Grade 7 Mathematics

Your complete companion to Grade 7 Math

Every unit has an instructional video, worked examples, printable practice and extension worksheets, and a levelled interactive quiz. Choose a unit from the sidebar to get started.

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Watch the Video
Start each unit by watching the concept video before working through examples.
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Study Examples
Work through the step-by-step examples before trying questions on your own.
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Print & Practise
Print practice worksheets to strengthen your skills, or tackle extension questions for a challenge.
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Take the Quiz
Test your knowledge with a 10+ question levelled quiz and get instant feedback.
⬢ Level 1 — Foundational
Core skills with guided practice. Build confidence here first.
⬢ Level 2 — Developing
Apply skills in slightly more complex situations.
⬢ Level 3 — Proficient
Multi-step problems and word problems with real context.
⬢ Level 4 — Extending
Challenging extensions that go beyond the expected standard.
1

Number Sense & Place Value

Place value, divisibility rules, prime & composite numbers, prime factorization, GCF and LCM — the building blocks of all number work in Grade 7.

Big Ideas

  • Every digit in a whole number has a specific place value — changing one digit can dramatically change the overall value.
  • Divisibility rules are patterns and shortcuts rooted in the structure of our base-ten number system.
  • Every whole number greater than 1 is either prime (exactly 2 factors) or composite (more than 2 factors).
  • Prime factorization gives every composite number a unique set of building blocks.
  • GCF and LCM connect number sense to real-world situations including sharing, scheduling, and design.
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Place Value
Reading, writing, ordering and rounding whole numbers up to 7 digits using standard, expanded, and word forms.
Divisibility
Divisibility rules for 2, 3, 4, 5, 6, 9, and 10 — shortcuts rooted in our base-ten system.
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Prime & Composite
Identifying prime and composite numbers, building factor trees, and writing prime factorizations.
GCF & LCM
Finding the greatest common factor and least common multiple and applying them to real-world problems.
How to use this page: Work through place value first, then divisibility rules, then primes and factorization — GCF and LCM build on all three.
1
Place Value
Find the value of the underlined digit in 4703 821.
1
Write out the place value columns: 4 millions | 7 hundred-thousands | 0 ten-thousands…
2
The underlined digit 7 sits in the hundred-thousands column.
3
Value = 7 × 100 000 = 700 000
Answer: 700 000
2
Divisibility Rules
Is 7 236 divisible by 9? Show the digit-sum check.
1
Add all digits: 7 + 2 + 3 + 6 = 18
2
Is 18 divisible by 9? 18 ÷ 9 = 2 ✓ Yes.
3
Therefore 7 236 is divisible by 9.
Answer: Yes — digit sum 18 is divisible by 9
3
Prime Factorization
Write the prime factorization of 48 using exponents.
1
Build a factor tree: 48 = 2 × 24 = 2 × 2 × 12 = 2 × 2 × 2 × 6 = 2 × 2 × 2 × 2 × 3
2
Count the 2s: four 2s and one 3.
3
Write with exponents: 2⁴ × 3
Answer: 48 = 2⁴ × 3
4
Finding GCF
Find GCF(24, 36) using prime factorization.
1
24 = 2³ × 3 and 36 = 2² × 3²
2
Take the lowest power of each shared prime factor.
3
Shared: 2 (lowest power 2²) and 3 (lowest power 3¹)
4
GCF = 2² × 3 = 4 × 3 = 12
Answer: GCF(24, 36) = 12
5
Finding LCM
Find LCM(6, 9) using prime factorization.
1
6 = 2 × 3 and 9 = 3²
2
Take the highest power of each prime that appears in either number.
3
Primes involved: 2¹ and 3²
4
LCM = 2 × 9 = 18
Answer: LCM(6, 9) = 18
6
GCF Word Problem
A farmer has 24 red and 36 white flowers. What is the greatest number of identical bouquets she can make using ALL the flowers?
1
"Greatest number of identical bouquets using all flowers" → find GCF.
2
GCF(24, 36) = 12 (from Example 4)
3
Each bouquet: 24÷12 = 2 red, 36÷12 = 3 white flowers.
Answer: 12 bouquets (2 red + 3 white each)
🪶 First Peoples Connection
Cedar baskets made by Coast Salish weavers often use repeating patterns with rows of exactly the same design. If a weaver uses 48 cedar strips and 36 bark strips to create identical rows, GCF(48, 36) = 12 tells her she can make 12 identical rows — each using 4 cedar strips and 3 bark strips. Mathematics supports design decisions that have been part of cultural practice for thousands of years.
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/36

Worked example: In 642 918, the underlined digit is in the ten-thousands place, so its value is 40 000.
  1. Write the value of the underlined digit in 5728 304. L1
  2. Write the value of the underlined digit in 3 064 912. L1
  3. Write 3 045 807 in expanded form. L1
  4. Write 6 000 000 + 400 000 + 20 000 + 90 + 7 in standard form. L1
  5. Order from least to greatest: 2 040 500, 2 400 050, 2 004 500, 2 400 500. L1
  6. Round 4 786 319 to the nearest thousand, ten-thousand, and hundred-thousand. L2
  7. Create a 7-digit number with a 9 in the hundred-thousands place and a 4 in the tens place. Explain your number. L2
  8. A student says 4 507 000 is greater than 4 570 000 because 507 is greater than 57. Explain the error. L3
Worked example: To test 7 236 for divisibility by 9, add the digits: 7+2+3+6=18. Since 18 is divisible by 9, the number is divisible by 9.
  1. Is 4 824 divisible by 4? Show your test. L1
  2. Is 3 531 divisible by 9? Show the digit-sum check. L1
  3. List all divisibility rules that apply to 8 460: 2, 3, 4, 5, 6, 9, or 10. L2
  4. Find one 4-digit number that is divisible by both 3 and 5 but not by 10. L2
  5. A number is divisible by 6. What must be true about the number? Explain using divisibility rules. L2
  6. Fill in the missing digit so 5 3□ 2 is divisible by 9. Are there multiple answers? L3
  7. Create a number that is divisible by 2, 3, 4, 5, and 10. Explain how each rule works. L3
Worked example: 72 can be broken into primes: 72 = 2 × 2 × 2 × 3 × 3 = 2³ × 3².
  1. Is 83 prime or composite? Explain how you checked. L2
  2. List all factors of 36. Then classify 36 as prime or composite. L1
  3. Write the prime factorization of 48 using exponents. L2
  4. Write the prime factorization of 90 using exponents. L2
  5. Draw or describe a factor tree for 120. Write the final prime factorization. L2
  6. A student wrote 45 = 5 × 9 and stopped. Why is this not a complete prime factorization? L2
  7. Find a composite number less than 50 that has exactly three different prime factors. L3
Worked example: For 24 and 36, the greatest shared factor is 12, so GCF(24,36)=12.
  1. Find GCF(30,45). Show your method. L2
  2. Find GCF(42,56). Show your method. L2
  3. Find LCM(8,12). Show your method. L2
  4. Find LCM(6,9,12). Show your method. L3
  5. List the first 8 multiples of 7 and the first 8 multiples of 9. Circle any common multiples. L1
  6. Use prime factorization to find GCF(72,96). L3
  7. Use prime factorization to find LCM(18,24). L3
  8. Explain the difference between GCF and LCM using the words “sharing” and “repeating.” L2
Worked example: “Greatest number of equal groups with no leftovers” usually means GCF. “When will events happen together again?” usually means LCM.
  1. Two school buses leave a depot at 7:00 am. Bus A returns every 15 minutes and Bus B every 20 minutes. When do they next leave together? L3
  2. A woodworker has lengths of cedar measuring 60 cm and 84 cm. What is the longest equal piece length with no waste? How many pieces of each length? L3
  3. Three drummers beat every 4, 6, and 9 seconds. They start together. How many seconds until they all beat together again? L4
  4. Find two numbers whose GCF is 12 and whose LCM is 60. Explain how you know. L4
  5. A class has 24 pencils and 36 erasers. What is the greatest number of identical supply bags that can be made using all items? L3
  6. Design your own GCF or LCM word problem. Solve it and explain why it uses GCF or LCM. L4
🚀 Extension Worksheet Extension

Name: _________________________    Date: _____________

Challenge yourself: These questions require creative thinking, multi-step reasoning, and connections beyond the standard curriculum.
  1. A number N has exactly three distinct prime factors: 2, 3, and 5. The prime factorization includes 2³, 3², and 5¹. What is N? List ALL factors of N.
  2. The GCF of two numbers is 18 and their LCM is 540. One of the numbers is 54. Find the other number. Show algebraic reasoning.
  3. A digital clock shows hours from 1–12. Starting at 12:00, the hour hand has turned exactly 1/3 of a full rotation. What time is shown? What fraction of a full rotation does the hour hand make in 4 hours?
  4. A salmon counting fence records exactly 4 200 salmon in the first week, and the count is divisible by 2, 3, 4, 5, 6, 7, and 10. What is the smallest number of additional salmon that could arrive in Week 2 so the two-week total is also divisible by 11?
  5. Cryptography connection: The RSA encryption system uses products of two large prime numbers as a "public key." Why does using primes make this secure? Research and write a 4–6 sentence explanation connecting prime factorization to digital security.
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Number Detective
Reasoning puzzle
Use number properties as clues to find mystery numbers.
Challenge

I am a 6-digit number. My digits sum to 27. I am divisible by 9 but not 6. My thousands digit is prime. My hundreds digit is twice my units digit. What numbers could I be? Find all possibilities and explain your reasoning.

Stretch

Create your own number puzzle with exactly one solution. Test it on a partner.

Factor Feast
Investigation
Explore which numbers have the most factors and why.
Challenge

List all numbers from 1 to 50 and count how many factors each has. Which number in this range has the most factors? What is special about its prime factorization? Predict: among 51–100, which number will have the most factors?

Discussion

Why do perfect squares have an odd number of factors? Prove it using an example.

GCF/LCM Algebra
Digit puzzle
Use GCF and LCM relationships algebraically.
Challenge

Two numbers have GCF = 12 and LCM = 180. Use exactly the digits 1, 2, 3, 4, 5, 6 (each once) to form two 3-digit numbers whose GCF is as large as possible. Record all attempts.

Stretch

If GCF(a,b) = g, then both a and b are multiples of g. Use this to explain why GCF × LCM = a × b for any two numbers a and b.

Cedar Strip Patterns
BC context · Design
Apply GCF to a real Northwest Coast weaving context.
Challenge

A Coast Salish weaver has 48 red strips, 60 yellow strips, and 36 black strips. She wants to make identical bundles using ALL strips with the same colour ratio in each. (a) How many bundles can she make? (b) What is the colour ratio per bundle? (c) If she adds 24 more of one colour to make the most bundles possible, which colour should she add and why?

Stretch

Generalize: if three quantities have a GCF of g, write a formula for the number of identical bundles and the amount of each quantity per bundle.

Prime Sieve
Collaborative
The Sieve of Eratosthenes — discover primes through elimination.
How it works

Each student gets a 10×10 grid (1–100). Starting from 2, cross out all multiples (but not 2 itself). Move to the next un-crossed number and repeat. What remains are primes.

Challenge

Count the primes up to 100. How many are there? Predict: roughly how many primes exist between 100 and 200? Between 200 and 300? Research the Prime Number Theorem and explain what it says about how primes thin out.

Divisibility Machine
Logic puzzle
Design a flowchart that classifies any number by divisibility.
Challenge

Design a flowchart that takes any whole number as input and outputs which of these it is divisible by: 2, 3, 4, 5, 6, 9, 10. Your flowchart must use the fewest possible yes/no decisions. Test it on 360, 225, and 1001.

Discussion

Why does the rule "divisible by 6 if divisible by both 2 and 3" work? Use prime factorization to explain.

LCM Real World Race
NRICH-style puzzle
When do repeating events coincide?
Challenge

Three First Nations drummers play at intervals of 4 seconds, 6 seconds, and 10 seconds. They all start together. (a) After how many seconds do all three play at the same time again? (b) In 2 minutes, how many times do exactly two of the three play together (but not all three)? (c) Create your own "timing coincidence" problem using three BC contexts.

Stretch

What is the minimum interval set (three numbers) that would make all three drummers coincide exactly once per minute?

Place Value Rearrangement
Open Middle
Maximize and minimize by rearranging digits.
Challenge

Use the digits 1, 2, 3, 4, 5, 6, 7 exactly once to form a 7-digit number. Version A: make it as large as possible while being divisible by 9. Version B: make it as small as possible while being divisible by 6. Version C: make a number divisible by both 4 and 5.

Discussion

For divisibility by 9, why does only the digit sum matter, regardless of digit order? Use expanded form to explain.

2

Fractions, Decimals & Percents

Operations with fractions, decimal place value, terminating vs repeating decimals, and fluent conversion between all three forms.

Big Ideas

  • Fractions, decimals, and percents are three different ways to represent the same part-to-whole relationship.
  • Equivalent fractions describe the same quantity using different numerators and denominators.
  • A fraction's decimal form terminates or repeats based entirely on the prime factors of the denominator.
  • Operations on fractions follow logical rules connected to what fractions mean.
  • ½ = 0.5 = 50% — fluency with these connections builds proportional reasoning for everything ahead.
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Fraction Operations
Equivalent fractions, simplifying, adding, subtracting, multiplying, and dividing fractions and mixed numbers.
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Decimal Operations
Place value to thousandths, multiplying and dividing decimals, terminating vs repeating decimals.
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Conversions
Moving fluently between fractions, decimals, and percents in all directions.
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Ordering & Comparing
Comparing mixed forms on a number line and solving proportional problems using all three representations.
How to use this page: Master fraction operations before decimals, and conversions before ordering. All four strands connect — use one to check your work in another.
1
Adding Fractions — Unlike Denominators
Calculate: ¾ + ⅝
1
Find the LCD of 4 and 8: LCD = 8
2
Convert: ¾ = ⁶⁄₈
3
⁶⁄₈ + ⁵⁄₈ = ¹¹⁄₈ = 1³⁄₈
Answer: 1³⁄₈
2
Subtracting Mixed Numbers
Calculate: 2⅓ − 1¾
1
Convert to improper: 2⅓ = ⁷⁄₃, 1¾ = ⁷⁄₄
2
LCD = 12: ²⁸⁄₁₂ − ²¹⁄₁₂ = ⁷⁄₁₂
Answer: ⁷⁄₁₂
3
Multiplying Fractions
Calculate: ⅔ × ⁹⁄₄
1
Cross-cancel: ⅔ × ⁹⁄₄ → ²⁄₁ × ³⁄₄ (cancel 3s)
2
Multiply: 2 × 3 = 6, 1 × 4 = 4⁶⁄₄ = 1½
Answer: 1½
4
Dividing Fractions
Calculate: 3½ ÷ ¾
1
Convert: 3½ = ⁷⁄₂
2
Multiply by the reciprocal: ⁷⁄₂ × ⁴⁄₃ = ²⁸⁄₆ = 4²⁄₃
Answer: 4⅔
5
Decimal Multiplication
Calculate: 4.85 × 3.2
1
Multiply ignoring decimals: 485 × 32 = 15 520
2
Count decimal places: 2 + 1 = 3 → place decimal 3 from right.
3
15 520 → 15.520
Answer: 15.52
6
Fraction → Decimal → Percent
Convert ⁷⁄₈ to a decimal and percent.
1
Divide: 7 ÷ 8 = 0.875
2
Multiply by 100: 0.875 × 100 = 87.5%
Answer: 0.875 = 87.5%
🪶 First Peoples Connection
A Fraser River salmon population of 6 400 decreases by ¼ due to low water levels. Calculating: ¼ × 6 400 = 1 600 fish lost. Remaining: 6 400 − 1 600 = 4 800. BC First Nations fisheries managers use proportional reasoning like this every season to make decisions about harvest limits and habitat restoration.
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/40

Worked example: To simplify 12/16, divide the numerator and denominator by their GCF, 4: 12/16 = 3/4.
  1. Convert 17/5 to a mixed number. L1
  2. Convert 3 2/3 to an improper fraction. L1
  3. Simplify 12/16 to lowest terms. Show the GCF. L1
  4. Write three equivalent fractions for 2/5. L1
  5. Which is larger: 5/8 or 3/4? Use common denominators. L2
  6. Place 1/4, 2/3, 5/6, and 1/2 in order from least to greatest. L2
  7. A recipe uses 3/4 cup of sugar. Write two equivalent measurements using eighths and twelfths. L2
  8. A student says 4/8 is greater than 1/2 because 4 is greater than 1. Explain the mistake. L3
Worked example: For 3/4 + 5/8, use denominator 8: 6/8 + 5/8 = 11/8 = 1 3/8.
  1. Calculate 3/4 + 5/8. L2
  2. Calculate 7/10 - 1/4. L2
  3. Calculate 2 1/3 - 1 3/4. L2
  4. Calculate 4 2/5 + 1 7/10. L2
  5. A ribbon is 5 1/2 m long. You cut off 2 3/4 m. How much is left? L3
  6. Find the missing value: □ + 3/8 = 7/8. L2
  7. Explain why you need a common denominator to add 1/3 + 1/4. L3
Worked example: To divide by a fraction, multiply by its reciprocal: 3/4 ÷ 2/5 = 3/4 × 5/2 = 15/8.
  1. Calculate 2/3 × 9/4. Simplify your answer. L2
  2. Calculate 5/6 × 3/10. Simplify your answer. L2
  3. Calculate 3 1/2 ÷ 3/4. L2
  4. Calculate 4/5 ÷ 2/3. L2
  5. A tray of brownies is 3/4 full. If 2/3 of that amount is eaten, what fraction of the whole tray was eaten? L3
  6. A student says division always makes a number smaller. Use 3 ÷ 1/2 to explain why this is not always true. L3
  7. Create a multiplication or division fraction problem that has an answer greater than 1. Solve it. L4
Worked example: A fraction terminates if the simplified denominator has only 2s and/or 5s as prime factors. For example, 3/8 terminates because 8=2³.
  1. Write 4.85 × 3.2. Show how you placed the decimal. L2
  2. Calculate 12.6 ÷ 0.3. L2
  3. Round 8.739 to the nearest tenth and nearest hundredth. L1
  4. Convert 7/8 to a decimal. L2
  5. Will 5/12 terminate or repeat as a decimal? Explain using prime factors. L3
  6. Will 9/40 terminate or repeat? Explain. L3
  7. A decimal is 0.375. Write it as a simplified fraction. L2
Worked example: To convert 0.625 to a percent, multiply by 100: 0.625 = 62.5%.
  1. Convert 3/5 to a decimal and percent. L1
  2. Convert 0.78 to a simplified fraction and percent. L1
  3. Convert 16% to a decimal and simplified fraction. L1
  4. Order from least to greatest: 0.625, 5/8, 63%, 0.6. L2
  5. A class survey says 3/8 of students walk to school. What decimal and percent is this? L2
  6. A sale saves 25% of the original price. What fraction of the price is saved? What fraction is still paid? L3
  7. Choose any three equivalent forms for the same number: one fraction, one decimal, and one percent. Explain why they match. L3
Worked example: Break the situation into steps: convert first, then calculate, then check whether the answer makes sense.
  1. A student reads 2/5 of a book on Monday and 0.35 on Tuesday. What fraction of the book is left? L3
  2. A recipe uses 1 1/2 cups of flour for one batch. How much flour is needed for 2 1/3 batches? L3
  3. A jar is 80% full. After pouring out 1/4 of the full jar amount, what percent full is it now? L4
  4. Find three different fractions between 1/3 and 1/2. Explain your strategy. L4
🚀 Extension Worksheet Extension
Extension Challenge: These questions explore fractions and decimals at a deeper level — perfect for students who want to go further.
  1. A recipe calls for 2¼ cups of flour for every 1½ cups of sugar. How much flour is needed for 4 cups of sugar? Write and solve a proportion.
  2. Show algebraically why 0.9̄ (0.999…) equals exactly 1. Use the "let x = 0.999…" approach and multiply by 10.
  3. A First Nations weaver mixes ⅔ of one dye colour with ¾ of another. If the total mixture must be exactly 2 litres, how much of each colour does she need? Set up and solve an equation.
  4. Investigate: which fractions with denominators from 1 to 20 produce terminating decimals, and which produce repeating decimals? Write a general rule based on the prime factorization of the denominator.
  5. A store sells two types of salmon at different prices per 100g. Store A: 3/8 kg for $6.75. Store B: 0.45 kg for $8.10. Calculate the unit price per 100g for each and determine the better value. Show all steps.
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Fraction Between Fractions
Open Middle
Find fractions squeezed between two others.
Challenge

Find a fraction between ⅓ and ½. Now find one between ⅓ and your answer. Keep going — how many times can you repeat this? Is there a limit? This property (that there is always a fraction between any two fractions) is called density. Explain why it is true using equivalent fractions.

Stretch

Find a fraction between 0.499 and 0.5. Express it as both a fraction and a decimal.

Repeating Decimal Algebra
Investigation
Convert any repeating decimal to a fraction algebraically.
Challenge

Convert 0.3̄, 0.6̄, 0.12̄, and 0.142857142857… to fractions using the "let x = …, multiply by 10ⁿ" method. What patterns do you notice? Can you predict what fraction 0.09̄ equals without calculating?

Stretch

Why do fractions with denominators whose only prime factors are 2 and 5 produce terminating decimals? Prove it using prime factorization.

Salmon Harvest Proportions
BC context · Menu
Apply fraction skills to First Nations fisheries management.
Challenge

A First Nations community has a quota of ³⁄₈ of the total salmon count. This week 4 800 salmon were counted, but the count has a ¹⁄₁₀ margin of error. (a) What is the quota range (min and max fish)? (b) If the community took ¹⁵⁰⁰ fish last week, what fraction of this week's quota remains? (c) Express the remaining quota as a decimal and a percent.

Stretch

If the quota fraction changes to 40% next season, what is the percentage increase in the quota compared to ³⁄₈? Show using both fraction and percent methods.

Decimal Target
Digit puzzle
Use place value to hit a decimal target.
Challenge

Use the digits 1, 2, 3, 4, 5 exactly once to create two decimals (one with 2 decimal places, one with 3) that multiply as close to 10 as possible. Record all attempts. Then arrange them to get the largest possible product and smallest possible product.

Discussion

When multiplying decimals, why does the number of decimal places in the product equal the total decimal places in both factors? Use expanded form to explain.

Benchmark Fractions Highway
Visual · Collaborative
Build a class number line from 0 to 2 with all key fractions.
How it works

Each student places ³ fractions on a shared 0–2 number line: one that is a terminating decimal, one repeating, and one whose decimal they must calculate. The class checks positions using equivalent forms.

Challenge

Find 5 fractions that are all equivalent to 0.625. How many different denominators (from 1 to 20) produce this value? What do they have in common?

Percent Reverse Engineering
NRICH-style
Work backwards from the result.
Challenge

A store applies a 30% discount, then adds BC tax (12%). A second store adds tax first, then applies 30% off. Does the order matter? Prove algebraically that the final price is the same either way. Then find a discount + tax combination where a small rounding difference could occur.

Stretch

If an item is discounted by x%, then another y%, what single discount is equivalent? Write a formula in terms of x and y.

Weaver's Ratio
Design task
Fraction operations in a cultural design context.
Challenge

A Musqueam weaver creates a blanket pattern using rows of three colours. Row 1: ½ red, ⅓ black, rest yellow. Row 2: ⅖ red, ¼ black, rest yellow. (a) What fraction is yellow in each row? (b) Which row has more yellow? By how much? (c) If the blanket is 180 cm wide, how wide is each colour in row 1 and row 2 in centimetres?

Stretch

Design your own 3-colour row where no fraction has denominator greater than 12 and all three colours appear in equal amounts. Is this possible? Prove or disprove.

Ordering Marathon
Compare strategies
Find the most efficient method for ordering mixed forms.
Challenge

Order these from least to greatest using three different methods — common denominator, decimal conversion, and number line estimation — then compare efficiency: ⅗, 0.62, 63%, ⁷⁄₁₁, 0.6̄, ⁵⁄₈.

Discussion

For which type of number is each method most efficient? Create a decision guide: "Use method X when…"

3

Integers

Extending the number line below zero — integer concepts, all four operations with integers, and BEDMAS with negative numbers.

Big Ideas

  • Integers extend the number line in both directions — negative numbers represent quantities below zero, before start, or in debt.
  • A positive and a negative integer of equal magnitude form a zero pair — they cancel: (+5) + (−5) = 0.
  • Subtracting an integer is the same as adding its opposite: a − b = a + (−b).
  • The sign rules for multiplication and division follow logically from extending patterns.
  • BEDMAS applies to all integer expressions exactly as it does to whole number expressions.
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Integer Concepts
Understanding negative numbers in context, the number line, absolute value, and zero pairs.
Adding & Subtracting
Rules for adding and subtracting integers, including subtracting a negative by adding its opposite.
✖️
Multiplying & Dividing
Sign rules for multiplication and division — why negative × negative is positive.
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BEDMAS with Integers
Applying the order of operations to expressions containing negative integers.
How to use this page: Start with the number line and zero pairs, then move to operations in order — add/subtract before multiply/divide. BEDMAS brings it all together.
1
Adding Integers
(+8) + (−5) = ?
1
Different signs → subtract magnitudes: 8 − 5 = 3
2
Larger magnitude is positive (+8), so answer is positive.
Answer: +3
2
Subtracting Integers
(+3) − (−9) = ?
1
Subtracting a negative = adding a positive: (+3) + (+9)
2
Same signs → add: 3 + 9 = 12
Answer: +12
3
Multiplying Integers
(−6) × (−7) = ?
1
Multiply the magnitudes: 6 × 7 = 42
2
Sign rule: negative × negative = positive.
Answer: +42
4
Dividing Integers
(+48) ÷ (−6) = ?
1
Divide magnitudes: 48 ÷ 6 = 8
2
Sign rule: positive ÷ negative = negative.
Answer: −8
5
BEDMAS with Integers
Simplify: (−3) × (4 + (−7)) − 8 ÷ (−2)
1
Brackets: 4 + (−7) = −3
2
Now: (−3) × (−3) − 8 ÷ (−2)
3
Division: 8 ÷ (−2) = −4
4
Multiplication: (−3) × (−3) = +9
5
Subtraction: 9 − (−4) = 9 + 4 = 13
Answer: +13
6
Real World: Temperature
Temperature at midnight: −8°C. It drops 3°C every hour for 4 hours. What is the temperature at 4 am?
1
Change over 4 hours: (−3) × 4 = −12°C
2
Final: (−8) + (−12) = −20°C
Answer: −20°C at 4 am
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/38

Worked example: A gain of $12 is +12. A loss of $12 is −12. They are opposites because they are the same distance from zero.
  1. Write an integer for each: 15 m below sea level, gain of $45, 7°C below zero, and sea level. L1
  2. Order from least to greatest: +5, −3, 0, −8, +1, −1. L1
  3. Which is greater: −4 or −7? Explain using a number line. L1
  4. Write the opposite of each: −9, +12, 0, −1. L1
  5. Find |−8|, |+3|, and |0|. Explain what absolute value means. L2
  6. Draw or describe a number line model showing −6 and +6. What is the same? What is different? L2
  7. A submarine is at −40 m and a bird is flying at +25 m. How far apart are they vertically? L3
Worked example: For −6 + 9, the signs are different, so subtract 9−6=3 and keep the sign of the larger absolute value: +3.
  1. Calculate (−8)+(+5). L1
  2. Calculate (+7)+(−12). L1
  3. Calculate (−9)+(−4). L1
  4. Calculate (+15)+(−6)+(+2). L2
  5. A football team gains 8 yards, loses 13 yards, then gains 5 yards. What is the total change? L2
  6. The temperature is −3°C in the morning and rises 11°C. What is the new temperature? L2
  7. Create an addition expression with three integers that has a sum of −10. L3
Worked example: Subtracting an integer means adding its opposite: 3 − (−9) = 3 + 9 = 12.
  1. Calculate (+3)−(−9). L2
  2. Calculate (−4)−(+7). L2
  3. Calculate (−10)−(−6). L2
  4. Fill in the missing number: −5 − □ = −12. L3
  5. Explain why 4 − (−2) is the same as 4 + 2. L2
  6. At noon, the temperature is +6°C. By midnight, it is −8°C. What was the temperature change? L3
  7. A student says −2 − 5 = +7. Explain and correct the mistake. L3
Worked example: Same signs give a positive product or quotient; different signs give a negative product or quotient.
  1. Calculate (−6)×(−7). L1
  2. Calculate (+48)÷(−6). L1
  3. Calculate (−9)×(+4). L1
  4. Calculate (−72)÷(−8). L1
  5. Find the missing integer: □ × (−5) = 35. L2
  6. Explain why the product of two negative integers is positive using a pattern. L3
Worked example: Use BEDMAS and keep integer rules: −3 + 2(−5) = −3 − 10 = −13.
  1. Evaluate −3 + 2(−5). L2
  2. Evaluate (−4)² − 10. L2
  3. Evaluate 18 ÷ (−3) + 7. L2
  4. Evaluate −2[5 + (−8)]. L3
  5. Insert brackets to make this true: −4 + 6 × 2 = 4. L4
  6. Create an integer expression that equals −20 and uses multiplication and addition. L4
Worked example: For word problems, identify what is positive, what is negative, and whether the situation means adding, subtracting, multiplying, or dividing.
  1. A hiker starts at 120 m above sea level and descends 180 m. What is the hiker’s elevation now? L2
  2. A bank account has $25. A $40 withdrawal is made. What is the balance? L2
  3. A game gives +5 points for a correct answer and −3 points for an incorrect answer. A player gets 6 correct and 4 incorrect. What is the score? L3
  4. Write a real-life situation for −4 × 6 = −24. L3
  5. Explain why −12 is less than −3 even though 12 is greater than 3. L3
🚀 Extension Worksheet Extension
Challenge yourself with these deeper integer problems.
  1. Find all integer values of n such that (−3) × n + 15 is between −12 and +12 (inclusive).
  2. A tide table shows: High tide +2.8 m, Low tide −1.4 m. (a) What is the tidal range? (b) If a boat needs at least 1.5 m of water and the harbour floor is at −0.8 m from mean sea level, during what portion of the tide cycle can the boat safely enter?
  3. Explain why "negative times negative equals positive" using the pattern: (+3)×(−2)=−6, (+2)×(−2)=−4, (+1)×(−2)=−2, 0×(−2)=0, (−1)×(−2)=___. What must the next result be to continue the pattern?
  4. Stock market challenge: A stock starts at $24. On consecutive days it changes: −$3, +$5, −$8, +$2, −$6. Write the calculation, find the final price, and determine the total absolute change (sum of magnitudes of each change).
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Zero Pair Art
Design task
Use zero pairs to create visual integer art.
Challenge

Create an "integer portrait" on a number line from −20 to +20. Choose 10 pairs of integers that are zero pairs. For each pair, write an addition equation and mark both numbers. Then create a single expression using all 20 numbers that equals a target value of your choice. Show all working.

Stretch

If you have n zero pairs and add one more positive integer p, write a formula for the sum of all 2n + 1 numbers.

Temperature Tracker
BC context · Investigation
Analyze real BC temperature data using integers.
Challenge

Research the average monthly temperatures for a BC city (e.g., Prince George or Smithers). Record 12 months. (a) Find the mean annual temperature. (b) Find the range. (c) Write an integer equation for the temperature change from the coldest to the warmest month. (d) If global warming raises each temperature by 1.5°C, recalculate the mean.

Discussion

In which months are temperatures negative? Write the total "degree-months below zero" as a single integer calculation.

Tide Level Puzzle
NRICH-style
Model tidal changes using integer operations.
Challenge

A BC harbour has tides: High tide +3.2 m, Low tide −1.4 m. A boat with 2 m draft needs at least 0.5 m clearance above the harbour floor (at −0.9 m). (a) At what minimum tide height can the boat safely dock? (b) Write an integer expression for the total tidal change over 3 complete cycles. (c) The tide drops ¼ of its range every 3 hours. Model the tide at hours 0, 3, 6, 9.

Stretch

Create a table showing "safe" and "unsafe" docking times using your model. Express safety as an integer inequality.

Sign Rule Detective
Reasoning
Discover and prove sign rules using patterns.
Challenge

Complete the pattern and explain each step: (+4)×(−3)=−12, (+3)×(−3)=−9, (+2)×(−3)=−6, (+1)×(−3)=−3, (0)×(−3)=0, (−1)×(−3)=___, (−2)×(−3)=___. What rule must hold to keep the pattern consistent? Now build the same type of pattern for division and for (−)×(+).

Stretch

Write a formal "proof by pattern" that negative × negative = positive. Why isn't this a complete mathematical proof? What would a complete proof require?

BEDMAS Challenge Relay
Collaborative
Build increasingly complex integer expressions.
How it works

Student A writes a two-integer expression. Student B adds one more operation (keeping BEDMAS in mind). Student C adds brackets that change the answer. Student D evaluates the final expression.

Challenge

Create expressions using integers from −10 to +10 that equal exactly 0, exactly 1, and exactly −7. Use at least 5 numbers and 4 operations in each.

Elevation Extremes
BC context · Open Middle
Combine integer operations with BC geography.
Challenge

Use BC geography: Mt. Fairweather (+4 663 m), Death Valley in California (−86 m for comparison), Marianas Trench (−10 935 m, for scale). (a) Calculate the total elevation difference between BC's highest peak and BC's deepest point (Douglas Channel floor: −670 m). (b) If you descend from Fairweather at 200 m per hour, write an integer sequence for your elevation every 2 hours. (c) When are you below sea level?

Stretch

Write a linear equation for elevation e after t hours of descent. When does e = 0? Solve algebraically.

Integer Target Builder
Digit puzzle
Hit a target using integers and operations.
Challenge

Use the integers −5, −3, −2, 0, +1, +4, +6 (each at most once) and any operations (including brackets) to make every integer from −10 to +10. Which target integers are impossible? Why?

Discussion

What is the maximum possible value you can make from these seven integers using only addition and subtraction? What about multiplication? What is the minimum?

Stock Market Simulation
Real world · Menu
Use integers to simulate investment decisions.
Challenge

A stock starts at $50. Over 5 days: Day 1: −$8, Day 2: +$12, Day 3: −$5, Day 4: −$3, Day 5: +$7. (a) Final price? (b) Greatest single-day loss expressed as a negative integer. (c) Absolute total change (sum of all magnitudes). (d) Mean daily change. (e) If each change is doubled, what is the new final price?

Stretch

Design a 5-day change sequence where the final price equals the starting price but the absolute total change is maximized. What is the maximum possible absolute change?

4

Ratio, Rate & Percent

Multiplicative relationships through ratios, rates, proportional reasoning, scale, percent of a number, and percent change.

Big Ideas

  • A ratio compares two quantities multiplicatively — how many times one is another, not just how much more.
  • A rate is a ratio that compares quantities with different units. A unit rate is per one unit of the second quantity.
  • Two ratios form a proportion if they are equivalent. Proportional reasoning is one of the most powerful tools in mathematics.
  • Percent is a ratio with a denominator of 100 — ½ = 0.5 = 50% = 50:100 all say the same thing.
  • Percent change is always calculated from the original value.
⚖️
Ratios & Rates
Writing and simplifying ratios, finding unit rates, comparing best-buy scenarios.
📐
Proportional Reasoning
Setting up and solving proportions, map scales, and scale diagrams.
💯
Percent of a Number
Finding a percent of a quantity, finding the whole given a percent, tip and tax calculations.
📈
Percent Change
Calculating percent increase and decrease — always from the original value.
How to use this page: Start with ratio and rate, then apply proportional reasoning, then connect to percent. Percent change comes last — it requires all earlier skills.
1
Writing & Simplifying Ratios
A bag has 8 red and 6 blue marbles. Write the ratio in all three forms and simplify.
1
Three forms: 8:6, ⁸⁄₆, "8 to 6"
2
GCF(8,6) = 2. Divide both: 4:3
Answer: 4:3 (simplified)
2
Unit Rate
A car travels 340 km in 4 hours. Find the unit rate (km/h).
1
Unit rate = rate per ONE unit: 340 ÷ 4 = 85
Answer: 85 km/h
3
Solving a Proportion
Solve: ³⁄₅ = n⁄₂₅
1
Cross-multiply: 3 × 25 = 5 × n
2
75 = 5n → n = 15
Answer: n = 15
4
Percent Change
A salmon population rises from 4 200 to 5 040. What is the percent increase?
1
Change: 5 040 − 4 200 = 840
2
% Change = 840 ÷ 4 200 × 100 = 20%
Answer: 20% increase
5
Map Scale
A BC map has scale 1:50 000. Two cities are 8.4 cm apart. Actual distance in km?
1
Actual cm: 8.4 × 50 000 = 420 000 cm
2
Convert: 420 000 cm ÷ 100 000 = 4.2 km
Answer: 4.2 km
6
Best Buy
750 mL juice for $3.29 or 1.25 L for $5.49? Which is better value?
1
A: $3.29 ÷ 7.5 = $0.439/100mL
2
B: $5.49 ÷ 12.5 = $0.439/100mL
Answer: Equal value! (both ≈ $0.44/100 mL)
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/34

Worked example: To simplify 18:24, divide both terms by 6: 18:24 = 3:4.
  1. Write the ratio 18:24 in lowest terms. Show the GCF. L1
  2. In a class there are 14 girls and 12 boys. Write the ratio of girls to boys in simplest form. L1
  3. Write three ratios equivalent to 5:8. L1
  4. A trail mix has peanuts and raisins in a ratio of 3:2. If there are 15 cups of peanuts, how many cups of raisins are needed? L2
  5. A team has a win:loss ratio of 7:3. If they have 21 wins, how many losses do they have? L2
  6. Explain the difference between a part-to-part ratio and a part-to-whole ratio using one example. L3
  7. Create a ratio problem where the simplified ratio is 4:5 but the original numbers are greater than 20. L3
Worked example: A car travels 360 km in 4 hours, so the unit rate is 360 ÷ 4 = 90 km/h.
  1. A car travels 360 km in 4 hours. Find the unit rate. L1
  2. A store sells 6 apples for $4.50. What is the cost per apple? L2
  3. A printer prints 48 pages in 6 minutes. How many pages per minute? L1
  4. A runner travels 12 km in 1.5 hours. Find the speed in km/h. L2
  5. Which is the better buy: 8 granola bars for $6.40 or 12 granola bars for $9.00? Show unit rates. L3
  6. A slush machine fills 30 cups in 12 minutes. At this rate, how long would 100 cups take? L3
  7. Create a rate problem involving time and distance. Solve using a unit rate. L3
Worked example: To solve 4/6 = n/30, notice 6 is multiplied by 5, so 4 × 5 = 20.
  1. Solve the proportion: 4/6 = n/30. L2
  2. Solve: 3/5 = x/40. L2
  3. Solve: 12/y = 4/7. L3
  4. A recipe uses 2 cups of rice for 5 people. How much rice is needed for 20 people? L2
  5. A map scale is 1 cm : 50 km. How far is 7.5 cm on the map? L3
  6. A photo is enlarged from 4 cm by 6 cm to 10 cm by 15 cm. Is the enlargement proportional? Explain. L3
  7. Find the error: A student solves 2/3 = x/12 and says x=18. Explain. L3
Worked example: To find 35% of 80, write 0.35 × 80 = 28.
  1. Find 20% of 150. L1
  2. Find 35% of 80. L2
  3. What percent of 60 is 15? L2
  4. A class has 28 students. If 75% completed the homework, how many students completed it? L2
  5. A price increases from $40 to $50. What is the percent increase? L3
  6. A student says 10% off and then another 10% off is the same as 20% off. Use a $100 item to check. L3
  7. Create a percent problem that can be solved using either a fraction or decimal method. L3
Worked example: Decide whether the problem asks for a comparison, a unit rate, a missing value, or a percent before calculating.
  1. A school dance has a student:adult ratio of 12:1. If 216 students attend, how many adults are needed? L3
  2. A smoothie recipe has fruit:juice:yogurt in the ratio 3:2:1. If you use 18 cups of fruit, how much juice and yogurt are needed? L3
  3. A bike travels 18 km in 45 minutes. Find the speed in km/h. L3
  4. An item is discounted by 25%, then tax of 12% is added. Starting from $80, what is the final price? L4
  5. Design two “best buy” options where the cheaper-looking option is not actually the better unit rate. L4
  6. Explain how ratios, rates, and percents are connected to fractions. L4
🚀 Extension Extension
  1. A BC First Nations community harvests salmon using a traditional practice ensuring only 60% of the counted fish are taken. If 4 800 salmon are counted, and the count has a 15% margin of error, what is the range of fish that might be harvested? Explain why the margin of error matters for sustainable fisheries management.
  2. A store marks up an item by 40% to get the selling price, then offers a "20% off sale." Show algebraically that this is NOT the same as a 20% markup. What is the actual percent increase from cost to final sale price?
  3. Two hikers start at the same trailhead. Hiker A walks at 4.5 km/h. Hiker B walks at 6 km/h but starts 45 minutes later. How long after Hiker B starts will they be at the same distance from the trailhead?
  4. A map of Vancouver Island has scale 1:250 000. The island is approximately 460 km long and 80 km wide. What are its dimensions on the map in cm?
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Best Buy Challenge
Comparison · BC context
Apply unit rates to real grocery decisions.
Challenge

Compare unit prices for 5 pairs of BC products (e.g., BC salmon: 400g for $8.99 vs 750g for $15.49; blueberries: 1 pint for $4.50 vs 2 pints for $7.99). Calculate the price per 100g or per unit for each. Which offers better value? Are there non-price factors a shopper should consider?

Stretch

A store offers "buy 2 get 1 free" on a $6.99 item. Calculate the effective unit rate. Compare to a competing store selling 3 of the same item for $14.49.

Map Scale Design
Design task
Create a scaled map of your school or neighbourhood.
Challenge

Choose a scale (e.g., 1:500) and create a scale diagram of part of your school grounds. Mark at least 5 key points, measure 4 distances on your map, and calculate actual distances. Include a scale bar and compass rose.

Stretch

If you change the scale to 1:1000, how do all measurements on your map change? What stays the same?

Salmon Population Dynamics
BC context · Investigation
Model population change using percent.
Challenge

A salmon run: Year 1: 12 000 fish. Year 2: increases 15%. Year 3: decreases 20%. Year 4: increases 8%. (a) Calculate the population each year. (b) Overall percent change from Year 1 to Year 4. (c) What single percent change from Year 1 would give the same Year 4 result? (d) At what percent increase in Year 3 would the population return to Year 1 levels?

Discussion

If a population decreases by 50% then increases by 50%, does it return to its original value? Prove algebraically. This is called the "percent change trap."

Proportion Puzzle Relay
Collaborative
Build chains of proportional reasoning.
How it works

Student A sets up a proportion from a real context. Student B solves it and creates a new context where the answer becomes one of the given values. Student C solves and extends. Continue for 4 rounds.

Challenge

Create a proportion chain involving at least 3 of these contexts: map scale, recipe scaling, speed/distance/time, population density, exchange rates.

Discount Trap
NRICH-style
Reveal the mathematics of sequential discounts.
Challenge

A jacket costs $200. Store A applies 30% off, then 10% off. Store B applies 10% off, then 30% off. Store C applies 40% off. (a) Calculate the final price at each store. (b) Which is cheapest? (c) Show algebraically that two sequential discounts of x% and y% are equivalent to a single discount of (x + y − xy/100)%.

Stretch

Find two discount percentages that together are equivalent to exactly 50% off.

Rate Race
Open Middle
Find the rate that satisfies multiple constraints.
Challenge

A canoe travels downstream at rate r + 3 km/h and upstream at r − 3 km/h, where r is the paddler's rate in still water. The canoe travels 24 km downstream and 12 km upstream in the same total time. Set up and solve a proportion equation to find r.

Discussion

What does it mean for the canoe's rate to equal the current's rate? What happens mathematically and physically?

Scale Drawing of BC
BC context · Design
Use proportional reasoning to analyze BC geography.
Challenge

BC is approximately 944 735 km² in area. On a 1:5 000 000 scale map, (a) a river appears 18.4 cm long — find its actual length; (b) two cities are actually 340 km apart — find their map distance; (c) a lake appears as a 6 cm × 4 cm rectangle — estimate its actual area.

Stretch

If the map scale changes to 1:10 000 000, by what factor do all distances change? By what factor does area change? Generalize for any scale change from 1:a to 1:b.

Tip, Tax & Truth
Menu-style
Navigate the mathematics of a restaurant bill.
Challenge

A family's meal in Vancouver costs $84.60 before tax. BC GST = 5%, PST = 7% (food is GST-exempt in BC but not all items are). (a) The drinks ($18.40) are taxable — calculate the bill with full tax on drinks only. (b) They want to leave exactly 18% tip on the pre-tax total. What is the tip? (c) They split the bill 3 ways equally. What does each person pay? (d) If one person pays with a $50 bill, what change do they receive?

Stretch

Research which BC food items are GST-exempt and which are not. Create a "tax guide" for a typical school cafeteria menu.

5

Patterns & Algebra

Linear patterns, T-tables, four-quadrant graphing, expressions, BEDMAS, one- and two-step equations.

Big Ideas

  • A pattern is a sequence that follows a rule — arithmetic (add/subtract) or geometric (multiply/divide).
  • A linear relation produces a straight-line graph and has a constant rate of change.
  • A variable is a symbol representing an unknown or changing quantity — expressions show relationships, equations show equality.
  • Solving an equation means finding the value that makes it true — inverse operations undo each other.
  • BEDMAS ensures expressions have only one correct value regardless of who evaluates them.
📈
Patterns & Relations
Arithmetic and geometric patterns, T-tables, rate of change, and linear vs non-linear sequences.
🗺️
Graphing & Coordinates
Plotting relations in all four quadrants, identifying intercepts, and reading graphs.
🔤
Expressions & BEDMAS
Writing, evaluating, and simplifying algebraic expressions with integers using order of operations.
⚖️
Equations
Solving one- and two-step equations, verifying solutions, and writing equations from word problems.
How to use this page: Patterns come first, then graphing, then expressions, then equations. Each strand builds on the one before — a linear pattern IS an equation in disguise.
1
Pattern Rule & Expression
Sequence: 4, 7, 10, 13, … Write the rule and expression for the nth term.
1
Common difference: +3
2
Start at 4 when n=1: 3(1)+1=4 ✓
3
Expression: 3n + 1
Answer: Rule: add 3. Expression: 3n + 1
2
Solving a Two-Step Equation
Solve: 3x − 5 = 16. Verify your answer.
1
Add 5 to both sides: 3x = 21
2
Divide by 3: x = 7
3
Verify: 3(7)−5 = 21−5 = 16 ✓
Answer: x = 7
3
Four-Quadrant Coordinates
Name the quadrant for: A(3,−2), B(−4,5), C(−1,−3).
1
A(3,−2): x positive, y negative → Quadrant IV
2
B(−4,5): x negative, y positive → Quadrant II
3
C(−1,−3): both negative → Quadrant III
A: Q IV, B: Q II, C: Q III
4
Rate of Change
A linear relation passes through (0, 3) and (1, 7). Find the rate of change and write the equation.
1
Rate of change = (7−3)÷(1−0) = 4
2
y-intercept = 3 (the point when x = 0)
3
Equation: y = 4x + 3
Answer: Rate = 4, Equation: y = 4x + 3
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/33

Worked example: For 4, 7, 10, 13, the pattern increases by 3, so the rule is “start at 4, add 3 each time.”
  1. Continue the pattern and write the rule: 4, 7, 10, 13, ___, ___, ___. L1
  2. Continue the pattern: 2, 6, 10, 14, ___, ___. What is the term-to-term rule? L1
  3. Write the first 6 terms for the rule: start at 5 and add 4 each time. L1
  4. Find the 10th term of the pattern 3, 8, 13, 18, .... L2
  5. Is 1, 4, 9, 16, 25 linear or non-linear? How do you know? L2
  6. Create a pattern with a constant difference of −3. Write the first 6 terms. L2
  7. A student says every increasing pattern is linear. Explain why this is not true. L3
Worked example: For y = 3n − 2, when n=1, y=1; when n=2, y=4.
  1. Complete the T-table for y = 3n − 2 using n = 1,2,3,4,5. L1
  2. Complete a T-table for y = 2n + 5 using n = 0,1,2,3,4. L1
  3. Graph the points from y = 2n + 1 for n=0 to 5. Describe the shape. L2
  4. A pattern has points (1,4), (2,7), (3,10), (4,13). Write the rule. L2
  5. A linear pattern starts at 6 and increases by 5 each step. Write an expression for term n. L3
  6. Compare y = 4n and y = 4n + 3. How are the graphs similar and different? L3
  7. Find a rule for a table where n: 1,2,3,4 and y: 10,17,24,31. L3
Worked example: If x=4, then 3x+2 = 3(4)+2 = 14.
  1. Evaluate 3x + 2 when x = 4. L1
  2. Evaluate 5a − 7 when a = 6. L1
  3. Evaluate 2m + 3n when m=5 and n=4. L2
  4. Write an expression for “six more than double a number.” L2
  5. Write an expression for “four less than three times a number.” L2
  6. A movie ticket costs $12 and snacks cost $s. Write an expression for the total cost for 4 people each buying a ticket and snacks. L3
Worked example: To solve 2x + 5 = 17, subtract 5 first: 2x=12, then divide by 2: x=6.
  1. Solve x + 9 = 21. L1
  2. Solve 3x = 27. L1
  3. Solve x/4 = 7. L1
  4. Solve 2x + 5 = 17. L2
  5. Solve 4x − 3 = 25. L2
  6. Solve (x/3) + 6 = 14. L3
  7. A student solves 5x + 2 = 22 and says x=6. Check and correct the answer. L3
Worked example: For growing patterns, connect the drawing, table, graph, and expression so they all describe the same relationship.
  1. A tile pattern uses 5 tiles in Figure 1, 8 in Figure 2, and 11 in Figure 3. Write a rule for Figure n. L3
  2. A savings account starts with $20 and grows by $6 each week. Write an expression for the amount after w weeks. L2
  3. Use your expression from the savings problem to find the amount after 12 weeks. L2
  4. A phone plan costs $15 plus $0.10 per text. Write an expression and find the cost for 80 texts. L3
  5. Create a visual growing pattern. Draw or describe Figures 1–4, make a T-table, and write a rule. L4
  6. Two patterns are A = 3n + 5 and B = 5n + 1. For what value of n are they equal? L4
🚀 Extension Extension
  1. A traditional First Nations basket design grows in a pattern. Row 1 has 3 beads, each subsequent row has 5 more. Write an expression for the number of beads in row n, and find which row first has more than 100 beads.
  2. Two linear relations are: y = 2x + 1 and y = −x + 7. Determine the point where they intersect by setting the expressions equal and solving for x, then finding y.
  3. A raven can fly 3 km in 6 minutes. Write an equation for distance d in terms of time t (in minutes). If a salmon swims at 0.8 km/min, how long until the raven has flown exactly twice the distance the salmon has swum (both starting at t = 0)?
  4. Create your own "growing pattern" using toothpicks or squares. Draw the first 4 terms, write a T-table, write the expression for the nth term, and use your expression to predict the 20th term.
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Growing Patterns Gallery
Design task
Create, analyze, and generalize a visual growing pattern.
Challenge

Design a growing pattern using shapes (toothpicks, dots, or tiles). Draw the first 4 terms. Complete a T-table for terms 1–10. Write an algebraic expression for term n. Use your expression to predict term 50 and term 100. Create a graph of the first 10 terms and label the rate of change and y-intercept.

Stretch

Modify your pattern so the expression becomes 2n + 5 instead of 3n − 1. What visual change creates this new rule?

Equation Card Sort
Collaborative · Reasoning
Match situations, equations, tables, and graphs.
How it works

Create cards for 5 linear relations — each set has a word problem, a T-table, an equation, and a graph. Mix all 20 cards. Partners must re-sort them into 5 matched sets.

Challenge

For the BC-context set: "A cedar canoe travels at a constant 6 km/h" — write the equation, T-table (for 0–5 hours), and graph. Add an equation for a salmon swimming at 4 km/h from the same start. Find when the canoe has travelled twice the distance of the salmon.

Intersection Investigations
NRICH-style
Find where two linear relations meet.
Challenge

Relations: y = 3x − 2 and y = −x + 10. (a) Complete T-tables for each (x from 0 to 5). (b) Find the intersection point algebraically. (c) Verify by substituting into both equations. (d) Create a BC story where these two relations represent two hikers starting from different points.

Stretch

Find all pairs of equations from y = 2x + 1, y = 3x − 4, y = x + 5 that intersect at a point with integer coordinates.

BEDMAS Battleship
Digit puzzle
Create expressions that equal specific values.
Challenge

Using the integers −3, −1, 2, 4, 6 (each at most once) and any operations and brackets, make every integer from −10 to +10. Record your expression for each. Which target values need brackets? Which work without?

Discussion

Without brackets, can changing the order of the same numbers and operations produce different results? Give 3 examples using these integers.

Canoe Journey Equations
BC context · Modelling
Write equations from a traditional travel context.
Challenge

A First Nations family paddles 24 km along a river in a traditional canoe. They start at 8:00 am. (a) At 4 km/h, write an equation for distance remaining d after t hours. When do they arrive? (b) If they rest for 30 minutes at the halfway point, rewrite the equation for each leg separately. (c) Plot both legs on a distance-time graph. (d) A second canoe leaves the same point 90 minutes later at 6 km/h — when does it overtake the first canoe?

Stretch

Write a system of equations and solve algebraically for the overtaking time and distance.

Equation Building Competition
Open Middle
Work backwards from solutions.
Challenge

The solution is x = 5. Create 6 different two-step equations that have x = 5 as the solution, using at least 3 different operations. Make one easy (L1), two medium (L2/L3), and three difficult (L4). Verify each by substituting x = 5.

Stretch

The solution is x = −3. Create 4 two-step equations with this solution. Why is it harder when the solution is negative?

The Totem Pole Builder
BC context · Investigation
Use patterns to model totem pole design costs.
Challenge

A totem pole carver charges a $500 base fee plus $120 per figure carved. (a) Write an equation for total cost C in terms of figures f. (b) Complete a T-table for 1–10 figures. (c) Graph the relation. (d) What does the y-intercept represent? (e) If a community has a budget of $1500, how many figures can they afford? (f) A second carver charges $300 + $150/figure. Under what conditions is each carver cheaper?

Stretch

Solve the system algebraically to find when both carvers cost the same. Interpret this point on the graph.

Pattern Prediction Challenge
Menu-style
Predict far-off terms without listing all the steps.
Challenge

Without listing all terms, find term 100 of: (a) 7, 11, 15, 19, … (b) 3, 6, 12, 24, … (c) a pattern where each term = previous term + 2n. For (a) and (b), write the general expression and explain how you derived it. For (c), first figure out the first 6 terms, then find term 100.

Discussion

For (b), this is a geometric sequence (multiply by a constant). Why can't it be represented by a linear equation y = mn + b? What type of equation would it need?

6

Geometry: Coordinates, Transformations, Tessellations & Circles

Angles, triangles, circles, polygons, surface area, and volume — developing spatial reasoning and geometric problem-solving skills.

Big Ideas

  • Coordinates locate points in four quadrants and on the axes, helping us describe position precisely.
  • Translations, reflections, and rotations preserve shape and size, so the image is congruent to the original.
  • Tessellations depend on angles fitting together around a point so that they total 360°.
  • For every circle, the ratio C ÷ d is constant and equal to π, so circumference scales directly with diameter.
  • Geometry connects to cultural design and symmetry through contexts such as medicine wheel overlays, birchbark biting, Northwest Coast patterning, and dreamcatcher construction.
📍
Strand 1 — Coordinates
Quadrants, axes, plotting, describing points, grid geometry, midpoint, and symmetry on the coordinate plane.
🔄
Strand 2 — Transformations
Single transformations first, then combinations of slides, flips, and turns, including why order can matter.
🧩
Strand 3 — Tessellations
Regular polygons, angle checks at a shared vertex, and patterns created by translations, reflections, and rotations.
Strand 4 — Circles
Circle parts, using radius and diameter, calculating circumference, and reasoning about why π stays constant.
How to use this page: work in the same order as the workbook — coordinates first, then transformations, then tessellations, then circles. The practice tab now includes a much larger Cartesian grid section to match the workbook more closely.
1
Quadrants & Axes
Name the quadrant or axis for the point (-4, 2).
1
The x-coordinate is negative, so the point is left of the y-axis.
2
The y-coordinate is positive, so the point is above the x-axis.
3
Negative x and positive y means Quadrant II.
Answer: Quadrant II
2
Rectangle on a Grid
Rectangle A(1,2), B(5,2), C(5,-3), D(1,-3). Find AB, BC, area, and perimeter.
1
AB is horizontal, so count the change in x: 5-1=4.
2
BC is vertical, so count the change in y: 2-(-3)=5.
3
Area: 4×5=20 square units.
4
Perimeter: 2(4+5)=18 units.
Answer: AB = 4, BC = 5, Area = 20, Perimeter = 18
3
Translation
Translate the point (4,-2) 3 units left and 5 units up.
1
Moving 3 left decreases x: 4-3=1.
2
Moving 5 up increases y: -2+5=3.
Answer: (1, 3)
4
Reflection & Rotation
Reflect (3,-2) over the y-axis, then rotate (2,3) 90° clockwise about the origin.
1
Reflection over the y-axis changes the sign of x only: (3,-2)→(-3,-2).
2
A 90° clockwise rotation uses the rule (x,y)→(y,-x).
3
So (2,3)→(3,-2).
Answers: Reflection → (−3, −2), Rotation → (3, −2)
5
Tessellation Check
Can 2 regular octagons and 1 square meet at a point with no gaps?
1
Interior angle of a regular octagon: 135°.
2
Interior angle of a square: 90°.
3
Add them: 135+135+90=360°.
4
Since the total is 360°, they fit exactly at a point.
Answer: Yes — this combination works
6
Circumference from Radius
A circle has radius 5 cm. Find the circumference using π ≈ 3.14.
1
Use C=2πr.
2
C=2×3.14×5.
3
C=31.4 cm.
Answer: 31.4 cm
7
Diameter from Circumference
A circular track has circumference 125.6 m. Find the diameter.
1
Use C=πd, so d=C÷π.
2
d=125.6÷3.14.
3
d=40.
Answer: 40 m
8
Order Matters
Start with (3,1). Compare: reflect over the y-axis then rotate 90° clockwise, versus rotate first then reflect.
1
Reflect then rotate: (3,1)→(-3,1)→(1,3).
2
Rotate then reflect: (3,1)→(1,-3)→(-1,-3).
3
The results are different, so the order matters.
Answer: Order matters because (1, 3) ≠ (−1, −3)
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___ / 35

Worked Example Image — Coordinates
How to answer: read x first and then y. For (3,4), move 3 right from the origin, then 4 up.
Plot the point (3, 4) Step 1: move 3 units right. Step 2: move 4 units up. xy 1234 1234 (3,4) Remember: 1. Start at the origin (0,0) 2. Read x first → left/right 3. Read y second → up/down Answer: the point is in Quadrant I.
Use this as a model when questions ask you to plot a point, identify a quadrant, or explain how coordinates work.
  1. Name the quadrant for each point: A(3,4), B(-2,5), C(-4,-1), D(6,-3). L1
  2. Write one point in each quadrant and one point on each axis. L1
  3. Name the quadrant, axis, or origin for: (0,4), (-2,0), (7,0), (0,0). L1
  4. Write the coordinates described by each clue: 4 right and 3 up; 5 left and 2 up; 6 right and 4 down; 3 left and 7 down. L1
  5. A point has x=-5 and its y-coordinate is the opposite of x. What are the coordinates? L1
  6. Rectangle A(1,2), B(5,2), C(5,-3), D(1,-3): find the lengths of AB and BC. L2
  7. Using the same rectangle, find the area and perimeter. L2
  8. Right triangle P(-4,1), Q(2,1), R(2,-3): identify the right-angle vertex and calculate the area. L2
  9. Points M(-3,4) and N(5,4) lie on the same horizontal line. What is the distance between them? L2
  10. A shape has vertices (-2,3), (2,3), (2,-3), (-2,-3). What type of quadrilateral is it, and what is special about its position relative to the axes? L2
  11. Find the midpoint of the line segment joining A(-4,-2) and B(4,4). L3
  12. A third point is C(0,1). Explain how you can check whether C lies on line segment AB. L3
  13. State whether each point is in a quadrant, on an axis, or at the origin: (-1,8), (0,-6), (4,-4), (0,0). L1
  14. Write a point that is the reflection of (3,5) across the y-axis, and another point that is the reflection across the x-axis. L2
Worked Example Image — Individual Transformations
How to answer: identify the rule first. This example reflects A(3,-2) over the y-axis, so only the x-value changes sign: (x,y) → (-x,y).
Reflect A(3, −2) over the y-axis The y-value stays the same. The x-value becomes its opposite. A(3,−2) A′(−3,−2) Rule (x, y) → (−x, y) Original: (3, −2) Image: (−3, −2) Answer: reflected over the y-axis.
Students can use the same idea for translations, reflections, and rotations: identify the rule, apply it carefully, then name the image coordinates.
  1. Translate (4,-2) 3 units left and 5 units up. L1
  2. Reflect (3,-2) over the y-axis. L1
  3. Rotate (2,3) 90° clockwise about the origin. L2
  4. Triangle P(1,2), Q(4,2), R(4,5): translate 3 left and 4 down. Write the image coordinates. L2
  5. Reflect the same triangle over the y-axis. Write the image coordinates. L2
  6. Rectangle A(-3,1), B(-1,1), C(-1,4), D(-3,4): rotate 180° about the origin and state which quadrant(s) the image lies in. L3
  7. Use the point (3,1) to show that doing two transformations in a different order can give a different result. L4
  8. Reflect (6,1) over the x-axis, then state the rule in words for this reflection. L1
  9. Rotate (-3,-4) 90° counter-clockwise about the origin. L2
  10. Describe the transformation fully: (2,3) → (-2,3), (4,1) → (4,-1), (3,2) → (2,-3). L3
Worked Example Image — Combinations & Tessellations
How to answer: for combinations, complete each transformation in the correct order. For tessellations, check whether the angles around one vertex add to 360°.
Combination example Start with A(1,2), translate 3 left and 1 down, then reflect over the x-axis. Start A(1,2) Step 1 A′(-2,1) 3 left, 1 down Step 2 A′′(-2,-1) reflect over x-axis Tessellation example Four squares can meet at one point because each interior angle is 90°. 90° 90° 90° 90° 90 + 90 + 90 + 90 = 360° So squares tessellate neatly around that shared vertex.
This model shows the two main ideas in this strand: follow each transformation step carefully, and test tessellations by checking whether the angles around a point total 360°.
  1. Which regular polygons tessellate on their own? Circle all that apply: triangle, square, pentagon, hexagon, octagon. L2
  2. Check whether 2 regular octagons and 1 square can meet at a point with no gaps. Show the angle total. L3
  3. Explain why a regular pentagon does not tessellate on its own. L4
  4. Triangle A(1,2), B(4,2), C(4,5): translate 3 left and 1 down, then reflect over the x-axis. Write the final image coordinates. L3
  5. Apply this combination to point (3,2): first reflect over the y-axis, then translate 4 units right. What is the final point? L2
  6. Check whether squares and equilateral triangles can tessellate together at a vertex by adding the angles in one working combination. L3
  7. State whether each claim is true or false: regular pentagons tessellate alone; reflecting twice over the same axis returns a figure to its start; the order of transformations never matters. L4
Worked Example Image — Circles & Circumference
How to answer: decide whether you know the radius or diameter first. This example starts with r = 5 cm, so use C = 2πr.
Find the circumference when r = 5 cm Radius is given, so use C = 2πr. r = 5 cm centre circumference Step-by-step C = 2πr C = 2 × 3.14 × 5 C = 31.4 cm Answer: the circumference is 31.4 cm.
Students can copy this structure for circle questions: identify the known measurement, choose the correct formula, substitute, and state the units.
  1. A circle has diameter 14 cm. Find the radius and the circumference. Use π ≈ 3.14. L1
  2. A circular track has circumference 125.6 m. Find its diameter. Use π ≈ 3.14. L2
  3. A bicycle wheel has radius 35 cm. How far does the bike travel in one full rotation? L3
  4. A semicircle has diameter 20 cm. Find the curved part only and then the total perimeter. L4
  5. A dreamcatcher hoop needs 47.1 cm of willow. Find the diameter and radius of the hoop. L4
  6. A circle has radius 9 cm. Find the diameter and circumference. Use π ≈ 3.14. L1
  7. Circle A has radius 6 cm. Circle B has diameter 15 cm. Which circle has the greater circumference, and by how much? L3
  8. The second hand of a clock is 12 cm long. How far does the tip travel in one full revolution? L2
🚀 Extension Worksheet Extension
Challenge yourself: These tasks come from the applied and extended flavour of the workbook. They ask you to explain, justify, compare, and generalize.
  1. Create a coordinate design with at least 8 vertices that has at least one point in every quadrant, one point on each axis, and a line of symmetry along either the x-axis or the y-axis. List all coordinates.
  2. Medicine wheel coordinate overlay: if a point representing summer is at (3,4), write the coordinates of the point directly opposite across the origin. Then give the reflections of (-4,2) over the x-axis, the y-axis, and both axes.
  3. Apply this combination to triangle A(1,2), B(4,2), C(4,5): translate 3 left and 1 down, reflect over the x-axis, then rotate 90° clockwise. Record each image and describe what stays the same.
  4. Show that two reflections over perpendicular axes are equivalent to one 180° rotation about the origin. Test your claim on at least two different points.
  5. Tessellation reasoning: explain why regular polygons with 7 or more sides do not tessellate alone. Use the idea that the angles meeting at one point must total 360°.
  6. A dreamcatcher has diameter 15 cm. Find the radius, the circumference, and how much willow is left over if branches come in lengths of 50 cm.
  7. Explain why the ratio C ÷ d is the same for every circle. Use the idea of scaling: if the diameter doubles, what happens to the circumference?
  8. Extension challenge: If the diameter of a circle increases by 1 m, by exactly how much does the circumference increase? Does your answer depend on the original size of the circle?
Teacher note: These are original low-floor, high-ceiling tasks built to fit Unit 6. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Coordinate Constellations Menu
Menu-style
Students create as few coordinate points as possible to satisfy a whole menu of geometric constraints.
Challenge

Create a set of points on a Cartesian grid so that, across your whole set, you have satisfied every condition below at least once:

  • one point in each quadrant
  • one point on the x-axis and one on the y-axis
  • two points with the same x-coordinate
  • two points with the same y-coordinate
  • a pair that are reflections across the y-axis
  • a pair that are reflections across the x-axis
  • three points that form a right triangle
  • two points whose midpoint is the origin

Goal: use the fewest possible points. Be ready to defend why your design is efficient.

Stretch

Add one new condition without increasing the number of points.

Open Middle: Four-Quadrant Builder
Digit puzzle
A constrained digit-placement task that pushes students to think about signs, symmetry, and efficient choices.
Challenge

Use the numbers 1, 2, 3, 4, 5, 6, 7, 8 exactly once to make four ordered pairs. Put one point in each quadrant.

Version A: make the quadrilateral formed by joining the points in order have the greatest possible perimeter.

Version B: make the quadrilateral have the smallest possible perimeter.

Discussion prompts

Which digits should be used far from the axes? When does symmetry help? Can two different-looking solutions have the same perimeter?

Mystery Fourth Vertex
NRICH-style puzzle
Students infer missing coordinates by using shape properties instead of guess-and-check alone.
Challenge

Find all possible fourth vertices for each shape. Sketch and justify every answer.

  • A(-2, 1), B(2, 1), C(2, 5) are three vertices of a rectangle.
  • P(-3, 0), Q(0, 3), R(3, 0) are three vertices of a kite.
  • M(-4, -1), N(0, 3), O(4, -1) are three vertices of a symmetric quadrilateral.
Stretch

Create your own “three vertices are given” puzzle that has exactly two correct answers.

Transformation Relay
Collaborative
A communication-rich task where one student designs, another transforms, and a third verifies by reasoning from coordinates.
How it works

Student A draws a simple polygon with integer coordinates and writes only the starting coordinates. Student B secretly chooses two transformations from this list: reflect in x-axis, reflect in y-axis, rotate 90° clockwise, rotate 180°, translate by a whole-number vector.

Student C must determine the final coordinates without seeing the drawing, then explain the rules that were used.

Challenge round

Find two different two-step transformation sequences that land the shape in the same final position.

Tessellation Vertex Lab
Investigation
Students test which polygons can meet around a point and then design their own successful combinations.
Challenge

You may use regular triangles, squares, pentagons, hexagons, octagons, and decagons. Build as many different “vertex recipes” as you can where the angles add to exactly 360°.

Record each successful recipe in a compact way, such as 3.3.3.3.3.3 for six triangles or 8.8.4 for two octagons and a square.

Questions to pursue

Which combinations are impossible? Why do pentagons keep causing trouble? Can a combination work at one vertex but still fail to tessellate as a full pattern?

Dreamcatcher Design Optimizer
Circles + reasoning
A circle task with choice, estimation, and justification instead of one fixed answer.
Challenge

You have exactly 100 ext{ cm} of willow to make one large dreamcatcher hoop or two smaller hoops.

  • Option 1: design one circle using as much of the willow as possible.
  • Option 2: design two circles with different diameters.
  • Option 3: design two equal circles.

For each option, find the diameter(s) and radius/radii, then decide which design gives the largest total diameter and which gives the largest total radius.

Stretch

What stays the same and what changes if you switch from “total willow” to “total diameter” as the quantity you want to maximize?

Symmetry Star Challenge
Design task
A build-and-analyze task that combines coordinates, symmetry, and transformations.
Challenge

Plot at least 8 points with integer coordinates to create a closed design that has:

  • one line of symmetry
  • at least one vertex in each quadrant
  • at least one vertex on an axis
  • one pair of points related by a 180° rotation about the origin
Teacher move

After students finish, add one surprise condition such as “it must also have rotational symmetry” or “you may only move one point.”

Which Sequence Wins?
Compare strategies
Students reason about whether different transformation sequences are equivalent.
Challenge

Start with triangle A(1,1), B(4,1), C(2,3). Compare these sequences:

  • reflect in the y-axis, then reflect in the x-axis
  • rotate 180° about the origin
  • rotate 90° clockwise twice

Do all three produce the same image? Prove it with coordinates. Then invent another pair of different-looking sequences that always agree.

7

Measurement

Area of circles & composite figures, volume of rectangular prisms and cylinders, surface area of rectangular prisms.

Big Ideas

  • The area of a circle uses the constant π: A = πr².
  • Composite figures can be split into simpler shapes whose areas are added (or subtracted).
  • Volume measures three-dimensional space — the formula V = base area × height works for any prism or cylinder.
  • 1 cm³ = 1 mL, so volume and capacity are directly connected.
  • Surface area is the total area of all faces — different from volume even though both involve the same 3D shape.
Area of Circles
Using A = πr² for circles, finding radius from area, and combining with polygon areas for composite figures.
📦
Volume
Volume of rectangular prisms using V = lwh, volume of cylinders using V = πr²h, and converting to capacity (litres).
📐
Surface Area
Finding surface area of rectangular prisms and cubes by calculating and summing the area of all faces.
🔗
Connections
Distinguishing area, perimeter, surface area, and volume — and applying measurement to real BC contexts.
How to use this page: Start with area of circles (connecting to Unit 6), then volume, then surface area. Always label units carefully — cm vs cm² vs cm³ are different things.
1
Area of a Circle
Circle with radius 6 cm. Find the area. (π ≈ 3.14)
1
Formula: A = πr²
2
A = 3.14 × 6² = 3.14 × 36 = 113.04 cm²
Answer: A = 113.04 cm²
2
Volume of a Cylinder
Cylinder: r = 4 cm, h = 10 cm. Find volume. (π ≈ 3.14)
1
Base area: A = πr² = 3.14 × 16 = 50.24 cm²
2
Volume: V = A × h = 50.24 × 10 = 502.4 cm³
Answer: V = 502.4 cm³
3
Surface Area of a Rectangular Prism
Rectangular prism: 6 cm × 4 cm × 3 cm. Find the surface area.
1
3 pairs of faces: lw, lh, wh
2
6×4=24, 6×3=18, 4×3=12
3
SA = 2(24+18+12) = 2(54) = 108 cm²
Answer: SA = 108 cm²
4
Volume to Capacity
A fish tank holds 60 000 cm³. How many litres?
1
Conversion: 1 L = 1 000 cm³
2
60 000 ÷ 1 000 = 60 L
Answer: 60 litres
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/32

Worked example: If the radius is 5 cm, use A = πr²: A ≈ 3.14 × 5² = 78.5 cm².
  1. Find the area of a circle with radius 5 cm. Use π ≈ 3.14. L1
  2. Find the area of a circle with diameter 12 m. L1
  3. Find the radius of a circle with diameter 18 cm. Then find its area. L1
  4. A circular table has radius 0.8 m. Find its area. L2
  5. A circular garden has diameter 10 m. How much soil area does it cover? L2
  6. Explain why you square the radius when finding area but not when finding circumference. L3
  7. A student uses diameter in A=πr² without halving it. Explain the error using a circle with diameter 14 cm. L3
Worked example: Break a composite figure into familiar shapes, find each area, then add or subtract.
  1. A rectangle is 12 cm by 8 cm. A semicircle with diameter 8 cm is attached to one side. Find the total area. L3
  2. A square has side length 10 cm. A circular hole with radius 3 cm is cut out. Find the remaining area. L3
  3. A shape is made from a 6 cm by 9 cm rectangle and a triangle with base 6 cm and height 4 cm. Find the area. L2
  4. A running track has two straight sections and two semicircle ends. The semicircles together make one full circle with radius 20 m. Find the area inside if the rectangle section is 60 m by 40 m. L4
  5. Draw or describe your own composite figure using at least one circle part. Label dimensions and find the area. L4
  6. A logo is a circle of radius 8 cm with a smaller circle of radius 3 cm removed. Find the shaded area. L3
Worked example: For a rectangular prism, use V = lwh. For a cylinder, use V = πr²h.
  1. A rectangular box is 8 cm × 5 cm × 4 cm. Find the volume. L1
  2. Find the volume of a rectangular prism with length 12 m, width 3 m, and height 5 m. L1
  3. A cylinder has radius 4 cm and height 10 cm. Find the volume. L2
  4. A cylinder has diameter 14 cm and height 6 cm. Find the volume. L2
  5. A water tank is a rectangular prism measuring 2 m by 1.5 m by 1 m. How many cubic metres does it hold? L2
  6. Which has greater volume: a cylinder with radius 3 cm and height 12 cm, or a rectangular prism 8 cm by 5 cm by 3 cm? L3
  7. A student doubles the height of a cylinder. What happens to the volume? Explain. L3
Worked example: For a rectangular prism, find all 6 faces or use SA = 2lw + 2lh + 2wh.
  1. Find the surface area of a rectangular prism with dimensions 4 cm, 5 cm, and 6 cm. L2
  2. Find the surface area of a cube with side length 7 cm. L1
  3. A cereal box is 20 cm by 8 cm by 30 cm. Find the surface area. L2
  4. A gift box has dimensions 12 cm by 10 cm by 8 cm. How much wrapping paper is needed, not including overlap? L2
  5. A box has no lid. Its base is 15 cm by 10 cm and height is 8 cm. Find the surface area of the open box. L3
  6. Explain the difference between volume and surface area using a shoebox example. L2
  7. Find two different rectangular prisms with volume 60 cm³. Compare their surface areas. L4
Worked example: Always check units: area is square units, volume is cubic units, and surface area is square units.
  1. A circular pizza has radius 15 cm. A square pizza has side length 25 cm. Which has greater area? L3
  2. A container is a cylinder with radius 5 cm and height 20 cm. Estimate whether it can hold 1.5 litres. Remember 1000 cm³ = 1 L. L4
  3. A classroom display board is 1.2 m by 2.4 m. How many square metres of paper cover it? L2
  4. Design a small package with a volume of exactly 120 cm³. Give dimensions and calculate surface area. L4
  5. A student gives an area answer in cm³. Explain why the unit is incorrect. L2
🚀 Extension Extension
  1. A drum used in a BC First Nations ceremony has a circular face of diameter 55 cm. The cedar rim is 4 cm wide. Find (a) the area of the circular face, (b) the area of just the rim, (c) what percent of the total circle the rim takes up.
  2. A cylindrical water storage tank holds exactly 10 000 litres. The height is 2.5 m. Calculate the radius of the tank. (Use π ≈ 3.14; remember 1 m³ = 1000 L.)
  3. Optimization: A canning company wants to design a cylinder that holds exactly 500 cm³ using the least amount of metal (minimum surface area). Using the formula SA = 2πr² + 2πrh with V = πr²h = 500, investigate different radius values (1 cm, 2 cm, 3 cm, 4 cm) to find the optimal dimensions.
  4. A composite solid is made of a rectangular prism (l = 10, w = 6, h = 4 cm) with a cylinder (r = 2 cm, h = 3 cm) drilled through from top to bottom. Find the remaining volume.
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Optimization: Least Material
Investigation
Find the most efficient cylinder dimensions.
Challenge

A can must hold exactly 330 cm³. You want to minimize the amount of metal used (surface area = 2πr² + 2πrh). Test radius values r = 1, 2, 3, 4, 5, 6 cm. For each, find h from V = πr²h = 330, then calculate SA. Which r minimizes material? Sketch the "best" can. How does it compare to a real soft drink can?

Stretch

Prove that the minimum surface area for a cylinder with fixed volume occurs when h = 2r (i.e., the height equals the diameter). Use the data from your table to support this.

Composite Figure Design
Design task
Create a composite shape with a target area.
Challenge

Design a BC-inspired composite shape (e.g., a totem pole silhouette, a salmon shape, a coast outline) made up of at least 3 different polygons and one circle/semicircle. Target total area: between 200 and 250 cm². Label all dimensions, show area calculations for each part, and verify the total.

Stretch

Calculate the perimeter of your composite shape. Explain which boundaries count as perimeter and which are internal dividing lines.

Cedar Box Builder
BC context · NRICH-style
Use surface area to plan material costs.
Challenge

A Haida artist builds traditional cedar boxes. Each box is 30 cm × 20 cm × 15 cm. (a) Calculate the surface area of one box. (b) Cedar planks cost $0.85/100 cm². How much does one box cost in materials? (c) She makes 12 boxes for a gallery — total material cost? (d) If she increases each dimension by 50%, by what factor does the surface area increase? By what factor does the volume increase?

Stretch

Prove algebraically that when all dimensions are multiplied by k, surface area multiplies by k² and volume multiplies by k³.

Fish Hatchery Tanks
BC context · Modelling
Combine volume and capacity in a fisheries context.
Challenge

A BC fish hatchery uses cylindrical tanks. Tank A: r = 80 cm, h = 120 cm. Tank B: r = 60 cm, h = 200 cm. (a) Which holds more water? By how many litres? (b) Both tanks are filled at 20 litres/minute. Which fills first? How much sooner? (c) If salmon need 15 litres each, how many salmon can each tank support?

Stretch

A new tank must hold exactly 3000 litres and have h = 2r. Find the dimensions of this tank (use π ≈ 3.14 and estimate to 2 decimal places).

Volume vs Surface Area
Compare strategies
Understand the difference between 3D measurements.
Challenge

Create 3 different rectangular prisms that all have volume = 24 cm³ (using integer dimensions). For each, calculate the surface area. Which has the smallest surface area? Which has the largest? What shape approaches the minimum surface area for a fixed volume?

Discussion

Why do animals in cold climates tend to be rounder (more sphere-like)? How does the ratio of surface area to volume relate to heat loss? Connect to BC wildlife (e.g., Pacific salmon vs arctic fish).

Dreamcatcher Measurement
BC context · Design
Apply circular measurement to a cultural context.
Challenge

A dreamcatcher hoop is made from a willow branch bent into a circle. The hoop has outer diameter 25 cm and the willow is 1.5 cm thick. (a) Find the area of the circular face of the hoop (annulus = outer circle − inner circle). (b) Find the circumference of the outer and inner circles. (c) If the hoop is decorated with beads placed every 3 cm along the outer circumference, how many beads are needed? (d) Web strings cross the inner circle 8 times — what is the total length of web strings if each crosses from edge to edge through the centre?

Stretch

If the hoop diameter doubles, by what factor does the annulus area change? By what factor does the circumference change? Generalize for any scale factor k.

Open Middle: Area = 60
Digit puzzle
Find all rectangular prisms with the same volume.
Challenge

Find all rectangular prisms with integer dimensions where Volume = 60 cm³. List them systematically. Which has the largest surface area? Which has the smallest? For which prism is the surface area closest to a cube's (i.e., most "cubic")?

Discussion

How does prime factorization help you find all the dimension combinations systematically? Use 60 = 2² × 3 × 5 as your starting point.

Estimation Clinic
Collaborative
Practice estimation strategies for measurement.
How it works

Provide 5 real objects (water bottle, textbook, eraser, roll of tape, tissue box). Each student estimates volume and surface area before measuring. Calculate percent error for each estimate.

Challenge

Develop a "personal benchmark" system: find a part of your body or an everyday object that is approximately 1 cm, 10 cm, and 100 cm². Use these benchmarks to estimate 5 more objects' measurements without measuring directly.

8

Data & Probability

Data collection, circle graphs, central tendency, outliers, theoretical vs experimental probability, two independent events.

Big Ideas

  • A sample is a subset of a population — well-designed sampling reduces bias and makes results more reliable.
  • Circle graphs show part-to-whole relationships; central angles must sum to exactly 360°.
  • Mean, median, and mode each measure "centre" differently — the best choice depends on the data.
  • An outlier is a data point far from the rest — it affects the mean much more than the median.
  • Theoretical probability predicts outcomes; experimental probability records them — both are valid and they converge with many trials.
📋
Data Collection
Populations vs samples, biased and unbiased survey questions, and designing fair data collection.
🥧
Circle Graphs
Calculating central angles, constructing circle graphs, and interpreting proportional data.
📊
Central Tendency
Mean, median, mode, range, and the effect of outliers on each measure.
🎲
Probability
Single events, sample space, two independent events, and comparing theoretical vs experimental probability.
How to use this page: Data collection and graphs first, then central tendency — these are two ways to summarize data. Probability is a separate strand but connects back through experimental data collection.
1
Central Tendency
Dataset: 4, 7, 9, 3, 7, 12, 5, 7, 8. Find mean, median, mode, range.
1
Order: 3, 4, 5, 7, 7, 7, 8, 9, 12
2
Mean: (3+4+5+7+7+7+8+9+12) ÷ 9 = 62 ÷ 9 ≈ 6.9
3
Median: middle value (5th of 9) = 7
4
Mode: 7 (appears 3 times)
5
Range: 12 − 3 = 9
Mean ≈ 6.9, Median = 7, Mode = 7, Range = 9
2
Two Independent Events
Flip a coin and roll a die. Find P(heads AND a 4).
1
Total outcomes: 2 × 6 = 12
2
Favourable outcomes: (H,4) = 1
3
P = 1/12
Answer: P(H and 4) = 1/12
3
Circle Graph — Central Angles
A survey of 400 students: 140 prefer hiking. Find the central angle for hiking.
1
Percent: 140 ÷ 400 = 35%
2
Central angle: 35% × 360° = 0.35 × 360 = 126°
Answer: 126°
4
Theoretical vs Experimental
A die is rolled 60 times; 6 appears 14 times. Compare theoretical and experimental probability.
1
Theoretical: P(6) = 1/6 ≈ 16.7%
2
Experimental: 14/60 ≈ 23.3%
3
These differ — that's normal! With more trials, results get closer to theoretical.
Theoretical ≠ Experimental (but both are valid)
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/34

Worked example: A good survey question is clear, unbiased, and gives choices that match what you want to measure.
  1. Write a clear survey question to find students’ favourite school lunch option. L1
  2. Explain why “Don’t you think soccer is the best sport?” is a biased survey question. L2
  3. Rewrite this biased question to make it fair: “Why is homework too hard?” L2
  4. A survey asks only 5 friends about favourite music. Explain why the sample may not represent the whole grade. L2
  5. Design a survey with at least 4 response categories and one “other” option. L3
  6. Explain the difference between categorical data and numerical data. Give one example of each. L2
Worked example: For 4,7,9,3,7, order first: 3,4,7,7,9. Median is 7 and mode is 7.
  1. Dataset: 4, 7, 9, 3, 7, 12, 5, 7, 8. Find mean, median, mode, and range. L2
  2. Dataset: 10, 12, 12, 15, 18, 20. Find mean, median, mode, and range. L2
  3. If 52 is added to the first dataset, which measure of central tendency is most affected? Why? L2
  4. Find a set of 6 numbers with median 10 and range 12. L3
  5. A student says mode is always the best average. Explain why this is not always true. L3
  6. Create a dataset where the mean is greater than the median because of an outlier. L3
  7. A basketball player scores 8, 12, 10, 9, and 26 points. Which average best represents a typical game? Explain. L4
Worked example: To find a central angle, multiply the percent by 360°. For 25%, 0.25 × 360° = 90°.
  1. A circle graph shows 40% of 250 students prefer soccer. How many students is that? L2
  2. A survey has sections: 50%, 25%, 15%, and x%. Find x. L2
  3. Find the central angle for a 25% section of a circle graph. L2
  4. Find the central angle for a 35% section of a circle graph. L2
  5. A class of 30 students chooses activities: art 6, sports 12, music 3, games 9. Convert each category to a percent. L3
  6. Using the activity data above, find the central angle for each section. L3
  7. Explain why all central angles in a circle graph must add to 360°. L3
Worked example: For a coin and a die, outcomes include H1, H2, ... H6, T1, T2, ... T6, so there are 12 outcomes.
  1. A bag has 5 red, 3 blue, and 2 green marbles. Write P(red) as a fraction, decimal, and percent. L1
  2. Flip a coin and roll a die. List the complete sample space. How many outcomes are there? L1
  3. Using the coin-and-die sample space, find P(tails AND even number). L2
  4. A spinner has 8 equal sections: 3 red, 2 blue, 2 green, 1 yellow. Find P(blue) and P(not blue). L2
  5. A card is chosen from numbers 1–12. Find the probability of choosing a multiple of 3. L2
  6. List all outcomes when two coins are flipped. What is P(exactly one head)? L2
  7. Create a probability event that is impossible, likely, and certain using the same bag of marbles. L3
Worked example: Theoretical probability is what should happen mathematically. Experimental probability is what actually happened in trials.
  1. A die is rolled 60 times and 6 appears 14 times. Compare theoretical and experimental probability. L3
  2. A coin is flipped 50 times and lands heads 31 times. Find the experimental probability of heads. L2
  3. Explain why experimental results may not match theoretical probability exactly. L2
  4. Design a 30-trial experiment with a spinner and record what data you would collect. L3
  5. A game has P(win)=1/4. In 40 plays, about how many wins would you expect? L2
  6. Two independent events have probabilities 1/2 and 1/3. Find the probability both happen. L3
  7. A student rolls a die three times and gets a 6 each time. Does this mean the die is unfair? Explain carefully. L4
🚀 Extension Extension
  1. Design a survey to investigate Grade 7 students' favourite outdoor activities in BC. Write 3 unbiased questions, describe how you would select a representative sample of 60 students from a school of 300, and explain what sampling method you used.
  2. Roll two dice and add the results. List all 36 possible outcomes. Find: P(sum = 7), P(sum > 9), P(sum is prime). Which sum is most likely? Explain why.
  3. A First Nations salmon monitoring program records the following weekly counts: 320, 285, 410, 290, 350, 315, 390. Calculate the mean and median. Which better represents the "typical" week and why? What would happen to the mean if one week recorded 850?
  4. Create a tree diagram for drawing 2 beads (without replacement) from a bag containing 1 red, 1 blue, 1 yellow bead. List all outcomes and find the probability that both beads are different colours.
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Class Data Investigation
Collaborative · BC context
Collect, display, and analyze real class data.
Challenge

Design a 3-question survey about outdoor activities in BC. Collect data from at least 20 people. Display results as a circle graph. Calculate mean, median, mode, and range for one numerical question. Write a 3-sentence conclusion about what your data shows.

Stretch

Identify one potential source of bias in your survey design and explain how it could be corrected. How might your results differ if you surveyed a different group?

Outlier Effect Lab
Investigation
Discover how outliers move the mean.
Challenge

Start with the dataset: 12, 14, 15, 16, 13, 14, 15. Calculate mean, median, mode, range. Now add these values one at a time and recalculate each time: (a) 14, (b) 100, (c) 0. Which measure changed the most each time? Write a rule for when to use mean vs median to represent "typical."

Stretch

A dataset has 8 values and a mean of 15. What single value could you add to make the mean exactly 18? Show the algebra.

Probability Fair Game?
NRICH-style
Analyze whether a game is fair.
Challenge

Two players roll a die. Player A wins if the result is prime. Player B wins if the result is composite. (a) Is this fair? Calculate P(A wins) and P(B wins). (b) Redesign the game so both players have P(win) = ½. (c) Create a new two-dice game that is fair but uses addition instead of individual rolls. Prove it's fair using a sample space table.

Stretch

For the original game, if Player A wins $3 and Player B wins $2, what is the expected earning per game for each player? Which player has the advantage?

Salmon Survey Design
BC context · Menu
Design and critique a real-world sampling method.
Challenge

A BC Ministry of Fisheries wants to estimate the salmon population in a river system. Propose a sampling method. (a) Describe your sampling strategy (random, systematic, or stratified). (b) What potential biases exist? (c) If a sample of 200 fish is tagged and released, and 15 of 120 fish caught later are tagged, estimate the total population using the capture-recapture method (Population ≈ first catch × second catch ÷ recaptured). (d) What assumptions does this method require?

Stretch

If the estimated population is 1 600 and the sustainable harvest is 35%, how many fish can be harvested? What if the estimate has a 20% margin of error — what is the safe harvest range?

Two-Event Space Builder
Investigation
Build and analyze complete sample spaces.
Challenge

Build the complete sample space for: (a) rolling two dice and recording the sum; (b) spinning a spinner with sections 1, 2, 3 and flipping a coin. For each: count total outcomes, find the most likely outcome, calculate P(sum > 6) or P(spinner > 1 AND heads). Compare theoretical probability to 30 simulated trials.

Discussion

Why does "sum = 7" have the highest probability in (a)? Prove it using the sample space table. How many ways can each sum from 2–12 be made?

Circle Graph Gallery
Design task
Design and decode circle graphs.
Challenge

Collect data on how Grade 7 students spend a typical weekend day (categories: sleep, screen time, outdoors, homework, meals, other). Create a circle graph with correct central angles. Then swap graphs with a partner and write 5 interpretation statements about their graph — each must include a calculation.

Stretch

Combine your graph and your partner's graph into a class average. How do you calculate the combined central angles when the sample sizes are different?

Experimental vs Theoretical Race
Compare strategies
Test the law of large numbers.
Challenge

Theoretical P(heads) = ½. Flip a coin 10 times, 30 times, 100 times. Record the experimental probability after each set. Plot "number of flips" on the x-axis and "experimental P(heads)" on the y-axis. What do you notice as the number of flips grows? Describe the pattern in words and connect it to the Law of Large Numbers.

Discussion

If a coin lands heads 7 times in a row, what is P(heads on the next flip)? Why do many people get this wrong?

Statistical Storytelling
Open Middle
Work backwards from statistics to data.
Challenge

Create a dataset of exactly 8 values (all integers from 1–20) that satisfies ALL of: mean = 11, median = 10.5, mode = 8, range = 14. Prove your dataset works. Then change exactly one value to make the mean = 12 while keeping median and mode the same.

Stretch

Prove that if a dataset has an even number of values, the median is always the mean of the two middle values. Why can't the median equal a value not in the dataset for an odd-sized dataset?

9

Financial Literacy

BC GST & PST, discounts & sale price, tips, income types, budgeting, and simple interest — all grounded in real BC financial contexts.

Big Ideas

  • BC GST (5%) and PST (7%) are applied to most goods — some items such as basic groceries are exempt.
  • A discount reduces the original price by a percent — the sale price is always calculated from the original.
  • Gross pay is total earnings before deductions; net pay is what you actually take home.
  • A budget balances income against expenses — tracking needs vs wants helps with financial decisions.
  • Simple interest I = Prt grows linearly; it is calculated on the original principal only.
🧾
Tax & Discount
Applying BC GST (5%) and PST (7%), calculating discounts and sale prices, and finding the original price.
💰
Income & Wages
Hourly wages, gross pay vs net pay, and comparing different pay structures.
📋
Budgeting
Needs vs wants, creating and balancing a budget, tracking income and expenses.
🏦
Simple Interest
Using I = Prt to calculate interest earned or owed, and planning savings goals.
How to use this page: Tax and discount first (builds directly on Unit 4 percent work), then income, then budgeting, then interest. These four strands reflect real BC financial decision-making.
1
BC Sales Tax (GST + PST)
Running shoes cost $120.00 in BC. Find GST, PST, and total price.
1
GST (5%): $120 × 0.05 = $6.00
2
PST (7%): $120 × 0.07 = $8.40
3
Total tax: $6.00 + $8.40 = $14.40
4
Total price: $120 + $14.40 = $134.40
Answer: Total = $134.40
2
Discount & Sale Price
A snowboard costs $280 with 30% off. Find the sale price.
1
Discount: $280 × 0.30 = $84
2
Sale price: $280 − $84 = $196
3
Shortcut: $280 × 0.70 = $196
Answer: Sale price = $196
3
Finding the Original Price
A jacket costs $68 after a 20% discount. What was the original price?
1
$68 = 80% of original (100% − 20%)
2
Original = $68 ÷ 0.80 = $85
Answer: Original price = $85
4
Simple Interest
$500 deposited at 3% simple interest per year. Interest after 2 years?
1
Formula: I = P × r × t
2
I = $500 × 0.03 × 2 = $30
Answer: Interest = $30. Total = $530.
🪶 First Peoples Connection — Traditional Economy
Many BC First Nations historically used potlatch ceremonies involving redistribution of wealth — a system where surplus resources were shared with the community. Compare this to modern concepts of budgeting and saving: how do both systems balance having enough for today vs. saving for future needs? Discuss with a partner.
🏠 Homework Homework

Name: _________________________    Date: _____________    Score: ___/33

Worked example: In BC, GST is 5% and PST is 7% for many purchases. For a $100 taxable item, total tax is $5 + $7 = $12.
  1. A bicycle costs $349.99 in BC. Calculate GST (5%), PST (7%), and total price. L1
  2. A video game costs $64.99. How much GST is charged? How much PST? L1
  3. Convert: 7% as a decimal; 12% as a fraction; 0.05 as a percent. L1
  4. A hoodie costs $42. Calculate GST, PST, and final total. L2
  5. A calculator costs $18.50. Calculate the final price after 12% tax. L2
  6. An item costs $250 before tax. Explain two ways to calculate the final price with 12% tax. L3
  7. A receipt shows $8.40 total tax at 12%. What was the pre-tax price? L3
Worked example: For a $195 jacket with 40% off, discount is 0.40 × 195 = $78, so sale price is $117.
  1. A ski jacket is $195 with 40% off. Find the discount amount and sale price. L2
  2. A tablet is $420 with 15% off. Find the sale price before tax. L2
  3. A pair of shoes is $89.99 with 25% off. Estimate the sale price. L2
  4. An item is on sale for $68 after a 20% discount. What was the original price? L3
  5. A price increases from $80 to $100. Find the percent increase. L3
  6. A $60 item is discounted by 30%, then tax is added. Find the final price in BC. L3
  7. Which saves more on a $120 item: 20% off or $25 off? Explain. L2
Worked example: Simple interest uses I = Prt. For $800 at 4% for 3 years: 800×0.04×3 = $96.
  1. A meal costs $56. Calculate a 15% tip. L2
  2. A worker earns $16.50/hour and works 36 hours this week. Calculate gross weekly pay. L3
  3. A student earns $12/hour babysitting and works 6 hours. How much do they earn? L1
  4. Calculate simple interest: $800 at 4% for 3 years. What is the total amount? L3
  5. Calculate simple interest on $1,200 at 3.5% for 2 years. L3
  6. A server earns $72 in tips over 6 hours. What is the tip income per hour? L2
  7. Explain the difference between gross pay and net pay. L2
Worked example: A budget is a plan for income, spending, and saving. Check that the total categories do not exceed the income.
  1. A student earns $12/hour, works 6 hours per week, and saves 40%. After 12 weeks, how much have they saved? L3
  2. A student has $240. They spend 25% on clothes and 15% on food. How much is left? L2
  3. Create a monthly budget for $160 income with categories for saving, spending, and giving. L2
  4. A snowboard costs $250 before tax. How much is the final price in BC? L2
  5. If a student saves $28.80 per week, how many weeks are needed to afford the snowboard from the previous question? L3
  6. A student wants to save $500 in 20 weeks. How much must they save per week? L2
  7. Explain why saving 20% of every paycheque can be more effective than saving “whatever is left.” L3
Worked example: The best financial choice is not always the cheapest at first; consider total cost, taxes, quality, and needs versus wants.
  1. You have $100 to spend on school supplies. Make a shopping list that includes tax and stays under budget. L3
  2. A store offers “buy 2, get 1 free” on $18 shirts. Another store offers 30% off each shirt. Which is cheaper for 3 shirts? L4
  3. A phone plan is $25/month plus $0.05 per text. Another is $35/month unlimited. When is the unlimited plan better? L4
  4. Explain the difference between a need and a want using three examples. L1
  5. Design a short financial advice poster for Grade 7 students about one of these topics: tax, discounts, saving, or budgeting. L4
🚀 Extension Extension
  1. Research BC's actual GST-exempt items. List 5 things that are GST-exempt and 5 that are PST-exempt. Explain the policy reasoning behind at least one exemption. Why might groceries be exempt from GST?
  2. Compound interest preview: $1000 invested at 5% annually for 3 years with compound interest vs simple interest. Calculate both and find the difference. (Compound: each year's interest is added to the principal before the next year's interest is calculated.)
  3. Budget challenge: You have $2000 to plan a 5-day camping trip to BC's backcountry for 4 people. Research realistic costs for food, transportation, permits, and gear. Create a detailed budget with categories, showing GST/PST where applicable, and determine if $2000 is enough.
  4. A First Nations artisan sells cedar baskets. The materials cost $45 each. She sells them at a 120% markup. A gallery then marks up her price by 35% for their commission. What does the final customer pay? What percent of the final price goes to the artisan?
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Budget Build
Design task · BC context
Create a realistic monthly budget for a Grade 7 student.
Challenge

You earn $15/hour and work 8 hours per week. Create a monthly budget. Research actual BC prices for: transportation (bus pass), phone plan, school supplies, food (3 lunches/week), entertainment, savings. Use GST/PST where applicable. Calculate percent of income for each category. Is your budget balanced?

Stretch

Your hours are cut to 6/week. Adjust your budget. Which category do you cut first, and why? Calculate the percent reduction in total spending.

Tax Investigation
Investigation · BC context
Investigate BC's actual tax rules.
Challenge

Research BC's GST and PST exemptions. Create a "tax classification table" for 20 items (at least 5 from each category: food, clothing, electronics, sports equipment, books). Calculate the total tax on a $200 shopping cart with 10 different items — some exempt, some not. Compare to a fictional province with a flat 10% tax on everything.

Discussion

Why does BC exempt basic groceries from GST? What is the policy argument? Who benefits most from this exemption?

Interest vs Debt Comparison
NRICH-style
Compare saving vs borrowing over time.
Challenge

Scenario A: You save $50/month at 3% simple annual interest for 5 years. Scenario B: You borrow $3000 at 8% simple annual interest and pay it back over 5 years. (a) For Scenario A, calculate total saved including interest each year for 5 years. (b) For Scenario B, calculate total interest paid. (c) Compare: how much more do you pay in interest in Scenario B vs earn in Scenario A? (d) What monthly savings rate would earn the same as the loan costs?

Stretch

Research compound interest. If Scenario A used compound interest instead, how much more would be earned over 5 years? (Compound annually: A = P(1 + r)ⁿ)

Artisan Economics
BC context · Menu
Apply financial literacy to a First Nations artisan context.
Challenge

A Haida artist sells carved pendants. Materials cost $18 each, she spends 2.5 hours making each, and values her time at $22/hour. (a) What is her total cost per pendant? (b) She wants to make 40% profit — what price should she charge (before tax)? (c) What does a customer pay with BC taxes? (d) She sells 12 pendants at a craft fair with a $75 table fee. Calculate net profit. (e) At what number of pendants sold does she break even (cover table fee)?

Stretch

If she increases her hourly rate by 10%, what new price maintains the same 40% profit margin? By what percent does the selling price increase?

Pay Structure Comparison
Open Middle
Compare different pay models.
Challenge

Three job offers: Job A: $14/hour, 30 hours/week. Job B: $1600/month flat salary. Job C: $0.45/item produced, typically 3000 items/month. (a) Calculate weekly/monthly gross pay for each. (b) Which pays most per month? (c) Job C is unpredictable — in a slow month you produce 2000 items. Recalculate. (d) After 15% tax deductions, what is net monthly pay for each job?

Stretch

At what hourly rate (for 30 hours/week) does Job A equal Job B? Set up and solve an equation.

Sale Season Strategy
Collaboration · Compare
Determine when to buy to maximize savings.
Challenge

A snowboard is $349.99 regularly. Deals throughout the year: January — 30% off + BC taxes; March — 15% off + no PST; October — buy 1 get 1 at 50% off (need one board). (a) Calculate the final price in each sale. (b) Which is cheapest? (c) In March, is saving PST better than the January extra discount? By how much? (d) If you buy two boards in October, what is each board's effective price?

Discussion

Create a general formula: for what discount percentage does "no PST" (7% off) give a better deal than an extra x% regular discount?

Needs vs Wants Debate
Collaborative
Categorize and defend spending priorities.
How it works

List 20 purchases a Grade 7 student might make. Each student categorizes them as Need or Want and assigns a priority rank 1–5. Compare rankings in groups of 4 — discuss disagreements.

Challenge

You have $500 and a ranked list of 15 potential purchases with prices (including BC taxes). You must include at least 2 "needs." Select items to maximize your total priority score while staying within budget. Set up and solve this as a constrained optimization — which combination wins?

Savings Goal Calculator
Modelling
Plan a savings strategy using simple interest.
Challenge

You want to buy a mountain bike that costs $680 + BC taxes. You have $200 saved at 3% simple annual interest. You can also save $35/month from earnings. (a) How long until you can afford the bike counting only savings (no interest)? (b) How much interest does your $200 earn during this time? (c) With interest included, how much sooner do you reach your goal? (d) If the bike goes on sale for 20% off at a specific date, set up an equation to find whether it's worth waiting for the sale.

Stretch

Build a month-by-month savings tracker spreadsheet (table) for 18 months showing: savings balance, monthly interest, cumulative total, and distance to goal.

10

Review & Consolidation

Final review across all units — Number & Operations, Algebra, Geometry, Measurement, Data & Probability. Build your portfolio and prepare for the end-of-year assessment.

Year in Review — Topics Covered

  • Units 1–4 & 9: Number Sense, Fractions, Integers, Ratio/Rate/Percent, Financial Literacy
  • Unit 5: Patterns, Expressions, Two-Step Equations, Linear Relations
  • Units 6–7: Geometry (Angles, Circles, Transformations) and Measurement (Area, Volume, SA)
  • Unit 8: Data Collection, Central Tendency, Circle Graphs, Probability

Revisit any unit's video tab to review a specific concept. Use the mixed quiz below to test your readiness across all strands.

📝 Mixed Review Worksheet All Units

Name: _________________________    Date: _____________    Score: ___/37

Worked example: Choose the most useful form before calculating: fractions for exact values, decimals for money, and percents for comparisons.
  1. Write the prime factorization of 84 and use it to find two factor pairs. L2
  2. Find GCF(36,60) and LCM(6,8,12). L2
  3. Calculate 3/4 + 5/8, 2 1/3 − 1 3/4, and 2/3 × 9/4. L2
  4. Order: 0.625, 5/8, 63%, and 6/10. L2
  5. Convert 0.375 to a fraction and percent. L2
  6. A $75 item is discounted 20%, then 12% tax is added. Find the final price. L3
Worked example: Use signs carefully and check answers with a number line or real-world context.
  1. Calculate (−8)+(+5), (+3)−(−9), (−6)×(−7), and (+48)÷(−6). L2
  2. Evaluate −3 + 2(−5). L2
  3. Evaluate (−4)² − 10. L2
  4. A diver is at −18 m and descends another 7 m. What is the new depth? L2
  5. A game score changes by +12, −20, +8, and −5. What is the total change? L2
  6. Explain why −5 − 8 is not the same as 8 − 5. L3
Worked example: Ratio compares quantities, rate compares quantities with different units, and percent compares to 100.
  1. Write 18:24 in simplest form. L1
  2. Find the unit rate: 300 km in 5 hours. L1
  3. Solve the proportion 3/5 = x/40. L2
  4. A recipe has a ratio of 2:3 for juice to water. If 12 cups of water are used, how much juice is needed? L2
  5. Find 35% of 240. L2
  6. A worker earns $17/hour for 24 hours. They save 30% of their gross pay. How much do they save? L3
Worked example: Connect patterns to tables, graphs, expressions, and equations.
  1. Continue the pattern and write the rule: 5, 9, 13, 17, ___, ___. L1
  2. Complete a T-table for y = 4n + 1 using n=1,2,3,4,5. L1
  3. Evaluate 5a − 3 when a=8. L1
  4. Solve 3x + 4 = 25. L2
  5. A growing pattern has 6 tiles in Figure 1, 10 in Figure 2, and 14 in Figure 3. Write a rule for Figure n. L3
  6. Two rules are A=2n+8 and B=5n−1. Find the value of n when they are equal. L4
Worked example: For geometry problems, draw or imagine the shape first, then choose the correct formula or transformation rule.
  1. Reflect point A(3,−4) over the y-axis. Write the new coordinate. L2
  2. Rotate point B(2,5) 90° clockwise about the origin. Write the new coordinate. L3
  3. Check whether a regular hexagon tessellates on its own by using its interior angle. L2
  4. Find the circumference of a circle with diameter 14 cm. L2
  5. Find the area of a circle with radius 6 cm. L2
  6. Find the volume of a rectangular prism measuring 8 cm by 5 cm by 4 cm. L1
  7. Find the surface area of a rectangular prism measuring 4 cm by 5 cm by 6 cm. L2
Worked example: Use data tools for summaries and probability tools for chance. Explain what your answer means in context.
  1. Dataset: 3, 5, 7, 7, 8, 11. Find mean, median, mode, and range. L2
  2. A circle graph section is 30%. Find the central angle. L2
  3. A bag has 4 red, 5 blue, and 1 yellow marble. Find P(blue). L1
  4. Flip a coin and roll a die. Find the probability of tails and an odd number. L2
  5. A die is rolled 80 times and lands on 2 fifteen times. Compare theoretical and experimental probability. L3
  6. Design one final review question that combines at least two units. Solve it and label which units it connects. L4
Teacher note: These are original low-floor, high-ceiling tasks built to fit this unit. They are designed to invite multiple strategies, discussion, and extension instead of one fixed method.
Math Autobiography
Reflection · Portfolio
Reflect on your Year 7 math journey.
Challenge

Write a 1-page mathematical autobiography. Include: (a) The unit or concept you found most challenging and how you overcame it. (b) A specific problem you solved that you are proud of — explain your solution. (c) A real-world connection you made between math class and your everyday life. (d) One mathematical question you still wonder about. Use at least 3 mathematical terms from the year.

Stretch

Select your best piece of mathematical work from the year. Write a 1-paragraph reflection explaining what mathematical thinking it demonstrates and what you would do differently.

Cross-Strand Challenge
NRICH-style · All units
Solve a problem that uses skills from 4+ units.
Challenge

A BC First Nations community plans a salmon festival. 480 guests attend. Food costs $18.75/person (+ BC taxes). A circular performance area has diameter 20 m. Tickets are sold at a 15% markup on cost. A fundraising game uses a spinner with 5 equal sections. Plan the festival by: (a) calculating total food cost with tax; (b) setting the ticket price; (c) finding the area and circumference of the performance space; (d) calculating P(winning) and expected earnings per 100 game plays if the prize is $5 and the game costs $2 to play.

Strand check

This problem uses Units 2 (fractions/percent), 4 (ratio/percent), 6 (circles), 7 (area), and 8 (probability). Identify which calculation belongs to which unit.

Design Your Own Assessment
Collaborative · Menu
Create a test that shows understanding.
Challenge

In groups of 4, each person writes 3 questions: one L1, one L3, and one L4, from a different unit (divide units 1–4 among the group). Compile into a 12-question "peer test." Exchange tests between groups. Mark using an answer key you create together.

Stretch

Write a marking rubric for your L4 question. What earns full marks, partial marks, and no marks? Use mathematical vocabulary in your rubric.

BC Context Portfolio
Design task
Apply all strands to a single BC scenario.
Challenge

Choose one BC context from this list: salmon fisheries, cedar basket weaving, BC mountain hiking, a First Nations community feast. Create a portfolio page that includes: (a) One number/fraction/percent problem; (b) One algebraic equation or pattern; (c) One geometry or measurement calculation; (d) One probability or data display. All must use realistic numbers from your chosen context.

Stretch

Connect two of your four problems with a "bridge" — a sentence explaining how the answer from one is used in another.

Estimation Olympics
Collaborative · All strands
Compete in a whole-class estimation challenge.
Events

Closest estimate wins each event: (a) Number Sense — estimate GCF(144, 252) without calculating; (b) Measurement — estimate the area of the classroom floor in m²; (c) Data — estimate the mean of 20 values shown for 10 seconds; (d) Probability — estimate P(sum = 7) for two dice as a percent without a table; (e) Geometry — estimate the circumference of a circle with diameter 37 cm.

Discussion

Which estimation required the most mathematical reasoning vs experience? Which benchmarks or strategies were most useful?

Error Analysis Gallery
Reasoning · All units
Find, fix, and explain common mistakes.
Challenge

Each card shows a worked solution with one mathematical error. For each: (a) identify the error; (b) explain why it is wrong; (c) show the correct solution. Cards cover: adding fractions incorrectly, wrong percent change direction, BEDMAS error with integers, incorrect surface area setup, biased probability claim.

Stretch

Create your own "error card" for a concept you found tricky. Write a plausible but wrong solution and the correct one. Include a hint that helps without giving away the error.

Linear Relation Scavenger Hunt
Investigation · Unit 5 focus
Find linear relations hiding in everyday life.
Challenge

Find 5 real-life linear relations (e.g., taxi fare vs distance, cell phone data cost vs GB used, temperature vs elevation, BC ferry cost vs passengers). For each: write the equation y = mx + b; identify m and b and explain what they mean in context; create a T-table; determine at what point the cost/quantity crosses a threshold of your choosing.

Stretch

Two of your five relations must come from BC-specific contexts (e.g., BC Ferries pricing, BC hydro rates, or local transit costs). Source your data from real websites and cite them.

Mathematical Postcard
Design task · Portfolio
Summarize the year in a beautiful one-pager.
Challenge

Design a "mathematical postcard" that represents everything you learned in Grade 7 Math. Include: (a) One equation or formula from each of the 4 strands; (b) A visual (graph, diagram, or geometric figure); (c) One BC context connection; (d) Your "mathematical motto" for Grade 8. Use colour, symbols, and mathematical notation — make it visually striking and mathematically accurate.

Teacher note

Display these in the classroom or compile into a class "Year in Math" booklet. These make excellent portfolio cover pages.