Question: A sequence of five real numbers forms a geometric progression. The sum of the first three terms is 21, and the sum of the last three terms is 84. Find the common ratio. - Redraw

Understanding the Context

In today’s digital landscape, curiosity-driven learning thrives on systems that feel accessible but deliver depth—like geometric progressions. This specific problem taps into a growing interest in structured thinking and logical reasoning, whether for academic study, coding applications, or financial modeling. Recent data shows rising engagement with STEM-focused content on mobile platforms—especially among users aged 18–45 seeking intellectual practice. Asking “the common ratio” isn’t merely academic; it’s a gateway to stronger analytical habits. The pairing of familiar terms—real numbers, geometric sequence, three-term sums—makes the problem immediately relatable. This subtle approach avoids jargon, inviting readers to explore the rhythm of mathematics without pressure, driving both dwell time and trust.

How This Sequence Actually Works

A geometric progression follows a consistent multiplicative pattern: each term after the first is found by multiplying the previous by a fixed value—the common ratio, denoted as ( r ).

Key Insights

Let the first term be ( a ). The sequence unfolds:
1st: ( a )
2nd: ( ar )
3rd: ( ar^2 )
4th: ( ar^3 )
5th: ( ar^4 )

Sum of first three:
[ a + ar + ar^2 = 21 ]
Factor out ( a ):
[ a(1 + r + r^2) = 21 ] — (Equation 1)

Sum of last three:
[ ar^2 + ar^3 + ar^4 = 84 ]
Factor out ( ar^2 ):
[ ar^2(1 + r + r^2) = 84 ] — (Equation 2)

Now divide Equation 2 by Equation 1:
[ \frac{ar^2(1 + r + r^2)}{a(1 + r + r^2)} = \frac{84}{21} ]
Simplify:
[ r^2 = 4 ]

So, ( r = 2 ) or ( r = -2 ). Since the terms are real numbers and sums are positive, a positive ratio of 2 is most consistent in context—though both values mathematically fit the sequence structure.

Final Thoughts

Common Questions and Clarifications

H3: Does this only apply to positive numbers?
Not at all—the problem allows for real numbers, including negative ratios. Both ( r = 2 ) and ( r = -2 ) are valid solutions under general real number conditions. However, in practical applications like income growth or decay rates, a positive ratio is often more intuitive. The math itself doesn’t restrict sign; only context matters.

H3: Why is the common ratio so important?
The ratio reveals the pace of change in the sequence. A ratio greater than 1 means each term grows multiplicatively, amplifying magnitudes steadily. A ratio less than 1 means gradual decay—both patterns appear in real-world data like population shifts or investment returns. Understanding ( r ) unlocks predictive insight and modeling depth.

H3: Can this concept apply beyond math?
Absolutely. Geometric progressions model phenomena ranging from web traffic growth and viral content spread to depreciation in asset value. Recognizing such patterns helps decision-makers and learners alike forecast and interpret real dynamics—an essential skill in data-driven societies.