Figure shows a string of linear mass density `1.0 g//cm` on which a wave pulse is travelling. Find the time taken (in milli second) by the pulse in travelling through a distance of `60 cm` on the string. Take `g = 10 m//s^(2)`.

Figure showa a string of linear mass density 1.0gcm^-1 on which a wave pulse is travelling. Find the time taken by the pulse in travelling through a distance of 50 cm on the string. Take g=10 ms^-2 .

Figure shows a string of linear mass density 1.0g cm^(-1) on which a wave pulse is travelling. Find the time taken by pulse in travelling through a distance of 50 cm on the string. Take g = 10 ms^(-2)

A wave pulse is travelling on a string of linear mass density 1.0 g cm^(-1) under a tension of 1 kg wt. Calculate the time taken by the pulse to travel a distance of 50 cm on the string.Given g = 10 ms^(-2) .

A wave pulse is travelling on a string of linear mass density 10gcm^(-1) under a tension of 1kg wt. Calculate the time taken by the pulse to travel a distance of 50cm on the string. Take g=10m//s^(2).

Find the tension in the horizontal string PQ and the string QR in the given figure. [Take g=10m//s^(2) ]

A way pulse is travelling on a string of linear mass density 6.4 xx 10^(-3)kg m^(-1) under a load of 80 kgf . Calculate the time taken by the pulse to traverse the string, if its length is 0.7 m .

In the given figure a string of linear mass density 3xx10^(-2) kg//m and length L=1 m, is stretched by a froce F=(3-kt)N , where k is a constant and t is time in sec. At the time t=0 , a pulse is generated at the end P of the string Find the value of k (in N//s) if the value of force becomes zero as the pulse reaches point Q.

An harmonic wave has been set up on a very long string which travels along the length of the string. The wave has a frequency of 50 Hz, amplitude 1 cm and wavelength 0.5 m. find (a) the time taken by the wave to travel a distance of 8 m along the length of string (b) the time taken by a point on the string to travel a distance of 8 m, once the wave has reached the point and sets it into motion (c ) also. consider the above case when the amplitude gets doubled