ARITHMETIC PROGRESSIONS-MCQs

NCERT Class 10 Mathematics Chapter 5 “Arithmetic Progressions” is a high scoring chapter that tests a student’s conceptual clarity, formula application, and problem solving speed in sequences and series. These 50 carefully designed MCQs cover every core concept of Arithmetic Progressions, including nth term, common difference, sum of n terms, term from the end, and typical exam pattern applications. Practising these questions will not only strengthen your understanding of APs but also help you build accuracy and confidence for CBSE board exams, school tests, and competitive entrance exams at Class 10 level.

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Exercise

ARITHMETIC PROGRESSIONS

by Academia Aeternum

1. Which of the following is an arithmetic progression (AP)?
2. The common difference of the AP \(10, 7, 4, 1, \ldots\) is:
3. The \(n\)th term of an AP with first term \(a\) and common difference \(d\) is:
4. For the AP \(5, 10, 15, \ldots\), the 7th term is:
5. If three numbers \(a, b, c\) are in AP, then:
6. The 10th term of the AP \(3, 6, 9, 12, \ldots\) is:
7. Which of the following sequences is NOT an AP?
8. In an AP, the 3rd term is \(12\) and the 7th term is \(28\). The common difference is:
9. The sum of the first \(n\) terms of an AP with first term \(a\) and common difference \(d\) is:
10. In an AP, if \(a_1 = 5\) and \(a_4 = 17\), then the common difference is:
11. Which of the following is an AP with common difference \(-3\)?
12. The 5th term of an AP is \(24\) and the 8th term is \(33\). The common difference is:
13. The 5th term of an AP with \(a = 4\) and \(d = 7\) is:
14. The sequence \(2, 5, 8, 11, \ldots\) has:
15. If the 10th term of an AP is \(25\) and the 15th term is \(45\), then the common difference is:
16. For an AP with first term \(a = 2\) and \(d = 2\), the value of \(S_{10} - S_5\) is:
17. The first term of an AP is \(7\) and the 7th term is \(28\). The common difference is:
18. Which term of the AP \(3, 7, 11, 15, \ldots\) is \(83\)?
19. The sum of the first 15 natural numbers using AP formula is:
20. If the first term of an AP is \(5\) and the common difference is \(3\), then the 12th term is:
21. In an AP, if \(a_3 = 9\) and \(a_7 = 25\), then \(a\) is:
22. The number of terms in the AP \(20, 18, 16, \ldots, 2\) is:
23. Which term of the AP \(7, 12, 17, 22, \ldots\) is \(92\)?
24. The 8th term of the AP whose first term is \(2\) and common difference is \(3\) is:
25. The sum of the first 10 terms of the AP \(2, 5, 8, 11, \ldots\) is:
26. The 10th term of an AP is \(46\) and the common difference is \(5\). The first term is:
27. The sum of the first 20 terms of the AP \(5, 8, 11, 14, \ldots\) is:
28. The arithmetic mean of \(12\) and \(24\) is:
29. If the sum of first \(n\) terms of an AP is \(S_n = 5n^2 + 3n\), then the first term is:
30. For the same AP in Q29, the common difference is:
31. The 15th term of the AP \(8, 13, 18, 23, \ldots\) is:
32. The number of terms in the AP \(7, 13, 19, \ldots, 97\) is:
33. The sum of first 7 terms of the AP \(3, 6, 9, \ldots\) is:
34. The sum of the first 50 terms of the AP \(2, 4, 6, \ldots\) is:
35. An AP has first term \(5\) and common difference \(3\). The sum of its first 12 terms is:
36. How many terms of the AP \(4, 7, 10, 13, \ldots\) are needed to make a sum of \(144\)?
37. The 15th term from the end of the AP \(6, 9, 12, \ldots, 96\) is:
38. If the sum of first 6 terms of an AP is \(54\) and the first term is \(3\), then the common difference is:
39. In an AP, the sum of first 5 terms is \(35\) and the first term is \(3\). The common difference is:
40. In an AP, the 4th term is \(10\) and the 10th term is \(22\). The common difference is:
41. For the AP of Q40, the first term \(a\) is:
42. Which of the following is NOT a property of an AP?
43. The 9th term of the AP \(2, 5, 8, 11, \ldots\) is:
44. The sum of the first 8 terms of AP \(7, 10, 13, 16, \ldots\) is:
45. In an AP, the first term is \(4\) and the 6th term is \(19\). The common difference is:
46. In an AP, if \(a = 2\) and \(d = 5\), then the sum of first 5 terms is:
47. The 3rd, 8th and 13th terms of an AP are:
48. In an AP, if the 7th term is \(20\) and the 13th term is \(38\), then the common difference is:
49. In an AP, if the 4th term is \(11\) and the common difference is \(2\), then the first term is:
50. In an AP, if the sum of the first \(n\) terms is \(S_n = 2n^2 + 3n\), then the 10th term is:

Frequently Asked Questions

A sequence of numbers where the difference between consecutive terms is constant.

The fixed amount added or subtracted to obtain the next term.

Subtract any term from the next: \(d = a_2 - a_1\).

\(a_n = a + (n - 1)d\).

The initial term, denoted by \(a\).

To find any term without listing all previous terms.

\(l = a + (n - 1)d\)

An AP with a fixed number of terms.

An AP that continues indefinitely.

\(S_n = \dfrac{n}{2}\Bigl [2a + (n - 1)d\Bigr]\)

\(S_n = \frac{n}{2} (a + l)\)

Verify if consecutive differences are equal.

Solve \(a + (n - 1)d =\) term and check if n is a positive integer.

The AP grows as n increases.

The AP decreases as n increases.

All terms are equal; constant AP.

4, 7, 10, 13, …

20, 15, 10, 5, …

Yes, if the difference remains constant.

Yes, APs can contain any real numbers.

They help model patterns, growth, and sequences in real life.

Savings plans, seating arrangements, installment payments.

Procedure used to generate the next term: add d each time.

The nth-term formula giving value at any position.

Because \(a_n\) increases linearly with \(n\).

Using wrong values of \(a\) or \(d\), sign errors.

Forgetting parentheses in \(S_n = \dfrac{n}{2}\Bigl [2a + (n - 1)d\Bigr]\).

Value inserted between two numbers to form an AP.

A.M. = \((a + b) / 2\).

Multiple means placed between two numbers by forming a complete AP.

Use \(S_n\) formula and solve quadratic for \(n\).

Using \(l = a + (n - 1)d\) to find unknowns.

The AP still works; terms increase/decrease steadily.

Solve \(a + (n - 1)d = 0\).

Only if \(d = 0\); otherwise terms differ.

Use \(S_n = n/2 (a + l)\) if the last term is known.

\(a_n = a + (n - 1)d\) and \(S_n = \dfrac{n}{2} \Bigl[2a + (n - 1)d\Bigr]\).

Writing AP forward and backward to derive \(S_n\) formula.

Linear increase/decrease by constant steps.

A straight ascending or descending line.

Use the nth-term relation to create equations.

Yes, to find term positions or earlier terms.

Finding term position, sum, or common difference.

Questions involving reasoning, real-life modeling, and pattern analysis.

To solve for \(n\) in sum or \(n\)th-term problems.

In forming equations for sequences and series.

Many patterns in tables or charts show constant increments.

Distance covered in equal intervals increases in AP.

Rearrange nth-term formula: \(a = a_n - (n - 1)d\).

Use \(a_n - a_m = (n - m)d\).

Yes, when deposits increase regularly.

Steps often rise by uniform height increments.

It forms a base for number series, sequences, and reasoning.

A sequence increasing/decreasing in equal increments.

Yes, when the change per period is constant.

Incorrect subtraction for d, choosing wrong \(n\), sign mistakes in equations.

Adjusting AP terms by adding, subtracting, or scaling all values.

New sequence is still an AP with common difference multiplied by that constant.

The resulting sequence remains an AP with unchanged common difference.

Yes, when raises occur in equal annual steps.

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