Wave Optics Test

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Wave Optics Test - 16

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Question 1
1 / -0

Read the following text and answer the following questions on the basis of the same:
In one of his experiments on interference, August Jean Fresnel used a biprism to induce interference between two beams. He split a diverging beam of light into two parts by using the biprism to refract them. This resulted in two split beams which acted as if they were from two coherent sources and which therefore interfered with each other.
A Fresnel Biprism is a thin double prism placed base to base and have very small refracting angle ( 0.5°). This is equivalent to a single prism with one of its angle nearly 179° and other two of 0.5° each.
In Young’s double Slits experiment, a single source is split in two coherent sources. For the Young’s slits experiment, we must approximate that the slits act as point sources. This however is not the case, since the slits have finite width. In this way, it gives rise to unwanted diffraction effects that causes errors.
The Fresnel biprism experiment overcomes this problem.
A Fresnel biprism is a variation of Young’s Slits experiment. When monochromatic light through a narrow slit falls on biprism that divides it into two components. One of these component is refracted from upper portion of biprism and the other one refracted through lower portion. Two virtual coherent sources formed from the original source. In this case, two virtual coherent sources are point sources and replace slits in Young’s experiment.
Q. Base angles of Fresnel biprism are:

A
A. 179°

B
B. 90°

C
C. 0.50°

D
D. None of these

Solution

A Fresnel Biprism is a thin double prism placed base to base and have very small refracting angle (0.5°).
Question 2
1 / -0

Read the following text and answer the following questions on the basis of the same:
In one of his experiments on interference, August Jean Fresnel used a biprism to induce interference between two beams. He split a diverging beam of light into two parts by using the biprism to refract them. This resulted in two split beams which acted as if they were from two coherent sources and which therefore interfered with each other.
A Fresnel Biprism is a thin double prism placed base to base and have very small refracting angle ( 0.5°). This is equivalent to a single prism with one of its angle nearly 179° and other two of 0.5° each.
In Young’s double Slits experiment, a single source is split in two coherent sources. For the Young’s slits experiment, we must approximate that the slits act as point sources. This however is not the case, since the slits have finite width. In this way, it gives rise to unwanted diffraction effects that causes errors.
The Fresnel biprism experiment overcomes this problem.
A Fresnel biprism is a variation of Young’s Slits experiment. When monochromatic light through a narrow slit falls on biprism that divides it into two components. One of these component is refracted from upper portion of biprism and the other one refracted through lower portion. Two virtual coherent sources formed from the original source. In this case, two virtual coherent sources are point sources and replace slits in Young’s experiment.
Q. The Fresnel biprism is:

A
A. a combination of two prisms with their bases in contact.

B
B. a combination of two prisms with their refracting surfaces in contact.

C
C. single prism

D
D. not a prism actually.

Solution

A Fresnel Biprism is a thin double prism placed base to base.
Question 3
1 / -0

Read the following text and answer the following questions on the basis of the same:
In one of his experiments on interference, August Jean Fresnel used a biprism to induce interference between two beams. He split a diverging beam of light into two parts by using the biprism to refract them. This resulted in two split beams which acted as if they were from two coherent sources and which therefore interfered with each other.
A Fresnel Biprism is a thin double prism placed base to base and have very small refracting angle ( 0.5°). This is equivalent to a single prism with one of its angle nearly 179° and other two of 0.5° each.
In Young’s double Slits experiment, a single source is split in two coherent sources. For the Young’s slits experiment, we must approximate that the slits act as point sources. This however is not the case, since the slits have finite width. In this way, it gives rise to unwanted diffraction effects that causes errors.
The Fresnel biprism experiment overcomes this problem.
A Fresnel biprism is a variation of Young’s Slits experiment. When monochromatic light through a narrow slit falls on biprism that divides it into two components. One of these component is refracted from upper portion of biprism and the other one refracted through lower portion. Two virtual coherent sources formed from the original source. In this case, two virtual coherent sources are point sources and replace slits in Young’s experiment.
Q. Fresnel biprism produces:

A
A. two real coherent sources.

B
B. two virtual coherent sources.

C
C. a number of real coherent sources.

D
D. a number of virtual coherent sources.

Solution

When monochromatic light through a narrow slit falls on Fresnel biprism that divides it into two components. One of these component is refracted from upper portion of biprism and the other one refracted through lower portion. Thus, two virtual coherent sources formed from the original source.
Question 4
1 / -0

Read the following text and answer the following questions on the basis of the same:
In one of his experiments on interference, August Jean Fresnel used a biprism to induce interference between two beams. He split a diverging beam of light into two parts by using the biprism to refract them. This resulted in two split beams which acted as if they were from two coherent sources and which therefore interfered with each other.
A Fresnel Biprism is a thin double prism placed base to base and have very small refracting angle ( 0.5°). This is equivalent to a single prism with one of its angle nearly 179° and other two of 0.5° each.
In Young’s double Slits experiment, a single source is split in two coherent sources. For the Young’s slits experiment, we must approximate that the slits act as point sources. This however is not the case, since the slits have finite width. In this way, it gives rise to unwanted diffraction effects that causes errors.
The Fresnel biprism experiment overcomes this problem.
A Fresnel biprism is a variation of Young’s Slits experiment. When monochromatic light through a narrow slit falls on biprism that divides it into two components. One of these component is refracted from upper portion of biprism and the other one refracted through lower portion. Two virtual coherent sources formed from the original source. In this case, two virtual coherent sources are point sources and replace slits in Young’s experiment.
Q. Which problem of Young’s double slit experiment is overcome by Fresnel biprism?

A
A. Young’s double slit arrangement gives rise to irregular interference fringe pattern which is overcome by Fresnel biprism which produces coherent sources by refraction in a prism

B
B. Finite width of slits in Young’s double slit experiment gives rise to unwanted diffraction effects that causes errors. This is overcome by Fresnel biprism by producing virtual coherent point sources.

C
C. Young’s double slit arrangement produces interference fringe pattern of low intensity which is overcome by Fresnel biprism.

D
D. All of the above

Solution

In Young’s double Slits experiment, a single source is split in two coherent sources. For the Young’s slits experiment, we must approximate that the slits act as point sources. This however is not the case, since the slits have finite width. In this way, it gives rise to unwanted diffraction effects that causes errors.
The Fresnel biprism experiment overcomes this problem.
When monochromatic light through a narrow slit falls on biprism that divides it into two components. One of these component is refracted from upper portion of biprism and the other one refracted through lower portion. Two virtual coherent point sources are formed from the original source.
Question 5
1 / -0

Read the following text and answer the following questions on the basis of the same:
Diffraction in a hall:
A and B went to purchase a ticket of a music programme. But unfortunately only one ticket was left. They purchased the single ticket and decided that A would be in the hall during the 1st half and B during the 2nd half.
Both of them reached the hall together. A entered the hall and found that the seat was behind a pillar which creates an obstacle. He was disappointed. He thought that he would not be able to hear the programme properly.
B was waiting outside the closed door. The door was not fully closed. There was a little opening.
But surprisingly, A could hear the music programme.
This happened due to diffraction of sound.
The fact we hear sounds around corners and around barriers involves both diffraction and reflection of sound.
Diffraction in such cases helps the sound to "bend around" the obstacles.
In fact, diffraction is more pronounced with longer wavelengths implies that we can hear low frequencies around obstacles better than high frequencies.
B was outside the door. He could also hear the programme. But he noticed that when the door opening is comparatively less he could hear the programme even being little away from the door. This is because when the width of the opening is larger than the wavelength of the wave passing through the gap then it does not spread out much on the other side. But when the opening is smaller than the wavelength more diffraction occurs and the waves spread out greatly – with semicircular wavefront. The opening in this case functions as a localized source of sound.
Q. Diffraction is more pronounced with ______ wavelengths.

A
A. Longer

B
B. Shorter

C
C. fluctuating

D
D. all

Solution

In fact, diffraction is more pronounced with longer wavelengths
Question 6
1 / -0

Read the following text and answer the following questions on the basis of the same:
Diffraction in a hall:
A and B went to purchase a ticket of a music programme. But unfortunately only one ticket was left. They purchased the single ticket and decided that A would be in the hall during the 1st half and B during the 2nd half.
Both of them reached the hall together. A entered the hall and found that the seat was behind a pillar which creates an obstacle. He was disappointed. He thought that he would not be able to hear the programme properly.
B was waiting outside the closed door. The door was not fully closed. There was a little opening.
But surprisingly, A could hear the music programme.
This happened due to diffraction of sound.
The fact we hear sounds around corners and around barriers involves both diffraction and reflection of sound.
Diffraction in such cases helps the sound to "bend around" the obstacles.
In fact, diffraction is more pronounced with longer wavelengths implies that we can hear low frequencies around obstacles better than high frequencies.
B was outside the door. He could also hear the programme. But he noticed that when the door opening is comparatively less he could hear the programme even being little away from the door. This is because when the width of the opening is larger than the wavelength of the wave passing through the gap then it does not spread out much on the other side. But when the opening is smaller than the wavelength more diffraction occurs and the waves spread out greatly – with semicircular wavefront. The opening in this case functions as a localized source of sound.
Q. Diffraction of sound takes place more when :

A
A. sound is diffracted through an opening having width equal to the wavelength of the sound.

B
B. sound is diffracted through an opening having width more than the wavelength of the sound.

C
C. sound is diffracted through an opening having width less than the wavelength of the sound.

D
D. diffraction of sound does not depend on the width of the opening.

Solution

When the width of opening is comparatively less than the wavelength of sound wave, the sound spread out much better i.e. better diffraction occurs.
When the width of the opening is larger than the wavelength, the wave passing through the opening does not spread out much on the other side.
Question 7
1 / -0

Read the following text and answer the following questions on the basis of the same:
Diffraction in a hall:
A and B went to purchase a ticket of a music programme. But unfortunately only one ticket was left. They purchased the single ticket and decided that A would be in the hall during the 1st half and B during the 2nd half.
Both of them reached the hall together. A entered the hall and found that the seat was behind a pillar which creates an obstacle. He was disappointed. He thought that he would not be able to hear the programme properly.
B was waiting outside the closed door. The door was not fully closed. There was a little opening.
But surprisingly, A could hear the music programme.
This happened due to diffraction of sound.
The fact we hear sounds around corners and around barriers involves both diffraction and reflection of sound.
Diffraction in such cases helps the sound to "bend around" the obstacles.
In fact, diffraction is more pronounced with longer wavelengths implies that we can hear low frequencies around obstacles better than high frequencies.
B was outside the door. He could also hear the programme. But he noticed that when the door opening is comparatively less he could hear the programme even being little away from the door. This is because when the width of the opening is larger than the wavelength of the wave passing through the gap then it does not spread out much on the other side. But when the opening is smaller than the wavelength more diffraction occurs and the waves spread out greatly – with semicircular wavefront. The opening in this case functions as a localized source of sound.
Q. A and B could hear the music programme due to phenomenon named

A
A. interference.

B
B. scattering.

C
C. diffraction.

D
D. dispersion.

Solution

The fact we hear sounds around corners and around barriers involves both diffraction and reflection of sound.
Question 8
1 / -0

Read the following text and answer the following questions on the basis of the same:
Diffraction in a hall:
A and B went to purchase a ticket of a music programme. But unfortunately only one ticket was left. They purchased the single ticket and decided that A would be in the hall during the 1st half and B during the 2nd half.
Both of them reached the hall together. A entered the hall and found that the seat was behind a pillar which creates an obstacle. He was disappointed. He thought that he would not be able to hear the programme properly.
B was waiting outside the closed door. The door was not fully closed. There was a little opening.
But surprisingly, A could hear the music programme.
This happened due to diffraction of sound.
The fact we hear sounds around corners and around barriers involves both diffraction and reflection of sound.
Diffraction in such cases helps the sound to "bend around" the obstacles.
In fact, diffraction is more pronounced with longer wavelengths implies that we can hear low frequencies around obstacles better than high frequencies.
B was outside the door. He could also hear the programme. But he noticed that when the door opening is comparatively less he could hear the programme even being little away from the door. This is because when the width of the opening is larger than the wavelength of the wave passing through the gap then it does not spread out much on the other side. But when the opening is smaller than the wavelength more diffraction occurs and the waves spread out greatly – with semicircular wavefront. The opening in this case functions as a localized source of sound.
Q. The minimum and maximum frequencies in the musical programme were 550 Hz and 10 kHz. Which frequency was better audible around the pillar obstacle?

A
A. 10 kHz

B
B. 550 kHz

C
C. Mid frequency

D
D. The complete frequency range

Solution

In fact, diffraction is more pronounced with longer wavelengths implies that you can hear low frequencies around obstacles better than high frequencies.
Question 9
1 / -0

Read the following text and answer the following questions on the basis of the same:
Diffraction in a hall:
A and B went to purchase a ticket of a music programme. But unfortunately only one ticket was left. They purchased the single ticket and decided that A would be in the hall during the 1st half and B during the 2nd half.
Both of them reached the hall together. A entered the hall and found that the seat was behind a pillar which creates an obstacle. He was disappointed. He thought that he would not be able to hear the programme properly.
B was waiting outside the closed door. The door was not fully closed. There was a little opening.
But surprisingly, A could hear the music programme.
This happened due to diffraction of sound.
The fact we hear sounds around corners and around barriers involves both diffraction and reflection of sound.
Diffraction in such cases helps the sound to "bend around" the obstacles.
In fact, diffraction is more pronounced with longer wavelengths implies that we can hear low frequencies around obstacles better than high frequencies.
B was outside the door. He could also hear the programme. But he noticed that when the door opening is comparatively less he could hear the programme even being little away from the door. This is because when the width of the opening is larger than the wavelength of the wave passing through the gap then it does not spread out much on the other side. But when the opening is smaller than the wavelength more diffraction occurs and the waves spread out greatly – with semicircular wavefront. The opening in this case functions as a localized source of sound.
Q. How the waveform will look like outside the door of the hall?

A
A. Sound repeater

B
B. Sound reflector

C
C. Localized sound source

D
D. None of the above

Solution

Sound spreads out well through a gap whose width is slightly smaller than the wavelength of the sound wave as if it is a localised source of sound.