Engineering & Architecture Admissions - Exam Prep Guide

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Engineering & Architecture Admissions

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Engineering & Architecture Admissions MCQ & Objective Questions

Engineering & Architecture Admissions play a crucial role in shaping the future of aspiring students in India. With the increasing competition in entrance exams, mastering MCQs and objective questions is essential for effective exam preparation. Practicing these types of questions not only enhances concept clarity but also boosts confidence, helping students score better in their exams.

What You Will Practise Here

Key concepts in Engineering Mathematics
Fundamentals of Physics relevant to architecture and engineering
Important definitions and terminologies in engineering disciplines
Essential formulas for solving objective questions
Diagrams and illustrations for better understanding
Conceptual theories related to structural engineering
Analysis of previous years' important questions

Exam Relevance

The topics covered under Engineering & Architecture Admissions are highly relevant for various examinations such as CBSE, State Boards, NEET, and JEE. Students can expect to encounter MCQs that test their understanding of core concepts, application of formulas, and analytical skills. Common question patterns include multiple-choice questions that require selecting the correct answer from given options, as well as assertion-reason type questions that assess deeper comprehension.

Common Mistakes Students Make

Misinterpreting the question stem, leading to incorrect answers.
Overlooking units in numerical problems, which can change the outcome.
Confusing similar concepts or terms, especially in definitions.
Neglecting to review diagrams, which are often crucial for solving problems.
Rushing through practice questions without understanding the underlying concepts.

FAQs

Question: What are the best ways to prepare for Engineering & Architecture Admissions MCQs?
Answer: Regular practice of objective questions, reviewing key concepts, and taking mock tests can significantly enhance your preparation.

Question: How can I improve my accuracy in solving MCQs?
Answer: Focus on understanding the concepts thoroughly, practice regularly, and learn to eliminate incorrect options to improve accuracy.

Start your journey towards success by solving practice MCQs today! Test your understanding and strengthen your knowledge in Engineering & Architecture Admissions to excel in your exams.

JEE Main

Q. A light ray traveling in glass (n=1.5) strikes the glass-air interface at an angle of 30°. Will it undergo total internal reflection?

A. Yes
B. No
C. Depends on the angle
D. Not enough information

Solution

Since sin(30°) < sin(θc) where θc = sin⁻¹(1/1.5) ≈ 41.8°, it will not undergo total internal reflection.

Correct Answer: B — No

Q. A liquid drop is formed on a surface. The angle formed between the tangent to the drop surface and the solid surface is called what?

A. Contact angle
B. Surface angle
C. Tension angle
D. Cohesion angle

Solution

The angle formed between the tangent to the drop surface and the solid surface is known as the contact angle, which indicates the wettability of the surface.

Correct Answer: A — Contact angle

Q. A liquid has a surface tension of 0.03 N/m. What is the height of the liquid column that can be supported by a capillary tube of radius 0.5 mm?

A. 1.2 cm
B. 2.4 cm
C. 3.6 cm
D. 4.8 cm

Solution

Using the formula h = 2T/(ρgr), we can calculate the height of the liquid column.

Correct Answer: B — 2.4 cm

Q. A liquid has a surface tension of 0.03 N/m. What is the pressure difference across a curved surface of radius 0.1 m?

A. 0.15 Pa
B. 0.3 Pa
C. 0.6 Pa
D. 0.9 Pa

Solution

Using the formula ΔP = 2γ/r, ΔP = 2 × 0.03 N/m / 0.1 m = 0.6 Pa.

Correct Answer: B — 0.3 Pa

Q. A long straight conductor carries a current I. What is the magnetic field at a distance r from the wire?

A. μ₀I/(2πr)
B. μ₀I/(4πr)
C. μ₀I/(πr)
D. μ₀I/(2r)

Solution

The magnetic field around a long straight conductor is given by B = μ₀I/(2πr).

Correct Answer: A — μ₀I/(2πr)

Q. A long straight conductor carrying current I produces a magnetic field B at a distance r from it. What is the expression for B?

A. μ₀I/(2πr)
B. μ₀I/(4πr)
C. μ₀I/(πr)
D. μ₀I/(8πr)

Solution

The magnetic field due to a long straight conductor is given by B = μ₀I/(2πr).

Correct Answer: A — μ₀I/(2πr)

Q. A long straight wire carries a current I. What is the magnetic field at a distance r from the wire?

A. μ₀I/(2πr)
B. μ₀I/(4πr)
C. μ₀I/(8πr)
D. μ₀I/(πr)

Solution

The magnetic field around a long straight wire is given by B = μ₀I/(2πr).

Correct Answer: A — μ₀I/(2πr)

Q. A long straight wire carries a uniform linear charge density λ. What is the electric field at a distance r from the wire?

A. λ/(2πε₀r)
B. λ/(4πε₀r²)
C. λ/(2πε₀r²)
D. 0

Solution

Using Gauss's law for a cylindrical surface around the wire, the electric field E at a distance r is E = λ/(2πε₀r).

Correct Answer: A — λ/(2πε₀r)

Q. A loop of wire is moved into a magnetic field at a constant speed. What happens to the induced EMF as it enters the field?

A. It increases
B. It decreases
C. It remains constant
D. It becomes zero

Solution

As the loop enters the magnetic field, the rate of change of magnetic flux increases, leading to an increase in induced EMF.

Correct Answer: A — It increases

Q. A loop of wire is moved into a magnetic field at a constant speed. What happens to the induced EMF as the loop enters the field?

A. Induced EMF increases
B. Induced EMF decreases
C. Induced EMF remains constant
D. Induced EMF becomes zero

Solution

As the loop enters the magnetic field, the magnetic flux through the loop increases, leading to an increase in induced EMF.

Correct Answer: A — Induced EMF increases

Q. A loop of wire is moved into a magnetic field at a constant speed. What is the effect on the induced current as the loop enters the field?

A. It increases
B. It decreases
C. It remains constant
D. It becomes zero

Solution

As the loop enters the magnetic field, the area of the loop within the field increases, leading to an increase in magnetic flux and thus an increase in the induced current according to Faraday's law.

Correct Answer: A — It increases

Q. A loop of wire is moved into a uniform magnetic field at a constant speed. What happens to the induced EMF as it enters the field?

A. It increases
B. It decreases
C. It remains constant
D. It becomes zero

Solution

As the loop enters the magnetic field, the area exposed to the magnetic field increases, leading to an increase in the induced EMF.

Correct Answer: A — It increases

Q. A loop of wire is placed in a changing magnetic field. What phenomenon is observed?

A. Electromagnetic induction
B. Magnetic resonance
C. Electrolysis
D. Thermal conduction

Solution

A changing magnetic field induces an electromotive force (EMF) in the loop, a phenomenon known as electromagnetic induction.

Correct Answer: A — Electromagnetic induction

Q. A loop of wire is placed in a changing magnetic field. What phenomenon is this an example of?

A. Electromagnetic induction
B. Magnetic resonance
C. Electrostatics
D. Magnetic hysteresis

Solution

This is an example of electromagnetic induction, where a changing magnetic field induces an electromotive force (EMF) in the loop of wire.

Correct Answer: A — Electromagnetic induction

Q. A loop of wire is placed in a uniform magnetic field. If the angle between the field and the normal to the loop is 60 degrees, what is the effective magnetic flux?

A. 0.5 B A
B. 0.866 B A
C. 0.866 B A²
D. B A

Solution

Effective magnetic flux (Φ) = B * A * cos(θ) = B * A * cos(60°) = 0.5 B A.

Correct Answer: B — 0.866 B A

Q. A loop of wire is placed in a uniform magnetic field. If the field strength is increased, what happens to the induced EMF?

A. It increases
B. It decreases
C. It remains constant
D. It becomes zero

Solution

According to Faraday's law, an increase in magnetic field strength leads to an increase in the induced EMF.

Correct Answer: A — It increases

Q. A loop of wire is placed in a uniform magnetic field. What happens if the magnetic field strength is increased?

A. Induced current flows in the loop
B. No effect on the loop
C. The loop will heat up
D. The loop will move

Solution

According to Faraday's law of electromagnetic induction, a change in magnetic field strength induces an electromotive force (EMF) in the loop, causing a current to flow.

Correct Answer: A — Induced current flows in the loop

Q. A loop of wire is placed in a uniform magnetic field. What happens to the induced EMF if the area of the loop is increased?

A. Increases
B. Decreases
C. Remains the same
D. Depends on the magnetic field strength

Solution

According to Faraday's law of electromagnetic induction, the induced EMF is directly proportional to the rate of change of magnetic flux, which increases with an increase in the area of the loop.

Correct Answer: A — Increases

Q. A machine does 300 J of work in 5 seconds. What is its power?

A. 60 W
B. 30 W
C. 50 W
D. 20 W

Solution

Power (P) = Work / Time = 300 J / 5 s = 60 W

Correct Answer: A — 60 W

Q. A machine does 500 J of work in 10 seconds. What is its power output?

A. 50 W
B. 100 W
C. 200 W
D. 500 W

Solution

Power is calculated using the formula P = W/t. Here, W = 500 J and t = 10 s, so P = 500 J / 10 s = 50 W.

Correct Answer: B — 100 W

Q. A machine does 500 J of work in 10 seconds. What is its power?

A. 50 W
B. 100 W
C. 200 W
D. 500 W

Solution

Power = Work / Time = 500 J / 10 s = 50 W.

Correct Answer: B — 100 W

Q. A machine does 600 J of work in 5 seconds. What is its power?

A. 120 W
B. 100 W
C. 150 W
D. 200 W

Solution

Power (P) = Work / Time = 600 J / 5 s = 120 W

Correct Answer: A — 120 W

Q. A magnetic field of 0.3 T is perpendicular to a circular loop of radius 0.1 m. What is the magnetic flux through the loop?

A. 0.03 Wb
B. 0.03 Tm²
C. 0.1 Wb
D. 0.1 Tm²

Solution

Magnetic flux (Φ) = B * A = 0.3 T * π(0.1 m)² = 0.03 Wb.

Correct Answer: A — 0.03 Wb

Q. A man can run at 5 km/h in still air. If he runs in a direction opposite to the wind blowing at 3 km/h, what is his effective speed?

A. 2 km/h
B. 5 km/h
C. 8 km/h
D. 3 km/h

Solution

Effective speed = speed of man - speed of wind = 5 - 3 = 2 km/h.

Correct Answer: A — 2 km/h

Q. A man can run at a speed of 5 m/s in still air. If he runs in a direction opposite to the wind blowing at 2 m/s, what is his effective speed?

A. 3 m/s
B. 5 m/s
C. 7 m/s
D. 10 m/s

Solution

Effective speed = speed of man - speed of wind = 5 - 2 = 3 m/s.

Correct Answer: A — 3 m/s

Q. A man can walk at a speed of 5 km/h. If he walks in a direction opposite to the wind blowing at 3 km/h, what is his effective speed?

A. 2 km/h
B. 5 km/h
C. 8 km/h
D. 3 km/h

Solution

Effective speed = speed of man + speed of wind = 5 + 3 = 8 km/h.

Correct Answer: C — 8 km/h

Q. A man is standing 100 meters away from a building. If the angle of elevation to the top of the building is 45 degrees, what is the height of the building?

A. 100 m
B. 50 m
C. 75 m
D. 25 m

Solution

Using tan(45°) = height/distance, we have height = distance * tan(45°) = 100 * 1 = 100 m.

Correct Answer: A — 100 m

Q. A man is standing 30 meters away from a tower. If the angle of elevation of the top of the tower from the man's position is 30 degrees, what is the height of the tower?

A. 15√3 meters
B. 30 meters
C. 15 meters
D. 10√3 meters

Solution

Height = distance * tan(angle) = 30 * tan(30°) = 30 * (1/√3) = 10√3 meters.

Correct Answer: A — 15√3 meters

Q. A man is standing 30 meters away from a tree. If the angle of elevation from his eyes to the top of the tree is 30 degrees, what is the height of the tree?

A. 15√3 meters
B. 15 meters
C. 30 meters
D. 45 meters

Solution

Height = distance * tan(angle) = 30 * tan(30°) = 30 * (1/√3) = 10√3 meters.

Correct Answer: A — 15√3 meters

Q. A man is standing 30 meters away from a tree. If the angle of elevation of the top of the tree from his eyes is 60 degrees, what is the height of the tree?

A. 15√3 meters
B. 30√3 meters
C. 45 meters
D. 30 meters

Solution

Height = distance * tan(angle) = 30 * √3 = 15√3 meters.

Correct Answer: A — 15√3 meters

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