5.10 Power - Class 11 Physics

After understanding work and energy in the previous sections of Chapter 5, the natural next question is: how fast is the work being done? Two machines may perform the same amount of work, but the one that completes it in less time is more powerful. This idea leads us to the concept of Power.

Power connects mechanics to real-world applications such as engines, motors, lifting systems, automobiles, turbines, and even rocket propulsion. In competitive exams like JEE Main and JEE Advanced, power is frequently tested in combination with force, velocity, circular motion, friction, and conservation of energy.

At Deeksha Vedantu, we emphasize conceptual clarity so that students can confidently apply power formulas in both board examinations and high-level competitive problems.

Definition of Power

Power is defined as the rate at which work is done.

Mathematically:

$\boldsymbol$

Where:

$\boldsymbol$ = power
$\boldsymbol$ = work done
$\boldsymbol$ = time taken

SI unit of power is Watt (W).

$\boldsymbol$

This means if 1 joule of work is done in 1 second, the power is 1 watt.

Dimensional Formula of Power

Work has dimension $\boldsymbol$ .

Therefore power has dimension:

$\boldsymbol$

Dimensional understanding is important in advanced problem solving.

Average Power

Average power is defined as total work done divided by total time taken.

$\boldsymbol{P_{avg} = \frac}$

This formula is useful when motion is not uniform but total time and total work are known.

Example 1 (Board Level)

A person lifts a 30 kg object to a height of 3 m in 6 seconds.

Work done:

$\boldsymbol$

Average power:

$\boldsymbol$

This example demonstrates how gravitational work converts into power.

Instantaneous Power

In most real-life situations, force and velocity vary continuously. Hence, we define instantaneous power.

$\boldsymbol$

Since infinitesimal work is:

$\boldsymbol$

Dividing both sides by $\boldsymbol$ :

$\boldsymbol$

This is one of the most important formulas in mechanics.

Vector Nature of Power

Power depends on the dot product between force and velocity.

$\boldsymbol$

Where $\boldsymbol$ is the angle between force and velocity.

Special Cases

If $\boldsymbol$ (parallel):

$\boldsymbol$

If $\boldsymbol$ (perpendicular):

$\boldsymbol$

This explains why centripetal force in uniform circular motion does no work and produces no power.

Power in Terms of Kinetic Energy

From Work–Energy Theorem:

$\boldsymbol$

Differentiating with respect to time:

$\boldsymbol{P = \frac{d} \left( \frac{1}{2} m v^2 \right)}$

$\boldsymbol{P = m v \frac{dv}}$

Since:

$\boldsymbol{F = m \frac{dv}}$

Thus:

$\boldsymbol$

This confirms consistency between definitions.

Units of Power

SI Unit: Watt (W)
$\boldsymbol$
$\boldsymbol$
Horsepower:

$\boldsymbol$

Horsepower is commonly used in automobile engines.

Power Delivered by Engines at Constant Speed

When a vehicle moves with constant velocity against resistive force $\boldsymbol$ :

$\boldsymbol$

If speed doubles, required power doubles (assuming resistive force constant).

Example 2 (JEE Type)

A car moves at constant speed 30 m/s against frictional force 500 N.

Power required:

$\boldsymbol$

Power While Climbing an Incline

If a body moves up an incline at constant speed:

$\boldsymbol$

If friction acts:

$\boldsymbol$

Such layered problems are common in JEE Main and Advanced.

Constant Power Engine – Acceleration Analysis

If engine delivers constant power $\boldsymbol$ :

$\boldsymbol$

$\boldsymbol{F = \frac{v}}$

Using Newton's Second Law:

$\boldsymbol{m \frac{dv} = \frac{v}}$

Thus acceleration:

$\boldsymbol{a = \frac{mv}}$

Acceleration decreases as velocity increases.

Integrating:

$\boldsymbol$

Thus velocity increases proportional to square root of time.

This is an important JEE Advanced result.

Power in Circular Motion

In uniform circular motion:

$\boldsymbol{\vec \perp \vec{v}}$

Thus:

$\boldsymbol$

Although force exists, no work is done.

However, if tangential force exists (non-uniform circular motion), power is non-zero.

Power and Momentum Relation

Since:

$\boldsymbol{\vec = \frac{d\vec{p}}}$

Power can be written as:

$\boldsymbol{P = \vec{v} \cdot \frac{d\vec{p}}}$

This form is useful in advanced dynamics.

Efficiency of Machines

Efficiency measures how effectively input power is converted to useful output power.

$\boldsymbol$

Efficiency is always less than 1 due to energy losses.

Example 3 (Elevator Problem)

A 1200 kg elevator moves upward at constant speed 2 m/s.

$\boldsymbol$

If efficiency is 75%:

$\boldsymbol$

Such multi-step reasoning is common in exams.

Power–Time Graph Interpretation

Total work done:

$\boldsymbol$

Area under power–time curve equals work done.

This graphical interpretation is frequently tested.

Advanced JEE Problem 1 (Variable Force)

If force varies with velocity as:

$\boldsymbol$

Power:

$\boldsymbol$

Power increases rapidly with velocity.

Advanced JEE Problem 2 (Block Pulled by Rope)

A block is pulled with constant power on the horizontal surface.

Since $\boldsymbol$ and friction acts, velocity increases gradually.

Acceleration:

$\boldsymbol{a = \frac{mv} - \frac{f}{m}}$

Multi-variable reasoning is required.

Advanced JEE Problem 3 (Rocket Insight)

Thrust force $\boldsymbol$ produces power:

$\boldsymbol$

As rocket speed increases, required power increases.

This explains high fuel consumption at high speeds.

Common Conceptual Mistakes

Confusing work with power.
Ignoring angle in dot product.
Assuming centripetal force does power.
Forgetting unit conversions.
Applying average formula in instantaneous cases.

Comprehensive Formula Table

Concept	Formula
Average Power	$\boldsymbol$
Instantaneous Power	$\boldsymbol$
Force–Velocity	$\boldsymbol$
Linear Case	$\boldsymbol$
Constant Power Acceleration	$\boldsymbol{a = \frac{mv}}$
Efficiency	$\boldsymbol$
Work from Power	$\boldsymbol$

FAQs

Q1. What is the physical meaning of power?

It represents how fast energy is transferred.

Q2. Why is power zero in circular motion?

Because force is perpendicular to velocity.

Q3. Why does acceleration decrease in constant power motion?

Because force decreases as velocity increases.

Q4. What is horsepower?

$\boldsymbol$

Q5. Why is power important in competitive exams?

Because it connects force, energy, motion, and real-world applications.

Conclusion

Power completes the study of work and energy by introducing the rate of energy transfer. The relation $\boldsymbol$ provides a powerful bridge between theoretical mechanics and practical systems like engines and motors.

At Deeksha Vedantu, we ensure students gain deep conceptual understanding along with mathematical precision, enabling them to solve even advanced JEE-level power problems confidently.

5.10 Power – Class 11 Physics

Definition of Power

Dimensional Formula of Power

Average Power

Example 1 (Board Level)

Instantaneous Power

Vector Nature of Power

Special Cases

Power in Terms of Kinetic Energy

Units of Power

Power Delivered by Engines at Constant Speed

Example 2 (JEE Type)

Power While Climbing an Incline

Constant Power Engine – Acceleration Analysis

Power in Circular Motion

Power and Momentum Relation

Efficiency of Machines

Example 3 (Elevator Problem)

Power–Time Graph Interpretation

Advanced JEE Problem 1 (Variable Force)

Advanced JEE Problem 2 (Block Pulled by Rope)

Advanced JEE Problem 3 (Rocket Insight)

Common Conceptual Mistakes

Comprehensive Formula Table

FAQs

Q1. What is the physical meaning of power?

Q2. Why is power zero in circular motion?

Q3. Why does acceleration decrease in constant power motion?

Q4. What is horsepower?

Q5. Why is power important in competitive exams?

Conclusion

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