Understanding the Context

What Is the Equation aₙ = 3 + (n – 1) · 6?

The expression aₙ = 3 + (n – 1) · 6 defines a linear recurrence relation commonly used to model arithmetic sequences—sequences where each term increases by a constant difference. Here’s what each component means:

• aₙ: Represents the nth term in the sequence
  
• n: The position or index (starting at 1)
  
• 3: The first term (when n = 1)
  
• 6: The common difference between consecutive terms
  
• (n – 1) · 6: Accounts for progression—each step adds 6

Example:
For n = 1:
a₁ = 3 + (1 – 1) · 6 = 3 + 0 = 3

Key Insights

For n = 2:
a₂ = 3 + (2 – 1) · 6 = 3 + 6 = 9

For n = 3:
a₃ = 3 + (3 – 1) · 6 = 3 + 12 = 15

So the sequence begins: 3, 9, 15, 21, 27,... where each term increases by 6.

Converting to Standard Form: aₙ = 6n – 3

Final Thoughts

To simplify analysis, we convert the recurrence into standard form for arithmetic sequences:
aₙ = a₁ + (n – 1)d, where:

• a₁ = 3 (first term)
  
• d = 6 (common difference)

Substituting:
aₙ = 3 + (n – 1) · 6
= 3 + 6n – 6
= 6n – 3

This linear function models aₙ as a direct variable of n, making it easy to compute any term without recursion. For instance:

• To find the 10th term: a₁₀ = 6×10 – 3 = 57
  
• The relationship is linear with slope 6 and y-intercept –3, visually represented on a graph.

The Mathematics Behind the Formula

The general structure aₙ = A + (n – 1)d is derived from:

• Starting at A = 3 (the base value)
  
• Building the sequence by repeatedly adding d = 6
  
• The closed-form formula avoids recalculating prior terms, offering O(1) time complexity for term lookup.