Date | May 2014 | Marks available | 4 | Reference code | 14M.3dm.hl.TZ0.2 |
Level | HL only | Paper | Paper 3 Discrete mathematics | Time zone | TZ0 |
Command term | Prove that | Question number | 2 | Adapted from | N/A |
Question
Consider the integers \(a = 871\) and \(b= 1157\), given in base \(10\).
(i) Express \(a\) and \(b\) in base \(13\).
(ii) Hence show that \({\text{gcd}}(a,{\text{ }}b) = 13\).
A list \(L\) contains \(n+ 1\) distinct positive integers. Prove that at least two members of \(L\)leave the same remainder on division by \(n\).
Consider the simultaneous equations
\(4x + y + 5z = a\)
\(2x + z = b\)
\(3x + 2y + 4z = c\)
where \(x,{\text{ }}y,{\text{ }}z \in \mathbb{Z}\).
(i) Show that 7 divides \(2a + b - c\).
(ii) Given that a = 3, b = 0 and c = −1, find the solution to the system of equations modulo 2.
Consider the set \(P\) of numbers of the form \({n^2} - n + 41,{\text{ }}n \in \mathbb{N}\).
(i) Prove that all elements of P are odd.
(ii) List the first six elements of P for n = 0, 1, 2, 3, 4, 5.
(iii) Show that not all elements of P are prime.
Markscheme
(i) METHOD 1
using a relevant list of powers of 13: (1), 13, 169, (2197) M1
\(871 = 5 \times {13^2} + 2 \times 13\) A1
\(871 = {520_{13}}\) A1
\(1157 = 6 \times {13^2} + 11 \times 13\) A1
\(1157 = 6{\text{B}}{{\text{0}}_{13}}\) A1
METHOD 2
attempted repeated division by 13 M1
\(871 \div 13 = 67;{\text{ }}67 \div 13 = 5{\text{rem}}2\) A1
\(871 = {520_{13}}\) A1
\(1157 \div 13 = 89;{\text{ }}89 \div 13 = 6{\text{rem11}}\) A1
\(1157 = 6{\text{B}}{{\text{0}}_{13}}\) A1
Note: Allow (11) for B only if brackets or equivalent are present.
(ii) \(871 = 13 \times 67;{\text{ }}1157 = 13 \times 89\) (M1)
67 and 89 are primes (base 10) or they are co-prime A1
So \(\gcd (871,{\text{ }}1157) = 13\) AG
Note: Must be done by hence not Euclid’s algorithm on 871 and 1157.
[7 marks]
let K be the set of possible remainders on division by n (M1)
then \(K = \{ {\text{0, 1, 2, }} \ldots n - 1\} \) has n members A1
because \(n < n + 1{\text{ }}\left( { = n(L)} \right)\) A1
by the pigeon-hole principle (appearing anywhere and not necessarily mentioned by name as long as is explained) R1
at least two members of L correspond to one member of K AG
[4 marks]
(i) form the appropriate linear combination of the equations: (M1)
\(2a + b - c = 7x + 7z\) A1
\( = 7(x + z)\) R1
so 7 divides \(2a + b - c\) AG
(ii) modulo 2, the equations become M1
\(y + z = 1\)
\(z = 0\) A1
\(x = 1\)
solution: (1, 1, 0) A1
Note: Award full mark to use of GDC (or done manually) to solve the system giving \(x = - 1,{\text{ }}y = - 3,{\text{ }}z = 2\) and then converting mod 2.
[6 marks]
(i) separate consideration of even and odd n M1
\({\text{eve}}{{\text{n}}^2} - {\text{even}} + {\text{odd is odd}}\) A1
\({\text{od}}{{\text{d}}^2} - {\text{odd}} + {\text{odd is odd}}\) A1
all elements of P are odd AG
Note: Allow other methods eg, \({n^2} - n = n(n - 1)\) which must be even.
(ii) the list is [41, 41, 43, 47, 53, 61] A1
(iii) \({41^2} - 41 + 41 = {41^2}\) divisible by 41 A1
but is not a prime R1
the statement is disproved (by counterexample) AG
[6 marks]