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JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced PDF Download

Q.1. AB is a cylinder of length 1m fitted with a thin flexible diaphragm C at the middle and other thin flexible diaphragms A and B at the ends. The portions AC and BC contain hydrogen and oxygen gases respectively. The diaphragms A and B are set into vibrations of same frequency. What is the minimum frequency of these vibrations for which diaphragm C is  a node? (Under the conditions of experiment vH2 = 1100 m/s, vO2 = 300 m/s).     

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Ans. 1650 Hz

Solution. It is given that C acts as a node. This implies that at A and B antinodes are formed. Again it is given that the frequencies are same.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

or, 11p1 = 3p2 

This means that the third harmonic in AC is equal to 11th harmonic in CB.

Now, the fundamental frequency in AC

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

and the fundamental frequency in CB

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

∴Frequency in AC = 3 × 550 = 1650
Hz and frequency in CB = 11 × 150 = 1650 Hz

Q.2. A  copper wire is held at the two ends by rigid supports. At 30°C, the wire is just taut, with negligible tension. Find the speed of transverse waves in this wire at 10°C.

Given : Young modulus of copper = 1.3 × 1011 N/m2 .

Coefficient of linear expansion of copper = 1.7 × 10-5 oC-1.

Density of copper = 9× 103 kg/m3.     (1979)

Ans. 70 m/s

Solution. Using the formula of the coefficient of linear expansion of wire, Δℓ = ℓαΔθ we get
F = YAαΔθ

Speed of transverse wave is given by


JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.3. A tube of a certain diameter and of length 48 cm is open at both ends. Its fundamental frequency of resonance is found to be 320 Hz. The velocity of sound in air is 320 m/sec.

Estimate the diameter of the tube.     

One end of the tube is now closed. Calculate the lowest frequency of resonance for the tube.

Ans. 3.33 cm; 163 Hz

Solution. Tube open at both ends :

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Tube closed at one end :

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.4. A source of sound of frequency 256 Hz is moving rapidly towards wall with a velocity of 5 m/sec. How many beats per second will be heard if sound travels at a speed of 330 m/sec?     (1981 -  4 Marks)

Ans. 8

Solution. 

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

NOTE : If the sound reaches the observer after being reflected from a stationary surface and the medium is also stationary, the image of the source in the reflecting surface will become the source of the reflected sound.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

v0, vs are + ve if they are directed from source to the observer and – ve if they are directed from observer to source.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

∴ Beat frequency = 264 – 256 = 8

Q.5. A string 25 cm long and having a mass of 2.5 gm is under tension. A pipe closed at one end is 40 cm long. When the string is set vibrating in its first overtone and the air in the pipe  in its fundamental frequency, 8 beats per second are heard. It is observed that decreasing the tension in the string decreases beat frequency. If the speed of sound in air is 320 m/s, find the tension in the string.         (1982 - 7 Marks)

Ans. 27.04 N

Solution.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

First Overtone

Mass of string per unit length JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

 Fundamental frequency

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Given that 8 beats/second are heard. The beat frequency decreases with the decreasing tension. This means that beat frequency decreases with decreasing vs. So beat frequency is given by the expression.

v = vs – vT

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.6. A uniform rope of length 12 m and mass 6 kg hangs vertically from a rigid support. A block of mass 2 kg is attached to the free end of the rope. A transverse pulse of wavelength 0.06 m is produced at the lower end of the rope. What is the wavelength of the pulse when it reaches the top of the rope?     (1984 - 6 Marks)

Ans. 0.75 m/s

Solution. KEY CONCEPT : The velocity of wave on the string is given by the formula

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where T is the tension and m is the mass per unit length.

Since the tension in the string will increase as we move up the string (as the string has mass), therefore the velocity of wave will also increase. (m is the same as the rope is uniform)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Since frequency remains the same

∴ λ2 = 2λ1 = 2 × 0.06 = 0.12 m

Q.7. A steel wire of length 1 m, m ass 0.1 kg and uniform cross-sectional area 10–6 m2 is rigidly fixed at both ends.

The temperature of the wire is lowered by 20°C. If transverse waves are set up by plucking the string in the middle, calculate the frequency of the fundamental mode of vibration.

Given for steel  Y = 2 × 1011 N/m2 

α = 1.21 × 10-5 per oC                      (1984 - 6 Marks)

Ans. 11 Hz

Solution. KEY CONCEPT : Using the formula of the coefficient of linear expansion,

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

The frequency of the fundamental mode of vibration.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.8. The vibrations of a string of length 60 cm fixed at both ends are represented by the equation—

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced                      (1985 - 6 Marks)

Where x and y are in cm and t in seconds. 
(i) What is the maximum displacement of a point at x = 5 cm? 
(ii) Where are the nodes located along the string? 
(iii) What is the velocity of the particle at x = 7.5 cm at t = 0.25 sec.? 
(iv) Write down the equations of the component waves whose superposition gives the above wave

Ans. (i)  3.46 cm
(ii) 0, 15, 30
(iii) zero
(iv)JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. (i) Here amplitude, A = 4 sin JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

At x = 5 m

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(ii) Nodes are the position where A = 0

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where n = 0, 1, 2 x = 15 cm, 30 cm, 60 cm, ....

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

At x = 7.5 cm, t = 0.25 cm

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

= y1 + y2

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.9. Two tuning forks with natural frequencies of 340 Hz each move relative to a stationary observer. One fork moves away from the observer, while the other moves towards him at the same speed. The observer hears beats of frequency 3 Hz.

Find the speed of the tuning fork.       (1986 - 8 Marks)

Ans. 1.5 m/s

Solution. The apparent frequency from tuning fork T1 as heard by the observer will be


JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where c = velocity of sound
v = velocity of turning fork The apparent frequency from tuning fork T2 as heard by the observer will be

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Given v1 – v2 = 3

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.10. The following equations represent transverse waves :

z1 = A cos (kx - ωt);                     (1987 - 7 Marks)

z2 = A cos (kx + ωt); z3 =A cos (ky - ωt)

Identify the combination (s) of the waves which will produce (i) standing wave (s), (ii) a wave travelling in the directon making an angle of 45° degrees with the positive x and positive y axes. In each case, find the positions at which the resultant intensity is always zero.

Ans. 

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advancedwhere n = 0, 1, 2, ...

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. (i)  KEY CONCEPT :  When two progressive waves having same amplitude and period, but travelling in opposite direction with same velocity superimpose, we get standing waves.

The following two equations qualify the above criteria and hence produce standing wave 

z1 = A cos (k x – ωt) 

z2 = A cos (k x + ωt)

The resultant wave is given by z = z1 + z2
⇒ z = A cos (k x – ωt) + A cos (k x + ωt) 

= 2A cos k x cos ωt 

The resultant intensity will be zero when 

2A cos k x = 0

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where n = 0, 1, 2, ...
(ii) The transverse waves
z1 = A cos (k x – ωt)
z3 = A cos (k y – ωt)

Combine to produce a wave travelling in the direction making an angle of 45° with the positive x and positive y axes.

The resultant wave is given by z = z1 + z3

z = A cos (k x – ωt) + A cos (ky – ωt)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

The resultant intensity will be zero when

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.11. A train approaching a hill at a speed of 40 km/hr sounds a whistle of frequency 580 Hz when it is at a distance of 1 km from a hill. A wind with a speed of 40 km/hr is blowing in the direction of motion of the train Find        (1988 - 5 Marks) 
(i) the Frequency of the whistle as heard by an observer on the hill, 
(ii) the distance from the hill at which the echo from the hill is heard by the driver and its frequency. 

(Velocity of sound in air =1,200 km/hr)

Ans. (i) 599 Hz  
(ii)  0.935 km, 621 Hz

Solution. (i) The frequency of the whistle as heard by observer on the hill

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(ii) Let echo from the hill is heard by the driver at B which is at a distance x from the hill.

The time taken by the driver to reach from A to B

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced           ... (i)

The time taken by the echo to reach from hill

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where tAH = time taken by sound from A to H with velocity (1200 + 40)

tHB = time taken by sound from H to B with velocity 1200 – 40 

From (i) and (ii)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

⇒ x = 0.935 km

The frequency of echo as heard by the driver can be calculated by considering that the source is the acoustic image.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.12. A source of sound is moving along a circular orbit of radius 3 metres with an angular velocity of 10 rad/s. A sound detector located far away from the source is executing linear simple harmonic motion along the line BD with an amplitude BC = CD = 6 metres. The frequency of oscillation of the detector is 5/π per second. The source is at the point A whenthe detector is at the point B. If the source emits a continous sound wave of frequency 340 Hz, find the maximum and the minimum frequencies recorded by the detector.        (1990 - 7 Mark)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Ans.  438.7 Hz, 257.3 Hz

Solution. The angular frequency of the detector = 2πv

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

The angular frequency of the detector matches with that of the source.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

⇒ When the detector is at C moving towards D, the source is at A1 moving leftwards. It is in this situation that the frequency heard is minimum

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Again when the detector is at C moving towards B, the source is at A3 moving rightward. It is in this situation that the frequency heard is maximum.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.13. The displacement of the medium in a sound wave is given by the equation y1 = A cos (ax + bt) where A, a and b are positive constants. The wave is reflected by an obstacle situated at x = 0. The intensity of the reflected wave is 0.64 times that of the incident wave.         (1991 - 4 × 2  Marks)

(a) What are the wavelength and frequency of incident wave?
(b) Write the equation for the reflected wave.
(c) In the resultant wave formed after reflection, find the maximum and minimum values of the particle speeds in the medium.
(d) Express the resultant wave as a superposition of a standing wave and a travelling wave. What are the positions of the antinodes of the standing wave ?

What is the direction of propagation of travelling wave?

Ans. JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(b) y = –0.8A cos(ax – bt)  
(c) 1.8 Ab, 0

(d) y = -1.6 A sin ax sin bt + 0.2 A cos(ax+ bt) JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. (a) KEY CONCEPT : Use the equation of a plan e progressive wave which is as follows.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

The given equation is 

y1 = A cos (ax + bt)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Also, 2πv = b

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(b) Since the wave is reflected by an obstacle, it will suffer a phase difference of p. The intensity of the reflected wave is 0.64 times of the incident wave.

Intensity of original wave I ∝ A2 
Intensity of reflected wave I ' = 0.64 I

⇒ I ' ∝ A'2  ⇒ 0.64 I ∝ A'2
⇒ 0.64 A2 ∝ A'2  ⇒ A' ∝ 0.8A 

So the equation of resultant wave becomes 

y2 = 0.8A cos (ax – bt + π) = – 0.8 A cos (ax – bt) 

(c) KEY CONCEPT : The resultant wave equation can be found by superposition principle 

y = y1 + y2     

= A cos (ax + bt) + [– 0.8 A cos (ax – bt)]

The particle velocity can be found by differentiating the above equation

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

= – Ab [sin (ax + bt) + 0.8 sin (ax – bt)]
= – Ab [sin axcos bt + cos ax sin bt + 0.8 sin ax cos bt – 0.8 cos ax sin bt]
v = – Ab [1.8 sin ax cos bt + 0.2 cos ax sin bt] 

The maximum velocity will occur when sin ax = 1 and cos bt = 1 under these condition cos ax = 0 and sin bt = 0

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(d) y = [A cos (ax + bt)] – [0.8 A cos (ax – bt)]
= [0.8 A cos (ax + bt) + 0.2 A cos (ax + bt)]  – [0.8 A cos (ax – bt)]
= [0.8 A cos (ax + bt) – 0.8 A cos (ax – bt)]  + 0.2 A cos (ax + bt)]

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

⇒ y = – 1.6 A sin ax sin bt + 0.2 A cos (ax + bt) where (– 1.6 A sin ax sin bt) is the equation of a standing wave and 0.2 A cos (ax + bt) is the equation of travelling wave.

The wave is travelling in –x direction.

NOTE : Antinodes of the standing waves are the positions where the amplitude is maximum,

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.14. Two radio stations broadcast their programmes at the same amplitude A and at slightly different frequencies ω1 and ω2 respectively, where ω1 - ω2 = 103 Hz A detector receives the signals from the two stations simultaneously.

It can only detect signals of intensity > 2 A2.                      (1993 - 4 Marks)

(i) Find the time interval between successive maxima of the intensity of the signal received by the detector.
(ii) Find the time for which the detector remains idle in each cycle of the intensity of the signal.

Ans. JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. Let the two radio waves be represented by the equations

y1 = A sin 2πv1

y2 = A sin 2πv2t

The equation of resultant wave according to superposition principle

y = y1 + y2 = A sin 2πv1t + A sin 2πv2

= A [sin 2 πv1t + sin 2πv2t]

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where the amplitude A' = 2A cos π (v1 – v2) t 

Now, intensity ∝ (Amplitude)2

⇒ I ∝ A'2

I ∝ 4A2 cos2π (v1 – v2) t

The intensity will be maximum when

cos2π (v1 – v2) t = 1 

or, cos π (v1 – v2) t = 1 

or, π (v1 – v2) t = nπ

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

∴ Time interval between two maxima

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Time interval between two successive maximas is 2π × 10–3 sec 

(ii) For the detector to sense the radio waves, the resultant intensity > 2A2

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

The detector lies idle  when the values of cos JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advancedis between 0 and 1/√2

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.15. A whistle emitting a sound of frequency 440 Hz is tied to a string of 1.5m length and rotated with an angular velocity of 20 rad s–1 in the  horizontal plane. Calculate the range of frequencies heard by an observer stationed at a large distance from the whistle.     (1996 - 3 Marks)

Ans. 403.3 Hz to 484 Hz

Solution. The whistle which is emitting sound is being rotated in a circle.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

r = 1.5 m (given); ω = 20 rads–1  (given) 

We know that 

v = rω = 1.5 × 20 = 30 ms–1 

When the source is instantaneously at the position A, then the frequency heard by the observer will be

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

When the source is instantaneously at the position B, then the frequency heard by the observer will be

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Hence the range of frequencies heard by the observer is 403.3 Hz  to 484 Hz.

Q.16. A band playing music at a frequency f is moving towards a wall at a speed vb. A motorist is following the band with a speed vm. If v is the speed of sound, obtain an expression for the beat frequency heard by the motorist.         (1997 - 5 Marks)

Ans. JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. KEY CONCEPT : Motorist will listen two sound waves.

One directly from the sound source and other reflected from the fixed wall. Let the apparent frequencies of these two waves as received by motorist are f 'and f '' respectively.

For Direct Sound : Vm will be positive as it moves towards the source and tries to increase the apparent frequency. Vb will be taken positive as it move away from the observer and hence tries to decrease the apparent frequency value.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

For reflected sound : 

For sound waves moving towards stationary observer (i.e. wall), frequency of sound as heard by wall

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

After reflection of sound waves having frequency f1 fixed wall acts as a stationary source of frequency f1 for the moving observer i.e. motorist. As direction of motion of motorist is opposite to direction of sound waves, hence frequency f '' of reflected sound waves as received by the motorist is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Hence, beat frequency as heard by the motorist

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.17. The air column in a pipe closed at one end is made to vibrate in its second overtone by a tuning fork of frequency 440 Hz. The speed of sound in air is 330 m s–1. End corrections may be neglected. Let P0 denote the mean pressure at any point in the pipe, and ΔP0 the maximum amplitude of pressure variation. 
(a) Find the length L of the air column.          (1998 - 8 Marks) 
(b) What is the amplitude of pressure variation at the middle of the column? (c) What are the maximum and minimum pressures at the open end of the pipe? 
(d) What are the maximum and minimum pressures at the closed end of the pipe?

Ans. JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(c) equal to mean pressure
(d) P0 + ΔP0 , P0 - ΔP0

Solution. (a) For second overtone as shown,

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(b) KEY CONCEPT : At any position x, the pressure is given by 

ΔP = ΔP0 cos kx cos ωt

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(c) At open end of pipe, pressure is always same i.e. equal to mean pressure  

∴ ΔP = 0, Pmax = Pmin =P0
(d) At the closed end : 

Maximum Pressure = P0 + ΔP0 

Minimum Pressure = P0 – ΔP0

Q.18. A long wire PQR is made by joining two wires PQ and QR of equal radii PQ has length 4.8 m and mass 0.06 kg. QR has length 2.56 m and mass 0.2 kg. The wire PQR is under a tension of 80 N. A sinusoidal wave-pulse of amplitude 3.5 cm is sent along the wire PQ from the end P. No power is dissipated during the propagation of the wave-pulse.

Calculate.      (1999 - 10 Marks)

(a) the time taken by the wave-pulse to reach the other end R of the wire, and (b) the amplitude of the reflected and tran smitted wave-pulses after the incident wave-pulse crosses the joint Q.

Ans. (a)  0.14s  
(b)  2.0 cm, 1.5 cm

Solution. Mass per unit length of PQ

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Mass per unit length of QR, JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Velocity of wave in PQ is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Velocity of wave in QR is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

∴ Time taken for the wave to reach from P to R

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

(b) When the wave which initiates from P reaches Q (a denser medium) then it is partly reflected and partly transmitted.

In this case the amplitude of reflected wave

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where Ai = amplitude of incident wave.

Also amplitude of transmitted wave is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

From (i), (ii) 

Therefore, At = 2 cm and  Ar = – 1.5 cm.

Q.19. A 3.6 m lon g vertical pipe resonates with a source of frequency 212.5 Hz when water level is at certain height in the pipe. Find the height of water level (from the bottom of the pipe) at which resonance occurs. Neglect end correction.

Now, the pipe is filled to a height H (≈ 3.6 m). A small hole is drilled very close to its bottom and water is allowed to leak.

Obtain an expression for the rate of fall of water level in the pipe as a function of H. If the radii of the pipe and the hole are 2 × 10-2 m and 1 × 10-3 m respectively, calculate the time interval between the occurance of first two resonances.

Speed of sound in air is 340 m/s and g = 10 m/s2.          (2000 - 10  Marks)

Ans. JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. Speed of sound, v = 340 m/s.

Let ℓ0 be the length of air column corresponding to the fundamental frequency. Then

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

NOTE : In closed pipe only odd harmonics are obtained.

Now, let ℓ1, ℓ2, ℓ3 ,ℓ4, etc. be the lengths corresponding to the 3rd harmonic, 5th harmonic, 7th harmonic etc. Then

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

or heights of water level are (3.6 – 0.4) m, (3.6 – 1.2) m, (3.6 – 2.0) m and (3.6 – 2.8) m.

Therefore heights of water level are 3.2 m, 2.4 m, 1.6 m and 0.8 m.

Let A and a be the area of cross-sections of the pipe and hole respectively. Then 

A = π (2 × 10–2)2 = 1.26 × 10–3 m–2 and a = π (10–3)2 = 3.14 × 10–6 m2

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Continuity equation at 1 and 2 gives,

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Therefore, rate of fall of water level in the pipe,

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Substituting the values, we get

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Between first two resonances, the water level falls from 3.2 m to 2.4 m.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.20. A boat is traveling in a river with a speed 10 m/s along the stream flowing with a speed 2 m/s. From this boat, a sound transmitter is lowered into the river through a rigid support.

The wavelength of the sound emitted from the transmitter inside the water is 14.45 mm. Assume that attenuation of sound in water and air is negligible. 

(a) What will be the frequency detected by a receiver kept inside the river downstream? 

(b) The transmitter and the receiver are now pulled up into air. The air is blowing with a speed 5 m/s in the direction opposite the river stream. Determine the frequency of the sound detected by the receiver. 

(Temperature of the air and water = 20oC; Density of river water = 103 kg/m3

Bulk modulus of the water = 2.088 x 109 Pa; Gas constant R = 8.31 J/mol-K; Mean molecular mass of air = 28.8 x 10-3 kg/mol; CP/CV  for air = 1.4)            (2001 - 10 Marks)

Ans. (a) 1.007 × 105 Hz,
(b)  1.03 × 105 Hz

Solution. KEY CONCEPT : The question is based on Doppler's effect where the medium through which the sound is travelling is also in motion.

By Doppler's formula

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

NOTE : Sign convention for Vm is as follows : If medium is moving from s to O then + ve and vice versa.

Similarly v0 and vs are positive if these are directed from S to O and vice versa.
(a) Situation 1.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Velocity of sound in water JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

c = 1445 m/s;  vm = + 2 m/s;  v0 = 0;  vs = 10 m/s

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

∴n' = 1.007 × 105 Hz

(b) Situation 2.

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Applying formula (1)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.21. Two narrow cylindrical pipes A and B have the same length.

Pipe A is open at both ends and is filled with a monoatomic gas of molar mass MA. Pipe B is open at one end and closed at the other end, and is filled with a diatomic gas of molar mass MB. Both gases are at the same temperature.      (2002 - 5 Marks )

(a) If the fr equen cy of the second h armon ic of the fundamental mode in pipe A is equal to the frequency of the third harmonic of the fundamental mode in pipe B, determine the value of MA/MB.
(b) Now the open end of pipe B is also closed (so that the pipe is closed at both ends). Find the ratio of the fundamental frequency in pipe A to that in pipe B.

Ans. (a) 400/189

(b) 3/4

Solution. (a) Second harmonic in pipe A is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Third harmonic in pipe B is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.22. A tuning fork of frequency 480 Hz resonates with a tube closed at one end of length 16 cm and diameter 5 cm in fundamental mode. Calculate velocity of sound in air. (2003 - 2 Marks)

Ans. 336 m/s

Solution. KEY CONCEPT : In the fundamental mode

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.23. A string tied between x = 0 and x = ℓ vibrates in fundamental mode. The amplitude A, tension T and mass per unit length μ is given. Find the total energy of the string.           (2003 - 4 Marks)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Ans.JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

The amplitude of vibration at a distance x from x = 0 is given by  A = a sin k x Mechanical energy at x of length dx is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

= 2π2µv2a2 sin2 kx dx 

But v = vλ 

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

∴ Total energy of the string

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.24. A whistling train approaches a junction. An observer standing at junction observes the frequency to be 2.2 KHz and 1.8 KHz of the approaching and the receding train respectively. Find the speed of the train (speed of sound = 300 m/s)         (2005 - 2  Marks)

Ans. 30 m/s

Solution. Let the speed of the train be vT 

While the train is approaching 

Let v be the actual frequency of the whistle. Then

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

where vS = Speed of sound = 300 m/s (given) 

v' = 2.2 K Hz. = 2200 Hz (given)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

While the train is receding

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Here, v' = 1.8 KHz = 1800 Hz (given)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Dividing (i) and (ii)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Q.25. A transverse harmonic disturbance is produced in a string.

The maximum transverse velocity is 3 m/s and maximum transverse acceleration is 90 m/s2. If the wave velocity is 20 m/s then find the waveform.      (2005 - 4  Marks)

Ans. JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Solution. KEY CONCEPT : The wave form of a transverse harmonic disturbance is

y =  a sin (ωt ± kx ± φ)

Given v max = aω = 3 m/s ... (i)
Amax =  aω2 = 90 m/s2 ... (ii)
Velocity of wave v = 20 m/s ... (iii)

Dividing (ii) by (i)

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

Substituting the value of w in (i), we get

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

From (iv), (v) and (vi) the wave form is

JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced

The document JEE Advanced (Subjective Type Questions): Waves | Chapter-wise Tests for JEE Main & Advanced is a part of the JEE Course Chapter-wise Tests for JEE Main & Advanced.
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