Exercises MAT2200 spring 2013 Ark 3 Cosets, Direct products and Abelian groups

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Exercises MAT2200 spring 2013 Ark 3 Cosets, Direct products and Abelian groups This Ark concerns the weeks No. (Feb ) andno. (Feb Mar ). The plans for those two weeks are as follows: On Wednesday Feb I plan to do Section 11 Direct products and Finitely generated Abelian Groups. On Friday Feb we do exercises + buffer for Wednesday. On Wednesday Feb I plan to do Section 13 and 14 Homomorphisms and Factor groups. On Friday Mar we do exercises + buffer. In several of the exercises you must factorise numbers into products of primes. Using a list of small prime numbers might be helpful. You find one with all the primes less than 1000 on : http://en.wikipedia.org/wiki/prime_number We had a small discussion on Friday about e.g and i.e. For those who were not there: e.g means for example. It is shorthand for latin exempli gratia. i.e. means that is. It is shorthand for latin id est. In american english they are followed by a comma, in british english they are not. Many of the exercises are taken from the book, but for your convenience I have copied them below with a reference to the book, sometimes I ve given them a little twist. The rest of the exercises I ve picked elsewhere. The exercises on this sheet cover Section 10 and Section 11 in the book, with a few more about permutation from Section 9. They are ment for the groups on Friday Feb and Mar and Thursday Feb and with the following distribution: Friday, Feb : No.:2,3,4,12,13,14,18,19 Friday, Mar :No.:20,24,25,28,32,33,34 Thursday, Feb : No.: 1, 5, 6, 7, 8, 9, 10, 11, 15, 16, 17 Thursday, Feb : No.: 21, 22, 23, 26, 27, 29, 30, 31 Key words: Permutations and orbits, Cosets, The theorem of Lagrange, Index of a subgroup, Direct products and Structure of finitely generated Abelian groups. More on orbits and permutations Problem 1. Let X be a finite set and let H S n be a subgroup. Just as for permutations, we define the orbit of x 2 X as B H (x) ={ (x) 2 H }.

Show that {B H (x)} x2x forms a partition of X. Problem 2. Let X be a set and let 2 S X apermutation.assumethatthepermutation 2 S X commutes with. i.e., (x) = (x) for all x 2 X. a) Show that i and commute for any integer i. b) Given a point x 2 X. Showthat maps the orbit B (x) of x bijectively into B ( (x)). c) Assume that is a cycle, and let B be its nontrivial orbit. Show that one may write = i where i is an suitable integer, and is a permutation that does not move any point in the nontrivial orbit B of ; i.e., is a composition of cycles disjoint from. Hint: Use subproblem b). Problem 3. Recall that the centraliser of a element g from a group G is the subgroup of all elements commuting with g, i.e., G = { a 2 G ag = ga }. Let be a cycle of length n in S n.showthatthecentraliserc Sn ( ) is given as C Sn ( )=h i. Hint: Use problem 2 c). Problem 4. a) Show that the number of n-cycles in S n is equal to (n 1)! b) Show that the number of k-cycles in S n is equal to n (k 1)!. k c) How many 2-cycles, 3-cycles and 4-cycles are there in S 4? d) How many cycles of each length between 2 and 5 are there in S 5? Cosets Problem 5. (Basically Section 10, No.: 1 on page 101 in the book). Find all cosets of the subgroup 4Z in Z. Problem 6. (Basically Section 10, No.: 4 on page 101 in the book). Find all cosets of the group 4Z 12 in Z 12. Problem 7. a) Let = e 2 i/18.describeallcosetsof 9 in µ 18. b) Let m 2 N and let = e i/m.describeallcosetsof m in µ 2m. Problem 8. Find the cosets of µ 3 in µ 6.Drawtheusualpictureofµ 6 and indicate the cosets. 2

Problem 9. (Basically Section 10, No.: 6 on page 101 in the book). Find all the cosets, both the left cosets and the right cosets, of the subgroup {e, s} of the group D 8 of symmetries of the square where s denotes the reflection through the x-axis. Single out a left coset which is not a right coset. Problem 10. Describe the cosets of the subgroup H = h r i of D 8 generated by the rotation r by an angle of /2 in positive direction. Is every left coset of H arightcoset? Problem 11. ( Section 10, No.: 23 on page 102 in the book). Give an example of a subgroup H of order 6 having 12 different cosets. Problem 12. ( Section 10, No.: 28 on page 103 in the book). Let G be a group and let H G be a subgroup. Assume that ghg 1 H for any element g 2 G. Showthat every left coset of H is a right coset. Problem 13. ( Section 10, No.: 29 on page 103 in the book). Let G be a group and H asubgroup.assumethateveryrightcosetofh is a left coset. Show that ghg 1 H for all g 2 G. This is the converse of exercise 12. Problem 14. Let H and K be two subgroups of the group G. Assumethateveryright coset of H is a left coset. Show that the product is a subgroup of G. The index of a subgroup HK = { hk h 2 H and k 2 K } Problem 15. Describe all subgroups of Z 14. Draw the subgroup diagram showing the inclusion relations between the different subgroups. Indicate the order and the index of each of the subgroups. Problem 16. Draw the subgroup diagram of the symmetric group S 3.Indicatethe indices of all the subgroups. Problem 17. (Basically Section 10, No.: 15,16 on page 102 in the book). Find the index of each of the cyclic subgroups generated by the -s below: =(1, 2, 5, 4)(2, 3) in S 5, =(1, 2, 4, 5)(3, 6) in S 6. What is the index of h 2 i in the two cases? Problem 18. Show that if H G is a subgroup of index two, then every left coset of H is a right coset. 3

The theorem of Lagrange Problem 19. (Basically Section 10, No.: 36 on page 103 in the book). Let G be a group of even order. a) Show that G contains an odd number of elements of order 2. Hint: The subsets {x, x 1 } form a partition of the group. b) Show that if the order of G equals 2n where n is an odd number and G is abelian, then G contains exactly one element of order two. Hint: Lagrange c) Find one example of a group whose order is of the form 2n with n odd and n>1, having n elements of order two. d) Find a group of order 64 with exactly one element of order two. Problem 20. Let G be a group having exactly one element H = h i be the subgroup generated by. a) Show that ghg 1 = H for all g 2 H. b) Show that all the left cosets of H are right cosets. of order two, and let c) Assume in addition that the order of G equals 2p where p is a prime. Show that G is abelian. Hint: Lagrange s theorem. Problem 21. Find all groups of order 101. Problem 22. Let G be a group of order 1111. ShowthatallpropersubgroupsofG are cyclic. Problem 23. Give an example of a group of order 2 n all whose elements are of order 2. Relate this to the theorem of Lagrange. Hint: Problem on Ark 1 can be useful. Problem 24. Show that every subgroup of S 5 of order 5 is cyclic and generated by a 5-cycle. Hint: Lagrange and factorisation in disjoint cycles. a) How many subgroups of order 5 are there in S 5? Hint: Determine first the number of 5-cycles. Direct products and Abelian groups Problem 25. ( Section 11, No.: 46 on page 111 in the book). Show that the direct product of two abelian groups is abelian. Problem 26. ( Section 11, No.: 1 on page 110 in the book). Find the orders of all elements in Z 2 Z 4.IsthegroupZ 2 Z 4 cyclic? Problem 27. ( Section 11, No.: 2 on page 110 in the book). Find the orders of all elements in Z 3 Z 4.IsthegroupZ 3 Z 4 cyclic? 4

Problem 28. ( Section 11, No.: 3,5 and 6 on page 110 in the book). Find the orders of the given elements (2, 6) in Z 4 Z 12, (8, 10) in Z 12 Z 18, (3, 10, 9) in Z 4 Z 12 Z 15. Problem 29. (Basically Section 11, No.: 11 on page 110 in the book). Find all subgroups of Z 2 Z 4.Whataretheirorders?Drawthesubgroupdiagram. Problem 30. ( Section 11, No.: 12 on page 110 in the book). Find all subgroups of Z 2 Z 2 Z 4 that are isomorphic to the Klein group. Problem 31. Which of the groups Z 2 Z 88 and Z 8 Z 22 are isomorphic to Z 2 Z 8 Z 11? Problem 32. Determine all abelian groups of order 2012 and of order 2013 up to isomorphism. Problem 33. ( Section 11, No.: 47 on page 113 in the book). Let A be an abelian group. Show that the set A 2 consisting of elements of order two is a subgroup. Show by an example that the hypothesis of A being abelian can not be omitted. Problem 34. ( Section 11, No.: 52 on page 113 in the book). Sow that a finite abelian group is cyclic if and only if it does not contain a subgroup isomorphic to Z p Z p for some prime p. Im Im Re Re µ 18 µ 6 Versjon: Monday, February 4, 2013 12:14:19 PM 5

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