GCSE Nov 2019 Edexcel Mathematics Higher Paper 3 (Calculator)

✏ Working:

\[ \begin{aligned} (x + 5)(x – 9) &= x \times x + x \times (-9) + 5 \times x + 5 \times (-9) \\ &= x^2 – 9x + 5x – 45 \end{aligned} \]

\[ -9x + 5x = -4x \] \[ \text{Result: } x^2 – 4x – 45 \]

✓ (M1) for 3 of 4 terms correct

✓ (A1) for correct final answer

Look at \( 9x^2 + 6x \):

• Numbers: The highest factor of 9 and 6 is 3.
• Algebra: The highest factor of \( x^2 \) and \( x \) is \( x \).

So the common factor is \( 3x \).

Divide each term by \( 3x \):

\[ \frac{9x^2}{3x} = 3x \quad \text{and} \quad \frac{6x}{3x} = 2 \]

Put the factor outside the bracket:

\[ 3x(3x + 2) \]

✓ (B2) for 3x(3x + 2)

Numerator:

\[ 29^2 – 4.6 = 841 – 4.6 = 836.4 \]

Denominator:

\[ \sqrt{35 – 1.9^3} = \sqrt{35 – 6.859} = \sqrt{28.141} \approx 5.3048… \]

Division:

\[ \frac{836.4}{5.3048…} \approx 157.668255… \]

✓ (M1) for 836.4 or 5.304… seen

✓ (A1) for 157.668255…

Value: \( 157.668255… \)

1st sf: 1

2nd sf: 5

3rd sf: 7

4th sf: 6

Check the next digit (5th digit) which is 6. Since 6 \(\geq\) 5, we round up the 4th digit.

\( 157.6 \rightarrow 157.7 \)

✓ (B1) for 157.7

1. Locate 34 on the Science axis (x-axis).
2. Go up to your line of best fit.
3. Go across to the Maths axis (y-axis).
4. Read the value.

Based on a standard line of best fit, the value is typically between 35 and 42.

✓ (M1) for drawing a suitable line of best fit

✓ (A1) for answer in range 35 – 42

Midpoint = \( \frac{\text{Start} + \text{End}}{2} \)

• 5 to 10: \( \frac{5+10}{2} = 7.5 \)
• 10 to 15: \( \frac{10+15}{2} = 12.5 \)
• 15 to 20: \( \frac{15+20}{2} = 17.5 \)
• 20 to 25: \( \frac{20+25}{2} = 22.5 \)

MP	Freq	\( f \times x \)
7.5	1	\( 7.5 \times 1 = 7.5 \)
12.5	2	\( 12.5 \times 2 = 25.0 \)
17.5	7	\( 17.5 \times 7 = 122.5 \)
22.5	8	\( 22.5 \times 8 = 180.0 \)

✓ (M1) for finding 4 products fx

Total Time: \( 7.5 + 25.0 + 122.5 + 180.0 = 335 \)

Total Frequency: \( 1 + 2 + 7 + 8 = 18 \)

Mean:

\[ \frac{335}{18} = 18.6111… \]

✓ (M1) for total fx ÷ total frequency

Round \( 18.6111… \) to 3 significant figures.

1st: 1, 2nd: 8, 3rd: 6. Next is 1 (round down).

\( 18.6 \)

✓ (A1)

Length: \( 1 \text{ cm} = 10 \text{ mm} \)

Volume: \( 1 \text{ cm}^3 = 1 \text{ cm} \times 1 \text{ cm} \times 1 \text{ cm} \)

Convert each side to mm:

\[ 10 \text{ mm} \times 10 \text{ mm} \times 10 \text{ mm} = 1000 \text{ mm}^3 \]

So, the conversion factor is 1000.

\[ 37 \times 1000 = 37,000 \text{ mm}^3 \]

✓ (B1)

Start: 13:30

Finish: 14:48

Hours: 13:30 to 14:30 is 1 hour.

Minutes: 14:30 to 14:48 is 18 minutes.

Total time = 1 hour 18 minutes.

18 minutes as a fraction of an hour is \( \frac{18}{60} \).

\[ \frac{18}{60} = 0.3 \text{ hours} \]

Total time in hours = \( 1 + 0.3 = 1.3 \text{ hours} \).

✓ (P1) for converting minutes to hours (1.3)

\[ \text{Speed} = \frac{65}{1.3} \]

Calculation:

\[ 65 \div 1.3 = 50 \]

✓ (P1) for using Distance ÷ Time

✓ (A1) for 50

Place the decimal point after the first non-zero digit: \( 3.246 \)

Count how many places the decimal moved (from the end): 7 places.

\[ 3.246 \times 10^7 \]

✓ (B1)

Move the decimal point 3 places to the left (because the power is negative).

\[ 4.96 \rightarrow 0.496 \rightarrow 0.0496 \rightarrow 0.00496 \]

✓ (B1)

Compare the powers:

• A has power \( 10^8 \)
• B has power \( 10^9 \)

\( 10^9 \) is 10 times bigger than \( 10^8 \).

Conclusion: No, Asma is incorrect. B is bigger because the power of 10 is higher (\( 10^9 > 10^8 \)).

✓ (C1) for “No” with correct explanation

For a pentagon, \( n = 5 \).

\[ \text{Sum} = (5 – 2) \times 180 = 3 \times 180 = 540^\circ \] \[ \text{One angle} = \frac{540}{5} = 108^\circ \]

✓ (P1) for process to find interior angle (108)

The angle marked \( 117^\circ \) is obtuse.

The angle at the vertex (inside the pentagon corner) is adjacent to \( 117^\circ \).

\[ \text{Parallelogram angle} = 180^\circ – 117^\circ = 63^\circ \]

✓ (P1) for 180 – 117 = 63

\[ \text{Pentagon Angle} = \text{Parallelogram Angle} + x \] \[ 108^\circ = 63^\circ + x \] \[ x = 108 – 63 \] \[ x = 45^\circ \]

✓ (P1) for complete process (108 – 63)

✓ (A1) for 45

Point 1: (1, 1)

• Vector from (0, 1): \( (1-0, 1-1) = (1, 0) \)
• Multiply by 2.5: \( (2.5, 0) \)
• Add to centre: \( (0+2.5, 1+0) = \mathbf{(2.5, 1)} \)

Point 2: (1, 3)

• Vector from (0, 1): \( (1-0, 3-1) = (1, 2) \)
• Multiply by 2.5: \( (2.5, 5) \)
• Add to centre: \( (0+2.5, 1+5) = \mathbf{(2.5, 6)} \)

Point 3: (2, 3)

• Vector from (0, 1): \( (2-0, 3-1) = (2, 2) \)
• Multiply by 2.5: \( (5, 5) \)
• Add to centre: \( (0+5, 1+5) = \mathbf{(5, 6)} \)

Plot the points (2.5, 1), (2.5, 6), and (5, 6).

Connect them to form a larger triangle.

✓ (B2) for vertices at (2.5, 1), (2.5, 6), (5, 6)

\[ \frac{9 + x}{7} = 11 – x \]

Multiply by 7:

\[ 9 + x = 7(11 – x) \]

Expand the bracket:

\[ 9 + x = 77 – 7x \]

✓ (M1) for multiplying by 7 correctly

Add \( 7x \) to both sides:

\[ 9 + 8x = 77 \]

Subtract 9 from both sides:

\[ 8x = 68 \]

Divide by 8:

\[ x = \frac{68}{8} \] \[ x = 8.5 \]

✓ (A1)

\[ \frac{4(y + 3)^3}{(y + 3)^2} \]

The term \( (y+3) \) is common.

\[ 4 \times (y+3)^{3-2} \] \[ 4(y+3)^1 \] \[ 4(y+3) \]

✓ (B1)

Path 1: Late, Not Late

\[ P(\text{L, NL}) = 0.07 \times 0.98 = 0.0686 \]

Path 2: Not Late, Late

\[ P(\text{NL, L}) = 0.93 \times 0.11 = 0.1023 \]

✓ (M1) for one correct product

\[ \text{Total Probability} = 0.0686 + 0.1023 \] \[ = 0.1709 \]

✓ (M1) for adding correct products

✓ (A1) for 0.1709

1. Lowest Value: First number = 173

2. Highest Value: Last number = 219

3. Median: Position = \( \frac{n+1}{2} = \frac{24}{2} = 12^{\text{th}} \) value.

• Count 12 numbers in the stem and leaf.
• 170s: 3 values
• 180s: 3 values (Total 6)
• 190s: We need the 6th value in this row (since 6+6=12).
• Row 19: 0, 0, 1, 4, 6, 7

Median = 197

4. Lower Quartile: Median of the lower half (first 11 numbers).

Position = \( \frac{11+1}{2} = 6^{\text{th}} \) value.

Count 6: 173, 174, 179, 186, 188, 188.

LQ = 188

5. Upper Quartile: Median of the upper half (last 11 numbers).

Position = 6th value from the end.

Count back 6: 219, 218, 218, 214, 209, 209.

UQ = 209

✓ (M1) for correctly identifying LQ (188), Median (197), or UQ (209)

\[ V = \pi \times 3^2 \times 25 \] \[ V = \pi \times 9 \times 25 \] \[ V = 225\pi \text{ cm}^3 \approx 706.858… \text{ cm}^3 \]

✓ (P1) for process to find volume of C

Volume of A = \( \frac{2}{15} \times 225\pi = 30\pi \approx 94.248 \text{ cm}^3 \)

Volume of B = \( \frac{13}{15} \times 225\pi = 195\pi \approx 612.61 \text{ cm}^3 \)

✓ (P1) for process to find volume of A or B

Mass of A:

\[ 1.21 \times 30\pi = 36.3\pi \approx 114.04 \text{ g} \]

Mass of B:

\[ 1.02 \times 195\pi = 198.9\pi \approx 624.86 \text{ g} \]

✓ (P1) for process to find mass of C (sum of parts)

\[ \text{Total Mass} = 114.04 + 624.86 = 738.90… \text{ g} \]

Round to 3 significant figures: 739 g

✓ (A1)

From Soup Group:

Ratio Lasagne : Curry = 5 : 3 (Total 8 parts)

Fraction choosing Curry = \( \frac{3}{8} \)

Total Fraction (Soup AND Curry) = \( \frac{2}{5} \times \frac{3}{8} = \frac{6}{40} \)

From Prawn Group:

Ratio Lasagne : Curry = 1 : 5 (Total 6 parts)

Fraction choosing Curry = \( \frac{5}{6} \)

Total Fraction (Prawns AND Curry) = \( \frac{3}{5} \times \frac{5}{6} = \frac{15}{30} = \frac{1}{2} \)

✓ (P1) for process to find proportion for curry in either group

Total Curry = (Soup & Curry) + (Prawns & Curry)

\[ \frac{6}{40} + \frac{1}{2} \]

Common denominator is 40:

\[ \frac{6}{40} + \frac{20}{40} = \frac{26}{40} \]

Simplify:

\[ \frac{13}{20} \]

✓ (P1) for complete process

✓ (A1)

Let the first number be \( 2n \).

Let the second number be \( 2n + 2 \).

✓ (M1) for correct expressions

Sum of squares = \( (2n)^2 + (2n + 2)^2 \)

Expand:

\[ (2n)^2 = 4n^2 \] \[ (2n + 2)^2 = (2n + 2)(2n + 2) = 4n^2 + 4n + 4n + 4 = 4n^2 + 8n + 4 \]

Add them together:

\[ 4n^2 + (4n^2 + 8n + 4) = 8n^2 + 8n + 4 \]

✓ (M1) for expanding both correctly

\[ 8n^2 + 8n + 4 \] \[ 4(2n^2 + 2n + 1) \]

Since \( 4(2n^2 + 2n + 1) \) is 4 times an integer, the result is always a multiple of 4.

✓ (A1) for complete proof

\[ y = \frac{k}{x^2} \]

Substitute the given values to find \( k \):

\[ 8 = \frac{k}{2.5^2} \] \[ 8 = \frac{k}{6.25} \] \[ k = 8 \times 6.25 \] \[ k = 50 \]

So the formula is \( y = \frac{50}{x^2} \).

✓ (M1) for correct relationship \( y = \frac{k}{x^2} \)

✓ (A1) for \( k = 50 \)

Substitute \( y = \frac{8}{9} \) into the formula:

\[ \frac{8}{9} = \frac{50}{x^2} \]

Cross multiply:

\[ 8x^2 = 9 \times 50 \] \[ 8x^2 = 450 \] \[ x^2 = \frac{450}{8} \] \[ x^2 = 56.25 \]

Find the square root:

\[ x = \sqrt{56.25} \] \[ x = \pm 7.5 \]

The question asks for the negative value.

\[ x = -7.5 \]

✓ (A1) for -7.5

Equation to solve: \( x^2 – 2x – 2 = 0 \)

Add \( 2x \) to both sides:

\[ x^2 – 2 = 2x \]

Subtract 1 from both sides to get \( x^2 – 3 \):

\[ x^2 – 3 = 2x – 1 \]

So, we need to find where the curve \( y = x^2 – 3 \) intersects the line \( y = 2x – 1 \).

✓ (M1) for relating to \( 2x – 1 \)

• If \( x = 0 \), \( y = -1 \). Point (0, -1).
• If \( x = 2 \), \( y = 3 \). Point (2, 3).
• If \( x = 3 \), \( y = 5 \). Point (3, 5).

Draw a straight line through these points on the graph.

✓ (M1) for drawing the line \( y = 2x – 1 \)

Look where the red line crosses the curve.

Read the x-values down to the axis.

• First point is between -0.6 and -0.8. Estimate: -0.7
• Second point is between 2.6 and 2.8. Estimate: 2.7

✓ (M1) for identifying intersection points

✓ (A1) for answers in range -0.6 to -0.8 and 2.6 to 2.8

\[ \cos C = \frac{6.2^2 + 6.1^2 – 3.4^2}{2 \times 6.2 \times 6.1} \] \[ \cos C = \frac{38.44 + 37.21 – 11.56}{75.64} \] \[ \cos C = \frac{64.09}{75.64} \] \[ C = \cos^{-1}(0.8473…) \] \[ C = 32.08^\circ \]

✓ (P1) for cosine rule substitution

✓ (P1) for angle C = 32.08…

Angle \( DAC = \frac{2}{5} \times 32.08… = 12.83^\circ \)

Now consider triangle ADC. We know:

• Angle \( C = 32.08^\circ \)
• Angle \( DAC = 12.83^\circ \)

Angles in a triangle add to 180, so Angle \( ADC = 180 – (32.08 + 12.83) = 135.09^\circ \)

\[ \frac{DC}{\sin(12.83)} = \frac{AC}{\sin(135.09)} \]

Substitute \( AC = 6.2 \):

\[ \frac{DC}{\sin(12.83)} = \frac{6.2}{\sin(135.09)} \] \[ DC = \frac{6.2 \times \sin(12.83)}{\sin(135.09)} \] \[ DC = \frac{6.2 \times 0.222…}{0.706…} \] \[ DC = 1.951… \]

✓ (P1) for sine rule setup

✓ (A1) for 1.95 cm (3 s.f.)

Pick two points on your tangent line to calculate \( \frac{\text{Change in y}}{\text{Change in x}} \).

Example points from tangent:

• Point 1: \( (4, 4) \)
• Point 2: \( (8, 18) \)

Change in distance (y) = \( 18 – 4 = 14 \text{ m} \)

Change in time (x) = \( 8 – 4 = 4 \text{ s} \)

\[ \text{Speed} = \frac{14}{4} = 3.5 \text{ m/s} \]

(Acceptable range is typically 3.05 to 3.7)

✓ (M1) for method to find gradient (change in y / change in x)

✓ (A1) for answer in range 3.05 – 3.7

Sequence: -1, 0, 3, 8, 15

1st Diff: +1, +3, +5, +7

2nd Diff: +2, +2, +2

Since the second difference is constant (2), it is a quadratic sequence (\( an^2 \)).

Coefficient of \( n^2 \) is half the second difference: \( \frac{2}{2} = 1 \).

So the sequence starts with \( n^2 \).

✓ (M1) for deducing \( n^2 \)

n	1	2	3	4	5
Sequence	-1	0	3	8	15
\( n^2 \)	1	4	9	16	25
Difference	-2	-4	-6	-8	-10

The difference sequence is: -2, -4, -6, -8, -10

This is the \( -2n \) times table.

So the full expression is \( n^2 – 2n \).

✓ (A1)

\[ p^4 = \frac{16}{81} \]

To find \( p \), take the 4th root:

\[ p = \sqrt[4]{\frac{16}{81}} \] \[ p = \frac{\sqrt[4]{16}}{\sqrt[4]{81}} \] \[ p = \frac{2}{3} \]

So \( P(H) = \frac{2}{3} \).

✓ (M1) for finding probability of heads (2/3)

\[ P(T) = 1 – \frac{2}{3} = \frac{1}{3} \]

We need \( P(T, T, T, T) = (\frac{1}{3})^4 \).

\[ (\frac{1}{3})^4 = \frac{1^4}{3^4} = \frac{1}{81} \]

✓ (A1)

Top Left: \( 7x – 14 = 7(x – 2) \)

Bottom Left: \( x^2 + 4x – 12 = (x + 6)(x – 2) \)

Top Right: \( x – 6 \) (Cannot factorise)

Bottom Right: \( x^3 – 36x = x(x^2 – 36) = x(x + 6)(x – 6) \)

✓ (M1) for factorising numerator/denominator of 1st fraction

✓ (M1) for factorising denominator of 2nd fraction

\[ \frac{7(x – 2)}{(x + 6)(x – 2)} \times \frac{x(x + 6)(x – 6)}{x – 6} \]

✓ (M1) for multiplication by reciprocal

Cancel terms present in both top and bottom:

• \( (x – 2) \) cancels with \( (x – 2) \)
• \( (x + 6) \) cancels with \( (x + 6) \)
• \( (x – 6) \) cancels with \( (x – 6) \)

Remaining terms:

\[ 7 \times x = 7x \]

So \( a = 7 \).

✓ (A1) for 7x

\[ 56.8 = \frac{1}{3} \times \pi \times r^2 \times 3.6 \]

Simplify:

\[ 56.8 = 1.2 \pi r^2 \] \[ r^2 = \frac{56.8}{1.2 \pi} \] \[ r^2 \approx 15.066… \] \[ r \approx 3.881… \text{ cm} \]

✓ (P1) for finding base radius r

\[ l^2 = r^2 + h^2 \] \[ l^2 = 15.066… + 3.6^2 \] \[ l^2 = 15.066… + 12.96 = 28.026… \] \[ l = \sqrt{28.026…} \approx 5.294… \text{ cm} \]

This \( l \) is the radius of the large sector.

✓ (P1) for finding slant height l

Circumference of cone base = \( 2 \pi r \)

\[ C = 2 \times \pi \times 3.881… \]

Arc Length of Sector = \( \frac{\theta}{360} \times 2 \pi L \)

(where L is the slant height/sector radius)

Set them equal:

\[ 2 \pi (3.881…) = \frac{\theta}{360} \times 2 \pi (5.294…) \]

Divide both sides by \( 2 \pi \):

\[ 3.881… = \frac{\theta}{360} \times 5.294… \]

✓ (P1) for setting up equation linking arc length and circumference

\[ \frac{\theta}{360} = \frac{3.881…}{5.294…} \] \[ \theta = \frac{3.881…}{5.294…} \times 360 \] \[ \theta \approx 263.92…^\circ \]

Round to 3 significant figures.

✓ (A1) for answer in range 263.9 – 264.1

Point P: \( P \) lies on \( OX \) in ratio 1:2.

\( \overrightarrow{OP} = \frac{1}{3} \overrightarrow{OX} = \frac{1}{3}\mathbf{a} \)

Point R: \( R \) lies on \( OY \) in ratio 1:3.

\( \overrightarrow{OR} = \frac{1}{4} \overrightarrow{OY} = \frac{1}{4}\mathbf{b} \)

✓ (P1) for finding OP or OR

Vector \( \overrightarrow{ZP} \):

\( \overrightarrow{ZP} = \overrightarrow{ZO} + \overrightarrow{OP} \)

\( \overrightarrow{ZO} = -(\mathbf{b} – \mathbf{a}) = \mathbf{a} – \mathbf{b} \)

\( \overrightarrow{ZP} = (\mathbf{a} – \mathbf{b}) + \frac{1}{3}\mathbf{a} = \frac{4}{3}\mathbf{a} – \mathbf{b} \)

Vector \( \overrightarrow{ZR} \):

\( \overrightarrow{ZR} = \overrightarrow{ZO} + \overrightarrow{OR} \)

\( \overrightarrow{ZR} = (\mathbf{a} – \mathbf{b}) + \frac{1}{4}\mathbf{b} = \mathbf{a} – \frac{3}{4}\mathbf{b} \)

✓ (P1) for finding ZP or ZR

Let’s factorise both vectors to see the relationship.

\( \overrightarrow{ZP} = \frac{4}{3}\mathbf{a} – \mathbf{b} = \frac{1}{3}(4\mathbf{a} – 3\mathbf{b}) \)

\( \overrightarrow{ZR} = \mathbf{a} – \frac{3}{4}\mathbf{b} = \frac{1}{4}(4\mathbf{a} – 3\mathbf{b}) \)

Both vectors are multiples of \( (4\mathbf{a} – 3\mathbf{b}) \), which means \( Z, P, R \) are collinear.

Ratio ZP : ZR

\( \frac{1}{3} : \frac{1}{4} \)

Multiply by 12 to remove fractions:

\( 4 : 3 \)

✓ (P1) for writing vectors as multiples

✓ (A1) for 4:3