Question
The number of bacteria, n , in a dish, after t minutes is given by \(n = 800{{\rm{e}}^{0.13t}}\) .
Find the value of n when \(t = 0\) .
Find the rate at which n is increasing when \(t = 15\) .
Answer/Explanation
Markscheme
\(n = 800{{\rm{e}}^0}\) (A1)
\(n = 800\) A1 N2
[2 marks]
evidence of using the derivative (M1)
\(n'(15) = 731\) A1 N2
[2 marks]
METHOD 1
setting up inequality (accept equation or reverse inequality) A1
e.g. \(n'(t) > 10000\)
evidence of appropriate approach M1
e.g. sketch, finding derivative
\(k = 35.1226 \ldots \) (A1)
least value of k is 36 A1 N2
METHOD 2
\(n'(35) = 9842\) , and \(n'(36) = 11208\) A2
least value of k is 36 A2 N2
[4 marks]
Question
The first two terms of a geometric sequence \({u_n}\) are \({u_1} = 4\) and \({u_2} = 4.2\).
(i) Find the common ratio.
(ii) Hence or otherwise, find \({u_5}\).
Another sequence \({v_n}\) is defined by \({v_n} = a{n^k}\), where \(a,{\text{ }}k \in \mathbb{R}\), and \(n \in {\mathbb{Z}^ + }\), such that \({v_1} = 0.05\) and \({v_2} = 0.25\).
(i) Find the value of \(a\).
(ii) Find the value of \(k\).
Find the smallest value of \(n\) for which \({v_n} > {u_n}\).
Answer/Explanation
Markscheme
(i) valid approach (M1)
eg\(\;\;\;\)\(r = \frac{{{u_2}}}{{{u_1}}},{\text{ }}\frac{4}{{4.2}}\)
\(r = 1.05\;\;\;{\text{(exact)}}\) A1 N2
(ii) attempt to substitute into formula, with their \(r\) (M1)
eg\(\;\;\;\)\(4 \times {1.05^n},{\text{ }}4 \times 1.05 \times 1.05 \ldots \)
correct substitution (A1)
eg\(\;\;\;\)\(4 \times {1.05^4},{\text{ }}4 \times 1.05 \times 1.05 \times 1.05 \times 1.05\)
\({u_5} = 4.862025{\text{ (exact), }}4.86{\text{ }}[4.86,{\text{ }}4.87]{\text{ }}\) A1 N2
[5 marks]
(i) attempt to substitute \(n = 1\) (M1)
eg\(\;\;\;\)\(0.05 = a \times {1^k}\)
\(a = 0.05\) A1 N2
(ii) correct substitution of \(n = 2\) into \({v_2}\) A1
eg\(\;\;\;\)\(0.25 = a \times {2^k}\)
correct work (A1)
eg\(\;\;\;\)finding intersection point, \(k = {\log _2}\left( {\frac{{0.25}}{{0.05}}} \right),{\text{ }}\frac{{\log 5}}{{\log 2}}\)
\(2.32192\)
\(k = {\log _2}5\;\;\;{\text{(exact), }}2.32{\text{ }}[2.32,{\text{ }}2.33]\) A1 N2
[5 marks]
correct expression for \({u_n}\) (A1)
eg\(\;\;\;\)\(4 \times {1.05^{n – 1}}\)
EITHER
correct substitution into inequality (accept equation) (A1)
eg\(\;\;\;\)\(0.05 \times {n^k} > 4 \times {1.05^{n – 1}}\)
valid approach to solve inequality (accept equation) (M1)
eg\(\;\;\;\)finding point of intersection, \(n = 7.57994{\text{ }}(7.59508{\text{ from 2.32)}}\)
\(n = 8\;\;\;\)(must be an integer) A1 N2
OR
table of values
when \(n = 7,{\text{ }}{u_7} = 5.3604,{\text{ }}{v_7} = 4.5836\) A1
when \(n = 8,{\text{ }}{u_8} = 5.6284,{\text{ }}{v_8} = 6.2496\) A1
\(n = 8\;\;\;\)(must be an integer) A1 N2
[4 marks]
Total [14 marks]
Question
The price of a used car depends partly on the distance it has travelled. The following table shows the distance and the price for seven cars on 1 January 2010.
The relationship between \(x\) and \(y\) can be modelled by the regression equation \(y = ax + b\).
On 1 January 2010, Lina buys a car which has travelled \(11\,000{\text{ km}}\).
The price of a car decreases by 5% each year.
Lina will sell her car when its price reaches \(10\,000\) dollars.
(i) Find the correlation coefficient.
(ii) Write down the value of \(a\) and of \(b\).
Use the regression equation to estimate the price of Lina’s car, giving your answer to the nearest 100 dollars.
Calculate the price of Lina’s car after 6 years.
Find the year when Lina sells her car.
Answer/Explanation
Markscheme
Note: There may be slight differences in answers, depending on which values candidates carry through in subsequent parts. Accept answers that are consistent with their working.
(i) valid approach (M1)
eg\(\,\,\,\,\,\)correct value for \(r\) (or for \(a\) or \(b\) seen in (ii))
\( – 0.994347\)
\(r = – 0.994\) A1 N2
(ii) \( – 1.58095,{\text{ }}33480.3\)
\(a = – 1.58,{\text{ }}b = 33500\) A1A1 N2
[4 marks]
Note: There may be slight differences in answers, depending on which values candidates carry through in subsequent parts. Accept answers that are consistent with their working.
correct substitution into their regression equation
eg\(\,\,\,\,\,\)\( – 1.58095(11000){\text{ }} + 33480.3\) (A1)
\(16\,089.85{\text{ }}(16\,120{\text{ from 3sf}})\) (A1)
\({\text{price}} = 16\,100{\text{ }}({\text{dollars}})\) (must be rounded to the nearest 100 dollars) A1 N3
[3 marks]
Note: There may be slight differences in answers, depending on which values candidates carry through in subsequent parts. Accept answers that are consistent with their working.
METHOD 1
valid approach (M1)
eg\(\,\,\,\,\,\)\(P \times {({\text{rate}})^t}\)
\({\text{rate}} = 0.95\) (may be seen in their expression) (A1)
correct expression (A1)
eg\(\,\,\,\,\,\)\(16100 \times {0.95^6}\)
\(11\,834.97\)
\(11\,800{\text{ }}({\text{dollars}})\) A1 N2
METHOD 2
attempt to find all six terms (M1)
eg\(\,\,\,\,\,\)\(\left( {\left( {(16\,100 \times 0.95) \times 0.95} \right) \ldots } \right) \times 0.95\), table of values
5 correct values (accept values that round correctly to the nearest dollar)
\(15\,295,{\text{ }}14\,530,{\text{ }}13\,804,{\text{ }}13\,114,{\text{ }}12\,458\) A2
\(11\,835\)
\(11\,800{\text{ }}({\text{dollars}})\) A1 N2
[4 marks]
Note: There may be slight differences in answers, depending on which values candidates carry through in subsequent parts. Accept answers that are consistent with their working.
METHOD 1
correct equation (A1)
eg\(\,\,\,\,\,\)\(16\,100 \times {0.95^x}{\text{ = }}10\,000\)
valid attempt to solve (M1)
eg\(\,\,\,\,\,\), using logs
9.28453 (A1)
year 2019 A1 N2
METHOD 2
valid approach using table of values (M1)
both crossover values (accept values that round correctly to the nearest dollar) A2
eg\(\,\,\,\,\,\)\({\text{P}} = 10\,147{\text{ }}({\text{1 Jan 2019}}),{\text{ P}} = 9\,639.7{\text{ }}({\text{1 Jan 2020}})\)
year 2019 A1 N2
[4 marks]