A transverse sinusoidal wave is generted at one end of long, horizontal string by a bar that moves up and down through a distance of `1.00 cm`. The motion is continuous and is repreated regularly `120` times per second. The string has linear density `90 gm//m` and is kept under a tension of `900 N`. Find :
The maximum value of the transverse component of the tension (in newton)

A transverse sinusoidal wave is generted at one end of long, horizontal string by a bar that moves up and down through a distance of 1.00 cm . The motion is continuous and is repreated regularly 120 times per second. The string has linear density 90 gm//m and is kept under a tension of 900 N . Find : What is the maximum power (in watt) transferred along the string.

A transverse sinusoidal wave is generted at one end of long, horizontal string by a bar that moves up and down through a distance of 1.00 cm . The motion is continuous and is repreated regularly 120 times per second. The string has linear density 90 gm//m and is kept under a tension of 900 N . Find : What is the transverse displacement y (in cm ) when the minimum power transfer occurs [Leave the answer in terms of pi wherever it occurs]

A transverse sinusoidal wave is generated at one end of a long horizontal string by a bar that moves the end up and down through a distance by 2.0 cm . the motion of bar is continuous and is repeated regularly 125 times per second. If klthe distance between adjacent wave crests is observed to be 15.6 cm and the wave is moving along positive x- direction, and at t=0 the element of the string at x=0 is at mean position y =0 and is moving downward, the equation of the wave is best described by

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.

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).

A transverse wave propagating on the string can be described by the equation y=2sin(10x+300t) where x and y are in metres and t in second.If the vibrating string has linear density of 0.6times10^(-3)g/cm ,then the tension in the string is