Stationary waves are set up by the superposition of two waves given by
`y_(1)=0.05sin(5pit-x)` and `y_(2)=0.05sin(5pit+x)`
where x and y are in metres and t is second. Find the displacement of a particle situated at a distance x=1m.

The standing waves are set up by the superimposition of two waves: y_(1)=0.05 sin (15pit-x) and y_(2)=0.05 sin (15pit+x) , where x and y are in metre and t in seconds. Find the displacement of particle at x=0.5m.

A stationary wave is formed by superposition of two waves given by 64.88 y_(1) = 0.02 sin (3pi t - x) and y_(2) = 0.02 sin (3pi t + x) where x, y are in metres and t is in seconds. Determine the displacement of a particle situated at a distance of x = 0.5 m.

Standing waves are produced by superposition of two waves y_(1) = 0.05 sin(3pi t - 2x), y_(2) = 0.05 six(3pi t +2x) where x and y are measured in metre and t in second. Find the amplitude of the particle at x = 0.5m.

Standing waves are produced by the superposition of two waves y_(1)=0.05 sin (3 pit-2x) and y_(2) = 0.05 sin (3pit+2x) Where x and y are in metres and t is in second. What is the amplitude of the particle at x = 0.5 m ? (Given, cos 57. 3 ^(@) = 0. 54)

The equation of a progressive wave is given by y = 0.5 sin (20 x - 400 t) where xand y are in metre and tis in second. The velocity of the wave is

The wave described by y = 0.25 "sin"(10 pi x - 2pit) , where x and y are in metres and t in seconds , is a wave travelling along the:

A wave is represented by the equation, y = 0.1 sin (60 t + 2x) , where x and y are in metres and t is in seconds. This represents a wave