A) \[y=0.2\sin \,2\pi \,\left( 6\,t+\frac{x}{60} \right)\]
B) \[y=0.2\sin \,\pi \,\left( 6\,t+\frac{x}{60} \right)\]
C) \[y=0.2\sin \,2\pi \,\left( 6\,t-\frac{x}{60} \right)\]
D) \[y=0.2\sin \,\,\pi \,\left( 6\,t-\frac{x}{60} \right)\]
Correct Answer: C
Solution :
Key Idea: The expression of travelling wave is sine or cosine function of \[\omega t\pm kx\]. |
The general expression of travelling wave can be written as |
\[y=A\,\sin \,(\omega t\pm kx)\] (i) |
For travelling wave along positive x-axis we should use minus \[(-)\] sign only. |
\[\therefore \] \[y=A\,\sin \,(\omega t-kx)\] |
but \[\omega =\frac{2\pi v}{\lambda }\] and \[k=\frac{2\pi }{\lambda }\] |
So, \[y=A\sin \frac{2\pi }{\lambda }(vt-x)\] |
Given, A = 0.2, m, i = 360 m/s, \[\lambda =60\,m,\] |
Substituting in Eq. (ii) we have |
\[y=0.2\sin \frac{2\pi }{60}(360\,t-x)\] |
or \[y=0.2\,\sin \,2\pi \,\left( 6\,t-\frac{x}{60} \right)\] |
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