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Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics PDF Download

Q.1. In YDSE, the interference pattern is found to have an intensity ratio between the bright and dark fringes as 9 . Find the ratio of amplitude and intensity of interfering sources.

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 9

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 3

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 4

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics


Q.2. A thin paper of thickness 0.02mm having refractive index 1.45 is pasted across one of the slits in Young's double slit experiment. The paper transmits 4/9 of the light falling on it.

(a) Find the ratio of the maximum intensity to the minimum intensity in the fringe pattern.

(b) How many fringes will cross through the centre if an identical paper piece is pasted on the other slit also? The wavelength of light used is 600nm.

(a) Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Where Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 25

(b) Fringe shift due to introduction of paper of refractive index μ is

Δ = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics where Δ = nβ = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

⇒ n = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 15


Q.3. The electric fields of two light sources with nearby frequencies ω1 and ω2 and wave vectors Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics and Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics are expressed as Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics and Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics, respectively. The interference pattern on the screen is photographed at t = t0 ; denote Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics by θ . For this pattern what will be the value of cosθ for bright fringe and dark fringe. Also write the expression for maximum and minimum intensities.

cosθ =+1 bright fringes

= -1 dark fringe

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics


Q.4. In an interference pattern with two coherent sources, the amplitude of intensity variation is found to be 5% of the average intensity. Find the relative intensities of the interference sources.

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 1.051

α = 40.2

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = α2 = 1616


Q.5. Two coherent sources whose intensity ratio is 81:1 produce interference pattern. Find the ratio of maximum and minimum inference of fringes.

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 9

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

= 100/64

=25/16


Q.6. Two coherent sources of intensity ratio β interfere. Then what will be the value of Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics in the interference pattern.

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics 

= Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics 

= Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics


Q.7. (a) Two beams of light having intensities I and 4I interfere to produce a fringe pattern on a screen. The phase difference between the beams is π/2 at point A and π at point B. Then find the difference between the resultant intensities at A and B.

(b) In Young’s double-hole experiment, calculate Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics where I represents the intensity at a point where the path difference isλ / 5 .

 (a) Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics


Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Intensity at position A is

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Intensity at position B is

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

(b) Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Now, δ = 2π/λ (Path difference) 

= Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 0.66


Q.8. Two waves travelling together along the same line are represented by y1 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics and y2 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics. Find

(i) the resultant amplitude

(ii) the initial phase angle of the resultant

(iii) the resultant equation for the sum of the two motions

y = y+ y2 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

y = Asin(ωt - ∅)

where A = 39.68 and ∅ = 39.39


Q.9. Three sinusoidal waves have the same frequency with amplitude , A, A/2 and A/3 while their phase angles are 0, π/2  and π respectively. Calculate the amplitude of the resultant wave.

y1 = Asinωt

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

y = y+ y2 + y3 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

= Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

R = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics


Q.10. At a given point in space the total light wave is composed of three phasors P1 = a , P2 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics and P3 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics. Calculate the intensity of light at this point.

P = P+ P2 + P3 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

= Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

I = P2 = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics


Q.11. Find the amplitude of the oscillation resulting from the addition of the following three oscillations of the same direction:

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Resultant oscillation

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

y = Asin(ωt + θ)

A = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

⇒A  = 1.89a

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Acosθ = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

tanθ = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics


Q.12. In the Young’s double slit experiment the waves passing from slits S1 and S2 are described by the following pair of equations

(a) y1 = 0.5sin (3t - 4.1401) , y2 = 0.5sin (3t -7.2817)

(b) y1 = 0.5sin (6t - 2.0202) , y2 = 0.5sin (6t -8.3034)

(c) y1 = 0.5cos (9t) , y2 = 0.5sin (9t - 9.4248)

Identify the pair for which the central point on the screen is

(i) bright

(ii) dark

(iii) neither completely bright nor completely dark.

(a) Δ∅ = 3.1416 = π

Δx = λ/2 (dark)

(b) Δ∅ = 2π

Δx = λ (bright)

(c) Δ∅ = 7π/2

Δx = 7λ/4 (neither bright nor dark)


Q.13. Two similar coherent sources produce interference pattern. Find the ratio of intensity at the center of bright fringe to the intensity at a point one quarter of the distance between

two fringes from the center.

At the centre I0 = 4a2

Phase difference at a distance one quarter between the two fringes = Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Intensity at that point 

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics

Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics = 2


Q.14. In Young’s double slit experiment, the two slits act as coherent sources of equal amplitude A and wavelength λ . In another experiment with the same set-up the two slits are sources of equal amplitude A and wavelength λ , but are incoherent. Calculate the ratio of the intensity of light at the midpoint of the screen in the first case to that in the second case.

When sources are coherent Im = 4I0

When sources are incoherent I = I0 + I0 = 2I0

Ratio Im/I = 2

The document Superposition Principle: Assignment | Oscillations, Waves & Optics - Physics is a part of the Physics Course Oscillations, Waves & Optics.
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FAQs on Superposition Principle: Assignment - Oscillations, Waves & Optics - Physics

1. What is the superposition principle?
Ans. The superposition principle is a fundamental concept in physics that states that when two or more waves interact with each other, the resulting wave is the sum of the individual waves. This principle applies to all types of waves, including electromagnetic waves, sound waves, and water waves.
2. How does the superposition principle apply to the IIT JAM exam?
Ans. In the context of the IIT JAM exam, the superposition principle is often applied in the study of quantum mechanics. It helps in understanding the behavior of quantum systems, such as particles and waves, by considering their wavefunctions and the superposition of different states.
3. Can you provide an example of the superposition principle in quantum mechanics?
Ans. Certainly! One example is the double-slit experiment, where a beam of particles or waves is directed at a barrier with two slits. According to the superposition principle, the wavefunction of each particle passes through both slits simultaneously, creating an interference pattern on a screen behind the barrier.
4. How is the superposition principle useful in solving problems in quantum mechanics?
Ans. The superposition principle allows us to express the wavefunction of a quantum system as a linear combination of its possible states. By applying mathematical equations like the Schrödinger equation, we can determine the probabilities of finding a system in different states and predict its behavior.
5. Are there any limitations to the superposition principle?
Ans. While the superposition principle is a powerful tool in quantum mechanics, it has its limitations. For instance, it does not hold for macroscopic objects, as their behavior is dominated by classical mechanics. Additionally, the superposition principle cannot be directly observed, but its effects can be detected through experiments and measurements.
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