Determine whether the following statements are True or False:
$1.$ The acceleration of $SHO$ at the mean position is maximum.
$2.$ The mechanical energy of $SHO$ depends on the maximum displacement.
$3.$ The periodic time for a seconds pendulum is $1 \, s$.
$4.$ If the frequency of $SHM$ is $v$,then the frequency of kinetic energy is also $v$.
$1.$ The acceleration of $SHO$ at the mean position is maximum.
$2.$ The mechanical energy of $SHO$ depends on the maximum displacement.
$3.$ The periodic time for a seconds pendulum is $1 \, s$.
$4.$ If the frequency of $SHM$ is $v$,then the frequency of kinetic energy is also $v$.
(A) $1.$ False. At the mean position,the displacement $x = 0$,so acceleration $a = -\omega^2 x = 0$. The acceleration is zero at the mean position and maximum at the extreme positions.
$2.$ True. The total mechanical energy of an $SHO$ is given by $E = \frac{1}{2} k A^2$,where $A$ is the maximum displacement (amplitude). Thus,it depends on the square of the amplitude.
$3.$ False. $A$ seconds pendulum is defined as a pendulum whose period of oscillation is $2 \, s$ (one second for each swing).
$4.$ False. If the frequency of $SHM$ is $v$,the kinetic energy oscillates as $K = \frac{1}{2} k A^2 \cos^2(\omega t) = \frac{1}{4} k A^2 (1 + \cos(2\omega t))$. Since the angular frequency is $2\omega$,the frequency of kinetic energy is $2v$.
$2.$ True. The total mechanical energy of an $SHO$ is given by $E = \frac{1}{2} k A^2$,where $A$ is the maximum displacement (amplitude). Thus,it depends on the square of the amplitude.
$3.$ False. $A$ seconds pendulum is defined as a pendulum whose period of oscillation is $2 \, s$ (one second for each swing).
$4.$ False. If the frequency of $SHM$ is $v$,the kinetic energy oscillates as $K = \frac{1}{2} k A^2 \cos^2(\omega t) = \frac{1}{4} k A^2 (1 + \cos(2\omega t))$. Since the angular frequency is $2\omega$,the frequency of kinetic energy is $2v$.
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Column $I$ Column $II$ $(A)$ The object moves on the $x$-axis under a conservative force such that its speed $v = c_1 \sqrt{c_2 - x^2}$,where $c_1, c_2 > 0$. $(p)$ The object executes simple harmonic motion. $(B)$ The object moves on the $x$-axis such that its velocity $v = -kx$,where $k > 0$. $(q)$ The object does not change its direction. $(C)$ An object is attached to a spring in an elevator accelerating upwards with constant acceleration $a$. The motion is observed from the elevator. $(r)$ The kinetic energy of the object keeps on decreasing. $(D)$ The object is projected vertically upwards with speed $2 \sqrt{GM_e / R_e}$. $(s)$ The object can change its direction only once.
| Column $I$ | Column $II$ |
| $(A)$ The object moves on the $x$-axis under a conservative force such that its speed $v = c_1 \sqrt{c_2 - x^2}$,where $c_1, c_2 > 0$. | $(p)$ The object executes simple harmonic motion. |
| $(B)$ The object moves on the $x$-axis such that its velocity $v = -kx$,where $k > 0$. | $(q)$ The object does not change its direction. |
| $(C)$ An object is attached to a spring in an elevator accelerating upwards with constant acceleration $a$. The motion is observed from the elevator. | $(r)$ The kinetic energy of the object keeps on decreasing. |
| $(D)$ The object is projected vertically upwards with speed $2 \sqrt{GM_e / R_e}$. | $(s)$ The object can change its direction only once. |
Fill in the blanks:
$1.$ If a tunnel is dug along the diameter of the Earth and a body is dropped freely in it,the motion of this body is .........,assuming there is no frictional force of the medium acting on it.
$2.$ When a body executes simple harmonic motion and makes $\frac{1}{2\pi}$ oscillations,its phase increases by ......... $rad$.
$3.$ For a body executing simple harmonic motion,the phase increases by ......... every second.
$4.$ The ratio of force constants of two springs is $1:2$ and the ratio of their mechanical energies is $2:9$. The ratio of the amplitudes of the two bodies suspended at the ends of the springs is .........
$1.$ If a tunnel is dug along the diameter of the Earth and a body is dropped freely in it,the motion of this body is .........,assuming there is no frictional force of the medium acting on it.
$2.$ When a body executes simple harmonic motion and makes $\frac{1}{2\pi}$ oscillations,its phase increases by ......... $rad$.
$3.$ For a body executing simple harmonic motion,the phase increases by ......... every second.
$4.$ The ratio of force constants of two springs is $1:2$ and the ratio of their mechanical energies is $2:9$. The ratio of the amplitudes of the two bodies suspended at the ends of the springs is .........
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