27 Arithmetic Progression Questions
Set 4: Sharpen your skills with Omtex Classes.
Part 1: Basic Calculations
Question 1
Find the next term of the AP: \( \sqrt{7}, \sqrt{28}, \sqrt{63}, \dots \)
Solution:
Simplify terms: \( \sqrt{7} \), \( \sqrt{4 \times 7} = 2\sqrt{7} \), \( \sqrt{9 \times 7} = 3\sqrt{7} \).
This is an AP with \( d = \sqrt{7} \).
Next term: \( 4\sqrt{7} = \sqrt{16 \times 7} = \sqrt{112} \).
Answer: \( \sqrt{112} \)
This is an AP with \( d = \sqrt{7} \).
Next term: \( 4\sqrt{7} = \sqrt{16 \times 7} = \sqrt{112} \).
Answer: \( \sqrt{112} \)
Question 2
Is 302 a term of the AP \( 3, 8, 13, \dots \)?
Solution:
\( a=3, d=5 \).
\( 302 = 3 + (n-1)5 \Rightarrow 299 = 5(n-1) \).
\( n-1 = 59.8 \). Since \( n \) is not an integer, it is not a term.
Answer: No
\( 302 = 3 + (n-1)5 \Rightarrow 299 = 5(n-1) \).
\( n-1 = 59.8 \). Since \( n \) is not an integer, it is not a term.
Answer: No
Question 3
If \( a_n = 3n^2 - 4n \), find the 5th term.
Solution:
Note: This formula usually represents \( S_n \) in quadratics, but if given as \( a_n \), simply substitute.
\( a_5 = 3(5)^2 - 4(5) = 3(25) - 20 = 75 - 20 = 55 \).
Answer: 55
\( a_5 = 3(5)^2 - 4(5) = 3(25) - 20 = 75 - 20 = 55 \).
Answer: 55
Question 4
How many multiples of 6 lie between 1 and 100?
Solution:
AP: \( 6, 12, \dots, 96 \).
\( 96 = 6 + (n-1)6 \Rightarrow 90 = 6(n-1) \Rightarrow 15 = n-1 \Rightarrow n=16 \).
Answer: 16
\( 96 = 6 + (n-1)6 \Rightarrow 90 = 6(n-1) \Rightarrow 15 = n-1 \Rightarrow n=16 \).
Answer: 16
Question 5
Find the common difference of the AP whose general term is \( a_n = 3n + 7 \).
Solution:
\( a_1 = 10, a_2 = 13 \).
\( d = 13 - 10 = 3 \).
(Shortcut: The coefficient of \( n \) is the common difference).
Answer: 3
\( d = 13 - 10 = 3 \).
(Shortcut: The coefficient of \( n \) is the common difference).
Answer: 3
Question 6
Find the sum of the first 20 even natural numbers.
Solution:
AP: \( 2, 4, 6, \dots \). \( a=2, d=2, n=20 \).
\( S_{20} = \frac{20}{2}[2(2) + 19(2)] = 10(4 + 38) = 10(42) = 420 \).
Or use formula \( n(n+1) = 20 \times 21 = 420 \).
Answer: 420
\( S_{20} = \frac{20}{2}[2(2) + 19(2)] = 10(4 + 38) = 10(42) = 420 \).
Or use formula \( n(n+1) = 20 \times 21 = 420 \).
Answer: 420
Question 7
If the 1st term is 7 and the 13th term is 35, find the common difference.
Solution:
\( a_{13} = a + 12d \Rightarrow 35 = 7 + 12d \).
\( 28 = 12d \Rightarrow d = 28/12 = 7/3 \).
Answer: 7/3
\( 28 = 12d \Rightarrow d = 28/12 = 7/3 \).
Answer: 7/3
Question 8
Check if the list of numbers \( 1^2, 3^2, 5^2, 7^2, \dots \) forms an AP.
Solution:
Terms: \( 1, 9, 25, 49 \).
\( 9-1 = 8 \). \( 25-9 = 16 \).
Differences are not constant.
Answer: No
\( 9-1 = 8 \). \( 25-9 = 16 \).
Differences are not constant.
Answer: No
Question 9
If 5 times the 5th term of an AP is equal to 8 times its 8th term, find the 13th term.
Solution:
\( 5(a+4d) = 8(a+7d) \)
\( 5a + 20d = 8a + 56d \)
\( -3a = 36d \Rightarrow a = -12d \Rightarrow a + 12d = 0 \).
\( a_{13} = a + 12d = 0 \).
Answer: 0
\( 5a + 20d = 8a + 56d \)
\( -3a = 36d \Rightarrow a = -12d \Rightarrow a + 12d = 0 \).
\( a_{13} = a + 12d = 0 \).
Answer: 0
Question 10
Find the sum of \( 2+4+6+\dots+200 \).
Solution:
\( a=2, l=200, n=100 \).
\( S_{100} = \frac{100}{2}(2+200) = 50(202) = 10100 \).
Answer: 10100
\( S_{100} = \frac{100}{2}(2+200) = 50(202) = 10100 \).
Answer: 10100
Part 2: Intermediate Questions
Question 11
How many two-digit numbers are divisible by 6?
Solution:
First: 12, Last: 96. \( d=6 \).
\( 96 = 12 + (n-1)6 \Rightarrow 84 = 6(n-1) \Rightarrow 14 = n-1 \Rightarrow n=15 \).
Answer: 15
\( 96 = 12 + (n-1)6 \Rightarrow 84 = 6(n-1) \Rightarrow 14 = n-1 \Rightarrow n=15 \).
Answer: 15
Question 12
Which term of the AP \( 53, 48, 43, \dots \) is the first negative term?
Solution:
\( a=53, d=-5 \).
\( 53 + (n-1)(-5) < 0 \Rightarrow 53 - 5n + 5 < 0 \)
\( 58 < 5n \Rightarrow n > 11.6 \).
First integer is 12.
Answer: 12th term
\( 53 + (n-1)(-5) < 0 \Rightarrow 53 - 5n + 5 < 0 \)
\( 58 < 5n \Rightarrow n > 11.6 \).
First integer is 12.
Answer: 12th term
Question 13
Find the sum of all three-digit numbers divisible by 9.
Solution:
AP: \( 108, 117, \dots, 999 \).
\( 999 = 108 + (n-1)9 \Rightarrow 891 = 9(n-1) \Rightarrow 99 = n-1 \Rightarrow n=100 \).
\( S_{100} = \frac{100}{2}(108+999) = 50(1107) = 55350 \).
Answer: 55350
\( 999 = 108 + (n-1)9 \Rightarrow 891 = 9(n-1) \Rightarrow 99 = n-1 \Rightarrow n=100 \).
\( S_{100} = \frac{100}{2}(108+999) = 50(1107) = 55350 \).
Answer: 55350
Question 14
The angles of a triangle are in AP. The largest angle is 90°. Find the other angles.
Solution:
Angles: \( a, a+d, a+2d \). \( a+2d = 90 \).
Sum: \( 3a+3d = 180 \Rightarrow a+d = 60 \).
\( a+d \) is the middle angle, so \( 60^\circ \).
AP: \( 30^\circ, 60^\circ, 90^\circ \).
Answer: 30°, 60°, 90°
Sum: \( 3a+3d = 180 \Rightarrow a+d = 60 \).
\( a+d \) is the middle angle, so \( 60^\circ \).
AP: \( 30^\circ, 60^\circ, 90^\circ \).
Answer: 30°, 60°, 90°
Question 15
Insert three arithmetic means between 3 and 19.
Solution:
AP: \( 3, A_1, A_2, A_3, 19 \). Total 5 terms.
\( 19 = 3 + 4d \Rightarrow 16 = 4d \Rightarrow d = 4 \).
Terms: \( 3+4=7 \), \( 7+4=11 \), \( 11+4=15 \).
Answer: 7, 11, 15
\( 19 = 3 + 4d \Rightarrow 16 = 4d \Rightarrow d = 4 \).
Terms: \( 3+4=7 \), \( 7+4=11 \), \( 11+4=15 \).
Answer: 7, 11, 15
Question 16
For what value of \( k \) are \( k, 2k-1, 2k+1 \) in AP?
Solution:
\( 2(2k-1) = k + (2k+1) \)
\( 4k - 2 = 3k + 1 \)
\( k = 3 \).
Answer: 3
\( 4k - 2 = 3k + 1 \)
\( k = 3 \).
Answer: 3
Question 17
Find the sum of the first \( n \) odd natural numbers.
Solution:
\( 1, 3, 5, \dots \). \( a=1, d=2 \).
\( S_n = \frac{n}{2}[2(1) + (n-1)2] = \frac{n}{2}[2 + 2n - 2] = \frac{n}{2}[2n] = n^2 \).
Answer: \( n^2 \)
\( S_n = \frac{n}{2}[2(1) + (n-1)2] = \frac{n}{2}[2 + 2n - 2] = \frac{n}{2}[2n] = n^2 \).
Answer: \( n^2 \)
Question 18
If the \( p \)th term of an AP is \( q \) and the \( q \)th term is \( p \), show that the \( n \)th term is \( p+q-n \).
Solution:
\( a+(p-1)d = q \) and \( a+(q-1)d = p \).
Subtracting: \( d(p-q) = q-p = -(p-q) \Rightarrow d = -1 \).
Substitute \( d \): \( a - p + 1 = q \Rightarrow a = p+q-1 \).
\( a_n = p+q-1 + (n-1)(-1) = p+q-1 - n + 1 = p+q-n \).
Answer: Proved
Subtracting: \( d(p-q) = q-p = -(p-q) \Rightarrow d = -1 \).
Substitute \( d \): \( a - p + 1 = q \Rightarrow a = p+q-1 \).
\( a_n = p+q-1 + (n-1)(-1) = p+q-1 - n + 1 = p+q-n \).
Answer: Proved
Part 3: Word Problems & Proofs
Question 19
A ladder has rungs 25 cm apart. The rungs decrease uniformly in length from 45 cm at the bottom to 25 cm at the top. If the top and the bottom rungs are 2.5 m apart, what is the length of the wood required for the rungs?
Solution:
Total height = 250 cm. Gap = 25 cm.
Number of rungs = \( \frac{250}{25} + 1 = 11 \).
AP: \( a=45, l=25, n=11 \).
\( S_{11} = \frac{11}{2}(45+25) = \frac{11}{2}(70) = 11 \times 35 = 385 \).
Answer: 385 cm
Number of rungs = \( \frac{250}{25} + 1 = 11 \).
AP: \( a=45, l=25, n=11 \).
\( S_{11} = \frac{11}{2}(45+25) = \frac{11}{2}(70) = 11 \times 35 = 385 \).
Answer: 385 cm
Question 20
If \( a, b, c \) are in AP, prove that \( \frac{1}{bc}, \frac{1}{ca}, \frac{1}{ab} \) are also in AP.
Solution:
If they are in AP, then \( \frac{1}{ca} - \frac{1}{bc} = \frac{1}{ab} - \frac{1}{ca} \).
Multiply entire equation by \( abc \):
\( b - a = c - b \Rightarrow 2b = a+c \).
Since \( a, b, c \) are in AP, \( 2b=a+c \) is true.
Answer: Proved
Multiply entire equation by \( abc \):
\( b - a = c - b \Rightarrow 2b = a+c \).
Since \( a, b, c \) are in AP, \( 2b=a+c \) is true.
Answer: Proved
Question 21
The sum of the first \( n \) terms of an AP is given by \( S_n = \frac{5n^2}{2} + \frac{3n}{2} \). Find the 20th term.
Solution:
\( a_{20} = S_{20} - S_{19} \).
\( S_{20} = \frac{5(400)}{2} + \frac{60}{2} = 1000 + 30 = 1030 \).
\( S_{19} = \frac{5(361)}{2} + \frac{57}{2} = \frac{1805+57}{2} = \frac{1862}{2} = 931 \).
\( a_{20} = 1030 - 931 = 99 \).
Answer: 99
\( S_{20} = \frac{5(400)}{2} + \frac{60}{2} = 1000 + 30 = 1030 \).
\( S_{19} = \frac{5(361)}{2} + \frac{57}{2} = \frac{1805+57}{2} = \frac{1862}{2} = 931 \).
\( a_{20} = 1030 - 931 = 99 \).
Answer: 99
Question 22
If the ratio of the sum of the first \( n \) terms of two APs is \( (7n+1):(4n+27) \), find the ratio of their 9th terms.
Solution:
Ratio of \( m \)th terms corresponds to replacing \( n \) with \( 2m-1 \) in sum ratio.
Here \( m=9 \), so replace \( n \) with \( 2(9)-1 = 17 \).
Ratio = \( \frac{7(17)+1}{4(17)+27} = \frac{119+1}{68+27} = \frac{120}{95} \).
Simplify: \( 24:19 \).
Answer: 24:19
Here \( m=9 \), so replace \( n \) with \( 2(9)-1 = 17 \).
Ratio = \( \frac{7(17)+1}{4(17)+27} = \frac{119+1}{68+27} = \frac{120}{95} \).
Simplify: \( 24:19 \).
Answer: 24:19
Question 23
If \( a, b, c \) are in AP, prove that \( (a-c)^2 = 4(b^2 - ac) \).
Solution:
Since AP, \( b = \frac{a+c}{2} \).
RHS: \( 4[(\frac{a+c}{2})^2 - ac] = 4[\frac{a^2+c^2+2ac}{4} - ac] \)
\( = a^2 + c^2 + 2ac - 4ac = a^2 + c^2 - 2ac = (a-c)^2 \).
LHS = RHS.
Answer: Proved
RHS: \( 4[(\frac{a+c}{2})^2 - ac] = 4[\frac{a^2+c^2+2ac}{4} - ac] \)
\( = a^2 + c^2 + 2ac - 4ac = a^2 + c^2 - 2ac = (a-c)^2 \).
LHS = RHS.
Answer: Proved
Question 24
The sum of the first 7 terms of an AP is 63 and the sum of its next 7 terms is 161. Find the 28th term.
Solution:
\( S_7 = 63 \Rightarrow \frac{7}{2}(2a+6d)=63 \Rightarrow a+3d=9 \).
\( S_{14} = 63 + 161 = 224 \Rightarrow \frac{14}{2}(2a+13d)=224 \Rightarrow 7(2a+13d)=224 \Rightarrow 2a+13d=32 \).
Solve: \( 2(9-3d)+13d=32 \Rightarrow 18-6d+13d=32 \Rightarrow 7d=14 \Rightarrow d=2 \).
\( a = 9 - 6 = 3 \).
\( a_{28} = 3 + 27(2) = 57 \).
Answer: 57
\( S_{14} = 63 + 161 = 224 \Rightarrow \frac{14}{2}(2a+13d)=224 \Rightarrow 7(2a+13d)=224 \Rightarrow 2a+13d=32 \).
Solve: \( 2(9-3d)+13d=32 \Rightarrow 18-6d+13d=32 \Rightarrow 7d=14 \Rightarrow d=2 \).
\( a = 9 - 6 = 3 \).
\( a_{28} = 3 + 27(2) = 57 \).
Answer: 57
Question 25
Solve for \( x \): \( 1 + 6 + 11 + 16 + \dots + x = 148 \).
Solution:
\( a=1, d=5, S_n=148 \).
\( 148 = \frac{n}{2}[2 + (n-1)5] \Rightarrow 296 = 2n + 5n^2 - 5n = 5n^2 - 3n \).
\( 5n^2 - 3n - 296 = 0 \). Using quadratic formula, \( n=8 \).
\( x = a_8 = 1 + 7(5) = 36 \).
Answer: 36
\( 148 = \frac{n}{2}[2 + (n-1)5] \Rightarrow 296 = 2n + 5n^2 - 5n = 5n^2 - 3n \).
\( 5n^2 - 3n - 296 = 0 \). Using quadratic formula, \( n=8 \).
\( x = a_8 = 1 + 7(5) = 36 \).
Answer: 36
Question 26
The sum of three numbers in AP is 12 and the sum of their cubes is 288. Find the numbers.
Solution:
Terms: \( a-d, a, a+d \). Sum \( 3a=12 \Rightarrow a=4 \).
\( (4-d)^3 + 4^3 + (4+d)^3 = 288 \).
\( 64 + (64 - 48d + 12d^2 - d^3) + (64 + 48d + 12d^2 + d^3) = 288 \).
\( 192 + 24d^2 = 288 \Rightarrow 24d^2 = 96 \Rightarrow d^2 = 4 \Rightarrow d = \pm 2 \).
Numbers: \( 2, 4, 6 \).
Answer: 2, 4, 6
\( (4-d)^3 + 4^3 + (4+d)^3 = 288 \).
\( 64 + (64 - 48d + 12d^2 - d^3) + (64 + 48d + 12d^2 + d^3) = 288 \).
\( 192 + 24d^2 = 288 \Rightarrow 24d^2 = 96 \Rightarrow d^2 = 4 \Rightarrow d = \pm 2 \).
Numbers: \( 2, 4, 6 \).
Answer: 2, 4, 6
Question 27
Split 24 into three parts such that they are in AP and their product is 440.
Solution:
Terms: \( a-d, a, a+d \). Sum \( 3a=24 \Rightarrow a=8 \).
Product: \( 8(64-d^2) = 440 \Rightarrow 64-d^2 = 55 \).
\( d^2 = 9 \Rightarrow d = 3 \).
Parts: \( 5, 8, 11 \).
Answer: 5, 8, 11
Product: \( 8(64-d^2) = 440 \Rightarrow 64-d^2 = 55 \).
\( d^2 = 9 \Rightarrow d = 3 \).
Parts: \( 5, 8, 11 \).
Answer: 5, 8, 11
For more study materials, visit Omtex Classes and Omtex.co.in.