Date | November 2009 | Marks available | 2 | Reference code | 09N.2.sl.TZ0.1 |
Level | SL only | Paper | 2 | Time zone | TZ0 |
Command term | Calculate | Question number | 1 | Adapted from | N/A |
Question
The diagram below shows a square based right pyramid. ABCD is a square of side 10 cm. VX is the perpendicular height of 8 cm. M is the midpoint of BC.
In a mountain region there appears to be a relationship between the number of trees growing in the region and the depth of snow in winter. A set of 10 areas was chosen, and in each area the number of trees was counted and the depth of snow measured. The results are given in the table below.
A path goes around a forest so that it forms the three sides of a triangle. The lengths of two sides are 550 m and 290 m. These two sides meet at an angle of 115°. A diagram is shown below.
Write down the length of XM.
Use your graphic display calculator to find the standard deviation of the number of trees.
Calculate the length of VM.
Calculate the angle between VM and ABCD.
Calculate the length of the third side of the triangle. Give your answer correct to the nearest 10 m.
Calculate the area enclosed by the path that goes around the forest.
Inside the forest a second path forms the three sides of another triangle named ABC. Angle BAC is 53°, AC is 180 m and BC is 230 m.
Calculate the size of angle ACB.
Markscheme
UP applies in this question
(UP) XM = 5 cm (A1)
[1 mark]
16.8 (G1)
UP applies in this question
VM2 = 52 + 82 (M1)
Note: Award (M1) for correct use of Pythagoras Theorem.
(UP) VM = \(\sqrt{89}\) = 9.43 cm (A1)(ft)(G2)
[2 marks]
\(\tan {\text{VMX}} = \frac{8}{5}\) (M1)
Note: Other trigonometric ratios may be used.
\({\rm{V\hat MX}} = 58.0^\circ \) (A1)(ft)(G2)
[2 marks]
UP applies in this question
l2 = 2902 + 5502 − 2 × 290 × 550 × cos115° (M1)(A1)
Note: Award (M1) for substituted cosine rule formula, (A1) for correct substitution.
l = 722 (A1)(G2)
(UP) = 720 m (A1)
Note: If 720 m seen without working award (G3).
The final (A1) is awarded for the correct rounding of their answer.
[4 marks]
UP applies in this question
\({\text{Area}} = \frac{1}{2} \times 290 \times 550 \times \sin 115\) (M1)(A1)
Note: Award (M1) for substituted correct formula (A1) for correct substitution.
(UP) = \(72\,300{\text{ }}{{\text{m}}^2}\) (A1)(G2)
[3 marks]
\(\frac{{180}}{{\sin {\text{B}}}} = \frac{{230}}{{\sin 53}}\) (M1)(A1)
Note: Award (M1) for substituted sine rule formula, (A1) for correct substitution.
B = 38.7° (A1)(G2)
\({\operatorname{A\hat CB}} = 180 - (53^\circ + 38.7^\circ )\)
\( = 88.3^\circ \) (A1)(ft)
[4 marks]
Examiners report
This part proved accessible to the great majority of candidates. The common errors were (1) the inversion of the tangent ratio (2) the omission of the units and (3) the incorrect rounding of the answer; with 58° being all too commonly seen.
A straightforward question that saw many fine attempts. Given its nature – where much of the work was done on the GDC – it must be emphasised to candidates that incorrect entry of data into the calculator will result in considerable penalties; they must check their data entry most carefully.
The use of the inappropriate standard deviation was seen, but infrequently.
This part proved accessible to the great majority of candidates. The common errors were (1) the inversion of the tangent ratio (2) the omission of the units and (3) the incorrect rounding of the answer; with 58° being all too commonly seen.
This part proved accessible to the great majority of candidates. The common errors were (1) the inversion of the tangent ratio (2) the omission of the units and (3) the incorrect rounding of the answer; with 58° being all too commonly seen.
Again, this part proved accessible to the majority with a large number of candidates attaining full marks. However, there were also a number of candidates who seemed not to have been prepared in the use of trigonometry in non right-angled triangles. Also, failing to round the answer in (a) to the nearest 10m was a common omission.
Again, this part proved accessible to the majority with a large number of candidates attaining full marks. However, there were also a number of candidates who seemed not to have been prepared in the use of trigonometry in non right-angled triangles. Also, failing to round the answer in (a) to the nearest 10 m was a common omission.
Again, this part proved accessible to the majority with a large number of candidates attaining full marks. However, there were also a number of candidates who seemed not to have been prepared in the use of trigonometry in non right-angled triangles. Also, failing to round the answer in (a) to the nearest 10 m was a common omission.