Mark Scheme (Results)

January 2012

GCE Core Mathematics C4 (6666) Paper 1

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January 2012 Publications Code UA030313 All the material in this publication is copyright © Pearson Education Ltd 2012

General Marking Guidance

•

All candidates must receive the same treatment. Examiners must mark the first candidate in exactly the same way as they mark the last.

•

Mark schemes should be applied positively. Candidates must be rewarded for what they have shown they can do rather than penalised for omissions.

•

Examiners should mark according to the mark scheme not according to their perception of where the grade boundaries may lie.

•

There is no ceiling on achievement. All marks on the mark scheme should be used appropriately.

•

All the marks on the mark scheme are designed to be awarded. Examiners should always award full marks if deserved, i.e. if the answer matches the mark scheme. Examiners should also be prepared to award zero marks if the candidate’s response is not worthy of credit according to the mark scheme.

•

Where some judgement is required, mark schemes will provide the principles by which marks will be awarded and exemplification may be limited.

•

When examiners are in doubt regarding the application of the mark scheme to a candidate’s response, the team leader must be consulted.

•

Crossed out work should be marked UNLESS the candidate has replaced it with an alternative response.

EDEXCEL GCE MATHEMATICS General Instructions for Marking

1. The total number of marks for the paper is 75. 2. The Edexcel Mathematics mark schemes use the following types of marks: • • • •

M marks: method marks are awarded for ‘knowing a method and attempting to apply it’, unless otherwise indicated. A marks: Accuracy marks can only be awarded if the relevant method (M) marks have been earned. B marks are unconditional accuracy marks (independent of M marks) Marks should not be subdivided.

3. Abbreviations These are some of the traditional marking abbreviations that will appear in the mark schemes and can be used if you are using the annotation facility on ePEN. • • • • • • • • • • • • • • •

bod – benefit of doubt ft – follow through the symbol will be used for correct ft cao – correct answer only cso - correct solution only. There must be no errors in this part of the question to obtain this mark isw – ignore subsequent working awrt – answers which round to SC: special case oe – or equivalent (and appropriate) dep – dependent indep – independent dp decimal places sf significant figures
The answer is printed on the paper The second mark is dependent on gaining the first mark

4. All A marks are ‘correct answer only’ (cao.), unless shown, for example, as A1 ft to indicate that previous wrong working is to be followed through. After a misread however, the subsequent A marks affected are treated as A ft, but manifestly absurd answers should never be awarded A marks.

General Principals for Core Mathematics Marking (But note that specific mark schemes may sometimes override these general principles). Method mark for solving 3 term quadratic: 1. Factorisation

( x 2 + bx + c) = ( x + p )( x + q ), where pq = c

, leading to x = ....

( ax + bx + c) = ( mx + p )( nx + q ), where pq = c and mn = a 2

, leading to x = …

2. Formula Attempt to use correct formula (with values for a, b and c), leading to x = …

3. Completing the square Solving

x

2

+ bx

+ c = 0

:

( x ± b2 )

2

± q ± c, q ≠ 0 ,

leading to x = …

Method marks for differentiation and integration: 1. Differentiation Power of at least one term decreased by 1. ( x → n

2. Integration Power of at least one term increased by 1. ( x

n

→

x

x

n −1

n +1

)

)

Use of a formula Where a method involves using a formula that has been learnt, the advice given in recent examiners’ reports is that the formula should be quoted first. Normal marking procedure is as follows: Method mark for quoting a correct formula and attempting to use it, even if there are mistakes in the substitution of values. Where the formula is not quoted, the method mark can be gained by implication from correct working with values, but may be lost if there is any mistake in the working.

January 2012 6666 Core Mathematics C4 Mark Scheme Question Number

Scheme

Marks

 dy  dy  dy  =  2 + 6y +  6 x y + 3x 2  = 8 x  dx  dx   dx 

1. (a)

 dy 8 x − 2 − 6 xy  =   6 y + 3x 2   dx dy 8(−1) − 2 − 6(−1)(1) 4 At P ( −1, 1) , m ( T ) = = = − 2 dx 6(1) + 3(−1) 9

M1 A1 B1

not necessarily required. dM1 A1 cso [5]

(b)

−1  9  So, m(N) = 4  =  − 9  4 9 N: y − 1 = ( x + 1) 4 N: 9 x − 4 y + 13 = 0

M1

M1 A1 [3] 8

(a)

M1: Differentiates implicitly to include either ± ky A1:

( 2 x + 3 y ) →  2 + 6 y ddyx  and ( 4 x 2

 d y B1: 6 x y + 3 x 2 . dx



2

dy dy  dy  or 3x 2 . (Ignore  =  ). dx dx  dx 

→ 8 x ) . Note: If an extra “sixth” term appears then award A0.

dM1: Substituting x = − 1 and y = 1 into an equation involving

dy . Allow this mark if either the numerator dx

dy 8 x − 2 − 6 xy is substituted into or evaluated correctly. = dx 6 y + 3x 2 If it is clear, however, that the candidate is intending to substitute x = 1 and y = − 1, then award M0. or denominator of

(b)

Candidates who substitute x = 1 and y = − 1, will usually achieve m ( T ) = − 4 Note that this mark is dependent on the previous method mark being awarded. • 4 8 A1: For − or − or − 0.4 or awrt − 0.44 18 9 If the candidate’s solution is not completely correct, then do not give this mark. 1 M1: Applies m(N) = − . their m(T) M1: Uses y − 1 = ( mN )( x − − 1) or finds c using x = − 1 and y = 1 and uses y = ( m N ) x + " c " ,

1 1 or mN = or mN = − their m(T) . their m(T) their m(T) A1: 9 x − 4 y + 13 = 0 or − 9 x + 4 y − 13 = 0 or 4 y − 9 x − 13 = 0 or 18 x − 8 y + 26 = 0 etc. Must be “ = 0”. So do not allow 9 x + 13 = 4 y etc. Where mN = −

 6 y + 3x 2  Note: mN = −   is M0M0 unless a numerical value is then found for mN .  8 x − 2 − 6 xy 

Alternative method for part (a): Differentiating with respect to y    dx  dx dx dx =  2 + 6 y +  6 xy + 3x 2  = 8 x    d y d y d y dy     dx dx dx M1: Differentiates implicitly to include either 2 or 6 xy or ± kx . (Ignore dy dy dy A1:





( 2 x + 3 y ) →  2 ddyx + 6 y  and 2

 dy B1: 6 x y + 3 x 2 . dx



 dx  =  ).   dy 

 2 dx   4 x → 8 x  . Note: If an extra “sixth” term appears then award A0. dy  

dM1: Substituting x = − 1 and y = 1 into an equation involving

dy dx or . Allow this mark if either the dy dx

dx 6 y + 3x 2 = is substituted into or evaluated correctly. dy 8 x − 2 − 6 xy If it is clear, however, that the candidate is intending to substitute x = 1 and y = − 1, then award M0. numerator or denominator of

Candidates who substitute x = 1 and y = − 1, will usually achieve m ( T ) = − 4 Note that this mark is dependent on the previous method mark being awarded. • 4 8 A1: For − or − or − 0.4 or awrt − 0.44 18 9 If the candidate’s solution is not completely correct, then do not give this mark.

Question Number 2. (a)

Scheme 1

Marks

1

∫ x sin 3x dx = − 3 x cos3x − ∫ − 3 cos 3x {dx}

M1 A1

1 1 = − x cos 3x + sin 3 x {+ c} 3 9

A1 [3]

(b)

∫

1 2 x 2 cos3 x dx = x 2 sin 3 x − x sin 3 x {dx} 3 3 1 2 1 1  = x 2 sin 3 x −  − x cos3 x + sin 3 x  {+ c} 3 3 3 9  2 2  1 2  sin 3x {+ c} = x sin 3x + x cos 3x − 9 27  3 

∫

M1 A1 A1 isw Ignore subsequent working

[3] 6

(a)

M1: Use of ‘integration by parts’ formula u v − ∫ v u ' (whether stated or not stated) in the correct direction,

where u = x → u ′ = 1 and v′ = sin 3 x → v = k cos3 x (seen or implied), where k is a positive or negative constant. (Allow k = 1 ). This means that the candidate must achieve x ( k cos3x ) −

∫ ( k cos 3x ) , where k is a consistent constant.

If x 2 appears after the integral, this would imply that the candidate is applying integration by parts in the wrong direction, so M0. 1 1 A1: − x cos3 x − − cos3x {dx} . Can be un-simplified. Ignore the {dx}. 3 3 1 1 A1: − x cos3 x + sin 3x with/without + c. Can be un-simplified. 3 9 M1: Use of ‘integration by parts’ formula u v − ∫ v u ' (whether stated or not stated) in the correct direction,

∫

(b)

where u = x 2 → u ′ = 2 x or x and v′ = cos3 x → v = λ sin 3 x (seen or implied), where λ is a positive or negative constant. (Allow λ = 1 ).

This means that the candidate must achieve x 2 (λ sin 3 x) − or x 2 (λ sin 3 x) −

∫ 2 x (λ sin 3x) , where u′ = 2 x

∫ x (λ sin 3x) , where u′ = x.

If x3 appears after the integral, this would imply that the candidate is applying integration by parts in the wrong direction, so M0. 1 2 2 A1: x sin 3x − x sin 3x {dx} . Can be un-simplified. Ignore the {dx}. 3 3 1 2 2 1 1  A1: x sin 3 x −  − x cos3 x + sin 3 x  with/without + c, can be un-simplified. 3 3 3 9  You can ignore subsequent working here. Special Case: If the candidate scores the first two marks of M1A1 in part (b), then you can award the final A1 1 2 as a follow through for x 2 sin 3 x − ( their follow through part(a) answer ) . 3 3

∫

Question Number

Scheme

Marks −2

3. (a)

1 5x  1  5x  −2  = (2 − 5 x)− 2 = ( 2 )  1 −  = 1 −  2 (2 − 5 x) 2  4 2   (− 2)(− 3) 1    =    1 + (− 2)(** x) + (** x) 2 + ...  4 2!   

−2

(2) − 2 or

1 4

B1

see notes M1 A1ft

2  1    5 x  (− 2)(− 3)  5 x  =    1 + (− 2)  −  + −   + ...  2!  4    2   2  

1 75 2  1 + 5 x; + x + ...   4 4  1 5 75 2 = + x; + x + ... 4 4 16

=

See notes below! A1; A1

[5] (b)

 2+kx  1 5  75  = (2 + kx)  + x +  x 2 + ...   2   16  4 4  (2 − 5 x)  2(5 x) k x 7 x x terms: + = 4 4 4 giving, 10 + k = 7 ⇒ k = − 3

Can be implied by later work M1 even in part (c).

k = −3

A1

[2] 2

(c)

2

150 x 5k x + 16 4 75 5(− 3) 75 15 45 So, A = + = − = 8 4 8 4 8

x 2 terms:

M1 45 5 or 5 or 5.625 8 8

A1

[2] 9 (a)

1 1 outside brackets or as candidate’s constant term in their binomial expansion. 4 4 M1: Expands to give a simplified or an un-simplified, (− 2)(− 3) (− 2)(− 3) 2 2 1 + (− 2)(** x) or (− 2) (** x ) + (** x ) or 1 + ...... + (** x ) , where ** ≠ 1 . 2! 2! (− 2)(− 3) A1: A correct simplified or an un-simplified 1 + (− 2)(** x) + (** x)2 expansion with candidate’s 2! follow through (** x ) . Note that (** x ) must be consistent.

B1: (2) − 2 or

You would award B1M1A0 for =

 1  5 x  (− 2)(− 3) (− 5 x)2 + ...  because ** is not consistent.  1 + (− 2)  −  + 4  2!  2  

2  1    5 x  (− 2)(− 3)  5 x  Invisible brackets    1 + (− 2)  −  + − + ...  is M1A0 unless recovered.   2!  4    2   2  

1 5 1 1 + x (simplified fractions) or Also allow 0.25 + 1.25 x or + 1 x . 4 4 4 4 1 75 2   Allow Special Case A1 for either SC: [ 1 + 5 x ; ... ] or SC: K  1 + 5 x + x + ...  . 4 4   75 2 11 2 A1: Accept only x or 4 x or 4.6875 x 2 16 16 Alternative method: Candidates can apply an alternative form of the binomial expansion. (See next page).

A1: For

3. (b)

M1: Candidate writes down (2 + kx) ( their part (a) answer, at least up to the term in x.) 75 2 1 5  1 5  (2 + kx)  + x + ...  or (2 + kx)  + x + x + ...  are fine. 16 4 4  4 4  This mark can also be implied by candidate multiplying out to find two terms (or coefficients) in x. A1: k = − 3

(c)

75 2 1 5  M1: Multiplies out their (2 + kx)  + x + x + ...  to give exactly two terms (or coefficients) in x 2 16 4 4  and attempts to find A using a numerical value of k. 45 5 45 2 A1: Either or 5 or 5.625 Note: x is A0. 8 8 8 Alternative method for part (a) (2 − 5 x)− 2 = (2)− 2 + (− 2)(2) −3 (−5 x); +

(− 2)( − 3) − 4 (2) (−5 x)2 2!

1 or (2)− 2 , 4 M1: Any two of three (un-simplified) terms correct. A1: All three (un-simplified) terms correct. 1 5 A1: + x 4 4 75 2 A1: x 16 Note: The terms in C need to be evaluated, so −2C0 (2) − 2 + −2C1 (2) −3 (−5 x); + −2C2 (2) − 4 (−5 x) 2 without further working is B0M0A0.

B1:

Alternative method for parts (b) and (c) 1 7  (2 + kx) = (2 − 5 x)2  + x + A x 2 + ...  2 4  1 7  (2 + kx) = (4 − 20 x + 25 x 2 )  + x + A x 2 + ...  2 4  25 2   (2 + kx) = 2 + (7 x − 10 x) +  4 Ax 2 − 35 x 2 + x  2   Equate x terms: k = − 3 25 45 45 ⇒ 4A = ⇒ A= 2 2 8 1 7  M1: For (2 + kx) = (4 ± λ x + 25 x 2 )  + x + A x 2 + ...  , where λ ≠ 0 2 4  A1: k = − 3 Equate x 2 terms: 0 = 4 A − 35 +

(b)

(c)

M1: Multiplies out to obtain three x 2 terms/coefficients, equates to 0 and attempts to find A. 45 5 45 2 A1: Either or 5 or 5.625 Note: x is A0. 8 8 8

Question Number

Scheme 2

4.

Volume = π

∫

  2x   2   3x + 

Marks 2

   dx 4 

Use of V = π ∫ y 2 dx . B1

0

2

1  = ( π )  ln ( 3x 2 + 4 )  3  0

 1  1  = ( π )  ln16  −  ln 4    3   3 1 So Volume = π ln 4 3

± k ln ( 3 x 2 + 4 )

M1

1 ln ( 3x 2 + 4 ) 3

A1

Substitutes limits of 2 and 0 dM1 and subtracts the correct way round. 1 2 π ln 4 or π ln 2 3 3

A1 oe isw

[5] 5 NOTE: π is required for the B1 mark and the final A1 mark. It is not required for the 3 intermediate marks. B1: For applying π ∫ y 2 . Ignore limits and dx . This can be implied by later working,

but the pi and

∫ 3x

2x 2 +4

must appear on one line somewhere in the candidate’s working.

B1 can also be implied by a correct final answer. Note: π

( ∫ y ) would be B0. 2

Working in x 4  M1: For ± k ln ( 3 x 2 + 4 ) or ± k ln  x 2 +  where k is a constant and k can be 1. 3  2 Note: M0 for ± k x ln ( 3 x + 4 ) .

(

)

Note: M1 can also be given for ± k ln p ( 3 x 2 + 4 ) , where k and p are constants and k can be 1.

1 1 1 1  4 1  ln ( 3x 2 + 4 ) or ln  ( 3 x 2 + 4 )  or ln  x 2 +  or ln ( p (3 x 2 + 4) ) . 3 3 3  3 3 3  1 x  1  2x  You may allow M1 A1 for   ln ( 3x 2 + 4 ) or   ln ( 3 x 2 + 4 ) 3 x  3  6x  dM1: Substitutes limits of 2 and 0 and subtracts the correct way round. Working in decimals is fine for dM1.  16  1 2 1 2 1 16 16 1   A1: For either π ln 4 , ln 4π , π ln 2, π ln 4 3 , π ln 2 3 , π ln   , 2 π ln  1  , etc. 3 3 3 3  4  46    A1: For

1 π (ln16 − ln 4) would be A0. 3 Working in u: where u = 3 x 2 + 4 , M1: For ± k ln u where k is a constant and k can be 1.

Note:

Note: M1 can also be given for ± k ln ( pu ) , where k and p are constants and k can be 1. 1 1 1 ln u or ln 3u or ln pu . 3 3 3 dM1: Substitutes limits of 16 and 4 in u or limits of 2 and 0 in x and subtracts the correct way round. A1: As above!

A1: For

Question Number

5. (a)

Scheme

π  x = 4sin  t +  , y = 3cos 2t , 6  dx π  dy  = 4cos  t +  , = − 6sin 2t dt 6  dt  dy − 6sin 2t So, = π dx  4cos  t +  6 

Marks 0 „ t < 2π B1 B1

B1

oe

[3] (b)

 dy   = 0 ⇒  − 6sin 2t = 0  dx  π  @ t = 0, x = 4sin   = 2 , 6  2π , x = 4sin  2  3  7π @ t = π , x = 4sin   6 @t=

@t=

π

M1 oe y = 3cos 0 = 3

→ (2, 3)

M1

 4 3 , y = 3cos π = − 3 → (2 3 , − 3)  = 2    = − 2 , y = 3cos 2π = 3 → ( − 2, 3) 

3π  5π  4( − 3 ) , x = 4sin  , y = 3cos 3π = − 3 → (− 2 3 , − 3)  = 2 2  3 

A1A1A1

[5] 8 (a)

dx π dy  = 4cos  t +  or = − 6sin 2t . They do not have to be simplified. dt 6 dt  dx dy B1: Both and correct. They do not have to be simplified. dt dt Any or both of the first two marks can be implied. Don’t worry too much about their notation for the first two B1 marks. dy dx dy 1 B1: Their divided by their or their × . Note: This is a follow through mark. dt dt dt  dx  their    dt  Alternative differentiation in part (a) dx x = 2 3 sin t + 2cos t ⇒ = 2 3 cos t − 2sin t dt dy y = 3(2cos 2 t − 1) ⇒ = 3 ( − 4cos t sin t ) dt dy or y = 3cos 2 t − 3sin 2 t ⇒ = − 6cos t sin t − 6sin t cos t dt dy or y = 3(1 − 2sin 2 t ) ⇒ = 3 ( − 4cos t sin t ) dt

B1: Either one of

5. (b)

dy equal to 0. dt dx Note that their numerator must be a trig function. Ignore equal to 0 at this stage. dt M1: Candidate substitutes a found value of t, to attempt to find either one of x or y. The first two method marks can be implied by ONE correct set of coordinates for ( x , y ) or ( y , x ) interchanged. A correct point coming from NO WORKING can be awarded M1M1. A1: At least TWO sets of coordinates. A1: At least THREE sets of coordinates. A1: ONLY FOUR correct sets of coordinates. If there are more than 4 sets of coordinates then award A0. Note: Candidate can use the diagram’s symmetry to write down some of their coordinates. π  Note: When x = 4sin   = 2 , y = 3cos 0 = 3 is acceptable for a pair of coordinates. 6 Also it is fine for candidates to display their coordinates on a table of values. Note: The coordinates must be exact for the accuracy marks. Ie (3.46..., -3) or (-3.46..., -3) is A0. dy Note: = 0 ⇒ sin t = 0 ONLY is fine for the first M1, and potentially the following M1A1A0A0. dx dy Note: = 0 ⇒ cos t = 0 ONLY is fine for the first M1 and potentially the following M1A1A0A0. dx dy Note: = 0 ⇒ sin t = 0 & cos t = 0 has the potential to achieve all five marks. dx Note: It is possible for a candidate to gain full marks in part (b) if they make sign errors in part (a).

M1: Candidate sets their numerator from part (a) or their

(b) An alternative method for finding the coordinates of the two maximum points. Some candidates may use y = 3cos 2t to write down that the y-coordinate of a maximum point is 3. They will then deduce that t = 0 or π and proceed to find the x-coordinate of their maximum point. These candidates will receive no credit until they attempt to find one of the x-coordinates for the maximum point. π  M1M1: Candidate states y = 3 and attempts to substitute t = 0 or π into x = 4sin  t +  . 6  M1M1 can be implied by candidate stating either (2, 3) or (2, − 3). Note: these marks can only be awarded together for a candidate using this method. A1: For both (2, 3) or (− 2, 3). A0A0: Candidate cannot achieve the final two marks by using this method. They can, however, achieve these marks by subsequently solving their numerator equal to 0.

Question Number 6. (a) (b)

Scheme

B1 cao

0.73508

[1]

1 π Area ≈ × ;× 0 + 2 ( their 0.73508 + 1.17157 + 1.02280 ) + 0  2 8 =

(c)

Marks

π

16

× 5.8589... = 1.150392325... = 1.1504 (4 dp)

{u = 1 + cos x}

⇒

awrt 1.1504 A1

du = − sin x dx

  2sin 2 x dx =    (1 + cos x) 

∫ ∫

B1 M1

∫

2(2sin x cos x) dx (1 + cos x)

B1 sin 2 x = 2sin x cos x

 4(u − 1) (1 − u )  .(−1) du = 4 du  u u   1  = 4  − 1 du = 4 ( ln u − u ) + c u  = 4ln (1 + cos x ) − 4 (1 + cos x ) + c = 4ln (1 + cos x ) − 4cos x + k

∫

=

(d)

= [ 4 ln1 − 0] − [ 4ln 2 − 4] = 4 − 4ln 2 {= 1.227411278...}

Error =

( 4 − 4ln 2 ) − 1.1504...

= 0.0770112776... = 0.077 (2sf )

B1 M1

∫

 π π  =  4ln  1 + cos  − 4cos  −  4ln (1 + cos 0 ) − 4cos 0  2 2  

[3]

dM1

AG Applying limits x =

A1 cso [5]

π

and M1 2 x = 0 either way round.

±4(1− ln 2) or ± (4 − 4ln 2) or awrt ± 1.2, A1 however found.

awrt ± 0.077 A1 cso [3] or awrt ± 6.3(%) 12

(a) (b)

B1: 0.73508 correct answer only. Look for this on the table or in the candidate’s working. 1 π π B1: Outside brackets × or or awrt 0.196 2 8 16 M1: For structure of trapezium rule [ ............. ] ; (0 can be implied). A1: anything that rounds to 1.1504 Bracketing mistake: Unless the final answer implies that the calculation has been done correctly 1 π Award B1M0A0 for × + 2 ( their 0.73508 + 1.17157 + 1.02280 ) (nb: answer of 6.0552). 2 8 1 π Award B1M0A0 for × (0 + 0) + 2 ( their 0.73508 + 1.17157 + 1.02280 ) (nb: answer of 5.8589). 2 8 Alternative method for part (b): Adding individual trapezia

Area ≈ B1:

π

π

 0 + 0.73508 0.73508 +1.17157 1.17157 + 1.02280 1.02280 + 0  × + + +  = 1.150392325... 8  2 2 2 2 

and a divisor of 2 on all terms inside brackets. 8 M1: One of first and last ordinates, two of the middle ordinates inside brackets ignoring the 2. A1: anything that rounds to 1.1504

6. (c)

du dx 1 = − sin x or du = − sin x dx or oe. = dx du − sin x B1: For seeing, applying or implying sin 2 x = 2sin x cos x. B1:

(u − 1) (1 − u ) ( du ) or ± k ( du ) . u u (λ u − 1) ( −λ + u ) ( du ) or ± ( du ) , where λ is a u u

M1: After applying substitution candidate achieves ± k

Allow M1 for “invisible” brackets here, eg: ±

∫

∫

∫

∫

positive constant.

∫

1   − 1 du → ± k ( ln u − u ) with/without u   + c . Note that this mark is dependent on the previous M1 mark being awarded. Alternative method: Candidate can also gain this mark for applying integration by parts followed by a correct method for integrating ln u. (See below). A1: Correctly combines their + c and " − 4 " together to give 4ln (1 + cos x ) − 4cos x + k dM1: An attempt to divide through each term by u and ± k

As a minimum candidate must write either 4ln (1 + cos x ) − 4 (1 + cos x ) + c → 4ln (1 + cos x ) − 4cos x + k or 4ln (1 + cos x ) − 4 (1 + cos x ) + k → 4ln (1 + cos x ) − 4cos x + k Note: that this mark is also for a correct solution only. Note: those candidates who attempt to find the value of k will usually achieve A0. (d)

M1: Substitutes limits of x =

π

2

and x = 0 into {4ln (1 + cos x ) − 4cos x} or their answer from part (c) and

 π π  Note that:  4ln  1 + cos  − 4cos  − [ 0] is M0. 2 2    A1: 4(1 − ln 2) or 4 − 4ln 2 or awrt 1.2, however found. This mark can be implied by the final answer of either awrt ± 0.077 or awrt ± 6.3 A1: For either awrt ± 0.077 or awrt ± 6.3 (for percentage error). Note this mark is for a correct solution only. Therefore if there if a candidate substitutes limits the incorrect way round and final achieves (usually fudges) the final correct answer then this mark can be withheld. Note that awrt 6.7 (for percentage error) is A0. Alternative method for dM1 in part (c)     (1 − u ) u du =  (1 − u ) ln u − − ln u du  =  (1 − u ) ln u + u ln u − du  = ( (1 − u ) ln u + u ln u − u ) u u    

subtracts the either way round.

∫

∫

∫

     (u − 1) u du =  (u − 1) ln u − ln u du  =  (u − 1) ln u −  u ln u − du   = ( (u − 1) ln u − u ln u + u ) u u      (1 − u ) So dM1 is for du going to ( (1 − u ) ln u + u ln u − u ) or ( (u − 1)ln u − u ln u + u ) oe. u Alternative method for part (d) 1   1 1  M1A1 for 4  − 1 du =  4 [ ln u − u ]2 = 4 ( ln1 − 1) − ( ln 2 − 2 )  = 4 (1 − ln 2 )   2  u  Alternative method for part (d): Using an extra constant λ from their integration.

or

∫

∫

∫

∫

∫

 π π    4ln  1 + cos 2  − 4cos 2 + λ  −  4ln (1 + cos 0 ) − 4cos 0 + λ      λ is usually − 4 , but can be a value of k that the candidate has found in part (d). Note: The extra constant λ should cancel out and so the candidate can gain all three marks using this method, even the final A1 cso.

Question Number 7. (a)

Scheme uuur uuur uuur OA = 2i − j + 5k , OB = 5i + 2 j + 10k , OC = 2i + 4 j + 9k uuur AB = = ± ( (5i + 2 j + 10k ) − (2i − j + 5k ) ) ; = 3i + 3 j + 5k

{

Marks

}

uuur & OD = − i + j + 4k M1; A1 [2]

(b)

 2  3     l : r =  −1  + λ  3  or  5  5    

[2]

ˆ Let θ = BAD

14 ° 71° 109 A

(c)

See notes M1 A1ft

C

D

d

 5  3     r =  2  + λ  3  10      5

Let d be the shortest distance from C to l. B

43

l

 −1   2   − 3   3 uuur uuur uuur       uuur   AD = OD − OA =  1  −  −1  =  2  or DA =  − 2   4   5   −1           1  3  −3      3 •  2 uuur uuur  5   −1  AB • AD     cos θ = uuur uuur = 2 2 AB . AD (3) + (3) + (5)2 . (− 3) 2 + (2) 2 + (−1) 2   −9 + 6 −5  cos θ = ±   (3)2 + (3)2 + (5)2 . (− 3) 2 + (2)2 + (−1) 2    −8 cos θ = ⇒ θ = 109.029544... = 109 (nearest °) 43 . 14

(d)

(e)

M1 Applies dot product formula between uuur uuur M1 their AB or BA uuur uuur and their AD or DA .

(

(

) )

Correct followed through expression or equation. A1 awrt 109

[4]

uuur uuur uuur uuur uuur OC = OD + DC = OD + AB = ( −i + j + 4k ) + ( 3i + 3j + 5k ) uuur uuur uuur uuur uuur OC = OB + BC = OB + AD = ( 5i + 2 j + 10k ) + ( −3i + 2 j − k ) uuur So, OC = 2i + 4 j + 9k Area ABCD =

(

1 2

°

)

( 43)( 14)sin109 ; × 2 = 23.19894905

A1 cso AG

M1 A1 [2]

awrt 23.2

M1; dM1 A1 [3]

(f)

d or 43 d = 23.19894905... = sin 71 14 ∴ d = 14 sin 71° = 3.537806563...

M1 awrt 3.54 A1 [2] 15

7. (a)

(b)

uuur uuur M1: Finding the difference between OB and OA . Can be implied by two out of three components correct in 3i + 3j + 5k or − 3i − 3 j − 5k A1: 3i + 3 j + 5k

M1: An expression of the form ( 3 component vector ) ± λ ( 3 component vector ) uuur uuur uuur uuur A1ft: r = OA + λ their ± AB or r = OB + λ their ± AB .

(

)

(

Note: Candidate must begin writing their line as r = or

(c)

)

 x   l = ... or  y  = ... So, Line = ... would be A0. z  

uuur uuur M1: An attempt to find either the vector AD or DA. Can be implied by two out of three components correct in − 3i + 2 j − k or 3i − 2 j + k , respectively. uuur uuur uuur uuur M1: Applies dot product formula between their AB or BA and their AD or DA .

(

(d)

(e)

)

(

)

A1ft: Correct followed through expression or equation. The dot product must be correctly followed through correctly and the square roots although they can be un-simplified must be followed through correctly. A1: Obtains an angle of awrt 109 by correct solution only. Award the final A1 mark if candidate achieves awrt 109 by either taking the dot product between:  3  −3  − 3  3         (i)  3  and  2  or (ii)  − 3  and  − 2  . Ignore if any of these vectors are labelled incorrectly.  5  −1   − 5  1         Award A0, cso for those candidates who take the dot product between:  −3  −3  3  3         (iii)  − 3  and  2  or (iv)  3  and  − 2  .  −5  −1   5  1         They will usually find awrt 71 and apply 180 – awrt 71 to give awrt 109. If these candidates give a convincing detailed explanation which must include reference to the direction of their vectors then this can be given A1 cso. If still in doubt, here, send to review. uuur uuur uuur uuur M1: Applies either OD + their AB or OB + their AD . uuur This mark can be implied by two out of three correctly followed through components in their OD . A1: For 2i + 4 j + 9k . M1:

1 2

( their AB )( their CB ) sin ( their 109° or 71° from (b) ) .

Awrt 11.6 will usually imply this mark.

dM1: Multiplies this by 2 for the parallelogram. Can be implied. Note: 12 ( ( their AB + their AB ) ) ( their CB ) sin ( their 109° or 71° from (b) )

(f)

A1: awrt 23.2 d M1: = sin ( their 109° or 71° from (b) ) or (their AB ) d = (their Area ABCD ) their AD

Award M0 for ( their AB ) in part (f), if the area of their parallelogram in part (e) is

( their AB )( their CB ) . Award M0 for

d = sin 71 their 43

or

( their

)

14 d = 23.19894905...

A1: awrt 3.54 Note: Some candidates will use their answer to part (f) in order to answer part (e).

7.

Alternative method for part (c): Applying the cosine rule:  −1   2   − 3   3 uuur uuur uuur       uuur   AD = OD − OA =  1  −  −1  =  2  or DA =  − 2   4   5   −1           1  5   −1   6   − 6 uuur uuur uuur       uuur   DB = OD − OA =  2  −  1  =  1  or BD =  −1   10   4   6           −6  uuur uuur uuur So AB = 43 , AD = 14 and DB = 73

cos θ =

(

) +( 2

43

) −( 2

14

73

)

M1: as above.

a2 + b2 − c2 M1: Cosine rule structure of cosθ = assigned 2ab uuur uuur uuur each of AB , AD and DB in any order as their a, b and c.

2

2 43 . 14 A1: Correct application of cosine rule.

  − 16 ⇒ θ = 109.029544...  = 109 (nearest °) cos θ = 2 43. 14   Alternative method for part (d):  2  3 uuur     OE =  −1  + λ  3   5 5      2 + 3λ   −1   3 + 3λ  uuur       DE =  −1 + 3λ  −  1  =  − 2 + 3λ   5 + 5λ   4   1 + 5λ         3 + 3λ   3  uuur uuur     DE • AB = 0 ⇒  − 2 + 3λ  •  3  = 0  1 + 5λ   5     

9 + 9λ − 6 + 9λ + 5 + 3λ = 0 ⇒ λ = −

 103  2 + 3λ   −1  43  uuur   110     DE =  −1 + 3λ  −  1  =  − 43   5 + 5λ   4   3       43  Length DE = 3.537806563...

8 43

A1: awrt 109 (no errors seen). AG

uuur uuur M1: Takes the dot product between DE and AB and progresses to find a value of λ

uuur dM1: Uses their value of λ to find DE A1: awrt 3.54

Question Number 8. (a)

Scheme

Marks

1 = A(5 − P ) + B P 1 1 A= ,B= 5 5 giving

1 5

P

+

Can be implied. M1 Either one. A1

1 5

See notes. A1 cao, aef

(5 − P )

[3]

(b)

∫

∫

1 1 dP = dt P (5 − P) 15 1 1 1 ln P − ln(5 − P ) = t ( + c ) 5 5 15 1 1 {t = 0, P = 1 ⇒} ln1 − ln(4) = 0 + c 5 5 eg:

B1 M1* A1ft 1   ⇒ c = − ln 4  5  

dM1* Using any of the subtraction (or addition) dM1* laws for logarithms CORRECTLY

1  P  1 1 ln   = t − ln 4 5  5 − P  15 5

 4P  1 ln   = t 5 − P 3 1t 4P 5−P −1t =e 3 eg: or eg: = e3 4P 5−P

Eliminate ln’s correctly. dM1*

gives 4 P = 5e 3 − Pe 3 ⇒ P (4 + e 3 ) = 5e 3 1t

1t

1t

 (÷ e 3 t )   1t  3  (÷ e ) 

1t

P = P =

1t

1

5e 3

1t

(4 + e 3 ) 5 (1 + 4e

− 13 t

)

or P =

Make P the subject. dM1* 25

(5 + 20e

− 13 t

etc.

A1

)

[8]

(c)

(a)

1 + 4e

− 13 t

>1 ⇒ P < 5.

So population cannot exceed 5000.

B1

[1] 12 M1: Forming a correct identity. For example, 1 = A(5 − P ) + B P . Note A and B not referred to in question. 1 1 A1: Either one of A = or B = . 5 5 1 1 1 1 5 A1: 5 + or any equivalent form, eg: , etc. Ignore subsequent working. + P (5 − P ) 5P 25 − 5 P This answer must be stated in part (a) only. 1 1 A B A1 can also be given for a candidate who finds both A = and B = and + is seen in their 5 5 P 5− P working.

Candidate can use ‘cover-up’ rule to write down

1 5

+

1 5

P (5 − P ) Candidate cannot gain the marks for part (a) in part (b).

, as so gain all three marks.

8. (b)

B1: Separates variables as shown. dP and dt should be in the correct positions, though this mark can be implied by later working. Ignore the integral signs. M1*: Both ± λ ln P and ± µ ln(± 5 ± P ) , where λ and µ are constants. Or ± λ ln mP and ± µ ln(n(± 5 ± P )) , where λ , µ , m and n are constants. A1ft: Correct follow through integration of both sides from their

∫

λ P

+

µ (5 − P )

dP =

∫

K dt

with or without + c dM1*: Use of t = 0 and P = 1 in an integrated equation containing c dM1*: Using ANY of the subtraction (or addition) laws for logarithms CORRECTLY. dM1*: Apply logarithms (or take exponentials) to eliminate ln’s CORRECTLY from their equation. dM1*: A full ACCEPTABLE method of rearranging to make P the subject. (See below for examples!) 5 A1: P = {where a = 5, b = 1, c = 4} . − 1t (1 + 4e 3 ) 25 Also allow any “integer” multiples of this expression. For example: P = − 1t (5 + 20e 3 ) Note: If the first method mark (M1*) is not awarded then the candidate cannot gain any of the six remaining marks for this part of the question. 1 1 1 5 5 Note: dP = 15 dt ⇒ + dP = 15 dt ⇒ ln P − ln(5 − P ) = 15t is B0M1A1ft. P(5 − P ) P (5 − P ) dM1* for making P the subject Note there are three type of manipulations here which are considered acceptable to make P the subject. 1t 1t 1t 1t 1t 5 P (1) M1 for = e 3 ⇒ P = 5e 3 − Pe 3 ⇒ P (1 + e 3 ) = 5e 3 ⇒ P = − 1t 5−P (1 + e 3 )

∫

(2) M1 for

∫

∫

∫

1t 1t 1t 1t P 5−P 5 5 5 = e3 ⇒ = e3 ⇒ − 1 = e3 ⇒ = e3 + 1 ⇒ P = 1t 5−P P P P (1 + e 3 )

2

1t 1t 1t 5 25  (3) M1 for P (5 − P ) = 4e 3 ⇒ P 2 − 5P = − 4e 3 ⇒  P −  − = − 4e 3 leading to P = ... 2 4  P P Note: The incorrect manipulation of = − 1 or equivalent is awarded this dM0*. 5−P 5

1 ⇒ 2 P − 5 = t leading to P = ... or equivalent is awarded this dM0* 3 − 13 t B1: 1 + 4e > 1 and P < 5 and a conclusion relating population (or even P) or meerkats to 5000. 25 − 1t For P = , B1 can be awarded for 5 + 20e 3 > 5 and P < 5 and a conclusion relating − 13 t (5 + 20e ) population (or even P) or meerkats to 5000. a B1 can only be obtained if candidates have correct values of a and b in their P = . − 1t (b + c e 3 ) 5 − 1t Award B0 for: As t → ∞ , e 3 → 0 . So P → = 5 , so population cannot exceed 5000, (1 + 0) Note: ( P ) − (5 − P ) = e

(c)

1 t 3

unless the candidate also proves that P = If unsure here, then send to review!

5 (1 + 4e

− 13 t

oe. is an increasing function. )

8.

Alternative method for part (b) 1 1 1 B1M1*A1: as before for ln P − ln(5 − P ) = t ( + c ) 5 5 15  P  1 Award 3rd M1for ln   = t+c 5 − P 3 Award 4th M1 for

1t P = Ae 3 5−P

1  = Ae0 ⇒ A = 5 −1  1 P 1 t = e3 5−P 4 then award the final M1A1 in the same way.

Award 2nd M1 for

t = 0, P = 1 ⇒

1  4

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