The speed on string with tension T and linear mass density `mu` is -

In (Q. 24.) the tension in string is T and the linear mass density of string is mu . The ratio of magnitude of maximum velocity of particle and the magnitude of maximum acceleration is

Which of the following is not the law of a stretched string ? ( n , l , T and m are frequency of vibration , length of vibrating string , tension in string and linear mass density , respectively .)

The speed of transverse wave v in a stretched string depend on length tension T in the string and liner mass density (mass per unit length). mu . Find the relation using method of dimensions.

A transverse periodic wave ona strin with a linear mass density of 0.200kg/m is described by the following equations y=0.05sin(420t-21.0x) where x and y in metres and t is in seconds. Tension in the string is

A mass m is suspended from the ceiling by a string with variable linear mass density (mu) .A wave pulse is produced at the top of an oscillator which travels from top to bottom with constant wave speed. (x axis is positive downwards). Then.

A transverse periodic wave on a string with a linear mass density of 0.200 kg/m is described by the following equation y=0.05 sin (420t-21.0 x) where x and y are in metres and t is in seconds.The tension in the string is equal to :

A transverse periodic wave on a string with a linear mass density of 0.200 kg//m is described by the following equation y = 0.05 sin(420t - 21.0 x) where x and y are in meters and t is in seconds. The tension in the string is equal to :

Power supplied to a vibrating string: A string with linear mass density mu=5.00xx10^(-2) kg//m is under a tension of 80.0 N. how much power must be supplied to the string to generate sinusoidal waves at a frequancy of 60.0 HZ and an amplitude of 6.00 cm?