A transverse wave described by
`y=(0.02m)sin[(1.0m^-1)x+(30s^-1)t]`
propagates on a stretched string having a linear mass density of `1.2xx10^-4 kgm^-1`. Find the tension in the string.

A transverse wave propagating on a stretched string of linear density 3 xx 10^(-4) kg m^(-1) is represented by the equation y = 0.2 sin (1.5 x + 60 t) Where x is in metres and t is in seconds . The tension in the string (in newtons) is :

Determine the tension T_(1) and T_(2) in the strings

A 4.0 kg block is suspended from the ceiling of an elevator through a string having a linear mass desity of 19.2xx10^-3 kgm^-1 . Find the speed (with respect to the string) with which a wave pulse can proceed on the string if the elavator accelerates up at the rate of 2.0ms^-2. Take g=10 ms^-2 .

A wave stretched between two rigid supports vibrate in its fundamental mode with a frequency of 45 Hz. The mass of wire is 3.5 xx 10^(-2) kg and its linear mass density is 4.0 xx 10^(-2) kg m^(-1) . What is (a) the speed of transverse wave on the string, and (b) the tension in the string?

Two charged particles having charge 2.0xx 10^(-8)C each are joined by an insulating string of length 1 m and the system is kept on a smooth horizontal table. Find the tension in the string.

A 200 Hz wave with amplitude 1 mm travels on a long string of linear mass density 6 g//m keep under a tension of 60 N . (a) Find the average power transmitted across a given point on the string. (b) Find the total energy associated with the wave in a 2.0 m long portion of the string.

The equation of a wave travelling on a string is y=(0.10mm)sin[3.14m^-1)x+(314s^-1)t] . (a) In which direction does the wave travel ? (b) Find the wave speed, the wavelength and the frequency of the wave. (c) What is the maximum displacement and the maximum speed of a portion of the string ?

The equation for a wave travelling in x-direction on a string is y = (3.0cm)sin[(3.14 cm^(-1) x - (314s^(-1))t] (a) Find the maximum velocity of a particle of the string. (b) Find the acceleration of a particle at x =6.0 cm at time t = 0.11 s.

A travelling wave is produced on a long horizontal string by vibrating an end up and down sinusoidal. The amplitude of vibration is 1.0cm and the displacement becomes zero 200 times per second. The linear mass density of the string is 0.10 kg m^(-1) and it is kept under a tension of 90 N. (a) Find the speed and the wavelength of the wave. (b) Assume that the wave moves in the positive x-direction and at t = 0 the end x= 0 is at its positive extreme position. Write the wave equation. (c ) Find the velocity and acceleration of the particle at x = 50 cm at time t = 10ms.