Solutions To Mathematics Textbooks/Algebra (9780132413770)/Chapter 2

Exercise 1.1

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  and  . If   and  , we have  , so the only set   with this composition law and identity is the set  .

Exercise 2.3

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a)  

b)  , but   in general. Consider for example the permutations  , so  , but  .

Exercise 2.4

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a)   is a subgroup of  

b)   is a subgroup of  .

c) Positive integers are not a subgroup of  , as they do not contain inverse elements of even 0.

d) The positive reals form a subgroup of  .

e) The set   is not a subgroup of  , as it does not contain the identity matrix.

Exercise 2.5

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Let   be a subgroup of  . If   has an identity element (possibly different from the identity of  ), then we have  , and multiplying both sides by   shows the identity elements are the same. Similarly if   has an inverse in  , we necessarily have   implying the inverses are the same.

Exercise 3.1

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Using the standard Euclidean algorithm we get   and  .

Exercise 3.2

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Let   be positive integers such that   is a prime number. Then, if  , we have  , so  . Because we want   to be prime, the only possibility is  .

Exercise 4.3

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Let   and   such that  . Then   so  .

Exercise 4.4

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Assume that a group   doesn't have a proper subgroup. Then

  •   must be finite. If   is infinite, take any   such that   doesn't generate  , and consider the set  . Since   does not generate  ,   is a proper subgroup of  , as is easy to show.
  •   has to be cyclic. Indeed, assume   is not cyclic, so no single element generates  . Then, for any element  ,   is a subgroup of  , since   is finite.
  •   has to have a prime number order. For contradiction, assume the order of   is  . Then, since   is a finite cyclic group, generated by an element  , we have that   is a proper subgroup.
  • Finally, if   has a prime order, no element of   generates a proper subgroup of  . This is because any element is of the form   for some element   and integer  . From Proposition 2.4.3 we know that the order of   is  , where   is the order of the group and  . In this case   is a prime number, so the order of   is either   or 1 (in the case that  ).

Exercise 4.5

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Let   be a cyclic group. Take any subgroup  . We assume   is finite (as the finite case has the main focus in the book, and in fact the definition on page 46 implicitly assumes so), so that   is finite as well. Let  . Then, since   is a subgroup, for every   it holds  . Hence, for the exponents   for which  , it holds  . Theorem 2.3.3 tells us that we can write   for some integer  . This shows that any element of   is of the form   so  .

Exercise 4.8 b

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Elementary matrices of the first type are matrices   with the entries  ,   for exactly one pair of indices   and 0 otherwise. It is easy to see from the determinant formula that the determinant of such matrices is always 1. From the product rule for the determinant it follows that all products of such matrices have determinant 1.

For the other direction, we consider the 2 by 2 case first and let   with  . Adding a scaled row to the other row and using the relation between the entries, we can manipulate the matrix as

 .

Since we can arrive to the identity matrix using only operations corresponding to multiplication with matrices of the first type and the condition  , the original matrix   can be produced from the identity by reversing the operations. Hence, we can generate   with only elementary matrices of the first type.The general case follows by induction: for any   matrix with determinant 1, assume we can manipulate   into the form

 ,

where   and  . It is easy to see that we can further manipulate   as follows:

 .

Note that in the second step the element   manipulates to 1 as we eliminate the row entries of the vector  , since otherwise the determinant of the manipulated matrix would not be equal to 1.

Exercise 4.9

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Elements of order 2 necessarily swap a pair of elements, or two pairs of elements. Such permutations are   totaling 9 permutations or order 2.

Exercise 4.11

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a) Any transposition that swaps elements   has a permutation matrix   that is an identity matrix where rows   have been swapped. These are elementary matrices of the second type. Any permutation matrix   corresponding to a permutation in   is an identity matrix whose rows have been permuted according to the permutation. From the permutation interpretation of   we know that   is invertible, so by Theorem 1.2.6 it is a product of elementary matrices. It is easy to see that only elementary matrices of type 2 are essential in such a product, as scaling or adding rows together are not needed. Hence,   can be decomposed into a product of elementary matrices of the second type, implying that the permutation is a product of transpositions.

b) First we show the following claim:

Claim: Any product of two transpositions can be written as a product of three-cycles.

Proof: Let   be a product of two transpositions, where   are some integers (possible some equal). Then we can write  .

Since any permutation in   is generated by transpositions, and the determinant of a transposition matrix is  , any permutation in   is a product of an even number of transpositions. Let   be a permutation, with a decomposition into transpositions  . Then we can group the product as  , where each product of two transpositions is also expressible as a product of three-cycles as shown in Claim.

Exercise 5.3

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Let   so that  . Then   so   is a group homomorphism. We have   and  .

Exercise 6.2

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Any homomorphism   satisfies  , so   must be a linear function with integer coefficient. In other words,   with  . For   to be injective, it suffices that  . For   to be surjective, we need  , since clearly  . The surjective functions   are also bijective, so they are isomorphisms.

Exercise 6.6

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Two elements   are conjugate, if for some  ,  . It is easy to see that for the given matrices, any matrix of the form   with   does the job. This matrix is also invertible, as its determinant is  . Since the determinant is negative, the matrices are not conjugate in  .

Exercise 7.1

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Let  , and   be a relation given by   if and only if there exists   such that  

Reflexivity:  , so  .

Symmetry: if  , then  , so  . Hence  , and vice versa.

Transitivity: if   and  , then   and  , so  . Therefore  .

Exercise 7.5

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  • The set   defines an equivalence relation on   that is the same as the usual "=" relation on the reals.
  • The relation defined by the empty set satisfies symmetry and transitivity, but fails reflexivity.
  • The locus   satisfies symmetry and transitivity, but fails reflexivity (for example   is not true).
  • The locus   is reflexive (  because  ), symmetric (since  ) and transitive (If   and   are solutions to the equation, then by symmetry also   and   are. Therefore also   and thus   is a solution.)

Exercise 7.6

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The number of equivalence relations in a set is equal to the number of partitions of the set. If the set has 5 elements, we have the following partitions:

  • Partitions to 1 set: 1
  • Partitions to 2 sets of sizes 1, 4: 5
  • Partitions to 2 sets of sizes 2, 3:  
  • Partitions to 3 sets of sizes 1, 1, 3:  
  • Partitions to 3 sets of sizes 1, 2, 2:  
  • Partitions to 4 sets of sizes 1, 1, 1, 2:  
  • Partitions to 5 sets of size 1 each: 1

The total number of partitions is thus 52.

Exercise 8.3

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Let   be a group such that   for some prime  . For any  ,   is a subgroup of   and by Lemma 2.8.7 has order   where  . If  , we are done as we have found an element of order  . Otherwise, consider   and notice that  , so   has order  .

Exercise 8.4

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For a group   of 35 elements we have a few cases.

  • If the group is cyclic, i.e.,  , we have that   has order 7 and   has order 5.
  • If the group is not cyclic, then for every   there is some integer   such that   is a subgroup of   order  . The order of   divides the order of  , so if   is not the identity, the order of   is either 5 or 7. Assume   is of order 5 and there is another element   of order 5 that is not a power of  . Then the subgroup of   generated by   and   has order 25. Indeed, all elements   for   are distinct (if not, we have for   that  , which implies that   is a power of  ), and there is 25 ways to choose the exponents. But 25 does not divide 35, so there cannot be another subgroup of order 5, and thus any element   that is not a power of   must generate a cyclic group of order 7.

Exercise 8.5

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If a group   contains an element   of order 6 and an element   of order 10, then   and   are subgroups of   and thus 6 and 10 divide the order of  . Hence, we can say that  .

Exercise 8.10

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Let   be a subgroup such that  . Then, since left (and right) cosets partition the group, we have   for some  . Because  , we must have   and so by Proposition 2.8.17   is normal.

For an example that this is not true for   such that  , consider   and  . Since  , we have indeed  . Then,   and  , so   is not normal.

Exercise 8.12

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Claim 1: For all   we have  .

Proof: Assume that  . Then  , since  . But since  , we have  , which contradicts the assumption that the cosets of   partition  .

Claim 2: For all   we have  .

Proof: Assume   for some  . Then we have   for some  . This implies  , and by Claim 1 we have  , so  . But then  , so unless   we have a contradiction.

Claim 1 and Claim 2 together prove that   is a subgroup of  .

Exercise 9.4

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The numbers involved are so small that solving by brute force becomes viable. To solve   we note that   so   so  .

To investigate the congruence   we note by computing every possibility that there is no element   modulo 6. Therefore there is no solution to the congruence.

Exercise 9.5

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Given equations

 

we can solve   and substitute to the other congruence equation to obtain  . This equation has a solution exactly when there exists   modulo  , or in other words an integer   such that  . This translates to saying that the equation   must have an integer solution  . But that is only possible when  .

Exercise 10.1

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It is not clear from the problem statement what the answer should look like. Therefore, the following candidate for answer might not be what is intended.

We show that each cycle of the form   has sign  . This is easy to see, as we can decompose  . Each transposition corresponds to an elementary matrix of type two, which has determinant  . The product form of the cycle has   transpositions, so the sign is as claimed. Therefore, if a permutation has a cycle decomposition to   cycles, each having   terms, the sign of the permutation is  .

Exercise 10.3

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Let   and  . We have  , and   has the subgroups   and   the subgroups  . The correspondences given by   are thus

Subgroup in   Subgroup in  
   
   
   
   

Notice that the subgroups   and   do not contain  .

Exercise 11.3

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Let   and assume   is generated by an element  . Then, for every element of   we would have   for some  . But since   are infinite, there are no   such that   and  , since the first condition would require   and the second  . The assumption that   are infinite means that   and  .

Exercise 11.4

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a)   is isomorphic to   by the function   given by   which has the inverse  . Seeing that   is a homomorphism is a direct consequence of multiplication rules of real numbers and properties of absolute value.

b) Let   be the set of invertible upper triangular matrices,   the set of invertible diagonal matrices and   the set of upper diagonal matrices with ones on the diagonal. In order to have a homomorphism  , we must have

 ,

for appropriate reals   and  . Using this notation for we have

 . (1)

On the other hand,

 . (2)

For   to be a homomorphism, we require these two to evaluate equal. However, the second coordinate in (1) has a dependency on   and  , whereas (2) does not have it. Hence, (1) and (2) are not equal in general.

c) Let  ,   (the angles of a circle with sum as the group operation) and  . Then   is isomorphic to   via the homomorphism   given by  . That   is a bijective homomorphism follows easily from the polar form representation of complex numbers.

Exercise 12.1

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Let   be a subgroup of  . Clearly   is not normal, as  . Then   and  . It is a straightforward computation to check that  . This set has 4 elements, but all cosets must have size 2, so it is not a coset.

Exercise 12.5

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Let   be the group of upper triangular matrices   with  .

a) Let   be the subset of   defined by  , i.e., the set of invertible diagonal matrices. It is easy to see that   is a group, as the inverse for each such matrix is also a diagonal matrix, and the product of two diagonal matrices is a diagonal matrix, and the identity is a diagonal matrix.   is however not a normal subgroup, since for any   with inverse   we can compute

 ,

which is not in   when  .

b) Let   be the subset of   defined by  . Again, it is easy to see that   is a subgroup of  . As above, we can compute

 ,

so   is a normal subgroup. The cosets are the sets containing the matrices

 ,

which are distinguished by the parameter  , as the variables   can be chosen arbitrarily (as long as  ). Hence, the quotient group is isomorphic to  . The homomorphism whose kernel   is is given by  .

c) Let   be the subset of   defined by  . Then again   is clearly a subgroup of  . We have

 ,

so   is a normal subgroup.To investigate the cosets of this group, we compute

 .

Here we can choose   as we like, so the top-right element doesn't impose any conditions on the cosets. Then, the elements of   for which it holds   generates a coset of   uniquely. This way we also obtain all cosets of  , since for every choice of   we can choose   and we see that this element is in the coset generated by  .

The quotient group is again isomorphic to   with the homomorphism whose kernel   is given by  .

Exercise M.6 a, b

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a) We observe the following:

  • Reflexivity: A point   is connected to itself by the path  . If  , then the path is contained in  .
  • Symmetry: Let   such that there exists a path   from   to   contained in  . Then the path   is a path from   to   contained in  
  • Transitivity. If   such that   is a path from   to   contained in   and   from   to   contained in  , then   is a path from   to   contained in   .

b) Path connection is an equivalence relation as shown in part a). Hence, path connected subsets partition the set  . In particular, the transitivity property ensures that if two points can be path connected, any points connected to those two points can be connected with both of the points.

Exercise M.7

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a) Let   such that   given by   and   given by  . Then   connects   to  . This path is also in  , since both paths   and   are in   and   is a group.

b) We show that for any matrix  , also the matrix   for any  . If   is the path joining   and  , simply consider the path  , since  . Hence, all matrices connected to identity by path form a normal subgroup.

Exercise M.8

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a) Elementary matrices of the first type are matrices   with the entries  ,   for exactly one pair of indices   and 0 otherwise. For each such  , there is a path to   just by setting   as the same matrix as  , with the exception that the element  . Clearly this is a continuous path from   to  , and since   is an elementary matrix of the first type, it also has determinant 1, and thus the path stays in  . Now, if we have the elementary matrices of the first type  , we have by M.7 a) that   is connected to  , as   are connected to  . We have now shown that any product of elementary matrices of type 1 are path connected to  , which implies that   is path connected, as the elementary matrices of type 1 generate  .

b) Let   such that  . We can path connect   to a matrix with determinant 1 by   so that  . This path is composition of continuous functions since   and   has always positive determinant, so it is a continuous path in  . Therefore, matrices with   form a connected component of  . By the same reasoning, if we just assumed that  , we can reason that the matrices with   form a connected component of  .

What remains to show is that these components are not connected. Let   be a matrix with a positive determinant and   a path connecting   to a matrix   with a negative determinant. Then,   has elements   that are continuous functions. From the determinant formula (1.6.4) we see that the determinant is then also a continuous function of the elements, as it is a sum of product of continuous functions. Then, since   and  , we must have   for some  . Therefore   is a path not contained in  , and hence   is a disjoint union of two connected components.

Exercise M.9

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Double cosets partition a group. Indeed, for every  , the double coset   contains  , since  . On the other hand, if  , then there are elements   such that  . This implies that  , and since   are subgroups,  , so  . This implies in turn that  .

Exercise M.14

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Multiplying from the left with the matrices   and their inverses corresponds to adding and subtracting rows. Multiplying from the right corresponds to adding and subtracting columns. Now, consider any  .

Claim 1: We can bring the matrix to the form   where   or   only by adding and subtracting rows.

Proof. If  , we have   since the matrix has determinant 1, so we can add the second column to the first one to obtain another matrix with determinant 1, whose entry on the first column, second row is non-zero. So we assume from now on that  . Using the row operations, we can perform what is essentially the Euclidean algorithm on the first column by subtracting the smaller column 1 element from the larger. Since  , we have  , which implies that   and so the row operation Euclidean algorithm terminates once it produces 1 on one of the rows of the 1st column.

Now, using the matrix produced in Claim 1, we can simply bring the matrix to the identity form only by applying row and column additions/subtractions. Hence, we have  , where   are some of the matrices   and their inverses.This can be solved to show that  .