A wave is given by the equation
` y = 10 sin 2 pi (100 t - 0.02 x) + 10 sin 2 pi (100 t + 0.02 x)`
Find the loop length , frequency , velocity and maximum amplitude of the stationary wave produced.

A plane progressive wave is represented by the equation y= 0.25 cos (2 pi t - 2 pi x) The equation of a wave is with double the amplitude and half frequency but travelling in the opposite direction will be :-

A transverse wave is derscried by the equation y=y_(0) sin 2 pi (ft - (x)/(lamda)) . The maximum particle velocity is equal to four times the wave velocity if :-

The equation sin x + sin y + sin z = -3 for 0le x le2pi, 0le y le 2pi, 0le z le 2pi has

Velocity of a wave y = 10 ^(-4) sin (100 t - (x)/(10)) m is …...m/s

One string wave is given by y (x,y) =0.1 sin {pi(5x-2t)} with all the values in SI units. Find (a) amplitude (b) wave length (c ) periodic time, frequency and displacement of this wave at x=3 m and t=2s.

Two mechanical waves, y_(1) = 2 sin 2 pi (5- t - 2x) & y_(2) = 4 sin 2 pi(fax + 100 t) propagate in a medium with same speed.

Two simple harmonic motion are represented by the equation y_(1)= 0.1 sin(100 pi t+(pi)/(3)) and y_(2)= 0.1 cos pi t . The phase difference of the velocity of particle-1 with respect to the velocity of particle-2 is…………

The equation of simple harmonic is as following y(t) = 10 sin (20t+ 45^(@)) . Find the amplitude of SHM.

in the given progressive wave y = 5 sin (100 pi t -0.4 pi x) where y and x are in metre, t is in second. What is the (a) amplitude (b) wave length (c) frequency (d) wave velocity (e) particle velocity amplitude,

A string of length 1 m fixed one end and on the other end a block of mass M = 4 kg is suspended. The string is set into vibration and represented by equation y =6 sin ((pi x)/(10)) cos (100 pi t) where x and y are in cm and t is in seconds. (i) Find the number of loops formed in the string. (ii) Find the maximum displacement of a point at x = 5//3 cm (iii) Calculate the maximum kinetic energy of the string. (iv) Write down the equations of the component waves whose superposition given the wave. .