4.6.1 Modelling with Sequences & Series

Modelling with Sequences and Series involves using mathematical sequences and series to represent real-world scenarios, often related to finance, physics, or other applied fields. This allows us to predict outcomes, calculate totals, and make informed decisions based on the patterns we observe.

Key Concepts:

Arithmetic Sequences:

A sequence where the difference between consecutive terms is constant, called the common difference $\ d .$
General form: $\ a_n = a_1 + (n-1)d$
Sum of the first $\ n$ terms: $\ S_n = \frac{n}{2} \left(2a_1 + (n-1)d\right) \ or \ S_n = \frac{n}{2} \left(a_1 + a_n\right)$

Geometric Sequences:

A sequence where each term is found by multiplying the previous term by a constant called the common ratio $\ r .$
General form: $\ a_n = a_1 r^{n-1}$
Sum of the first $\ n$ terms: $\ S_n = \frac{a_1(1-r^n)}{1-r} \ for \ r \neq 1$
Sum to infinity (for $\ |r| < 1 ): \ S_\infty = \frac{a_1}{1-r}$

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Examples of Modelling:

Population Growth (Geometric Sequence):

Suppose a population of bacteria doubles every hour, and you start with 100 bacteria.
The population after $\ n$ hours can be modelled by a geometric sequence: $P_n = 100 \times 2^{n}$
If you want to know the total population after 6 hours: $P_6 = 100 \times 2^6 = 100 \times 64 = :highlight[6400 bacteria]$

Loan Repayments (Geometric Series):

Consider a loan where you repay a fixed amount each month with interest. If you repay £500 monthly on a loan that charges 1% interest per month on the remaining balance:
The balance after each payment decreases according to a geometric series.
If the initial loan is £10,000 and monthly interest rate is 1%: $R_n = 10000 \times (1.01)^n - \frac{500 \times (1.01^n - 1)}{0.01}$
This series helps to determine how many months it will take to pay off the loan.

Savings Plan (Arithmetic Sequence):

Suppose you save £100 in the first month, and each subsequent month you increase your savings by £10.
The amount saved after $\ n$ months forms an arithmetic sequence: $S_n = 100 + (n-1) \times 10 = 90 + 10n$
The total savings after $\ n$ months: $T_n = \frac{n}{2} \left(2 \times 100 + (n-1) \times 10 \right) = \frac{n}{2} \times (200 + 10n - 10) = \frac{n}{2} \times (10n + 190)$

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Example Exam Question:

Question: A company decides to increase its annual bonus to employees by £500 each year. In the first year, the bonus is £2000. Find the total bonus an employee would receive over 10 years.

[4 marks]

Solution:

Identify the Sequence: The bonus amounts form an arithmetic sequence with $\ a_1 = :highlight[£2000]$ and $\ d = :highlight[£500] .$
Use the Formula for the Sum of an Arithmetic Sequence: $S_n = \frac{n}{2} \times (2a_1 + (n-1)d)$ Here $\ n = :highlight[10] \, \ a_1 = :highlight[2000] \, and \ d = :highlight[500] .$
Substitute the Values: $S_{10} = \frac{10}{2} \times (2 \times 2000 + (10-1) \times 500)$ $= 5 \times (4000 + 4500) = 5 \times 8500 = :highlight[42500]$ Final Answer: The total bonus over 10 years is £42,500.

Modelling with Sequences & Series Simplified Revision Notes for A-Level AQA Maths Pure

4.6.1 Modelling with Sequences & Series

Key Concepts:

Examples of Modelling:

Example Exam Question:

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