Date | November 2011 | Marks available | 2 | Reference code | 11N.3dm.hl.TZ0.5 |
Level | HL only | Paper | Paper 3 Discrete mathematics | Time zone | TZ0 |
Command term | Show that and State | Question number | 5 | Adapted from | N/A |
Question
A version of Fermat’s little theorem states that when p is prime, a is a positive integer and a and p are relatively prime, then \({a^{p - 1}} \equiv 1(\bmod p)\).
Use the above result to show that if p is prime then \({a^p} \equiv a(\bmod p)\) where a is any positive integer.
Show that \({2^{341}} \equiv 2(\bmod 341)\).
(i) State the converse of the result in part (a).
(ii) Show that this converse is not true.
Markscheme
consider two cases M1
let a and p be coprime
\({a^{p - 1}} \equiv 1(\bmod p)\) R1
\( \Rightarrow {a^p} \equiv a(\bmod p)\)
let a and p not be coprime
\(a \equiv 0(\bmod p)\) M1
\({a^p} = 0(\bmod p)\) R1
\( \Rightarrow {a^p} = a(\bmod p)\)
so \({a^p} = a(\bmod p)\) in both cases AG
[4 marks]
\(341 = 11 \times 31\) (M1)
we know by Fermat’s little theorem
\({2^{10}} \equiv 1(\bmod 11)\) M1
\( \Rightarrow {2^{341}} \equiv {({2^{10}})^{34}} \times 2 \equiv {1^{34}} \times 2 \equiv 2(\bmod 11)\) A1
also \({2^{30}} \equiv 1(\bmod 31)\) M1
\( \Rightarrow {2^{341}} \equiv {({2^{30}})^{11}} \times {2^{11}}\) A1
\( \equiv {1^{11}} \times 2048 \equiv 2(\bmod 31)\) A1
since 31 and 11 are coprime R1
\({2^{341}} \equiv 2(\bmod 341)\) AG
[7 marks]
(i) converse: if \({a^p} = a(\bmod p)\) then p is a prime A1
(ii) from part (b) we know \({2^{341}} \equiv 2(\bmod 341)\)
however, 341 is composite
hence 341 is a counter-example and the converse is not true R1
[2 marks]
Examiners report
There were very few fully correct answers. In (b) the majority of candidates assumed that 341 is a prime number and in (c) only a handful of candidates were able to state the converse.
There were very few fully correct answers. In (b) the majority of candidates assumed that 341 is a prime number and in (c) only a handful of candidates were able to state the converse.
There were very few fully correct answers. In (b) the majority of candidates assumed that 341 is a prime number and in (c) only a handful of candidates were able to state the converse.