A sinusoidal progressive wave is generated in a string. It's equation is given by `y = (2mm) sin (2 pi x - 100 pi t + pi//3)` The time when particle at `x = 4 m` first passes through mean position, will be :-

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 :-

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

In the equation of motion of waves in x-direction is given by y= 10^(-4) sin(600t-2x+(pi)/(3)) where x and y are in metre and t is in second, then the velocity of wave will be………… ms^(-1) .

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 y=a sin 2 pi//lamda (vt -x) is expression for :-

The equation of normal to y = sin x at ((pi)/(2),1) is ……….

The displacement y of a wave travelling in the x-direction is given by y = 10^(-4) sin ((600t - 2x + (pi)/(3))meters where x is expressed in meters and t in seconds. The speed of the wave-motion, in ms^(-1) , is

A progressive wave on a string having linear mass density rho is represented by y=A sin((2 pi)/(lamda)x-omegat) where y is in mm. Find the total energy (in mu J ) passing through origin from t=0 to t=(pi)/(2 omega) . [Take : rho = 3 xx 10^(-2) kg//m , A = 1mm , omega = 100 rad..sec , lamda = 16 cm ].