Date | May 2015 | Marks available | 6 | Reference code | 15M.3dm.hl.TZ0.5 |
Level | HL only | Paper | Paper 3 Discrete mathematics | Time zone | TZ0 |
Command term | Prove | Question number | 5 | Adapted from | N/A |
Question
State the Fundamental theorem of arithmetic for positive whole numbers greater than \(1\).
Use the Fundamental theorem of arithmetic, applied to \(5577\) and \(99\,099\), to calculate \(\gcd (5577,{\text{ }}99\,099)\) and \({\text{lcm}}(5577,{\text{ }}99\,099)\), expressing each of your answers as a product of prime numbers.
Prove that \(\gcd (n,{\text{ }}m) \times {\text{lcm}}(n,{\text{ }}m) = n \times m\) for all \(n,{\text{ }}m \in {\mathbb{Z}^ + }\).
Markscheme
every positive integer, greater than \(1\), is either prime or can be expressed uniquely as a product of primes A1A1
Note: Award A1 for “product of primes” and A1 for “uniquely”.
[2 marks]
\(5577 = 3 \times 11 \times {13^2}{\text{ and }}99099 = {3^2} \times 7 \times {11^2} \times 13\) M1
\(\gcd (5577,{\text{ }}99099) = 3 \times 11 \times 13,{\text{ lcm}}(5577,{\text{ }}99099) = {3^2} \times 7 \times {11^2} \times {13^2}\) A1A1
[3 marks]
METHOD 1
\(n = p_1^{{k_1}}p_2^{{k_2}} \ldots p_r^{{k_r}}\) and \(m = p_1^{{j_1}}p_2^{{j_2}} \ldots p_r^{{j_r}}\) M1
employing all the prime factors of \(n\) and \(m\), and inserting zero exponents if necessary R1
define \({g_i} = \min ({k_i},{\text{ }}{j_i})\) and \({h_i} = \max ({k_i},{\text{ }}{j_i})\) for \(i = 1 \ldots r\) (M1)
\(\gcd (n,{\text{ }}m) = p_1^{{g_1}}p_2^{{g_2}} \ldots p_r^{{g_r}}\) and \({\text{lcm}}(n,{\text{ }}m) = p_1^{{h_1}}p_2^{{h_2}} \ldots p_r^{{h_r}}\) A1A1
noting that \({g_i} + {h_i} = {k_i} + {j_i}\) for \(i = 1 \ldots r\) R1
\(\gcd (n,{\text{ }}m) \times {\text{lcm}}(n,{\text{ }}m) = n \times m\) for all \(n,{\text{ }}m \in {\mathbb{Z}^ + }\)AG
METHOD 2
let \(m\) and \(n\) be expressed as a product of primes where \(m = ab\) and \(n = ac\) M1
\(a\) denotes the factors that are common and \(b,{\text{ }}c\) are the disjoint factors that are not common R1
\(\gcd (n,{\text{ }}m) = a\) A1
\({\text{lcm}}(n,{\text{ }}m) = \gcd (n,{\text{ }}m)bc\) A1
\(\gcd (n,{\text{ }}m) \times {\text{lcm}}(n,{\text{ }}m) = a \times (abc)\) M1
\( = ab \times ac\) and \(m = ab\) and \(n = ac\) so R1
\(\gcd (n,{\text{ }}m) \times 1{\text{ cm}}(n,{\text{ }}m) = n \times m\) for all \(n,{\text{ }}m \in {\mathbb{Z}^ + }\) AG
[6 marks]
Total [11 marks]
Examiners report
In part (a), most candidates omitted the 'uniquely' in their definition of the fundamental theorem of arithmetic. A few candidates defined what a prime number is.
In part (b), a substantial number of candidates used the Euclidean algorithm rather than the fundamental theorem of arithmetic to calculate \(\gcd (5577,{\text{ }}99099)\) and \({\text{lcm}}(5577,{\text{ }}99099)\).
In part (c), a standard proof that has appeared in previous examination papers, was answered successfully by candidates who were well prepared.