IB Maths AI HL Sequences & Series Paper 1 & 2 common difference d ~7 min read

Arithmetic Sequences & Series

An arithmetic sequence goes up (or down) by the same fixed amount each time — the common difference. Two formulae do almost everything: one for any term, one for the sum of the first n terms. Both are in the formula booklet.

📘 What you need to know

An arithmetic sequence has a constant difference between consecutive terms — the common difference d.
A negative d means the sequence decreases.
nth term: u_n = u₁ + (n − 1)d.
Sum of the first n terms: S_n = n2(2u₁ + (n − 1)d) or n2(u₁ + u_n).
If u₁ and d are unknown, two given terms give simultaneous equations.
If n is unknown, substituting into S_n often leads to a quadratic in n.

Arithmetic sequences

An arithmetic sequence is one where each term differs from the previous by a fixed amount, the common difference d. For 1, 4, 7, 10, … the difference is d = 3; a negative d gives a decreasing sequence.

The terms 4, 9, 14, 19, 24 rise by a constant d = 5. That fixed step is what makes the sequence arithmetic.

n^th term of an arithmetic sequence u_n = u₁ + (n − 1)d u₁ = first term, d = common difference — given in the formula booklet

The sum of an arithmetic series

An arithmetic series is the sum of the terms of an arithmetic sequence. There are two formulae for S_n — use whichever fits the information given.

Sum of the first n terms S_n = n2(2u₁ + (n − 1)d) S_n = n2(u₁ + u_n) use the second when the last term u_n is known — both are in the booklet

The second form is quicker when you already know the last term; the first only needs u₁ and d.

Working backwards

Many questions give you a term or a sum and ask for u₁, d or n. Two given terms produce two equations — solve them simultaneously for u₁ and d.

Finding n: if the number of terms is unknown, substitute into the S_n formula — this usually gives a quadratic in n. Solve it and keep only the positive whole-number answer.

🧭 Recipe — arithmetic sequences and series

Identify u₁ and d — d is the constant step between terms.
For a term, use u_n = u₁ + (n − 1)d.
For a sum, use S_n = n2(2u₁ + (n−1)d), or n2(u₁ + u_n) if the last term is known.
If u₁ or d is unknown, form two equations from the given terms and solve simultaneously.
If n is unknown, substitute into the formula and solve the resulting equation — often a quadratic.

Worked examples

WE 1

Finding a term

An arithmetic sequence has first term 5 and common difference 4. Find the 12th term.

use u_n = u₁ + (n − 1)d u₁₂ = 5 + (12 − 1)(4) = 5 + 11 × 4 = 5 + 44 u₁₂ = 49 it is (n − 1) lots of d — the first term already counts as term 1.

WE 2

Finding u₁ and d from two terms

The 3rd term of an arithmetic sequence is 17 and the 8th term is 42. Find the first term and the common difference.

write each term with the formula u₃: u₁ + 2d = 17 u₈: u₁ + 7d = 42 subtract the equations 5d = 25 ⇒ d = 5 u₁ = 17 − 2(5) = 7 u₁ = 7, d = 5 subtracting the two equations eliminates u₁ and gives d at once.

WE 3

Summing an arithmetic series

Find the sum of the first 20 terms of the arithmetic sequence 3, 7, 11, 15, …

u₁ = 3, d = 4, n = 20 S₂₀ = 202(2(3) + (20 − 1)(4)) = 10(6 + 76) = 10 × 82 S₂₀ = 820 use the first sum formula — it needs only u₁, d and n.

WE 4

Finding n from a sum

An arithmetic sequence has first term 4 and common difference 3. How many terms are needed for the sum to reach 175?

set S_n = 175 n2(2(4) + (n − 1)(3)) = 175 n2(3n + 5) = 175 ⇒ 3n² + 5n − 350 = 0 solve the quadratic in n n = 10 or n = −³⁵⁄₃ (reject) n = 10 terms an unknown n in S_n gives a quadratic — keep only the positive whole number.

WE 5

Which term has a given value?

An arithmetic sequence is 2, 9, 16, 23, … Which term of the sequence is equal to 100?

u₁ = 2, d = 7; set u_n = 100 2 + (n − 1)(7) = 100 7(n − 1) = 98 ⇒ n − 1 = 14 100 is the 15th term solving u_n = value gives n — it must be a positive integer.

WE 6

Full question: term, sum and a block of terms

An arithmetic sequence has first term 6 and common difference 5. (a) Find the 25th term. (b) Find the sum of the first 25 terms. (c) Find the sum of the 11th to the 25th terms inclusive.

(a) u₂₅ = u₁ + 24d = 6 + 24(5) = 126 (b) S₂₅ = 252(2(6) + 24(5)) = 252(132) = 1650 (c) 11th to 25th = S₂₅ − S₁₀ S₁₀ = 5(12 + 45) = 285; 1650 − 285 (a) 126 · (b) 1650 · (c) 1365 a block of terms is S of the last minus S just before the block starts.

💡 Top tips

The nth term uses (n − 1)d, not nd — the first term is already term 1.
Pick the sum formula to fit: use S_n = n2(u₁ + u_n) when the last term is known.
Two given terms ⇒ two equations — subtract them to eliminate u₁ and find d.
An unknown n inside S_n usually gives a quadratic — expect to solve one.
The sum of a block of terms is S_last − S_before.

⚠ Common mistakes

Using nd instead of (n − 1)d in the nth-term formula.
Finding the common difference the wrong way round — it is a later term minus an earlier one.
Forgetting the n2 factor in the sum formula.
Keeping a negative or non-integer n from a quadratic — only a positive whole number is valid.
Treating a multiplied or squared sequence as arithmetic — arithmetic means a constant added difference.

Next up: Geometric Sequences & Series — sequences where you multiply by a fixed common ratio instead of adding a fixed difference. The structure mirrors this note: an nth-term formula and a sum formula, plus a new idea, the sum to infinity.

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