A particle is executing simple harmonic motion with frequency f. … - Vidyadip

MCQ

A particle is executing simple harmonic motion with frequency $f$. The frequency at which its kinetic energy change into potential energy is

A
$f / 2$
B
$f$
✓
$2 f$
D
$4 f$

✓

Answer

Correct option: C.

$2 f$

(c) In S.H.M., frequency of K.E. and P.E.$=2 \times(\text { Frequency of oscillating particle })$

Need a full question paper?

Generate a complete, print-ready paper with questions like this in minutes — across 16+ boards, with answer keys.

Start Generating Free

Explore more

More "MCQ" from Simple Harmonic Motion→Simple Harmonic Motion — all question types→JEE physics STD 12 Science question papers→CBSE Board STD 12 Science question papers→CBSE Board question paper generator→

Similar questions

The specific heat of a gas in an isothermal process is

A liquid is kept in a cylindrical vessel which is being rotated about a vertical axis through the centre of the circular base. If the radius of the vessel is $r$ and angular velocity of rotation is $\omega$, then the difference in the heights of the liquid at the centre of the vessel and the edge is

An alternating current source of frequency $100 Hz$ is joined to a combination of a resistance, a capacitance and a coil in series. The potential difference across the coil, the resistance and the capacitor is $46,8$ and $40$ volt respectively. The electromotive force of alternating current source in volt is

For copper-iron $( Cu - Fe )$ couple, the thermo e.m.f. (temperature of cold junction $\left.=0^{\circ} C \right)$ is given by $E=\left(14 \theta-0.02 \theta^2\right) \mu V$. The neutral temperature will be

A constant volume gas thermometer shows pressure reading of $50 \mathrm{~cm}$ and $90 \mathrm{~cm}$ of mercury at $0^{\circ} \mathrm{C}$ and $100^{\circ} \mathrm{C}$ respectively. When the pressure reading is $60 \mathrm{~cm}$ of mercury, the temperature is

An incompressible fluid flows steadily through a cylindrical pipe which has radius $2 r$ at point $A$ and radius $r$ at $B$ further along the flow direction. If the velocity at point $A$ is $v$, its velocity at point $B$ is

A wave equation which gives the displacement along $y-$ direction is given by $y=0.001 \sin (100 t+x)$ where $x$ and $y$ are in meterand $t$ is time in second. This represented a wave

Two identical coaxial circular loops carry current each circulating in the clockwise direction. If the loops are approaching each other, then

The mass of a body measured by a physical balance in a lift at rest is found to be $m$. If the lift is going up with an acceleration $a$, its mass will be measured as

Following figure shows on adiabatic cylindrical container of volume $V_0$ divided by an adiabatic smooth piston (area of cross-section = \$ in two equal parts. An ideal gas $\left(C_P / C_V=\gamma\right)$ is at pressure $P$ and temperature $T$ in left part and gas at pressure $P$ and temperature $T$ in right part. The piston is slowly displaced and released at a position where it can stay in equilibrium. The final pressure of the two parts will be (Suppose $x=$ displacement of the piston)