A wave of length 2m is superposed on its reflected wave to form a stationary wave. A node is located at x = 3m. The next node will be located at x=

A wave represented by the equation y = a cos(kx - wt) is superposed with another wave to form a stationary wave such that point x= 0 is a node. The equation for the other wave is

A wave representing by the equation y = A cos(kx - omegat) is suerposed with another wave to form a stationary wave such that point x = 0 is a node. The equation for the other wave is

A wave is represented by the equation y = a sin(kx - omega t) is superimposed with another wave to form a stationary wave such that the point x = 0 is a node. Then the equation of other wave is :-

A wave represented by the equation y=acos(kx-omegat) is superposed with another wave to form stationary wave such that the point x=0 is a node. The equation for the other wave is:

At which point of a stationary wave the sound heard is maximum, at the node or the antinode ?

In a stationary longitudinal wave, nodes are points of

When a stationary wave is formed, then its frequency is

A wave represented by a given equation [y (x, t) = a sin (omega t - kx)] superimposes on another wave giving a stationary wave having antinode at x = 0 then the equation of the another wave is

A metallic rod of length 1m is rigidly clamped at its mid point. Longirudinal stationary wave are setup in the rod in such a way that there are two nodes on either side of the midpoint. The amplitude of an antinode is 2 xx 10^(-6) m . Write the equation of motion of a point 2 cm from the midpoint and those of the constituent waves in the rod, (Young,s modulus of the material of the rod = 2 xx 10^(11) Nm^(-2) , density = 8000 kg-m^(-3) ). Both ends are free.

The r.m.s. voltage of the wave form shown is