A wave in two different strings

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A wave traveling from a denser string to a lighter string will experience changes in amplitude due to differences in mass density. The continuity of the wave function at the interface requires that the sum of the incident and reflected amplitudes equals the transmitted amplitude. The relationship can be expressed as A_t = (2K_1A_i) / (K_1 + K_2), where K_1 and K_2 are the wave numbers for the two strings. Additionally, the principle of conservation of energy applies, ensuring that the energy of the incident wave equals the sum of the energies of the reflected and transmitted waves. The discussion emphasizes the importance of continuity and differentiability of the wave function at the boundary between the two strings.
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A string has two parts: one with a very high mass density (per unit length), and the other with a very low mass density. A wave with amplitude A moves from the dense part toward the light part. What will be the amplitude of the wave which is transmitted to the light part?

hhegab
 
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okay what u have done so far on this
ur thoughts
 
Some Hints which will initiate you

1) function representing a wave should be bounded
2) function is continuous, Differentiable and bounded
 
and there should be a node at the meeting poing (between the two strings)

hhegab
 
no i don't think so, u have any reasons for that
 
consider
y_i=A_isin(\omega t-K_1x)
y_r=A_rsin(\omega t+K_1x)
y_t=A_tsin(\omega t-K_2x)

now function should be continuous
Left Hand Limit = Right Hand Limit (Consider x=0 at the joint)
which give A_i+A_r=A_t

now function is derivable at x=0
for which u will have (A_r-A_i)K_1=A_tK_2

solving from two equations u will have
A_t=\frac{2K_1A_i}{K_1+K_2}
OR
A_t=\frac{2\sqrt{\mu_1}}{\sqrt{\mu_1}+\sqrt{\mu_2}}.A_i
 
Last edited:
or you can look at the problem like this...

Total Energy is conserved in both the regions of the rope. Thus, consider the wave from the lighter density rope as the incident wave. When this incident wave meets the higher density rope, a part of it gets reflected and a part of it gets transmitted. So, by law of conservation of energy,


Energy of the incident wave = Energy of the reflected wave + Energy of the Transmitted wave.

Also if A_{i} is the amplitude of the incident wave,
A_{t} is the amplitude of the reflected wave and A_{r} is the reflected component of the wave, then,

A_{i} = A_{r} + A_{t}

Use the total energy equation of the wave,

\Delta E = A/2[\mu^2 * A^2 * \Delta x * \sqrt{T/\mu}]

where,
The tension T is constant throughout the string, \mu is the mass per unit length and A is the amplitude and \Delta x is the displacement which is also assumed to be constant for a small portion of the wave. Thus equating the total energies on both sides, you will get the same answer that himanshu has given you.


Sridhar
 
now function is derivable at x=0
for which u will have
(A_r-A_i)K_1=A_tK_2

Left Hand Derivative = Right Hand Derivative

Also the derivative \frac{dy}{dx} represents Strain which will be same at a single point
 

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