Phase space diagrams are useful tools in analyzing all kinds of dynamical problems. They are especially useful in studying the changes in motion as initial position and momentum are changed. Here we consider some simple dynamical systems in one-dimension. For such systems, phase space is a plane in which position is plotted along the horizontal axis and momentum is plotted along the vertical axis. The phase space diagram is the $x(t)$ vs. $p(t)$ curve in this plane. The arrow on the curve indicates the time flow. For example, the phase space diagram for a particle moving with constant velocity is a straight line as shown in the figure. We use the sign convention in which position or momentum upwards (or to the right) is positive and downwards (or to the left) is negative.
$1.$ The phase space diagram for a ball thrown vertically up from the ground is:
$2.$ The phase space diagram for simple harmonic motion is a circle centered at the origin. In the figure, the two circles represent the same oscillator but for different initial conditions, and $E_1$ and $E_2$ are the total mechanical energies respectively. Then:
$(A) E_1 = \sqrt{2} E_2$
$(B) E_1 = 2 E_2$
$(C) E_1 = 4 E_2$
$(D) E_1 = 16 E_2$
$3.$ Consider the spring-mass system, with the mass submerged in water, as shown in the figure. The phase space diagram for one cycle of this system is:
Give the answer for questions $1, 2,$ and $3.$
$1.$ The phase space diagram for a ball thrown vertically up from the ground is:
$2.$ The phase space diagram for simple harmonic motion is a circle centered at the origin. In the figure, the two circles represent the same oscillator but for different initial conditions, and $E_1$ and $E_2$ are the total mechanical energies respectively. Then:
$(A) E_1 = \sqrt{2} E_2$
$(B) E_1 = 2 E_2$
$(C) E_1 = 4 E_2$
$(D) E_1 = 16 E_2$
$3.$ Consider the spring-mass system, with the mass submerged in water, as shown in the figure. The phase space diagram for one cycle of this system is:
Give the answer for questions $1, 2,$ and $3.$
- A$(D, C, B)$
- B$(A, B, C)$
- C$(B, B, D)$
- D$(D, A, D)$
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Similar Questions
When a body is in $S.H.M.$,match the following:
List-$I$ List-$II$ $A$. Velocity is maximum $I$. Acceleration is maximum $B$. $K.E.$ is $\left(\frac{3}{4}\right)^{\text{th}}$ of total energy $II$. At mean position $C$. $P.E.$ is $\left(\frac{3}{4}\right)^{\text{th}}$ of total energy $III$. At half of the amplitude $D$. Acceleration is maximum $IV$. At $\frac{\sqrt{3}}{2}$ times the amplitude
| List-$I$ | List-$II$ |
| $A$. Velocity is maximum | $I$. Acceleration is maximum |
| $B$. $K.E.$ is $\left(\frac{3}{4}\right)^{\text{th}}$ of total energy | $II$. At mean position |
| $C$. $P.E.$ is $\left(\frac{3}{4}\right)^{\text{th}}$ of total energy | $III$. At half of the amplitude |
| $D$. Acceleration is maximum | $IV$. At $\frac{\sqrt{3}}{2}$ times the amplitude |
You are holding a shallow circular container of radius $R$,filled with water to a height $h$ $(h \ll R)$. When you walk with speed $v$,it is seen that water starts spilling over. This happens due to the resonance of the periodic impulse given to the container (due to walking) with the oscillation of the water in the container. If the time period of water oscillating in the container is inversely proportional to $\sqrt{h}$,then $v$ is proportional to
The displacement-time graph of a particle executing $SHM$ is shown. Which of the following statements is wrong?
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View SolutionThe displacement-time graph of a particle executing $SHM$ is shown. Which of the following statements is/are true?
$A$ body performs linear $S$.$H$.$M$. with amplitude $a$. When it is at a distance $\frac{a}{3}$ from the extreme position,the magnitude of velocity is $\frac{1}{3}$ times the magnitude of acceleration. The period of $S$.$H$.$M$. is:
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