When a wave travels in a medium, displacement of a particle is given by `y=a"sin"2pi(bt-cx)` , where a, b and c are constant . The maximum particle velocity will be twice the wave velocity , if

When a wave travels in a medium, the particle displacement is given by the equation y=asin 2pi(bt-cx), where a,b and c are constants. The maximum particle velocity will be twice the wave velocity. If

When a wave travels in a medium, the particle displacement is given by, y = psin2 pi (qt - rx), where p, q and r are constants. The maximum particle velocity will be twice the wave velocity if

When a wave transverses in a medium, the displacement of a particle located at distance x at time t is given by y=a sin (bt-cx) where a, b and c are constants of the wave. The dimension of b//c are same as that of:

How does particle velocity differ from wave velocity?

A longitudinal wave is represented by x = x_(0) "sin"2pi("nt" - ("x")/(lambda)) The maximum particle velocity will be four times the wave velocity if

The equation of a simple harmonic wave is given by y = 3 sin"(pi)/(2) (50t - x) where x and y are in meters and x is in second .The ratio of maximum particle velocity to the wave velocity is

The equation of a simple harmonic wave is given by y = 3 sin"(pi)/(2) (50t - x) where x and y are in meters and x is in second .The ratio of maximum particle velocity to the wave velocity is

A progressive wave is represented by y = 5 sin(100pit - 2pix) where x and y are in m and t is in s. The maximum particle velocity is

A transverse wave is described by the equation y=A sin 2pi( nt- x//lambda_0) . The maximum particle velocity is equal to 3 times the wave velocity if

The relation between the particles velocity and wave velocity is -