Concept:
- Simple Harmonic Motion (SHM): The Simple Harmonic Motion is studied to discuss the periodic Motion Mathematically.
- In Simple Harmonic motion, the motion is between two extreme points, and the restoring force responsible for the motion tends to bring the object to mean position.
- The motion of a Simple pendulum and a block attached to spring are common examples of SHM.
Mathematically, SHM is Defined as:
x = A Sin (ωt + ɸ),
x is the displacement of the body from mean Position, at time t. ɸ is phase Difference.
A is Amplitude of Motion, that is the Maximum distance the body in SHM can move from mean Position.
ω is Angular Speed = \(\omega = \frac{2\pi }{T}\)
T is the time period of Motion,
- Potential Energy of the body in SHM is
P = \(\frac{1}{2}m\omega ^{2}x^{2}\)
- Kinetic Energy of the body in SHM is
K = \(\frac{1}{2}m\omega ^{2}(A^{2}-x^{2})\)
- Total Energy of the Body in SHM (E)
E= \(\frac{1}{2}m\omega ^{2}A^{2}\)
Calculation:
Given,
Potential Energy = Kinetic Energy at some displacement x from mean position.
\(\frac{1}{2}m\omega ^{2}x^{2}\) = \(\frac{1}{2}m\omega ^{2}(A^{2}-x^{2})\)
⇒ \(\frac{1}{2}m\omega ^{2}x^{2} = \frac{1}{2}m\omega ^{2}A^{2}- \frac{1}{2}m\omega ^{2}x^{2}\)
⇒\(2\times \frac{1}{2}m\omega ^{2}x^{2} = \frac{1}{2}m\omega ^{2}A^{2}\)
⇒\(x^{2} = \frac{1}{2}A^{2}\)
⇒ \(x = \pm \frac{A}{\sqrt{2}} \)
So, Option A / √ 2 is the correct option.
Additional Information
- Potential Energy is maximum at Extreme positions while Kinetic Energy is Maximum at mean Position.
- Potential Energy is zero at mean Position while Kinetic Energy is zero at Extreme Positions.
Stay updated with the Physics questions & answers with Testbook. Know more about Oscillations and ace the concept of Energy in Simple Harmonic Motion.
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2
Answer
Hint: This problem can be solved by using the direct formula for the potential energy of a body in SHM in terms of its displacement and the kinetic energy of a body in terms of its displacement and amplitude. By equating these two, we can get the required value of displacement in terms of the amplitude.
Formula used:
$KE=\dfrac{1}{2}K\left( {{A}^{2}}-{{x}^{2}} \right)$ $PE=\dfrac{1}{2}K{{x}^{2}}$Complete answer:
Let us write the expressions for the potential and kinetic energy of a body executing simple harmonic motion (SHM).The kinetic energy $KE$ of a body in simple harmonic motion with amplitude $A$ at a point where its displacement from the mean position is $x$ is given by $KE=\dfrac{1}{2}K\left( {{A}^{2}}-{{x}^{2}} \right)$ --(1)Where $K=m{{\omega }^{2}}$, where $m$ is the mass of the body and $\omega $ is the angular frequency of the SHM.The potential energy $PE$ of a body in simple harmonic motion with amplitude $A$ at a point where its displacement from the mean position is $x$ is given by $PE=\dfrac{1}{2}K{{x}^{2}}$ --(2)Where $K=m{{\omega }^{2}}$, where $m$ is the mass of the body and $\omega $ is the angular frequency of the SHM.Now, let us analyze the question.The amplitude of the SHM is $A$.Let the displacement of the body from the mean position at a certain instant be $x$.Let the kinetic energy of the body at this instant be $KE$.Let the potential energy of the body at this instant be $PE$.Now, according to the question, the kinetic energy is equal to the potential energy. $\therefore KE=PE$ Now, using (1) and (2) in the above equation, we get$\dfrac{1}{2}K\left( {{A}^{2}}-{{x}^{2}} \right)=\dfrac{1}{2}K{{x}^{2}}$ Where $K=m{{\omega }^{2}}$, where $m$ is the mass of the body and $\omega $ is the angular frequency of the SHM.$\Rightarrow {{A}^{2}}-{{x}^{2}}={{x}^{2}}$ $\Rightarrow {{A}^{2}}={{x}^{2}}+{{x}^{2}}=2{{x}^{2}}$ $\Rightarrow {{x}^{2}}=\dfrac{{{A}^{2}}}{2}$ Square rooting both sides we get$\sqrt{{{x}^{2}}}=\sqrt{\dfrac{{{A}^{2}}}{2}}$$\Rightarrow x=\dfrac{A}{\sqrt{2}}$ Hence, the required displacement of the body from the mean position is $\dfrac{A}{\sqrt{2}}$.So, the correct answer is “Option C”.
Note:
Students must note that the sum of the kinetic energy and the potential energy at any instance in the SHM remains the same as the total mechanical energy is conserved. This constant value is equal to $\dfrac{1}{2}K{{A}^{2}}$. The kinetic energy at the mean position has this value as the potential energy is zero at this point. Also, at the extreme positions, the potential energy is this value as the kinetic energy at the extreme points is zero (as the body has zero speed at this point).