Date | May 2022 | Marks available | 2 | Reference code | 22M.3.AHL.TZ1.2 |
Level | Additional Higher Level | Paper | Paper 3 | Time zone | Time zone 1 |
Command term | Sketch | Question number | 2 | Adapted from | N/A |
Question
This question asks you to explore cubic polynomials of the form for and corresponding cubic equations with one real root and two complex roots of the form for .
In parts (a), (b) and (c), let and .
Consider the equation for .
Consider the function for .
Consider the function for where and .
The equation for has roots and where and .
On the Cartesian plane, the points and represent the real and imaginary parts of the complex roots of the equation .
The following diagram shows a particular curve of the form and the tangent to the curve at the point . The curve and the tangent both intersect the -axis at the point . The points and are also shown.
Consider the curve for . The points and are as defined in part (d)(ii). The curve has a point of inflexion at point .
Consider the special case where and .
Given that and are roots of the equation, write down the third root.
Verify that the mean of the two complex roots is .
Show that the line is tangent to the curve at the point .
Sketch the curve and the tangent to the curve at point , clearly showing where the tangent crosses the -axis.
Show that .
Hence, or otherwise, prove that the tangent to the curve at the point intersects the -axis at the point .
Deduce from part (d)(i) that the complex roots of the equation can be expressed as .
Use this diagram to determine the roots of the corresponding equation of the form for .
State the coordinates of .
Show that the -coordinate of is .
You are not required to demonstrate a change in concavity.
Hence describe numerically the horizontal position of point relative to the horizontal positions of the points and .
Sketch the curve for and .
For and , state in terms of , the coordinates of points and .
Markscheme
A1
[1 mark]
mean A1
AG
[1 mark]
METHOD 1
attempts product rule differentiation (M1)
Note: Award (M1) for attempting to express as
A1
A1
Note: Where is correct, award A1 for solving and obtaining .
EITHER
A1
OR
A1
OR
states the gradient of is also and verifies that lies on the line A1
THEN
so is the tangent to the curve at AG
Note: Award a maximum of (M0)A0A1A1 to a candidate who does not attempt to find .
METHOD 2
sets to form (M1)
EITHER
A1
attempts to solve a correct cubic equation (M1)
OR
recognises that and forms A1
attempts to solve a correct quadratic equation (M1)
THEN
is a double root R1
so is the tangent to the curve at AG
Note: Candidates using this method are not required to verify that .
[4 marks]
a positive cubic with an -intercept , and a local maximum and local minimum in the first quadrant both positioned to the left of A1
Note: As the local minimum and point A are very close to each other, condone graphs that seem to show these points coinciding.
For the point of tangency, accept labels such as or the point labelled from both axes. Coordinates are not required.
a correct sketch of the tangent passing through and crossing the -axis at the same point as the curve A1
Note: Award A1A0 if both graphs cross the -axis at distinctly different points.
[2 marks]
EITHER
(M1)A1
OR
attempts to find M1
A1
THEN
AG
[2 marks]
METHOD 1
(A1)
(A1)
attempts to substitute their and into M1
EITHER
A1
sets so M1
OR R1
OR
sets so M1
OR R1
A1
THEN
so the tangent intersects the -axis at the point AG
METHOD 2
(A1)
(A1)
attempts to substitute their and into and attempts to find M1
EITHER
A1
sets so M1
OR R1
OR
sets so M1
OR R1
A1
METHOD 3
(A1)
the line through parallel to the tangent at has equation
A1
sets to form M1
A1
A1
since there is a double root , this parallel line through is the required tangent at R1
[6 marks]
EITHER
(since ) R1
Note: Accept .
OR
and R1
THEN
hence the complex roots can be expressed as AG
[1 mark]
(seen anywhere) A1
EITHER
attempts to find the gradient of the tangent in terms of and equates to (M1)
OR
substitutes and to form (M1)
OR
substitutes and into (M1)
THEN
roots are (seen anywhere) and A1A1
Note: Award A1 for and A1 for . Do not accept coordinates.
[4 marks]
A1
Note: Accept “ and ”.
Do not award A1FT for .
[1 mark]
attempts to find M1
sets and correctly solves for A1
for example, obtaining leading to
so AG
Note: Do not award A1 if the answer does not lead to the AG.
[2 marks]
point is of the horizontal distance (way) from point to point A1
Note: Accept equivalent numerical statements or a clearly labelled diagram displaying the numerical relationship.
Award A0 for non-numerical statements such as “ is between and , closer to ”.
[1 mark]
(A1)
a positive cubic with no stationary points and a non-stationary point of inflexion at A1
Note: Graphs may appear approximately linear. Award this A1 if a change of concavity either side of is apparent.
Coordinates are not required and the -intercept need not be indicated.
[2 marks]
A1
[1 mark]
Examiners report
Part (a) (i) was generally well done with a significant majority of candidates using the conjugate root theorem to state as the third root. A number of candidates, however, wasted considerable time attempting an algebraic method to determine the third root. Part (a) (ii) was reasonably well done. A few candidates however attempted to calculate the product of and .
Part (b) was reasonably well done by a significant number of candidates. Most were able to find a correct expression for and a good number of those candidates were able to determine that . Candidates that did not determine the equation of the tangent had to state that the gradient of is also 1 and verify that the point (4,3) lies on the line. A few candidates only met one of those requirements. Weaker candidates tended to only verify that the point (4,3) lies on the curve and the tangent line without attempting to find .
Part (c) was not answered as well as anticipated. A number of sketches were inaccurate and carelessly drawn with many showing both graphs crossing the x-axis at distinctly different points.
Part (d) (i) was reasonably well done by a good number of candidates. Most successful responses involved use of the product rule. A few candidates obtained full marks by firstly expanding , then differentiating to find and finally simplifying to obtain the desired result. A number of candidates made elementary mistakes when differentiating. In general, the better candidates offered reasonable attempts at showing the general result in part (d) (ii). A good number gained partial credit by determining that and/or . Only the very best candidates obtained full marks by concluding that as or , then when .
In general, only the best candidates were able to use the result to deduce that the complex roots of the equation can be expressed as . Although given the complex roots , a significant number of candidates attempted, with mixed success, to use the quadratic formula to solve the equation .
In part (f) (i), only a small number of candidates were able to determine all the roots of the equation. Disappointingly, a large number did not state as a root. Some candidates determined that but were unable to use the diagram to determine that . Of the candidates who determined all the roots in part (f) (i), very few gave the correct coordinates for C2 . The most frequent error was to give the y-coordinate as .
Of the candidates who attempted part (g) (i), most were able to find an expression for and a reasonable number of these were then able to convincingly show that . It was very rare to see a correct response to part (g) (ii). A few candidates stated that P is between R and A with some stating that P was closer to A. A small number restated in words.
Of the candidates who attempted part (h) (i), most were able to determine that . However, most graphs were poorly drawn with many showing a change in concavity at rather than at . In part (h) (ii), only a very small number of candidates determined that A and P coincide at (r,0).