Embibe Experts Solutions for Chapter: Wave Motion on a String, Exercise 4: Exercise - 4

Two transverse sine waves each of amplitude $4 \mathrm{mm}$ wavelength$2 \mathrm{m}$ and time period $1 \mathrm{s}$ and in phase at $x=0, t=0$are travelling along the $x$-axis in opposite direction. Obtain the equation of the resultant wave and comment on its nature calculate the maximum displacement at $x=2.333 \mathrm{m}.$ Also locate the antinodes and nodes.

A tube$1.0 \mathrm{m}$ long is closed at one end. A wire of length$0.3 \mathrm{m}$and mass $1 \times {10}^{–2} \mathrm{kg}$ is stretched between two fixed ends and is placed near the open end. When the wire is plucked at its mid point the air column resonates in its$1^{\mathrm{st} }$overtone. Find the tension in the wire if it vibrates in its fundamental mode.$[V_{\mathrm{sound}} = 330 \mathrm{m} {\mathrm{s}}^{-1}]$

A point isotropic sound source is located on the perpendicular to the plane of a ring, drawn through the centre $O$ of the ring. The distance between the point $O$ and the source is $l=1.00$ $\mathrm{m}$ and the radius of the ring is $R=0.50$ $\mathrm{m}$. Find the mean energy flow across the area enclosed by the ring, if at point $O$, the intensity of sound is equal to $I_0=30$ $\mathrm{\mu W} {\mathrm{m}}^{-2}$. The damping of the waves is negligible.

A guitar string is $180 \mathrm{cm}$ long and has a fundamental frequency of $90 \mathrm{Hz}$. Where should it be pressed to produce a fundamental frequency of $135 \mathrm{Hz}$?

A piano wire weighing $4 \mathrm{g}$ and having a length of $90.0 \mathrm{cm}$ emits a fundamental frequency corresponding to the “Middle $C$” $(\nu = 125 \mathrm{Hz})$. Find the tension in the wire.

The length of a sonometer wire is $1.21 \mathrm{m}$. Find the length of the three segments for fundamental frequencies to be in the ratio $1 : 2 : 3$.

In the figure shown $A$ and $B$ are two ends of a string of length $100 \mathrm{m}.\mathit{ }{S}_1$ and $S_2$ are two sources due to which points $‘A’$ and $‘B’$ oscillate in $‘y’$ and $‘z’$ directions respectively according to the equation $y=2\sin (100\mathrm{\pi }t+30°)$ and $z=3\sin (100\pi t+60°)$ where $t$ is in $\sec$ and $y$ is in $\mathrm{mm}$. The speed of propagation of disturbance along the string is $50 \mathrm{m} {\mathrm{s}}^{-1}$. Find the instantaneous position vector (in $\mathrm{mm}$) and velocity vector in $(\mathrm{m} {\mathrm{s}}^{-1})$ of a particle $‘P’$ of string which is at $25 \mathrm{m}$ from $A$. You have to find these parameters after both the disturbances from $S_1$ and $S_2$ have reached $‘P’$. Also find the phase difference between the waves at the point $‘P’$ when they meet at $‘P’$ first time.

A string of mass $m$ is fixed at both ends. The fundamental tone oscillations are excited with angular frequency $\mathrm{\omega }$ and maximum displacement amplitude $a_{\max }$. Find:
(a) the maximum kinetic energy of the string;
(b) the mean kinetic energy of the string averaged over one oscillation period.