Date | May 2011 | Marks available | 4 | Reference code | 11M.3srg.hl.TZ0.1 |
Level | HL only | Paper | Paper 3 Sets, relations and groups | Time zone | TZ0 |
Command term | Copy and complete | Question number | 1 | Adapted from | N/A |
Question
The binary operator multiplication modulo 14, denoted by \( * \), is defined on the set S = {2, 4, 6, 8, 10, 12}.
Copy and complete the following operation table.
(i) Show that {S , \( * \)} is a group.
(ii) Find the order of each element of {S , \( * \)}.
(iii) Hence show that {S , \( * \)} is cyclic and find all the generators.
The set T is defined by \(\{ x * x:x \in S\} \). Show that {T , \( * \)} is a subgroup of {S , \( * \)}.
Markscheme
A4
Note: Award A4 for all correct, A3 for one error, A2 for two errors, A1 for three errors and A0 for four or more errors.
[4 marks]
(i) closure: there are no new elements in the table A1
identity: 8 is the identity element A1
inverse: every element has an inverse because there is an 8 in every row and column A1
associativity: (modulo) multiplication is associative A1
therefore {S , \( * \)} is a group AG
(ii) the orders of the elements are as follows
A4
Note: Award A4 for all correct, A3 for one error, A2 for two errors, A1 for three errors and A0 for four or more errors.
(iii) EITHER
the group is cyclic because there are elements of order 6 R1
OR
the group is cyclic because there are generators R1
THEN
10 and 12 are the generators A1A1
[11 marks]
looking at the Cayley table, we see that
T = {2, 4, 8} A1
this is a subgroup because it contains the identity element 8, no new elements are formed and 2 and 4 form an inverse pair R2
Note: Award R1 for any two conditions
[3 marks]
Examiners report
Parts (a) and (b) were well done in general. Some candidates, however, when considering closure and associativity simply wrote ‘closed’ and ‘associativity’ without justification. Here, candidates were expected to make reference to their Cayley table to justify closure and to state that multiplication is associative to justify associativity. In (c), some candidates tried to show the required result without actually identifying the elements of T. This approach was invariably unsuccessful.
Parts (a) and (b) were well done in general. Some candidates, however, when considering closure and associativity simply wrote ‘closed’ and ‘associativity’ without justification. Here, candidates were expected to make reference to their Cayley table to justify closure and to state that multiplication is associative to justify associativity. In (c), some candidates tried to show the required result without actually identifying the elements of T. This approach was invariably unsuccessful.
Parts (a) and (b) were well done in general. Some candidates, however, when considering closure and associativity simply wrote ‘closed’ and ‘associativity’ without justification. Here, candidates were expected to make reference to their Cayley table to justify closure and to state that multiplication is associative to justify associativity. In (c), some candidates tried to show the required result without actually identifying the elements of T. This approach was invariably unsuccessful.