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JEE Main · MCQ · Sequences & Series · Geometric Progression
MCQ · Mathematics · Sequences & Series
Q. Let $a_1,\ \dfrac{a_2}{2},\ \dfrac{a_3}{2^2},\ \ldots,\ \dfrac{a_{10}}{2^9}$ be a G.P. of common ratio $\dfrac{1}{\sqrt{2}}$. If
$$a_1 + a_2 + \cdots + a_{10} = 62,$$
then $a_1$ is equal to:
A$\sqrt{2} – 1$
B$2(\sqrt{2}-1)$ ✓
C$2 – \sqrt{2}$
D$2(2-\sqrt{2})$
✅ Correct Answer: (B) $2(\sqrt{2}-1)$
Step-by-Step Solution
1
Understand the modified GP structure
The sequence $a_1,\ \dfrac{a_2}{2},\ \dfrac{a_3}{4},\ \ldots,\ \dfrac{a_{10}}{2^9}$ is a GP with ratio $\dfrac{1}{\sqrt{2}}$.
So the $n$-th term of this modified GP is:
So the $n$-th term of this modified GP is:
$\dfrac{a_n}{2^{n-1}} = a_1 \cdot \left(\dfrac{1}{\sqrt{2}}\right)^{n-1}$
Therefore:
$a_n = a_1 \cdot 2^{n-1} \cdot \left(\dfrac{1}{\sqrt{2}}\right)^{n-1} = a_1 \cdot \left(\dfrac{2}{\sqrt{2}}\right)^{n-1} = a_1 \cdot (\sqrt{2})^{n-1}$
2
Verify: original sequence $\{a_n\}$ is GP with ratio $\sqrt{2}$
| $n$ | $a_n = a_1(\sqrt{2})^{n-1}$ |
|---|---|
| 1 | $a_1$ |
| 2 | $a_1\sqrt{2}$ |
| 3 | $a_1 \cdot 2$ |
| 4 | $a_1 \cdot 2\sqrt{2}$ |
| 10 | $a_1 \cdot (\sqrt{2})^9 = a_1 \cdot 16\sqrt{2}$ |
3
Compute $(\sqrt{2})^{10}$
$(\sqrt{2})^{10} = (2^{1/2})^{10} = 2^5 = 32$
4
Apply GP sum formula with $r = \sqrt{2}$, $n = 10$
$S_{10} = a_1 \cdot \dfrac{(\sqrt{2})^{10} – 1}{\sqrt{2} – 1} = a_1 \cdot \dfrac{32 – 1}{\sqrt{2}-1} = \dfrac{31\,a_1}{\sqrt{2}-1}$
5
Set equal to 62 and solve for $a_1$
$\dfrac{31\,a_1}{\sqrt{2}-1} = 62$
$a_1 = \dfrac{62(\sqrt{2}-1)}{31} = 2(\sqrt{2}-1)$
$a_1 = \dfrac{62(\sqrt{2}-1)}{31} = 2(\sqrt{2}-1)$
$a_1 = 2(\sqrt{2}-1)$ → Option (B) ✓
Related Theory
📌 Geometric Progression — Fundamentals
A Geometric Progression (GP) is a sequence where each term is obtained by multiplying the previous term by a fixed non-zero number called the common ratio $r$.
General form: $a,\ ar,\ ar^2,\ ar^3,\ \ldots$
$n$-th term: $T_n = a\cdot r^{n-1}$
Sum of $n$ terms ($r \neq 1$): $$S_n = \frac{a(r^n – 1)}{r-1} \quad \text{if } r > 1$$ $$S_n = \frac{a(1-r^n)}{1-r} \quad \text{if } r < 1$$ Both forms give the same result — choose whichever avoids negative denominators for cleaner arithmetic.
General form: $a,\ ar,\ ar^2,\ ar^3,\ \ldots$
$n$-th term: $T_n = a\cdot r^{n-1}$
Sum of $n$ terms ($r \neq 1$): $$S_n = \frac{a(r^n – 1)}{r-1} \quad \text{if } r > 1$$ $$S_n = \frac{a(1-r^n)}{1-r} \quad \text{if } r < 1$$ Both forms give the same result — choose whichever avoids negative denominators for cleaner arithmetic.
$T_n = ar^{n-1}$
$S_n = \dfrac{a(r^n-1)}{r-1}$
$S_\infty = \dfrac{a}{1-r}$ for $|r|<1$
📌 Modified GP — Finding the Original Sequence’s Ratio
This problem presents a modified GP: instead of the original $a_n$, the terms $\dfrac{a_n}{2^{n-1}}$ form a GP. This is a common JEE trick.
Key logic: If $b_n = \dfrac{a_n}{f(n)}$ is a GP with ratio $r$, then: $$\frac{b_{n+1}}{b_n} = r \Rightarrow \frac{a_{n+1}/f(n+1)}{a_n/f(n)} = r \Rightarrow \frac{a_{n+1}}{a_n} = r \cdot \frac{f(n+1)}{f(n)}$$ Here $f(n) = 2^{n-1}$, so $f(n+1)/f(n) = 2$, giving $a_{n+1}/a_n = (1/\sqrt{2})\cdot 2 = \sqrt{2}$.
So the original $\{a_n\}$ is a GP with ratio $\sqrt{2}$ — completely different from the given ratio $1/\sqrt{2}$.
Key logic: If $b_n = \dfrac{a_n}{f(n)}$ is a GP with ratio $r$, then: $$\frac{b_{n+1}}{b_n} = r \Rightarrow \frac{a_{n+1}/f(n+1)}{a_n/f(n)} = r \Rightarrow \frac{a_{n+1}}{a_n} = r \cdot \frac{f(n+1)}{f(n)}$$ Here $f(n) = 2^{n-1}$, so $f(n+1)/f(n) = 2$, giving $a_{n+1}/a_n = (1/\sqrt{2})\cdot 2 = \sqrt{2}$.
So the original $\{a_n\}$ is a GP with ratio $\sqrt{2}$ — completely different from the given ratio $1/\sqrt{2}$.
📌 Powers of $\sqrt{2}$ — Must Know Values
Since $\sqrt{2} = 2^{1/2}$, powers of $\sqrt{2}$ are powers of 2 divided by appropriate roots:
$(\sqrt{2})^1 = \sqrt{2}$ $(\sqrt{2})^2 = 2$ $(\sqrt{2})^4 = 4$ $(\sqrt{2})^6 = 8$ $(\sqrt{2})^8 = 16$ $(\sqrt{2})^{10} = 32$ $(\sqrt{2})^{2k} = 2^k$
The key result here: $(\sqrt{2})^{10} = 2^5 = 32$. This makes the numerator $r^n – 1 = 32 – 1 = 31$, which divides cleanly into 62, giving a clean answer.
$(\sqrt{2})^1 = \sqrt{2}$ $(\sqrt{2})^2 = 2$ $(\sqrt{2})^4 = 4$ $(\sqrt{2})^6 = 8$ $(\sqrt{2})^8 = 16$ $(\sqrt{2})^{10} = 32$ $(\sqrt{2})^{2k} = 2^k$
The key result here: $(\sqrt{2})^{10} = 2^5 = 32$. This makes the numerator $r^n – 1 = 32 – 1 = 31$, which divides cleanly into 62, giving a clean answer.
📌 Rationalisation Not Needed Here — Clean Division
The equation $\dfrac{31a_1}{\sqrt{2}-1} = 62$ gives $a_1 = \dfrac{2(\sqrt{2}-1)}{1}$ directly — no rationalisation needed since the answer itself contains $\sqrt{2}-1$.
However, if you need to verify: multiply numerator and denominator of $\dfrac{2}{\sqrt{2}-1}$ by $(\sqrt{2}+1)$: $$\frac{2(\sqrt{2}+1)}{(\sqrt{2})^2-1^2} = \frac{2(\sqrt{2}+1)}{1} = 2\sqrt{2}+2$$ This would be $a_1$ if we rationalised, but the answer $2(\sqrt{2}-1)$ is the correct form.
Quick check: $2(\sqrt{2}-1) \approx 2(1.414-1) = 2(0.414) \approx 0.828 > 0$ ✓ (positive first term makes sense for a positive GP)
However, if you need to verify: multiply numerator and denominator of $\dfrac{2}{\sqrt{2}-1}$ by $(\sqrt{2}+1)$: $$\frac{2(\sqrt{2}+1)}{(\sqrt{2})^2-1^2} = \frac{2(\sqrt{2}+1)}{1} = 2\sqrt{2}+2$$ This would be $a_1$ if we rationalised, but the answer $2(\sqrt{2}-1)$ is the correct form.
Quick check: $2(\sqrt{2}-1) \approx 2(1.414-1) = 2(0.414) \approx 0.828 > 0$ ✓ (positive first term makes sense for a positive GP)
📌 Why the Sum Equals 62
With $a_1 = 2(\sqrt{2}-1)$ and ratio $r = \sqrt{2}$:
$$S_{10} = \frac{2(\sqrt{2}-1) \cdot (32-1)}{\sqrt{2}-1} = 2 \times 31 = 62 \ ✓$$
The $(\sqrt{2}-1)$ factors cancel beautifully, confirming the answer. This type of cancellation is a hallmark of well-constructed JEE problems.
📌 Properties of GP Important for JEE
1. Product of terms equidistant from ends: In a finite GP, $T_k \cdot T_{n+1-k}$ = constant = $a \cdot l$ (first × last).
2. Three terms in GP: If $a, b, c$ are in GP → $b^2 = ac$ (GM property).
3. Inserting $n$ GMs between $a$ and $b$: Common ratio $= (b/a)^{1/(n+1)}$.
4. GP with negative ratio: Terms alternate in sign.
5. Log of GP terms form AP: If $a_1, a_2, \ldots$ is GP, then $\log a_1, \log a_2, \ldots$ is AP.
2. Three terms in GP: If $a, b, c$ are in GP → $b^2 = ac$ (GM property).
3. Inserting $n$ GMs between $a$ and $b$: Common ratio $= (b/a)^{1/(n+1)}$.
4. GP with negative ratio: Terms alternate in sign.
5. Log of GP terms form AP: If $a_1, a_2, \ldots$ is GP, then $\log a_1, \log a_2, \ldots$ is AP.
$b^2 = ac$ (three terms in GP)
$T_k \cdot T_{n+1-k} = a\cdot l$
GM of $n$ numbers $= (a_1 a_2 \cdots a_n)^{1/n}$
📌 Common Mistakes to Avoid
❌ Mistake 1: Assuming the original sequence $\{a_n\}$ also has ratio $1/\sqrt{2}$. It does not — the ratio of $\{a_n\}$ is $\sqrt{2}$.
❌ Mistake 2: Computing $(\sqrt{2})^{10}$ incorrectly. Remember $(\sqrt{2})^{10} = 2^{10/2} = 2^5 = 32$, not $\sqrt{2}^{10} = 10\sqrt{2}$.
❌ Mistake 3: Using $S = a(1-r^n)/(1-r)$ with $r>1$. This gives negative denominator — use $a(r^n-1)/(r-1)$ when $r > 1$.
❌ Mistake 4: Not simplifying $\dfrac{62(\sqrt{2}-1)}{31} = 2(\sqrt{2}-1)$, and incorrectly rationalising the answer.
❌ Mistake 2: Computing $(\sqrt{2})^{10}$ incorrectly. Remember $(\sqrt{2})^{10} = 2^{10/2} = 2^5 = 32$, not $\sqrt{2}^{10} = 10\sqrt{2}$.
❌ Mistake 3: Using $S = a(1-r^n)/(1-r)$ with $r>1$. This gives negative denominator — use $a(r^n-1)/(r-1)$ when $r > 1$.
❌ Mistake 4: Not simplifying $\dfrac{62(\sqrt{2}-1)}{31} = 2(\sqrt{2}-1)$, and incorrectly rationalising the answer.
📌 JEE Exam Strategy for GP Problems
GP problems in JEE often involve:
• Modified sequences (like this one — divide/multiply terms by functions of $n$)
• Combined AP-GP problems (AGP — Arithmetico-Geometric Progression)
• Infinite GP with $|r|<1$
• Finding number of terms given first term, last term, ratio
For modified GP problems, always derive the ratio of the original sequence first before applying any sum formula. This is the most common source of error.
Time target: 2–3 minutes for this type in JEE Main.
• Modified sequences (like this one — divide/multiply terms by functions of $n$)
• Combined AP-GP problems (AGP — Arithmetico-Geometric Progression)
• Infinite GP with $|r|<1$
• Finding number of terms given first term, last term, ratio
For modified GP problems, always derive the ratio of the original sequence first before applying any sum formula. This is the most common source of error.
Time target: 2–3 minutes for this type in JEE Main.
Frequently Asked Questions
1. What is the ratio of the original sequence $\{a_n\}$?
$\sqrt{2}$. The given ratio $1/\sqrt{2}$ applies to the modified sequence $a_n/2^{n-1}$.
2. What is the general term $a_n$?
$a_n = a_1 \cdot (\sqrt{2})^{n-1}$.
3. What is $(\sqrt{2})^{10}$?
$(\sqrt{2})^{10} = 2^5 = 32$.
4. What GP sum formula is used?
$S_{10} = a_1(r^{10}-1)/(r-1) = a_1 \cdot 31/(\sqrt{2}-1)$.
5. How is $a_1$ solved from $31a_1/(\sqrt{2}-1) = 62$?
$a_1 = 62(\sqrt{2}-1)/31 = 2(\sqrt{2}-1)$.
6. What is the correct answer?
Option (B): $2(\sqrt{2}-1)$.
7. How do you verify the answer?
$S_{10} = 2(\sqrt{2}-1) \cdot 31/(\sqrt{2}-1) = 2 \times 31 = 62$ ✓
class=”faq-q”>8. What is the ratio of the modified GP?
$1/\sqrt{2}$ — given directly in the problem.
9. Why does $(\sqrt{2}-1)$ cancel?
Because $a_1 = 2(\sqrt{2}-1)$ contains this factor, which cancels with the denominator in the sum formula, giving $S_{10} = 62$ ✓.
10. Is the answer positive?
Yes. $2(\sqrt{2}-1) \approx 0.828 > 0$, consistent with a positive GP.
11. What is the last term $a_{10}$?
$a_{10} = a_1(\sqrt{2})^9 = 2(\sqrt{2}-1)\cdot 16\sqrt{2} = 32\sqrt{2}(\sqrt{2}-1) = 32(2-\sqrt{2}) = 64-32\sqrt{2}$.
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