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Understanding compound percentages

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visibility 157update 7 months agobookmarkshare

🎯 In this topic you will

  • Use and understand compound percentages
 

🧠 Key Words

  • compound percentage
Show Definitions
  • compound percentage: A percentage change applied repeatedly over time, where each change is based on the new value after the previous change.
 

You already know how to work out a percentage increase and decrease using a multiplier. For example:

When a price of $300$ is increased by 20%, the new price is $300 \times 1.2 = 360$.

The multiplier is 1.2 because $100\% + 20\% = 120\% = \tfrac{120}{100} = 1.2$

When a price of $300$ is decreased by 20%, the new price is $300 \times 0.8 = 240$.

The multiplier is 0.8 because $100\% - 20\% = 80\% = \tfrac{80}{100} = 0.8$

A compound percentage change is when a percentage increase or decrease is followed by another percentage increase or decrease.

 
Worked example

The value of a new car is $12{,}000.
In the first year, the value of the car decreases by 20%.
In the second year, the value of the car decreases by 15%.
Work out the value of the car at the end of the second year.

Answer:

$100\% - 20\% = 80\% = 0.8$

$12{,}000 \times 0.8 = 9600$

$100\% - 15\% = 85\% = 0.85$

$9600 \times 0.85 = 8160$

In the first year, the value of $12{,}000 decreases by $20\%$, so the multiplier is $0.8$. At the end of the first year, the car is worth $9600$.

In the second year, the value of $9600$ decreases by $15\%$, so the multiplier is $0.85$. Multiplying gives $9600 \times 0.85 = 8160$.

At the end of the second year, the value of the car is $8160$.

 

🧠 PROBLEM-SOLVING Strategy

Compound Percentages with Multipliers

Handle successive increases/decreases by multiplying the corresponding multipliers in one step.

  1. Build a single-step multiplier.
    Increase by $P\%$ ⇒ multiplier $1+\dfrac{P}{100}$; Decrease by $P\%$ ⇒ multiplier $1-\dfrac{P}{100}$.
  2. Chain changes by multiplying.
    Overall multiplier = product of each step’s multiplier.
    Example: $+20\%$ then $-15\%$$1.20\times0.85=1.02$ (net $+2\%$).
  3. Same increase then same decrease.
    $(1+\tfrac{P}{100})(1-\tfrac{P}{100})=1-\left(\tfrac{P}{100}\right)^2<1$ for $P>0$ ⇒ overall decrease.
  4. From two values to % change.
    Given original $x$ and new $y$, multiplier $m=\dfrac{y}{x}$, % change $(m-1)\times100\%$.
  5. Repeated equal changes (compound interest/decay).
    After $n$ periods at rate $r$ per period: amount = $\text{initial}\times(1+r)^n$ (growth) or $\text{initial}\times(1-r)^n$ (decay).
Reasoning Tip: Order matters when the rates differ (e.g., $+20\%$ then $-10\%$ vs $+10\%$ then $-20\%$) because $1.20\times0.90\neq1.10\times0.80$.

Worked example

  1. Car depreciation:$12{,}000$$20\%$, then ↓$15\%$.
    Step multipliers: $0.80$ and $0.85$. Overall multiplier: $0.80\times0.85=0.68$.
    Final value: $12{,}000\times0.68=8{,}160$.
  2. Mixed change:$200$$10\%$, then ↑$15\%$.
    Multiplier: $1.10\times1.15=1.265$. Result: $200\times1.265=253$.
  3. Back-to-back equal rates:$60$$20\%$ then ↓$20\%$.
    Multiplier: $1.20\times0.80=0.96$$60\times0.96=57.6$ (overall $-4\%$).
Algebra connection: For successive rates $r_1,r_2,\dots,r_n$ (as decimals), $\text{overall multiplier}=\prod_{k=1}^n(1+r_k)$; final value $= \text{initial}\times\prod_{k=1}^n(1+r_k)$.
 

EXERCISE

1. Copy and complete the workings for these compound percentage changes:

a. $200 increased by 10%, then increased by 15%.

b. $200 decreased by 10%, then decreased by 15%.

c. $200 increased by 20%, then decreased by 5%.

👀 Show answer

1a.
$200 × 1.1 = 220
220 × 1.15 = $253

1b.
$200 × 0.9 = 180
180 × 0.85 = $153

1c.
$200 × 1.2 = 240
240 × 0.95 = $228

🔎 Reasoning Tip

Remember:

  • For an increase, add the percentage onto 100%.
  • For a decrease, subtract the percentage from 100%.
 

🧠 Think like a Mathematician

Task: Investigate what happens to the value of an item when it increases by a percentage and then decreases by the same percentage.

Discussion Statements:

Marcus: “I think that after the increase and decrease, the value of the coin will still be $800.”
Sofia: “I think that after the increase and decrease, the value of the coin will be less than $800.”

Questions:

a) Who do you think is correct, Marcus or Sofia? Explain why.
b) Work out who is correct. Explain the mistake the other person has made.
c) If the coin has a 10% decrease followed by a 10% increase, will the final value be more or less than $800? Explain why.
d) Check your answer by working out the new value of the coin.
👀 show answer
  • a) Sofia is correct. After an increase and then a decrease by the same percentage, the final value is lower than the starting value.
  • b) Calculation: Start = $800. Increase by 10%: $800 \times 1.1 = 880$. Decrease by 10%: $880 \times 0.9 = 792$. Final value = $792. Marcus’s mistake: he assumed the effects of +10% and -10% cancel each other out, but the base values are different.
  • c) If the coin first decreases by 10%, $800 \times 0.9 = 720$. Then increase by 10%: $720 \times 1.1 = 792$. The final value is still less than $800.
  • d) In both cases (increase then decrease, or decrease then increase), the final value = $792, which is less than $800.
 

EXERCISE

3a. Work out these compound percentage changes:

  • i) 60 increased by 20%, then decreased by 20%
  • ii) 60 decreased by 20%, then increased by 20%

3b. Which sign, <, > or = is missing from this sentence?

60 increased by 20%, then decreased by 20% □ 60 decreased by 20%, then increased by 20%

3c. Without doing any calculations, decide which sign (<, > or =) is missing from each sentence:

  • i) 72 decreased by 15%, then increased by 15% □ 72 increased by 15%, then decreased by 15%
  • ii) 140 increased by 8%, then decreased by 8% □ 140 decreased by 8%, then increased by 8%
👀 Show answer

3a i)
60 × 1.2 = 72
72 × 0.8 = 57.6

3a ii)
60 × 0.8 = 48
48 × 1.2 = 57.6

3b.
Both results are 57.6, so the missing sign is =

3c i)
If you decrease then increase by the same percentage, the final value is less than the original. Missing sign: <

3c ii)
Same reasoning: increasing then decreasing (or vice versa) leaves the value smaller. Missing sign: <

 

🧠 Think like a Mathematician

Task: Compare three different methods for working out compound percentage increases and reflect on which approach is most effective.

Methods:

Anil: First increase: $50 \times 1.2 = 60$ Second increase: $60 \times 1.1 = 66$
Raj: Both increases together: $50 \times 1.2 \times 1.1 = 66$
Mari: Multiplier: $1.2 \times 1.1 = 1.32$ Final value: $50 \times 1.32 = 66$

Questions:

a) What is the difference between Anil’s method and Raj’s method?
b) What is the difference between Raj’s method and Mari’s method?
c) Whose method is easiest to use if you have a calculator?
d) Whose method is easiest to use if you do not have a calculator?
e) Whose method do you prefer? Explain why.
👀 show answer
  • a) Anil increases the number step by step, while Raj combines the two percentage increases in one calculation. Both give the same result.
  • b) Raj directly multiplies by both factors, while Mari first simplifies the combined multiplier $(1.2 \times 1.1 = 1.32)$ before multiplying once. Both methods are equivalent.
  • c) Raj’s or Mari’s methods are easiest with a calculator, since they involve fewer separate steps.
  • d) Anil’s step-by-step method is easier without a calculator because it uses simpler numbers at each stage.
  • e) Preference may vary: - If you want fewer steps, Mari’s method is simplest. - If you want to check progress after each stage, Anil’s method is clearer. - Raj’s method is a balance between the two.
 

EXERCISE

5a. Work out the final value after these compound percentage increases (Raj’s method):

  • i) 120 increased by 25%, then increased by 30%
  • ii) 40 increased by 15%, then increased by 40%

5b. Work out the final value after these compound percentage increases (Mari’s method):

  • i) 400 increased by 50%, then increased by 5%
  • ii) 90 increased by 12%, then increased by 8%

🔎 Reasoning Tip

Remember that in part bi, the multiplier for a 5% increase is 1.05.

👀 Show answer

6. Mari uses the train company ‘GoRail’ to travel to work.

  • In 2018, GoRail increased the cost of a ticket by 7%.
  • In 2019, GoRail increased the cost of a ticket by 5%.

6a. Use Mari’s method to work out the multiplier for the compound percentage increase.
6b. In 2017, Mari buys a ticket for $60. How much will this ticket cost her in 2019?

👀 Show answer

6a.
Multiplier = 1.07 × 1.05 = 1.1235

6b.
60 × 1.1235 = $67.41

7a. Work out the final value after these compound percentage decreases (Raj’s method):
i) 100 ↓10%, then ↓20%    ii) 80 ↓25%, then ↓12%

7b. Work out the final value after these compound percentage decreases (Mari’s method):
i) 600 ↓50%, then ↓5%    ii) 76 ↓30%, then ↓9%

👀 Show answer

8. Mari buys a new motorbike. In year 1 the value decreases by 18%. In year 2 it decreases by 12%.

8a. Find the multiplier for the compound percentage decrease.
8b. If the bike cost $6400 in 2017, what will it be worth after two years?

👀 Show answer

8a. Multiplier = (1 − 0.18)(1 − 0.12) = 0.82 × 0.88 = 0.7216

8b. Value after two years = 6400 × 0.7216 = $4618.24

9. Match each percentage change (left) with its multiplier (right).

Changes

  1. 20% increase then 10% decrease
  2. 18% increase then 30% decrease
  3. 12% decrease then 20% increase
  4. 40% decrease then 35% increase
  5. 15% increase then 32% decrease
  6. 5% decrease then 8% increase

Multipliers

  1. 1.056
  2. 0.782
  3. 1.08
  4. 0.826
  5. 1.026
👀 Show answer

Tip: Convert each change to a multiplier and multiply them.

  • A: 1.2 × 0.9 = 1.08 → matches iii
  • B: 1.18 × 0.7 = 0.826 → matches iv
  • C: 0.88 × 1.2 = 1.056 → matches i
  • D: 0.6 × 1.35 = 0.81leftover card (not listed)
  • E: 1.15 × 0.68 = 0.782 → matches ii
  • F: 0.95 × 1.08 = 1.026 → matches v

Answer map: A→iii, B→iv, C→i, D→0.81 (extra), E→ii, F→v.

10.
Context: $5000 invested at 4% interest per year (compound, added at year end).

10a. Zara says: for the end of year 2, instead of writing 5000 × 1.04 × 1.04, Pieter could write 5000 × (1.04)². Is she correct? Explain.

10b. For the end of year 3, write a single calculation instead of 5000 × 1.04 × 1.04 × 1.04.

10c. For the end of year 4, write a single calculation instead of multiplying four 1.04s.

10d. If the investor writes 5000 × (1.04)^8, for how many years has the money been invested? Explain.

10e. Write a calculation to find the amount at the end of: i) 12 years   ii) 20 years   iii) n years.

10f. After how many years will the balance be more than $9000? Show working.

👀 Show answer

10a.Yes. By index laws, multiplying by 1.04 twice is the same as raising 1.04 to the power 2: 1.04 × 1.04 = (1.04)². So 5000 × 1.04 × 1.04 = 5000 × (1.04)².

10b.5000 × (1.04)³.

10c.5000 × (1.04)^4.

10d.5000 × (1.04)^8 corresponds to 8 years, because the exponent counts how many yearly 4% growth factors are applied.

10e.
i) 5000 × (1.04)^12
ii) 5000 × (1.04)^20
iii) 5000 × (1.04)^n

10f. Solve 5000(1.04)^t > 9000(1.04)^t > 1.8. Using logs: t > ln(1.8)/ln(1.04) ≈ 14.99. Therefore after 15 years it first exceeds $9000: 5000 × (1.04)^15 ≈ $9004.72.

11.
Context: The population of a town is 10,000. It decreases at a steady rate of 10% per year.

11a. Write a calculation to work out the population of the town after:
i) 1 year    ii) 2 years    iii) 3 years

11b. What does the calculation 10000 × (0.9)⁵ represent?

11c. What does the calculation 10000 × (0.9)¹⁰ represent?

11d. After how many years does the population of the town first fall below 6000 people? Show how you worked it out.

11e. Write a calculation to work out the population of the town after n years.

👀 Show answer

11a.
i) After 1 year: 10000 × 0.9 = 9000
ii) After 2 years: 10000 × (0.9)² = 8100
iii) After 3 years: 10000 × (0.9)³ = 7290

11b. This represents the town’s population after 5 years.

11c. This represents the town’s population after 10 years.

11d. Solve 10000 × (0.9)ᵗ < 6000.
(0.9)ᵗ < 0.6 → t > ln(0.6)/ln(0.9) ≈ 5.13.
So after 6 years, the population first falls below 6000.

11e. General formula: 10000 × (0.9)ⁿ

 

⚠️ Be careful! Compound Percentages

  • Chain changes by multiplying multipliers, not adding percentages.
    Example: +20% then −15% ⇒ 1.20 × 0.85 = 1.02 (overall +2%), not +5%.
  • Order matters when the rates differ. +20% then −10% ≠ +10% then −20% because 1.20×0.90 ≠ 1.10×0.80.
  • +P% then −P% is a net decrease. Net factor =(1+P/100)(1−P/100)=1−(P/100)² < 1.
  • Build one-step multipliers. Overall multiplier = product of step multipliers.
    Example: ↓18% then ↓12% ⇒ 0.82 × 0.88 = 0.7216.
  • Use powers for repeated equal changes. After n periods at rate r: initial × (1±r)n.
  • Use the correct base for % change between two values. Multiplier = new ÷ original; % change = (multiplier−1)×100%.
  • Distinguish “increase by A%” vs “is A% of”.
    “Increase by 132%” ⇒ factor 2.32; “is 132% of” ⇒ factor 1.32.
  • Delay rounding. Keep extra decimals in the multiplier product; round only the final answer.
  • Sense-check. Multiplier > 1 ⇒ bigger; < 1 ⇒ smaller; = 1 ⇒ unchanged. Compare against easy benchmarks (10%, 25%, 50%).
 

📘 What we've learned — Compound Percentages

  • Compound percentage change: apply one increase/decrease after another using successive multipliers.
  • Build multipliers: Increase by $P\%$: $1+\tfrac{P}{100}$ Decrease by $P\%$: $1-\tfrac{P}{100}$
  • Chain changes: multiply step multipliers. Example: +20% then −15% ⇒ $1.20\times0.85=1.02$ (net +2%).
  • Equal rise and fall: $(1+\tfrac{P}{100})(1-\tfrac{P}{100})=1-(\tfrac{P}{100})^2$ ⇒ always less than 1 (overall decrease).
  • General formula: after $n$ periods at rate $r$: growth $=\text{initial}\times(1+r)^n$ decay $=\text{initial}\times(1-r)^n$
  • Interpret multipliers: $>1$ = increase, $
  • Sense-check: compare with single-step changes. Order doesn’t matter if rates are the same, but does if they differ.

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