Date | May 2011 | Marks available | 4 | Reference code | 11M.1.sl.TZ1.5 |
Level | SL only | Paper | 1 | Time zone | TZ1 |
Command term | Show that | Question number | 5 | Adapted from | N/A |
Question
Let \(g(x) = \frac{{\ln x}}{{{x^2}}}\) , for \(x > 0\) .
Use the quotient rule to show that \(g'(x) = \frac{{1 - 2\ln x}}{{{x^3}}}\) .
The graph of g has a maximum point at A. Find the x-coordinate of A.
Markscheme
\(\frac{{\rm{d}}}{{{\rm{d}}x}}\ln x = \frac{1}{x}\) , \(\frac{{\rm{d}}}{{{\rm{d}}x}}{x^2} = 2x\) (seen anywhere) A1A1
attempt to substitute into the quotient rule (do not accept product rule) M1
e.g. \(\frac{{{x^2}\left( {\frac{1}{x}} \right) - 2x\ln x}}{{{x^4}}}\)
correct manipulation that clearly leads to result A1
e.g. \(\frac{{x - 2x\ln x}}{{{x^4}}}\) , \(\frac{{x(1 - 2\ln x)}}{{{x^4}}}\) , \(\frac{x}{{{x^4}}}\) , \(\frac{{2x\ln x}}{{{x^4}}}\)
\(g'(x) = \frac{{1 - 2\ln x}}{{{x^3}}}\) AG N0
[4 marks]
evidence of setting the derivative equal to zero (M1)
e.g. \(g'(x) = 0\) , \(1 - 2\ln x = 0\)
\(\ln x = \frac{1}{2}\) A1
\(x = {{\rm{e}}^{\frac{1}{2}}}\) A1 N2
[3 marks]
Examiners report
Many candidates clearly knew their quotient rule, although a common error was to simplify \(2x\ln x\) as \(2\ln {x^2}\) and then "cancel" the exponents.
For (b), those who knew to set the derivative to zero typically went on find the correct x-coordinate, which must be in terms of e, as this is the calculator-free paper. Occasionally, students would take \(\frac{{1 - 2\ln x}}{{{x^3}}} = 0\) and attempt to solve from \(1 - 2\ln x = {x^3}\) .