm] & \makebox[.5cm] & \makebox[.5cm] & \makebox[.5cm] & Total\\ \hline
Scores & & & & & & & \\ \hline
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\vskip 5mm
\centerline{{\bf Part I: Groups} (Choose at least two.)}
\vskip 3mm


\num
\item  Let \(H\) and \(K\) be finite groups.  Let \(G = H \times K\).
\num
\item  If \(h \in H\) has order \(m\) and \(k \in K\) has order \(n\), what is the order of \point{h,k} in \(G\)?  Justify your answer.
\item  How many elements of order 20 are there in the group \linebreak \mbox{\((\ZZ/2\ZZ) \times (\ZZ/4\ZZ) \times (\ZZ/10\ZZ)\)}?

\mun

\item  In each item below you are given a group \(G\) with a subgroup \(H\).  Determine if \(H\) is a normal subgroup of \(G\).  Justify your answers.
\num
\item  \(G\) is a finite group with a unique element \(b\) of order 2; \(H = \gen b\).
\item  \(G = S_4\); \(H = \gen{(123)}\).
\item  \(G = D_{12}\), the dihedral group of order 12; \(H\) is a Sylow 2-subgroup of \(G\).  
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\item  
\num
\item  Prove that there are no simple groups of order $105$.
\item  How many isomorphism classes of abelian groups of order $360$ are there?  For each one give both its invariant factor decomposition and its elementary divisor decomposition.
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\item  Let \(G\) be a group, and let \(H\) be a {\em normal} subgroup of \(G\), and let \(K\) be any subgroup of \(G\). 
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\item  Prove that \(HK = \setbuild{hk}{h \in H, k \in K}\) is a subgroup of \(G\).
\item  Now suppose further that \(H\) has index \(p\), where \(p\) is a prime number.  Prove that either \(K\) is a subgroup of \(H\) or \([K:K\cap H] = p\).
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\item  Find all automorphisms of the group \(\ZZ \times \ZZ/n\ZZ\).  Your answer should include the following:
\num
\item  Describe each automorphism; that is, say what \(\pi(a,b)\) is for each automorphism \(\pi\) and each \((a,b) \in \ZZ \times \ZZ/n\ZZ\).
\item  Prove that each function you describe really is injective and surjective.
\item  Prove that there are no other automorphisms.
\item  State how many automorphisms there are in all.
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\pagebreak
\centerline{{\bf Part II: Rings and Linear Algebra} (Choose at least two.)}
\vskip 3mm

\item  \num
\item   Let \(R\) be a commutative ring with identity.  Prove that \(R\) is a field if and only if the only ideals of \(R\) are \(\{0\}\) and \(R\).
\item  Give an example of a ring that has exactly three ideals.
\item  Show that \(\MM_2(\RR)\), the ring of \(2\times 2\) matrices with entries from the real numbers, has no nontrivial proper two-sided ideals but is not a division ring.
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\item  Let \(\phi:R \rightarrow S\) be a homomorphism of rings, \(I\) an ideal of \(R\), \(J\) an ideal of \(S\).   
\num
\item  Prove that \(\phi\inv(J)\) is an ideal of \(R\).
\item  Prove that if \(\phi\) is {\em surjective}, then \(\phi(I)\) is an ideal of \(S\).
\item  Give an example to show that the previous part need not be true if \(\phi\) is not surjective.
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\item  Let \(R = \ZZ\bpoint{\sqrt{-3}}\). 
\num
\item  Prove that the elements \(1 + \sqrt{-3}, 1 - \sqrt{-3}\), and 2 are all irreducible in $R$.
\item  Prove that \(R\) is not a unique factorization domain.
\item  Prove that \(R = \ZZ\bpoint{\sqrt{-3}}\) is not isomorphic to \(S = \ZZ\bpoint{\sqrt{-2}}\).
\mun

\item  
\num  
\item  Let \(R\) be a PID.  If \(I\) is a nonzero prime ideal of \(R\), prove that \(I\) is maximal.
\item  Give an example of an integral domain \(R\) with a nonzero prime ideal that is not maximal.  Justify your answer.
\item  In \(\ZZ_2[x]\), is the ideal generated by \(x^3+1\) a prime ideal?  Justify your answer.
\item  Consider the quotient ring 
\[
\ZZ_2[x]\modbig{\point{x^3+1}} = \setbuild{a + bX + cX^2}{a,b,c \in \ZZ_2},
\]
where \(X\) is the residue of \(x\) modulo \point{x^3+1}.
\num
\item  List all the units of \(R\).
\item  List all zero-divisors of \(R\).
\item  List all ideals of \(R\).  Which of them are prime?
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\item  \num
\item  Let \(A\) be an \(n \times n\) matrix with real entries having eigenvalues \(\lambda_1 \neq \lambda_2\) and associated eigenvectors \(\vv_1, \vv_2\) respectively.  Show that \(\vv_1\) and \(\vv_2\) are linearly independent.  
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\item  Let \(A\) be the \(5 \times 5\) matrix whose entries are all 1, that is,
\[
A = \vec{1 & 1 & 1 & 1 & 1\\ 1 & 1 & 1 & 1 & 1\\ 1 & 1 & 1 & 1 & 1\\ 1 & 1 & 1 & 1 & 1\\ 1 & 1 & 1 & 1 & 1}.
\]
\num

\item  Determine the eigenvalues for \(A\).
\item  Determine bases for the eigenspaces of \(A\).
\item  Is \(A\) diagonalizable?  If so, give a diagonal matrix similar to \(A\).
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