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GCSE November 2021 Edexcel Higher Paper 1 (Non-Calculator)
Table of Contents
- Question 1 (Arithmetic)
- Question 2 (Venn Diagrams)
- Question 3 (Fractions)
- Question 4 (Percentages)
- Question 5 (Ratio)
- Question 6 (Prisms & Volume)
- Question 7 (Surface Area)
- Question 8 (Quadratics)
- Question 9 (Indices)
- Question 10 (Estimation)
- Question 11 (Algebraic Expressions)
- Question 12 (Cumulative Frequency)
- Question 13 (Recurring Decimals)
- Question 14 (Algebraic Area)
- Question 15 (Algebraic Fractions)
- Question 16 (Probability)
- Question 17 (Inequalities)
- Question 18 (Trapezium & Ratio)
- Question 19 (Surds)
- Question 20 (Graphs & Equations)
- Question 21 (Functions)
- Question 22 (Completing the Square)
Question 1 (6 marks)
(a) Work out \( 3.67 \times 4.2 \)
(b) Work out \( 59.84 \div 1.6 \)
Worked Solution
Part (a): Multiplication
Step 1: Ignore decimals temporarily
To make the multiplication easier, we remove the decimal points. We can put them back at the end.
We need to calculate \( 367 \times 42 \).
We can use long multiplication (column method):
367 x 42 ----- 734 (367 × 2) 14680 (367 × 40) ----- 15414
Step 2: Replace the decimal points
Count the total decimal places in the original question:
- \( 3.67 \) has 2 decimal places.
- \( 4.2 \) has 1 decimal place.
- Total = 3 decimal places.
We place the decimal point in our answer so it has 3 decimal places.
✓ (3 marks)
Part (b): Division
Step 1: Adjust to divide by a whole number
It is difficult to divide by a decimal like \( 1.6 \). We can multiply both numbers by 10 to make the divisor a whole number (16).
Step 2: Perform division (Bus Stop Method)
Now we divide \( 598.4 \) by \( 16 \).
037.4
───────
16 │598.4
-48
---
118
-112 (16 × 7)
----
6 4
-6 4 (16 × 4)
----
0
✓ (3 marks)
Final Answer:
(a) \( 15.414 \)
(b) \( 37.4 \)
Question 2 (3 marks)
\( \mathscr{E} = \{ \text{even numbers less than 19} \} \)
\( A = \{6, 12, 18\} \)
\( B = \{2, 6, 14, 18\} \)
Complete the Venn diagram for this information.
Worked Solution
Step 1: List all elements in the Universal Set
What are we including?
The universal set \( \mathscr{E} \) contains all even numbers strictly less than 19.
Step 2: Identify the Intersection
Find numbers in both lists
Look at sets A and B to see which numbers appear in both.
\( A = \{\mathbf{6}, 12, \mathbf{18}\} \)
\( B = \{2, \mathbf{6}, 14, \mathbf{18}\} \)
Intersection \( A \cap B = \{6, 18\} \)
These go in the middle overlapping section.
Step 3: Fill the remaining sections
Remaining parts of A: Numbers in A that are not in the intersection.
\( \{12\} \) goes in the left circle only.
Remaining parts of B: Numbers in B that are not in the intersection.
\( \{2, 14\} \) go in the right circle only.
Outside the circles: Numbers in \( \mathscr{E} \) that are not in A or B.
Used: \( \{2, 6, 12, 14, 18\} \)
Leftover: \( \{4, 8, 10, 16\} \)
Completed Diagram
Question 3 (3 marks)
Work out \( 4\frac{1}{5} – 2\frac{2}{3} \)
Give your answer as a mixed number.
Worked Solution
Step 1: Convert to Improper Fractions
Why do this?
Subtracting mixed numbers can be messy if the fractional part of the second number is larger than the first. Improper fractions avoid this.
The sum becomes: \( \frac{21}{5} – \frac{8}{3} \)
Step 2: Find a Common Denominator
We need a number divisible by both 5 and 3. The lowest common multiple is 15.
Step 3: Subtract and Simplify
Now convert back to a mixed number:
\[ 23 \div 15 = 1 \text{ remainder } 8 \] \[ \frac{23}{15} = 1\frac{8}{15} \]Final Answer:
\( 1\frac{8}{15} \)
✓ (3 marks)
Question 4 (4 marks)
At the end of 2017
- the value of Tamara’s house was £220,000
- the value of Rahim’s house was £160,000
At the end of 2019
- the value of Tamara’s house had decreased by 20%
- the value of Rahim’s house had increased by 30%
At the end of 2019, whose house had the greater value?
You must show how you get your answer.
Worked Solution
Step 1: Calculate Tamara’s New Value
Decrease by 20%
We can find 10% first, then 20%, and subtract it.
Original Value: £220,000
220000 - 44000 ------- 176000
Tamara’s house is now £176,000.
Step 2: Calculate Rahim’s New Value
Increase by 30%
We can find 10% first, then 30%, and add it.
Original Value: £160,000
160000 + 48000 ------- 208000
Rahim’s house is now £208,000.
Step 3: Compare and Conclude
Tamara: £176,000
Rahim: £208,000
Rahim’s house has the greater value.
Final Answer:
Rahim (£208,000 is greater than £176,000)
✓ (4 marks)
Question 5 (3 marks)
Rosie, Matilda and Ibrahim collect stickers.
\( \text{Rosie} : \text{Matilda} : \text{Ibrahim} = 4 : 7 : 15 \)
Ibrahim has 24 more stickers than Matilda.
Ibrahim has more stickers than Rosie.
How many more?
Worked Solution
Step 1: Use the difference to find the value of one part
What do we know?
Ibrahim has 15 parts and Matilda has 7 parts.
The difference in stickers is 24.
We know these 8 parts represent 24 stickers.
\[ 1 \text{ part} = 24 \div 8 = 3 \text{ stickers} \]Step 2: Calculate difference between Ibrahim and Rosie
We need to find how many more stickers Ibrahim has than Rosie.
Ibrahim: 15 parts
Rosie: 4 parts
Since 1 part = 3 stickers:
\[ \text{Difference} = 11 \times 3 = 33 \text{ stickers} \]Final Answer:
33
✓ (3 marks)
Question 6 (3 marks)
The diagram shows a prism.
The cross section of the prism is a right-angled triangle.
The base of the triangle has length \( 5 \text{ cm} \).
The prism has length \( 25 \text{ cm} \).
The prism has volume \( 750 \text{ cm}^3 \).
Work out the height of the prism.
Worked Solution
Step 1: Understand the Volume Formula
What is the formula for a prism?
\[ \text{Volume} = \text{Area of Cross Section} \times \text{Length} \]
We know the Volume (\(750\)) and the Length (\(25\)). We need to find the Area of the Cross Section first.
Step 2: Calculate Area of Cross Section
Divide 750 by 25
We know that \( 25 \times 3 = 75 \), so \( 25 \times 30 = 750 \).
Step 3: Use Area to find Height
Area of a Triangle
The cross section is a right-angled triangle.
\[ \text{Area} = \frac{1}{2} \times \text{base} \times \text{height} \]
We know Area = 30 and base = 5.
Multiply both sides by 2 to clear the fraction:
\[ 60 = 5 \times h \] \[ h = \frac{60}{5} \] \[ h = 12 \]Final Answer:
\( 12 \text{ cm} \)
✓ (3 marks)
Question 7 (4 marks)
The diagram shows a cube with edges of length \( x \text{ cm} \) and a sphere of radius \( 3 \text{ cm} \).
The surface area of the cube is equal to the surface area of the sphere.
Show that \( x = \sqrt{k\pi} \) where \( k \) is an integer.
Worked Solution
Step 1: Find the Surface Area of the Sphere
Use the given formula
Radius \( r = 3 \).
Formula: \( A = 4\pi r^2 \)
Step 2: Find the Surface Area of the Cube
Cube Properties
A cube has 6 identical square faces.
Each face has side length \( x \), so area of one face is \( x^2 \).
Step 3: Equate and Solve for x
We are told the surface areas are equal.
Divide by 6:
\[ x^2 = \frac{36\pi}{6} \] \[ x^2 = 6\pi \]Square root both sides:
\[ x = \sqrt{6\pi} \]Step 4: Identify k
The question asks for the form \( \sqrt{k\pi} \).
Comparing \( \sqrt{6\pi} \) with \( \sqrt{k\pi} \), we can see that:
\[ k = 6 \]Result Shown: \( x = \sqrt{6\pi} \)
✓ (4 marks)
Question 8 (3 marks)
Solve \( x^2 = 5x + 24 \)
Worked Solution
Step 1: Rearrange into Standard Form
Get equation equal to zero
Subtract \( 5x \) and \( 24 \) from both sides to get \( ax^2 + bx + c = 0 \).
Step 2: Factorise the Quadratic
Find two numbers
We need two numbers that:
- Multiply to make \( -24 \)
- Add to make \( -5 \)
Pairs for 24: (1, 24), (2, 12), (3, 8), (4, 6).
To get \( -5 \), we use \( -8 \) and \( +3 \).
\( -8 \times 3 = -24 \) and \( -8 + 3 = -5 \).
Step 3: Solve for x
Either bracket could be zero.
If \( x – 8 = 0 \), then \( x = 8 \)
If \( x + 3 = 0 \), then \( x = -3 \)
Final Answer:
\( x = 8 \) and \( x = -3 \)
✓ (3 marks)
Question 9 (4 marks)
(a) Write down the value of \( 7^0 \)
(b) Find the value of \( 3 \times 3^6 \times 3^{-6} \)
(c) Find the value of \( 2^{-4} \)
(d) Find the value of \( 27^{\frac{1}{3}} \)
Worked Solution
Part (a)
Rule: Any non-zero number to the power of 0 is 1.
Part (b)
Rule: When multiplying terms with the same base, add the powers.
Remember that \( 3 \) is the same as \( 3^1 \).
Part (c)
Rule: A negative power means the reciprocal (1 over).
\[ x^{-n} = \frac{1}{x^n} \]
Part (d)
Rule: A fractional power \( \frac{1}{n} \) means the \( n \)-th root.
\[ x^{\frac{1}{3}} = \sqrt[3]{x} \]
What number multiplied by itself 3 times gives 27?
\( 3 \times 3 \times 3 = 27 \)
\[ = 3 \]Final Answers:
(a) \( 1 \)
(b) \( 3 \)
(c) \( \frac{1}{16} \)
(d) \( 3 \)
Question 10 (4 marks)
The diagram shows a shape made from 6 identical squares.
The total area of the shape is \( 5406 \text{ cm}^2 \).
(a) Find an estimate for the length of one side of each square.
Give your answer correct to the nearest whole number.
(b) Is your answer to part (a) an underestimate or an overestimate?
You must give a reason for your answer.
Worked Solution
Part (a): Estimation
Step 1: Estimate the Total Area
The area is \( 5406 \). We need a number that is easy to divide by 6.
\( 54 \) is a multiple of \( 6 \), so \( 5400 \) is a good estimate.
Step 2: Find Area of One Square
There are 6 identical squares.
Step 3: Find Side Length
Area of square = \( \text{side}^2 \).
Part (b): Error Analysis
Reasoning
We rounded the area down from 5406 to 5400.
This means our calculation used a smaller number than the real one.
Underestimate.
Because I rounded the total area down (\( 5400 < 5406 \)), the resulting side length is slightly smaller than the actual value.
Final Answer:
(a) \( 30 \text{ cm} \)
(b) Underestimate (with reason)
✓ (4 marks)
Question 11 (4 marks)
The diagram shows two rectangles, A and B.
All measurements are in centimetres.
The area of rectangle A is equal to the area of rectangle B.
Find an expression for \( y \) in terms of \( w \).
Worked Solution
Step 1: Form Expressions for Area
Area = length × width
Area of A: \( 6(2w + y) \)
Area of B: \( 7w(3y + 6) \)
Step 2: Equate and Expand
We are told the areas are equal.
Expand the brackets:
\[ 12w + 6y = 21wy + 42w \]Step 3: Isolate Terms with y
We need \( y \) as the subject. Move all terms containing \( y \) to one side and others to the other side.
Simplify the right side:
\[ 6y – 21wy = 30w \]Step 4: Factorise and Divide
Factor out \( y \) on the left side.
Divide by the bracket to get \( y \) alone:
\[ y = \frac{30w}{6 – 21w} \]Note: You can also simplify by dividing top and bottom by 3:
\[ y = \frac{10w}{2 – 7w} \]Final Answer:
\( y = \frac{30w}{6 – 21w} \) or \( y = \frac{10w}{2 – 7w} \)
✓ (4 marks)
Question 12 (3 marks)
The cumulative frequency table gives information about the heights, in cm, of 40 plants.
| Height (\(h\) cm) | Cumulative Frequency |
|---|---|
| \( 0 < h \leq 5 \) | 4 |
| \( 0 < h \leq 10 \) | 11 |
| \( 0 < h \leq 15 \) | 24 |
| \( 0 < h \leq 20 \) | 34 |
| \( 0 < h \leq 25 \) | 38 |
| \( 0 < h \leq 30 \) | 40 |
(a) On the grid, draw a cumulative frequency graph for this information.
(b) Use the graph to find an estimate for the median height of the plants.
Worked Solution
Part (a): Plotting the Graph
Rules for Cumulative Frequency Graphs:
- Plot points at the upper bound of each interval.
- Points: \((5, 4), (10, 11), (15, 24), (20, 34), (25, 38), (30, 40)\).
- Join with a smooth curve starting from \((0, 0)\).
Part (b): Finding the Median
Step 1: Locate Median Position
Median position = \( \frac{1}{2} \times \text{Total Frequency} \).
\( \frac{1}{2} \times 40 = 20 \).
Step 2: Read from Graph
Go to 20 on the vertical axis (Cumulative Frequency). Go across to the curve, then down to the horizontal axis.
Reading from the graph at CF = 20 gives approximately \( 13.5 \text{ cm} \).
Final Answer:
(b) \( 13 \text{ to } 14 \text{ cm} \)
✓ (3 marks)
Question 13 (1 mark)
Ted is trying to change \( 0.4\dot{3} \) to a fraction.
Here is the start of his method:
\( x = 0.4\dot{3} \)
\( 10x = 4.3\dot{4} \)
\( 10x – x = 4.3\dot{4} – 0.4\dot{3} \)
Evaluate Ted’s method so far.
Worked Solution
Analyzing the Error
What went wrong?
Ted’s goal is to eliminate the recurring decimal part.
- \( x = 0.43333… \)
- \( 10x = 4.3333… \)
If he subtracts \( 10x – x \), he gets:
\( 4.333… – 0.433… \)
The decimal parts do not match perfectly at the start (\( .333 \) vs \( .433 \)).
He needs to multiply by a power of 10 that moves the non-recurring part past the decimal point, and another to align the recurring part.
Correct Method would be:
\( 10x = 4.333… \)
\( 100x = 43.333… \)
Then \( 100x – 10x = 43.33… – 4.33… \)
This eliminates the recurring decimal.
Evaluation:
Ted’s method is flawed because the decimal parts of \( 10x \) and \( x \) are not the same, so subtracting them does not eliminate the recurring part.
✓ (1 mark)
Question 14 (3 marks)
Here is a shape with all its measurements in centimetres.
The area of the shape is \( A \text{ cm}^2 \).
Show that \( A = 2x^2 + 24x + 46 \).
Worked Solution
Step 1: Split the Shape
Split into two rectangles.
Option 1: Vertical split.
- Rectangle 1 (Left): Width \( x + 1 \), Height \( x + 11 \).
- Rectangle 2 (Right): Need dimensions.
Total Width = \( 2x + 6 \). Width of Left = \( x + 1 \).
Width of Right = \( (2x + 6) – (x + 1) = x + 5 \).
Height of Right: The top indent is 4 down from top of left? No, look at the diagram. The side labelled 4 is the vertical drop.
Height of Right = Total Height (\( x + 11 \)) – Top Step (4) = \( x + 7 \).
Wait, looking at the diagram, the side length 4 is vertical. So the right rectangle has height \( x + 11 – 4 = x + 7 \) if splitting horizontally? Or is 4 horizontal?
Let’s look at the labels again. The “4” is next to the vertical drop. So the height of the right section is \( (x+11) – 4 = x + 7 \)?? No, let’s assume vertical split.
Actually, simpler split: Horizontal Split.
- Top Rectangle: Width \( x + 1 \), Height \( 4 \). (Wait, is 4 the height? The label is vertical). Let’s assume the vertical segment is 4.
- If the vertical segment is 4, then the top-left part is higher.
Let’s try standard decomposition:
Large Rectangle – Missing Corner
Total Width: \( 2x + 6 \)
Total Height: \( x + 11 \)
Area of Large = \( (2x + 6)(x + 11) \)
Missing Rectangle (Top Right):
Width = \( (2x + 6) – (x + 1) = x + 5 \)
Height = 4.
Subtract Area: \( 4(x + 5) \).
Area = Total Rectangle – Missing Piece
\[ A = (2x + 6)(x + 11) – 4(x + 5) \]Step 2: Expand and Simplify
Expand \( (2x + 6)(x + 11) \):
\[ 2x(x) + 2x(11) + 6(x) + 6(11) \] \[ = 2x^2 + 22x + 6x + 66 \] \[ = 2x^2 + 28x + 66 \]Expand \( 4(x + 5) \):
\[ 4x + 20 \]Subtract:
\[ (2x^2 + 28x + 66) – (4x + 20) \] \[ = 2x^2 + 28x – 4x + 66 – 20 \] \[ = 2x^2 + 24x + 46 \]Result Shown:
\( A = 2x^2 + 24x + 46 \)
✓ (3 marks)
Question 15 (3 marks)
Show that \( \frac{4x+3}{2x} + \frac{3}{5} \) can be written in the form \( \frac{ax+b}{cx} \) where \( a, b \) and \( c \) are integers.
Worked Solution
Step 1: Find a Common Denominator
The denominators are \( 2x \) and \( 5 \).
Common denominator = \( 2x \times 5 = 10x \).
Step 2: Combine and Simplify
Expand the numerator:
\[ 5(4x+3) = 20x + 15 \] \[ \text{Numerator} = 20x + 15 + 6x \] \[ = 26x + 15 \]Step 3: Final Format
This matches the form \( \frac{ax+b}{cx} \) where \( a=26, b=15, c=10 \).
Final Answer:
\( \frac{26x + 15}{10x} \)
✓ (3 marks)
Question 16 (4 marks)
There are only 3 red counters and 5 yellow counters in a bag.
Jude takes at random 3 counters from the bag.
Work out the probability that he takes exactly one red counter.
Worked Solution
Step 1: Identify Total Counters and Setup
Totals
Red = 3, Yellow = 5.
Total = 8 counters.
Selection
He picks 3 counters without replacement (implied by “takes 3 counters”).
Step 2: List Winning Combinations
We want exactly one red.
This means 1 Red and 2 Yellows.
Possible orders:
- Red, Yellow, Yellow (RYY)
- Yellow, Red, Yellow (YRY)
- Yellow, Yellow, Red (YYR)
Step 3: Calculate Probability for Each Case
Case 1: R Y Y
\[ P(R) = \frac{3}{8} \] \[ P(Y|R) = \frac{5}{7} \text{ (one less counter)} \] \[ P(Y|RY) = \frac{4}{6} \text{ (two less counters)} \] \[ P(RYY) = \frac{3}{8} \times \frac{5}{7} \times \frac{4}{6} = \frac{60}{336} \]Case 2: Y R Y
\[ P(YRY) = \frac{5}{8} \times \frac{3}{7} \times \frac{4}{6} = \frac{60}{336} \]Case 3: Y Y R
\[ P(YYR) = \frac{5}{8} \times \frac{4}{7} \times \frac{3}{6} = \frac{60}{336} \]Step 4: Sum Probabilities and Simplify
Simplify fraction (divide by 12):
\[ 180 \div 12 = 15 \] \[ 336 \div 12 = 28 \] \[ = \frac{15}{28} \]Final Answer:
\( \frac{15}{28} \)
✓ (4 marks)
Question 17 (3 marks)
On the grid show, by shading, the region that satisfies all of these inequalities.
\[ 2y + 4 < x \]
\[ x < 3 \]
\[ y < 6 - 3x \]
Label the region R.
Worked Solution
Step 1: Convert Inequalities to Lines
Line 1: \( 2y + 4 = x \)
Rearrange for y: \( 2y = x – 4 \implies y = \frac{1}{2}x – 2 \).
Intercept: -2. Gradient: 0.5.
Points: (0, -2), (4, 0).
Line 2: \( x = 3 \)
Vertical line passing through x = 3.
Line 3: \( y = 6 – 3x \)
Intercept: 6. Gradient: -3.
Points: (0, 6), (2, 0).
Step 2: Draw Lines and Identify Region
Since the inequalities are strictly \( < \), we draw dashed lines.
Testing Region:
- \( 2y + 4 < x \): Region "below/right" line 1. (Test (0,0): \( 4 < 0 \) False. So shade away from origin, or region is where (0,0) isn't).
- \( x < 3 \): Region left of line 2.
- \( y < 6 - 3x \): Region below line 3. (Test (0,0): \( 0 < 6 \) True. So (0,0) is in this region).
We need the region that satisfies all three.
Note: The region R is the area below both diagonal lines and to the left of the vertical line.
Answer: Region shaded on grid.
✓ (3 marks)
Question 18 (5 marks)
Here is trapezium \( ABCD \).
The area of the trapezium is \( 66 \text{ cm}^2 \).
The length of \( AB \) : the length of \( CD \) = \( 2 : 3 \).
Find the length of \( AB \).
Worked Solution
Step 1: Find the Height of the Trapezium
Use Trigonometry
Drop a perpendicular from B to line CD. Let’s call the point on CD “M”.
Triangle BMC is a right-angled triangle.
- Hypotenuse \( BC = 6 \).
- Angle \( C = 30^\circ \).
- Height \( h = BM \) is the opposite side.
\( \sin(30^\circ) = \frac{h}{6} \)
We know \( \sin(30^\circ) = 0.5 \).
\[ h = 6 \times \sin(30^\circ) = 6 \times 0.5 = 3 \text{ cm} \]Step 2: Set up Algebra for Parallel Sides
Use the Ratio
\( AB : CD = 2 : 3 \)
Let \( AB = 2x \) and \( CD = 3x \).
Step 3: Use the Area Formula
Area of Trapezium
\[ \text{Area} = \frac{1}{2}(a + b)h \]
Here \( a = 2x \), \( b = 3x \), \( h = 3 \), Area = 66.
Multiply by 2:
\[ 132 = 15x \] \[ x = \frac{132}{15} \]Step 4: Solve for x and find AB
Simplify fraction (divide by 3):
\[ x = \frac{44}{5} = 8.8 \]We need length of \( AB = 2x \).
\[ AB = 2 \times 8.8 = 17.6 \text{ cm} \]Final Answer:
\( 17.6 \text{ cm} \)
✓ (5 marks)
Question 19 (4 marks)
Show that \( \frac{8 + \sqrt{12}}{5 + \sqrt{3}} \) can be written in the form \( \frac{a + \sqrt{3}}{b} \), where \( a \) and \( b \) are integers.
Worked Solution
Step 1: Simplify the Surd
Simplify \( \sqrt{12} \).
\( \sqrt{12} = \sqrt{4 \times 3} = 2\sqrt{3} \).
Step 2: Rationalise the Denominator
Multiply top and bottom by \( 5 – \sqrt{3} \).
Step 3: Expand Brackets
Numerator:
\[ 8(5) – 8(\sqrt{3}) + 2\sqrt{3}(5) – 2\sqrt{3}(\sqrt{3}) \] \[ = 40 – 8\sqrt{3} + 10\sqrt{3} – 2(3) \] \[ = 40 + 2\sqrt{3} – 6 \] \[ = 34 + 2\sqrt{3} \]Denominator:
\[ 5^2 – (\sqrt{3})^2 = 25 – 3 = 22 \]Step 4: Simplify Fraction
Divide everything by 2:
\[ \frac{17 + \sqrt{3}}{11} \]This matches the form \( \frac{a + \sqrt{3}}{b} \) with \( a=17, b=11 \).
Result Shown:
\( \frac{17 + \sqrt{3}}{11} \)
✓ (4 marks)
Question 20 (3 marks)
The diagram shows the graph of \( x^2 + y^2 = 30.25 \).
Use the graph to find estimates for the solutions of the simultaneous equations
\( x^2 + y^2 = 30.25 \)
\( y – 2x = 1 \)
Worked Solution
Step 1: Plot the Line
Draw the line \( y – 2x = 1 \)
Rearrange: \( y = 2x + 1 \).
Find points:
- If \( x = 0 \), \( y = 1 \). Point (0, 1).
- If \( x = 2 \), \( y = 5 \). Point (2, 5).
- If \( x = -2 \), \( y = -3 \). Point (-2, -3).
Draw a straight line through these points on the graph.
Step 2: Read Intersections
Identify where the line crosses the circle.
Point 1 (Top Right):
\( x \approx 2.1 \), \( y \approx 5.1 \)
Point 2 (Bottom Left):
\( x \approx -2.9 \), \( y \approx -4.7 \)
Final Answer:
\( x = 2.1, y = 5.1 \)
\( x = -2.9, y = -4.7 \)
✓ (3 marks)
Question 21 (6 marks)
The functions \( f \) and \( g \) are such that
\[ f(x) = 3x^2 + 1 \quad \text{for } x > 0 \quad \text{and} \quad g(x) = \frac{4}{x^2} \quad \text{for } x > 0 \]
(a) Work out \( gf(1) \)
The function \( h \) is such that \( h = (fg)^{-1} \)
(b) Find \( h(x) \)
Worked Solution
Part (a): Composite Function gf(1)
Order of Operations
\( gf(1) \) means \( g(f(1)) \). We calculate \( f(1) \) first, then put the result into \( g \).
Step 1: Find f(1)
\[ f(1) = 3(1)^2 + 1 \] \[ = 3(1) + 1 = 4 \]Step 2: Find g(4)
Now substitute 4 into \( g(x) \):
\[ g(4) = \frac{4}{4^2} \] \[ = \frac{4}{16} \] \[ = \frac{1}{4} \]Part (b): Inverse of Composite Function
Step 1: Find fg(x)
\( fg(x) \) means \( f(g(x)) \). We substitute \( g(x) \) into \( f(x) \).
\( f(x) = 3x^2 + 1 \), so replace \( x \) with \( \frac{4}{x^2} \).
Step 2: Find the Inverse
Let \( y = \frac{48}{x^4} + 1 \). Rearrange to make \( x \) the subject.
Subtract 1:
\[ y – 1 = \frac{48}{x^4} \]Multiply by \( x^4 \):
\[ x^4(y – 1) = 48 \]Divide by \( (y – 1) \):
\[ x^4 = \frac{48}{y – 1} \]Take the fourth root:
\[ x = \sqrt[4]{\frac{48}{y – 1}} \]Step 3: Format Final Answer
Replace \( y \) with \( x \) for the function notation \( h(x) \).
\[ h(x) = \sqrt[4]{\frac{48}{x – 1}} \]Final Answer:
(a) \( \frac{1}{4} \)
(b) \( \sqrt[4]{\frac{48}{x – 1}} \)
✓ (6 marks)
Question 22 (4 marks)
Find the coordinates of the turning point on the curve with equation \( y = 9 + 18x – 3x^2 \)
You must show all your working.
Worked Solution
Step 1: Rearrange and Factorise
Completing the Square
First, write the terms in descending order of powers of \( x \).
\( y = -3x^2 + 18x + 9 \)
Factor out the coefficient of \( x^2 \) (which is -3) from the first two terms.
Step 2: Complete the Square Inside the Bracket
For \( x^2 – 6x \):
Halve the coefficient of \( x \) (-6 becomes -3).
\( (x – 3)^2 = x^2 – 6x + 9 \).
So, \( x^2 – 6x = (x – 3)^2 – 9 \).
Substitute this back into our equation:
\[ y = -3[ (x – 3)^2 – 9 ] + 9 \]Step 3: Expand and Simplify
Expand the outer square bracket by multiplying by -3:
\[ y = -3(x – 3)^2 + (-3 \times -9) + 9 \] \[ y = -3(x – 3)^2 + 27 + 9 \] \[ y = -3(x – 3)^2 + 36 \]Step 4: Identify Turning Point
The vertex form is \( y = a(x – h)^2 + k \).
The turning point is at \( (h, k) \).
Here, we have \( (x – 3)^2 \), so \( h = 3 \).
The constant is \( +36 \), so \( k = 36 \).
Turning Point = \( (3, 36) \)
Final Answer:
\( (3, 36) \)
✓ (4 marks)