Have you ever swung in a pendulum swing , if yes you may observe that you have the maximum velocity at the position when you come down and zero velocity when you are at the highest point. Why is it happening? It is because of energy when you come down the swing’s energy converted into kinetic form and when you reach at the top it has potential energy.

**Table of Contents**

- What is Energy?
- Energy in Simple Harmonic Motion
- Practice Problems of Energy in Simple Harmonic Motion
- FAQs of Energy in Simple Harmonic Motion

## What is Energy?

Energy is defined as the ability to do work. Energy objects have some kind of energy either moving or at rest. As per the laws of conservation of energy, “energy cannot be created or destroyed, although it can be converted from one form to another”. The unit of energy is joule (J).

Energy has various types. In Simple harmonic motion we deal with only mechanical energy. Mechanical energy is also of two types kinetic energy and potential energy.

## Energy in Simple Harmonic Motion

When a particle is in simple harmonic motion it also possesses energy. We know that when the particle is at mean position it have maximum velocity and kinetic energy is proportional to square of velocity, so particle have maximum kinetic energy at mean position and when it is at extreme positions it has maximum restoring force means maximum ability of doing work hence maximum potential energy. Let's see mathematically how we calculate energies in simple harmonic motion.

### Kinetic Energy of Simple Harmonic Motion

Kinetic energy of an object is due to its motion.Consider a particle of mass m is in simple harmonic motion with amplitude ‘a’ along a path PQ. let's O be the mean position. Hence OA=OB=a.

Now suppose a particle is given an infinitely small displacement dx against the restoring force force F and work down to displace the particle is dw.

Then

Now for total work in displacing the particle from mean potion (x=0) to a distance x, will be equal to the integration of equation .

On integrating equation we get,

Hence, Total work done

Puting

The work done by external forces will store in the form of potential energy.

Therefore Potential energy

From the equation we can see that Potential energy is the function of the square of x i.e. . The graphical representation of Potential energy can be seen in figure.

The equation can be used for calculating the Potential energy for a particle performing simple harmonic motion.

**Total energy or mechanical energy of simple harmonic motion**

For a particle which is in simple harmonic motion the total energy of the particle will be equal to the sum of their kinetic and potential energy.

Total energy = kinetic energy + potential energy

We can see from the equation that the total energy of a particle in simple harmonic motion is constant. However the kinetic energy and potential energy are interchangeable. Graph of total energy with displacement is shown in figure.

We can see from the graph that

- At the mean position, the total energy is in purely kinetic form. And at extreme positions the energy is in purely potential form.
- In another position kinetic energy and potential energy is interconvertible and their sum is constant.

Now consider a block connected with spring executing SHM given by

Then the velocity of particle will be

SO,The kinetic energy of particle

From the equation we can see that kinetic energy is a function of time.

As spring force F=-kx is a conservative force so the potential energy associated with this is

Potential energy is also a function of time.

Now total energy

The total mechanical energy of a harmonic motion is independent of time.

The graph of time K, U and E with time is shown in figure.

## Practice Problems

**Q1.**A Object of mass 10 g performing simple harmonic motion of amplitude 10 cm and period s. Determine its kinetic energy when it is at a distance of 8 cm from its equilibrium position.

**Ans.**

Given: Mass m=10 g , Amplitude a = 10 cm , PeriodT = ,Displacement x = 8 cm

Angular velocity

Kinetic energy

Ans

**Q.**A particle of mass 10 g executes simple harmonic motion of amplitude 5 cm and period s. Find Potential energy, After it has crossed it means potion.

**A2.**

Given: Mass m=10 g , Amplitude a = 5 cm , PeriodT = , time elapsed =, as particle passes through mean position, .

Angular velocity

Displacement of particle from mean position )

)

Potential energy

Ans

**Q3.**Total energy of a particle in simple harmonic motion of mass 0.5 kg is 25 J. Finds its speed when crossing the mean potion.

**Ans.**Given: Mass m=0.5 kg , Total energy E=25 J.

When the particle passes through its mean potion it has maximum speed.

Now Total energy

But

Hence the speed of particles passing through the mean potion is 10 m/s.

**Q4.**Find the position of a particle in simple harmonic motion at the instant when the kinetic energy of the particle is 8 times its potential energy.

**Ans.**Given:

Now

Particle will be at a distance from the mean potion on either side.

## FAQs

**Q1.**Total kinetic energy of simple harmonic motion depends on?

**Ans.**Total energy is proportional to mass (m), square of frequency and square of amplitude .

**Q2.**Explain energy in SHM?

**Ans.**Energy of simple harmonic motion is the sum of kinetic and potential energy at any instant.It remains constant for all times.

**Q3.**At what potion Kinetic energy and potential energy will be the equal in simple harmonic motion?

**Ans.**Kinetic energy of a particle is given by

Potential energy of particle is given by

According to question

So, at KInetic energy and potential energy will be equal in SHM.

**Q4.**Is the energy of particles executing simple harmonic motion zero at extreme positions?

**Ans.**No, only kinetic energy is zero.

**Q5.**What is the type of curve on an energy displacement graph for kinetic and potential energy in simple harmonic motion?

**Ans.**Energy graph is parabola in shape.

**Related link**

Periodic and oscillatory motion | The simple pendulum |

Simple harmonic motion, Force law for simple harmonic motion | Damped oscillation, Forced oscillation, Resonance , Practice Problems, FAQs |