Major Competitive Exams

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Major Competitive Exams

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Major Competitive Exams MCQ & Objective Questions

Major Competitive Exams play a crucial role in shaping the academic and professional futures of students in India. These exams not only assess knowledge but also test problem-solving skills and time management. Practicing MCQs and objective questions is essential for scoring better, as they help in familiarizing students with the exam format and identifying important questions that frequently appear in tests.

What You Will Practise Here

Key concepts and theories related to major subjects
Important formulas and their applications
Definitions of critical terms and terminologies
Diagrams and illustrations to enhance understanding
Practice questions that mirror actual exam patterns
Strategies for solving objective questions efficiently
Time management techniques for competitive exams

Exam Relevance

The topics covered under Major Competitive Exams are integral to various examinations such as CBSE, State Boards, NEET, and JEE. Students can expect to encounter a mix of conceptual and application-based questions that require a solid understanding of the subjects. Common question patterns include multiple-choice questions that test both knowledge and analytical skills, making it essential to be well-prepared with practice MCQs.

Common Mistakes Students Make

Rushing through questions without reading them carefully
Overlooking the negative marking scheme in MCQs
Confusing similar concepts or terms
Neglecting to review previous years’ question papers
Failing to manage time effectively during the exam

FAQs

Question: How can I improve my performance in Major Competitive Exams?
Answer: Regular practice of MCQs and understanding key concepts will significantly enhance your performance.

Question: What types of questions should I focus on for these exams?
Answer: Concentrate on important Major Competitive Exams questions that frequently appear in past papers and mock tests.

Question: Are there specific strategies for tackling objective questions?
Answer: Yes, practicing under timed conditions and reviewing mistakes can help develop effective strategies.

Start your journey towards success by solving practice MCQs today! Test your understanding and build confidence for your upcoming exams. Remember, consistent practice is the key to mastering Major Competitive Exams!

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Q. A rotating body has an angular momentum L. If the moment of inertia of the body is I, what is the angular velocity ω of the body? (2021)

A. L/I
B. I/L
C. L^2/I
D. IL

Solution

Angular momentum L is given by L = Iω, thus ω = L/I.

Correct Answer: A — L/I

Q. A rotating disc has a radius R and is spinning with an angular velocity ω. What is the linear speed of a point on the edge of the disc?

A. Rω
B. ω/R
C. R/ω
D. ω

Solution

The linear speed v of a point on the edge of the disc is given by v = Rω.

Correct Answer: A — Rω

Q. A rotating disc has an angular velocity of ω. If the radius of the disc is doubled while keeping the mass constant, what happens to the angular momentum?

A. It doubles
B. It remains the same
C. It quadruples
D. It halves

Solution

Angular momentum L = Iω, where I is the moment of inertia. If radius is doubled, I increases by a factor of 4, but ω decreases by a factor of 2, so L remains the same.

Correct Answer: A — It doubles

Q. A rotating object has a kinetic energy of 100 J. If its angular velocity is doubled, what will be its new kinetic energy?

A. 100 J
B. 200 J
C. 400 J
D. 800 J

Solution

Kinetic energy of rotation is given by KE = (1/2)Iω². If ω is doubled, KE becomes (1/2)I(2ω)² = 4(1/2)Iω² = 4KE = 400 J.

Correct Answer: C — 400 J

Q. A rotating object has a moment of inertia I and an angular velocity ω. What is its rotational kinetic energy? (2020)

A. (1/2)Iω
B. (1/2)Iω²
C. Iω²
D. I/2ω²

Solution

Rotational kinetic energy K.E. = (1/2)Iω².

Correct Answer: B — (1/2)Iω²

Q. A rotating object has a moment of inertia of 3 kg·m² and is rotating with an angular velocity of 10 rad/s. What is its rotational kinetic energy?

A. 15 J
B. 30 J
C. 50 J
D. 100 J

Solution

Rotational kinetic energy K = (1/2)Iω² = (1/2)(3 kg·m²)(10 rad/s)² = 150 J.

Correct Answer: B — 30 J

Q. A rotating object has a moment of inertia of 3 kg·m² and is spinning with an angular velocity of 4 rad/s. What is its kinetic energy? (2023)

A. 12 J
B. 24 J
C. 48 J
D. 6 J

Solution

The rotational kinetic energy is given by KE = 0.5 I ω² = 0.5 * 3 * (4)² = 24 J.

Correct Answer: B — 24 J

Q. A rotating object has a moment of inertia of 5 kg·m² and is rotating with an angular velocity of 4 rad/s. What is its kinetic energy? (2022)

A. 40 J
B. 20 J
C. 10 J
D. 80 J

Solution

The rotational kinetic energy is given by KE = (1/2)Iω² = (1/2)(5 kg·m²)(4 rad/s)² = 40 J.

Correct Answer: A — 40 J

Q. A rotating object has an angular momentum L. If its moment of inertia is halved and angular velocity is doubled, what is the new angular momentum? (2022)

A. L
B. 2L
C. 3L
D. 4L

Solution

L = Iω, if I is halved and ω is doubled, L' = (1/2)(2ω) = L.

Correct Answer: B — 2L

Q. A rotating object has an angular momentum L. If the moment of inertia of the object is doubled while keeping the angular velocity constant, what happens to the angular momentum?

A. It doubles
B. It halves
C. It remains the same
D. It quadruples

Solution

Angular momentum L = Iω. If I is doubled and ω remains constant, L also doubles.

Correct Answer: A — It doubles

Q. A rotating object has an angular momentum of 10 kg·m²/s and a moment of inertia of 2 kg·m². What is its angular velocity?

A. 5 rad/s
B. 2 rad/s
C. 10 rad/s
D. 20 rad/s

Solution

Using L = Iω, we find ω = L/I = 10/2 = 5 rad/s.

Correct Answer: A — 5 rad/s

Q. A rotating object has an angular momentum of 10 kg·m²/s. If its moment of inertia is 2 kg·m², what is its angular velocity?

A. 5 rad/s
B. 2 rad/s
C. 10 rad/s
D. 20 rad/s

Solution

Using L = Iω, we have ω = L/I = 10 kg·m²/s / 2 kg·m² = 5 rad/s.

Correct Answer: A — 5 rad/s

Q. A rotating object has an angular momentum of 12 kg·m²/s and a moment of inertia of 4 kg·m². What is its angular velocity?

A. 3 rad/s
B. 4 rad/s
C. 2 rad/s
D. 1 rad/s

Solution

Angular momentum L = Iω, thus ω = L/I = 12 kg·m²/s / 4 kg·m² = 3 rad/s.

Correct Answer: A — 3 rad/s

Q. A rotating object has an angular momentum of 15 kg·m²/s. If its moment of inertia is 3 kg·m², what is its angular velocity?

A. 5 rad/s
B. 10 rad/s
C. 15 rad/s
D. 20 rad/s

Solution

Angular momentum L = Iω, thus ω = L/I = 15 kg·m²/s / 3 kg·m² = 5 rad/s.

Correct Answer: B — 10 rad/s

Q. A rotating object has an angular momentum of L. If its angular velocity is doubled and its moment of inertia remains constant, what will be the new angular momentum?

A. L
B. 2L
C. 4L
D. L/2

Solution

Angular momentum L = Iω, if ω is doubled, L becomes 2I(2ω) = 4L.

Correct Answer: C — 4L

Q. A rotating object has an angular momentum of L. If its moment of inertia is doubled while keeping the angular velocity constant, what will happen to its angular momentum?

A. It doubles
B. It halves
C. It remains the same
D. It becomes zero

Solution

Angular momentum L = Iω; if I is doubled and ω remains constant, L remains the same.

Correct Answer: C — It remains the same

Q. A rotating object has an angular momentum of L. If its moment of inertia is halved and the angular velocity is doubled, what is the new angular momentum?

A. L
B. 2L
C. 4L
D. L/2

Solution

New angular momentum L' = I'ω' = (1/2 I)(2ω) = Iω = L.

Correct Answer: C — 4L

Q. A rotating object has an angular momentum of L. If its moment of inertia is halved and its angular velocity is doubled, what is the new angular momentum?

A. L
B. 2L
C. 4L
D. L/2

Solution

New angular momentum L' = I'ω' = (1/2I)(2ω) = L.

Correct Answer: C — 4L

Q. A rotating object has an angular velocity of 30 rad/s and a moment of inertia of 3 kg·m². What is its rotational kinetic energy?

A. 135 J
B. 450 J
C. 270 J
D. 90 J

Solution

Rotational kinetic energy K = (1/2)Iω² = (1/2)(3 kg·m²)(30 rad/s)² = 450 J.

Correct Answer: B — 450 J

Q. A rotating object has an angular velocity of 30 rad/s. If it is brought to rest in 5 seconds, what is the angular deceleration?

A. 6 rad/s²
B. 5 rad/s²
C. 3 rad/s²
D. 4 rad/s²

Solution

Angular deceleration = (final angular velocity - initial angular velocity) / time = (0 - 30 rad/s) / 5 s = -6 rad/s².

Correct Answer: A — 6 rad/s²

Q. A rotating system has an initial angular momentum L. If no external torque acts on it, what will be the angular momentum after some time?

A. L
B. 0
C. Increases
D. Decreases

Solution

Angular momentum is conserved in the absence of external torque.

Correct Answer: A — L

Q. A rotating wheel has an angular momentum of 10 kg·m²/s. If its moment of inertia is 2 kg·m², what is its angular velocity?

A. 5 rad/s
B. 10 rad/s
C. 20 rad/s
D. 2 rad/s

Solution

Using L = Iω, we have ω = L/I = 10/2 = 5 rad/s.

Correct Answer: A — 5 rad/s

Q. A rotating wheel has an angular momentum of L. If its angular velocity is doubled, what will be the new angular momentum?

A. L
B. 2L
C. 4L
D. L/2

Solution

Angular momentum L = Iω, if ω is doubled, L becomes 2I(2ω) = 4L.

Correct Answer: C — 4L

Q. A rotating wheel has an angular momentum of L. If the wheel's angular velocity is doubled, what happens to its angular momentum?

A. L
B. 2L
C. 4L
D. L/2

Solution

Angular momentum L = Iω; if ω is doubled, L becomes 2I(2ω) = 4L.

Correct Answer: C — 4L

Q. A rotating wheel has an angular momentum of L. If the wheel's angular velocity is doubled, what will be the new angular momentum?

A. L
B. 2L
C. 4L
D. L/2

Solution

Angular momentum L is proportional to angular velocity, so if angular velocity is doubled, angular momentum becomes 4L.

Correct Answer: C — 4L

Q. A runner completes a 400 m lap in 50 seconds. What is his average velocity?

A. 6 m/s
B. 7 m/s
C. 8 m/s
D. 9 m/s

Solution

Average velocity = total distance / total time = 400 m / 50 s = 8 m/s.

Correct Answer: A — 6 m/s

Q. A runner completes a 400 m lap in 50 seconds. What is the average speed of the runner in m/s? (2019)

A. 6 m/s
B. 7 m/s
C. 8 m/s
D. 9 m/s

Solution

Average speed = Total distance / Total time = 400 m / 50 s = 8 m/s.

Correct Answer: A — 6 m/s

Q. A runner completes a 400 m lap in 50 seconds. What is the average velocity of the runner?

A. 8 m/s
B. 6 m/s
C. 4 m/s
D. 2 m/s

Solution

Average velocity = total displacement / total time. Since the runner returns to the starting point, displacement = 0. Average velocity = 0 m / 50 s = 0 m/s.

Correct Answer: B — 6 m/s

Q. A runner completes a 400 m lap in 50 seconds. What is the runner's average velocity?

A. 8 m/s
B. 6 m/s
C. 4 m/s
D. 2 m/s

Solution

Average velocity = total displacement / total time. Since the runner returns to the starting point, displacement = 0. Average velocity = 0 m/s.

Correct Answer: A — 8 m/s

Q. A runner completes a 400 m track in 50 seconds. What is their speed in m/s? (2023)

A. 6 m/s
B. 7 m/s
C. 8 m/s
D. 9 m/s

Solution

Speed = Distance/Time = 400 m/50 s = 8 m/s

Correct Answer: A — 6 m/s

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